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<body><div id='divhlpmain'><sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Data Module<br>
</font></b><font size="2">Overview<br>
</font><font size="3"><br>
<font size="2">The data module is designed for easy, rapid generation of vehicle system models. The <b><font size="3"><br>
</font></b></font></font><font size="2">The data module allows the user to enter data, read in or save models, create new models and adjust data in existing models.<br>
<br>
Icons representing the various vehicle-powertrain subsystems allow the user to view the data for that section of the model and adjust, add or delete data from the model. Graphical features allow the user to view the results of changes to the specific data-set and adjust data as fit. <br>
</font><br>
The vehicle system model sub-components and relevant icons are:<br>
<br>
<u><b><u>Vehicle</u></b></u><b></b> Data<br>
<b><br>
</b>Dyno<b></b> Data<br>
<b><br>
</b>Tyre<b></b> Data<br>
<b><br>
</b>Driveline<b></b> Data<br>
<b><br>
</b>Gearbox<b></b> Data<br>
<b><br>
</b>Engine<b></b> Data<br>
<b><br>
</b>Hybrid Drive System<b></b> Data<br>
<b><br>
</b>Driver<b></b> Data<br>
<br>
When an icon is selected the relevant data entry window is displayed with various vehicle and powertrain parameters available for editing. A more complete explanation of each of the model sub-sections is available, eg. See Vehicle Data.<br>
<br>
When the user is satisfied with the model it can be saved using the save or save-as icons in the main window toolbar. This will write the model as a <b>*.car file. <br>
<br>
</b>Additional advanced data sections are also used as subsets of these major data sections.<b><br>
</b><font size="3"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font size="4">The *.CAR File<br>
</font><font size="2"><br>
<br>
The *.car file is an ASCII text format file which contains the complete model specification. It is arranged in a logical format with a section for each of the vehicle subsystems. The example below presents a typical *.car file, in this case a model of a Lotus Esprit racing car :<br>
<br>
</font><font face="Times New Roman"><font size="1">esprit cardat file<br>
race esprit 400 hp<br>
erace 206<br>
VEHICLE<br>
1200.<br>
1.770 0.3700 1.900 -0.2530 -0.3030<br>
1.205<br>
2.438 1.533 1.624 1.414 0.4000<br>
</font></font>TYRE<br>
0.3146<br>
2 1.400 0.9500<br>
10.00 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00<br>
DRIVE<br>
2<br>
0.7385 0.7385<br>
0.0000E+00 0.0000E+00<br>
3.500 0.9700 2<br>
GEARBOX<br>
5 0.2000 0.0000E+00 2<br>
3.363 0.9800 0.1000E-02<br>
2.059 0.9700 0.1000E-02<br>
1.387 0.9700 0.1000E-02<br>
1.037 0.9700 0.1000E-02<br>
0.8205 0.9700 0.1000E-02<br>
GSHIFT<br>
1<br>
acc<br>
1 0 1<br>
1.000<br>
0.0000E+00 7400.<br>
0.0000E+00 7400.<br>
0.0000E+00 7400.<br>
0.0000E+00 7400.<br>
0.0000E+00 7400.<br>
2 0<br>
CLUTCH<br>
1 1.000<br>
PDRIVE<br>
1.000 1.000 2<br>
ENGINE<br>
1<br>
102.0 102.2 10.00 4 4 0.0000E+00<br>
1000. 7500.<br>
10<br>
1000. 7.000<br>
2000. 12.40<br>
2500. 18.20<br>
3000. 18.90<br>
3900. 20.50<br>
5000. 18.80<br>
6000. 17.80<br>
6500. 16.78<br>
7000. 15.10<br>
7500. 13.20<br>
DRIVER<br>
0.9000 0.8000 0.6000 0.0000E+00 0.0000E+00 0<br>
<font face="Arial"><font size="2"><br>
This illustrates how the data is split into obvious sections eg. VEHICLE, TYRE, DRIVE, ENGINE, GSHIFT (for shift-strategy), etc. A model is constructed using any of the file sub-sections listed here:<br>
<br>
</font></font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">VEHICLE &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">DYNO<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">TYRE&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">DRIVETRAIN&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">GEARBOX&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">GLOSS<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">GSHIFT<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">TORQUE CONVERTER<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">CLUTCH<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">ENGINE&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">ENG_SCALE<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">MAP<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">OPTIMUM<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">CATALYST<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">WARM-UP<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">AUXILLARIES<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">PDRIVE<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">GRID<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">HYBRID<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">DRIVER<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">AERODYNAMICS<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">HYBPOWER<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">HYBLOSS<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">HYBBATTERY<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">HYBCONTROL<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">XTYRE<br>
</font></font></span><br>
A working LOTUS VEHICLE SIMULATION model must include at least those sub-components marked with <br>
The user is able to create *.car files using the text editor available in the <font face="Times New Roman"><b><font face="Arial">File</font></b></font><font face="Times New Roman"><b></b></font> menu-bar, though the LOTUS VEHICLE SIMULATION user interface makes this approach relatively inefficient. In the following sections that explain the details of each data sub-section, reference is given to the correct format for the text components of that part of the *.car file.<br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">How to Create a Model<br>
</font></b><font size="3"><br>
</font><font size="2">To create a new model, select the <u>file new icon</u></font><b> </b>at the far left of the main window tool-bar or <b><u>File / New</u></b> from the menu-bar. The user is prompted to confirm this action since any current data will be lost. If this is done a new untitled model is created and the user is free to begin entering data.<br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">How to Load a Model<br>
</font></b><font size="2"><br>
<font face="Arial">To load a previously created model or one of the supplied examples, select the <u>file open icon</u></font></font> from the main window tool-bar or the <b><u>File/Open</u></b> menu from the menu-bar. This brings up the standard windows file-browser.<b><font size="3"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font></b><font size="4">How to Save a Model<br>
</font><font size="2"><br>
To save a model, select the <u>file save icon</u></font> from the main window tool-bar or the menu-bar option <b><u>File/Save</u></b>. If no change has been made to the model, this automatically brings up the browser to add a new file-name. Otherwise the file is overwritten.<br>
<br>
To save the current model unchanged or otherwise, select <b><u>File/Save As</u></b> from the menu-bar or the <u>file save as</u> from the main window tool-bar. This will automatically bring up the browser and prompt the user to enter a new filename. If the same or another used filename is entered the user is prompted to accept overwriting of that file.<b><font size="3"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup></font></b><sup>#</sup><font size="4">How to Change a Variable<br>
</font><font size="2"><br>
To change a variable in any of the data windows, use the mouse or tab key to select the relevant value box, and type in the new number.<br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><b><font size="4">How to Change an Option<br>
</font></b><font size="2"><br>
To change an option, for instance the type of drive layout (<b><u>Data/Drive/Final Drive)</u></b></font>, use the mouse to select the arrow at the right of the display box. This presents the available options and allows selection from the list.<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">How to Use Spreadsheets<br>
</font></b><font size="2"><br>
To manipulate data in a spreadsheet, for instance in an engine map (<b><u>Data/Engine/Engine Maps</u></b></font>), first ensure that a map is available. If not select <b><u>Option/On</u></b> and enter the required number of loads and speeds. <br>
<br>
To copy a section of data, drag the pointer across the section and with the area highlighted, press the right button. This calls a <b>pointer pop-down menu </b>to access the <b>copy</b> option. Then moving to the desired cell, select it and repeat the menu selection procedure choosing<b> paste</b>. <b><font size="3"><br>
</font></b><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><font size="4">How to Create a Detailed Hybrid Model<br>
</font><font size="2"><br>
Lotus Vehicle Simulation contains two levels to which a 'Hybrid' vehicle can be modelled. <br>
<br>
At the <u>simple level</u></font> it consists of a conventionally defined vehicle model with the hybrid portion providing a simple energy storage model. This simple model provides limited functionality acting as a 'range extender' with settings for its minimum and maximum storage capacity its charge / discharge efficiency and the maximum input and output torque's. Whilst this level provides an insight into the possible benefits of a hybrid vehicle the model detail is not adequate for a in-depth study of hybrid component matching.<br>
<br>
The <u>extended level</u> allows the individual hybrid components to be defined in detail including, a thermal model, <u>efficiency map</u> and performance envelope. A <u>control strategy</u> is also defined that controls target levels of battery charge, auxiliary power unit (APU) shutdown, allowable rate of change in speed of the APU, the aggressiveness of the charging regime and a time history smoothing function. <br>
<br>
The components available within the extended hybrid model are;<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
APU Generator<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Drive Motor<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Drive Regenerator<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Battery<br>
<br>
To build an extended hybrid model a number of the conventional vehicle data modules are used as well as the unique hybrid data sections this provides for the greatest flexibility in defining a hybrid vehicle.<br>
<br>
The engine data sections are used to define the IC engine that drives the APU generator, thus the data sections for performance, maps, catalyst, warm up, etc. are applicable and can be used in any hybrid simulation.<br>
<br>
The 'primary drive' data section can also be used with hybrid models the output from which is taken as the input speed to the APU generator.<br>
<br>
The 'Gearbox' should be defined as a single speed manual transmission, (normally 1:1 ratio), this does not provide a connection between the APU and the final drive, since the hybrid model is currently restricted to a 'Series Hybrid', but is required to pass the data checking routines and avoid the gear shift strategies being employed.<br>
<br>
The final drive module is used, the drive motor and drive regenerator hybrid components being connected to the input of the final drive.<br>
<br>
The hybrid components themselves are defined via the four data windows associated with the extended hybrid model that specifiy, the component performance, the component efficiencies, the battery charge/discharge voltage model and the hybrid control strategy. Some of the components are optional, (i.e. the drive regenerator), and some components have different levels of data definition, (i.e. from single fixed value to full 2D map).<br>
<br>
<b><font size="3"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font></b><font size="4">Vehicle Data - Variables</font><font size="3"><br>
</font><font size="2"><br>
This window is accessed using the <u><b><u>Vehicle icon</u></b></u></font><b></b> on the tool bar or through the <b>Data/Vehicle</b> option from the pull-down menus. This section is concerned with the *.car file titles, the calculation run number and the basic vehicle dimensions.<br>
<br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<b><span style="font-size:11pt">Title Variables</span></b><font size="2"><br>
<br>
</font><b>Main Title</b> (80 characters max.)<br>
<b>Secondary Title</b> (80 characters max.)<font size="3"><br>
<b><font size="2">Test Number </font></b></font>(80 characters max.)<br>
<b>Results Counter</b> (integer)<font size="3"><br>
</font><b><font size="2"><br>
<span style="font-size:11pt">Vehicle Variables<font size="2"><br>
<br>
</font></span></font></b>Test Weight (kg) - Total weight including occupants<br>
<b>Wheelbase (m) - </b>Vehicle wheelbase from front to rear wheels<br>
<b>Front Track (m) - </b>Vehicle track for cornering calculations<br>
<b>Rear Track (m) - </b>Vehicle track for cornering calculations<br>
<b>D.C.o.G (m) - </b>Distance of centre of gravity from front wheels<br>
<b>H.C.o.G (m) - </b>Height of centre of gravity above the ground<br>
<b>Frontal area (m2) </b> Vehicle frontal area<b><br>
Drag coefficient -</b> Vehicle drag coefficient<br>
<b>Plan area (m2) -</b> required for aerodynamic pitching moments<br>
<b>Front lift Coeff - </b>Vehicle aerodynamic front lift coefficient<font size="3"><br>
<b><font size="2">Rear Lift Coeff -</font></b></font> Vehicle aerodynamic rear lift coefficient<br>
<b>Air Density (kg/m3) - </b> Ambient air density<br>
<br>
To view a diagrammatic representation of these variables, select the graphics icon at the top right of the vehicle window.<br>
<br>
The vehicle data values for <font face="Times New Roman"><font face="Arial">drag coefficient</font></font><font face="Times New Roman"><font face="Arial">, </font></font><font face="Times New Roman"><font face="Arial">front lift coefficient</font></font><font face="Times New Roman"><font face="Arial"> and </font></font><font face="Times New Roman"><font face="Arial">rear lift coefficient</font></font><font face="Times New Roman"><font face="Arial"> can also be defined as non-linear functions using the <u>extended aerodynamic</u></font></font> data option.<br>
<br>
{button ,AL(`list10',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Dynamometer Data - Variables<br>
</font></b><font size="2"><br>
This window is accessed using the <u><b><u>Dyno icon</u></b></u></font><b></b> on the tool bar or through the <b>Data/Dynamometer </b>option from the pull-down menus. The section is concerned with the load vs. vehicle speed relationship applied by a chassis dynamometer if the vehicle is to be simulated as running on this type of test-bed - useful for correlation between measured emissions testing and simulation. <br>
<br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
To select a dynamometer model to be included in the simulation, select <b>on</b> from the options list in the dyno window. To remove select <b>off</b>. To derive a curve based on the input vehicle and tyre data, select <b>derive</b>. This will automatically calculation values for the variables described below, though the user is free to adjust these as desired.<br>
<br>
<b><span style="font-size:11pt">Chassis Dyno Variables<br>
</span></b><font size="2"><br>
</font><b>Inertia Class - </b>Dyno Effective Mass - Inertia (Kg)<b><br>
<span style="font-size:11pt"><br>
</span></b><font size="2">Three curve fitting constants - </font>Define the chassis dyno load at the roller periphery via the form - <i>Brake Force = A + B.V + C.V2</i><b><br>
</b><br>
A - Brake Constant (N)<br>
<b>B - </b>Brake Constant (N/m/s) <br>
<b>C - </b>Brake Constant (N/(ms)2)<b><br>
</b><br>
To view the calculated characteristic load vs. vehicle speed relationship based on the input variables, select the graphics icon at the top right of the dyno window. The graphics window pull down menu provides access to options such as autoscaling (To bring the axes scales within the boundaries of the curve), zoom functions and printing.<br>
<br>
{button ,AL(`list10',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<b><font size="3"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font></b><font size="4">Tyre Data - Variables<br>
</font><font size="3"><br>
</font><font size="2">This window is accessed using the <u><b><u>Tyre icon</u></b></u></font><b></b> on the tool bar or through the <b>Data/Tyre</b> option from the pull-down menus. The tyre window is concerned with the load vs. vehicle speed relationship for tyre rolling resistance and the definition of tyre rolling radius and efficiency.<br>
<br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
The tyre model is a pre-requisite of the simulation and hence cannot be switched off. To select default Lotus values for the tyre rolling resistance curve coefficients select from the tyre data menubar the <u>CopyData</u> / <u>Set Rolling Resistance to Default Values</u>. <br>
<br>
The tyre data can be defined for both front and rear tyres separately or as a common tyre. Select the required setting from the options presented. Selecting <b>common</b> will display the data currently stored that will be used for both front and rear. Selecting either <b>front</b> or <b>rear</b> will display the data to be used for that particular tyre. With either <b>front</b> or <b>rear</b> selected this implies that the data stored for <b>common</b> is ignored, and the required data must be provided for both front and rear tyres.<br>
<br>
The common tyre data values can be copied into the currently displayed 'front' or 'rear' tyre using the menu option <u>CopyData</u> / <u>Tyre Data from Common</u>.<br>
<u> </u> <br>
The tyre data window menubar option <u>Extended</u> / <u>Tyre</u> opens the <u>extended tyre model data window</u>, that provides the option of a non-linear definition for the rolling radius.<br>
<br>
The tyre rolling resistance coefficients can be edited using the spline list and edit function that is available through either the menu option <u>List</u> / <u>Tyre Spline</u> or the <u>spline edit icon</u>. This provides a tool for listing and editing the spline in different units, any changes can be saved back in to the tyre data window in the correct units.<br>
<br>
<b><span style="font-size:11pt">Tyre Variables<br>
</span></b><font size="2"><br>
</font><b>Rolling Radius (m) - </b>Note: using the tyre unloaded radius is an approximation - more sophisticated approaches are possible (eg. See European Tyre and Rim Technical Organisation documentation supplied). To define a non-linear rolling radius refer to the <u>extended tyre model</u><br>
<b>Drive Efficiency (0-1) - </b>Tyre transmission efficiency - typically ~ 0.95<br>
<b>Coefficient of Slip () - </b> Coefficient of friction between the tyre and the road. Typically in the range 0.8 - 1.15. Related to tyres resistance to wheel-spin/slip<br>
<b>Rolling Resistance Coefficient (N/1000N) - Three curve fitting constants - </b>Define the tyre rolling resistance via a curve-fitted polynomial of the form - <i>Tyre Rolling Resistance Coefficient = (Constant) + (V Coefficient).V + (V2 Coefficient).V2 + (V3 Coefficient).V3 + (V4 Coefficient).V4 + (V5 Coefficient).V5</i><b><br>
</b><br>
Constant<br>
V Coefficient <br>
<b>V2 Coefficient<br>
V3 Coefficient<br>
V4 Coefficient<br>
V5 Coefficient<br>
</b><br>
{button ,AL(`list10',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<b><font size="3"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font></b><font size="4">Driveline Data - Introduction<br>
</font><font size="3"><br>
</font><font size="2">This window is accessed using the <u><b><u>Driveline icon</u></b></u></font><b></b> on the tool bar or through the <b>Data/Driveline</b> option from the pull-down menus. This action will call into view the <b>driveline sub-menu</b> which provides access to the various driveline data-windows as listed below :<br>
<br>
<u><b>Torque Converter/Clutch</b></u><b> -</b> Options for torque converters and clutches<b><br>
<u>Torque Converter Lock-up</u></b><b> - </b>Definition of torque converter lock-up characteristics<b><br>
<u>Torque Converter Idle</u></b><b> -</b> Definition of torque converter idle strategy<b><br>
<u>Final Drive</u></b><b> - </b>Specification of final drive system, system inertia<font face="Times New Roman"><font face="Arial">s, transmission efficiencies and drive ratio.<span style="font-size:9pt"><br>
</span></font></font><font size="2"><br>
This data can also be entered directly into the <u><b>*.car file</b></u></font><b></b> through the available text editor.<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></b><font size="4">Torque Converter / Clutch<br>
</font><font size="2"><br>
This window is accessed using the <u><b><u>Driveline icon</u></b></u></font><b></b> on the tool bar or through the <b>Data/Driveline</b> option from the pull-down menus, and then selected <b>TC/Clutch</b> from the <b>Driveline sub-menu</b>.<br>
<br>
The TC/Clutch window provides the user with the facility to specify the type of drive coupling. Currently LOTUS VEHICLE SIMULATION supports models of common Clutches and Torque Converters. <br>
<br>
<b>Selecting Coupling Type</b><br>
<br>
To switch between clutch and torque converter, select <font face="Times New Roman"><b><font face="Arial">Options</font></b></font><font face="Times New Roman"><b></b></font> and choose between the two available options. Switching from clutch to torque converter will activate the Torque Converter spreadsheets and data boxes. Switching back to clutch will disable these features. <br>
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<b>Using a Clutch Model</b><br>
<br>
To use a clutch, select <b><font face="Arial">clutch</font></b><font face="Times New Roman"><b></b></font> from the <b><font face="Arial">options</font></b><font face="Times New Roman"><b></b></font> menu. The clutch model has a single data variable, <b><font face="Arial">Declutch Speed</font></b><font face="Times New Roman"><b></b></font> (km/h).<br>
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This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<b>Torque Converters, Fluid Coupling or Torque Multiplier</b><br>
<br>
A torque converter is a standard coupling system for modern automatic transmissions. It is sometimes referred to as a <font face="Arial">Fluid Coupling</font><font face="Times New Roman"><font face="Arial"> or Torque Multiplier.<br>
</font></font><br>
<b>Using a Torque Converter</b><br>
<br>
To use a torque converter model, select <font face="Times New Roman"><b><font face="Arial">Torque Converter</font></b></font><font face="Times New Roman"><b></b></font> from the <b><font face="Arial">Options</font></b><font face="Times New Roman"><b></b></font> pop-down menu. This activates the torque converter data entry boxes and spreadsheet.<br>
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<b>Torque Converter Data</b><br>
<br>
Various data entries are used to model the torque converter characteristics :<b><span style="font-size:11pt"><br>
<br>
<font size="2">Number of Speed Ratios</font></span></b> : The number of points over which the torque converter is modelled. (Up to 20 points)<br>
<b>Spreadsheet</b> : A spreadsheet for data entry of speed ratios, torque ratios and input capacity.<br>
<b>Spreadsheet Data Variables</b> :<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>Speed Ratio</b> = Output Speed / Input Speed<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>Torque Ratio</b> = Output Torque / Input Torque<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>Input Capacity (Rad/s/Torque)</b> = Torque converter input capacity at this speed ratio<br>
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This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
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<b>Torque Converter Calculations</b><br>
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After adjustment of the variables the user must select <b><font face="Arial">Update</font></b><font face="Times New Roman"><b></b></font> to display the re-calculated estimates for stall speed and stall torque.<br>
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<b>Graphical Display of Torque Converter Characteristics <br>
</b><br>
To display the torque converter characteristic curves, select the <u><b><u>Graph Icon</u></b></u><b></b> from the top right of the window. This includes functions for autoscaling, zoom, printing and data-picking accessed from the pull-down menu at the top right of the graph display window.<b><span style="font-size:11pt"><br>
</span></b><font size="2"><br>
<b>Factoring a Torque Converter Characteristic Curve</b></font><br>
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The user is able to apply speed and load factors to the torque converter curve, by using the <b><font face="Arial">Factor</font></b><font face="Times New Roman"><b></b></font> menu-bar pull down menu . Both speed factoring and load factors are available. The user is prompted to enter a factor as a ratio of 1. <br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font></b><font size="4">Torque Converter Lock-up<br>
</font><font size="3"><br>
</font><font size="2">The torque converter lock-up window is accessed from the <b>Driveline</b></font> menu selected by clicking the <u><b><u>Driveline icon</u></b></u><b></b> in the data icons tool-bar or selecting <b>Driveline</b> from the main window menu-bar pull down menu <b>Data</b>.<br>
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The window is used to create or modify and existing torque converter lock-up strategy. Lock-up does not have to be incorporated when using a torque converter but modern automatic transmission typically employ some lock-up strategy to improve efficiency.<br>
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This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
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<b>Using a Lock-Up Strategy</b><br>
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To activate the lock-up model, select <b><font face="Arial">On</font></b><font face="Times New Roman"><b><font face="Arial"> </font></b></font>from the <font face="Times New Roman"><b><font face="Arial">Options</font></b></font><font face="Times New Roman"><b></b></font> pop-down menu in the Lock-up window. This activates the data entry boxes and spreadsheet.<br>
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The lock-up strategy is defined as a set of lock-on and lock-off points defined in terms of any <b>map variable </b>vs. speed (Various speed variables are available) for a range or torque fractions (up to 10).<br>
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<b>Lock-Up Data</b><br>
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The lock-up strategy is defined using the following variables :<br>
<b><br>
</b>Load Units : The units used to define the load fraction. This can simply load fraction, or alternatively, any of the map variables specified at the <b><font face="Arial">engine map data</font></b><font face="Times New Roman"><b></b></font> window. Note : If the load unit chosen relates to a map undefined, the system will not operate correctly.<br>
<b>Speed Units</b> :The units used to define the speed variable. Four are presently available : <br>
<b>1. Engine Speed (RPM)<br>
2. Propshaft Speed (RPM)<br>
3. Road Speed (MPH)<br>
4. Road Speed (KMH)</b><br>
<b>Load Fraction </b>: The load fraction for the currently displayed set of lock points. To add a fraction use the <b><font face="Arial">Functions</font></b><font face="Times New Roman"><b></b></font> pull-down menu at the top right of the window.<br>
<b>Spreadsheet</b> : A spreadsheet is used to define the lock points<br>
<b>Lock-Up</b> : Speed at which lock-up occurs when load is equals load fraction displayed.<br>
<b>Lock-Off</b> : Speed at which lock-off occurs when load is equals load fraction displayed.<br>
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<b>Adding a Load Fraction in the Torque Converter Lock-Up Window</b><br>
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To initially add fractions or add a load fraction to an existing set of torque converter lock-up data, use the <b><font face="Arial">Functions</font></b><font face="Times New Roman"><b></b></font> pull-down menu at the top left of the window.<br>
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<b>Deleting a Load Fraction in the Torque Converter Lock-Up Window</b><br>
<b><br>
</b>To delete load fractions from an existing set of torque converter lock-up data, use the <b><font face="Arial">Functions</font></b><font face="Times New Roman"><b></b></font> pull-down menu at the top left of the window.<br>
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<b>Inserting an Extra Load Fraction in the Torque Converter Lock-Up Window</b><br>
<b><br>
</b>To insert a load fractions into an existing set of torque converter lock-up data, use the <b><font face="Arial">Functions</font></b><font face="Times New Roman"><b></b></font> pull-down menu at the top left of the window. A new load fraction map is inserted ahead of the load fraction visible when the insertion is carried out.<br>
<b><br>
Displaying the TC Lock-Up Data Graphically</b><br>
<br>
To view the torque converter lock map graphically, select the <u><b><u>Graphic Icon</u></b></u><b></b> at the top-right of the torque converter Lock Up Window. The graphics window includes features for autoscaling, zoom, data-pick and printing, accessed using the pull-down menu at the top left of the graphics window.<b><br>
</b><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></b><font size="4">Torque Converter Idle<br>
</font><font size="2"><br>
</font>The <font face="Arial">Torque Converter Idle</font><font face="Times New Roman"><font face="Arial"> window is accessed from the <b>Driveline</b></font></font> menu selected by clicking the <u><b><u>Driveline icon</u></b></u><b></b> in the data icons tool-bar or selecting <b>Driveline</b> from the main window menu-bar pull down menu <b>Data</b>.<br>
<br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
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The window is used to set the torque idle strategy. This is concerned with the operation of the Torque Converter during periods of zero power transmission. There are three options accessed using the <font face="Times New Roman"><b><font face="Arial">Idle Mode</font></b></font><font face="Times New Roman"><b><font face="Arial"> </font></b></font>pop-down menu in the window :<br>
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<b>Normal Idle</b> : Gearbox remains in drive<br>
<b>Full Neutral Idle</b> : Gearbox in neutral and hence no drag torque on the engine <br>
<b>Semi-Neutral Idle</b> : Gearbox in a <font face="Times New Roman"><font face="Arial">semi-neutral</font></font><font face="Times New Roman"><font face="Arial"> mode where there exists some speed ratio between the engine and converter input and output speed. In this mode the user enters data in the </font></font><font face="Times New Roman"><b><font face="Arial">Speed Ratio</font></b></font><font face="Times New Roman"><b></b></font> data box.<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></b><font size="4">Final Drive<br>
</font><font size="2"><br>
The </font><font face="Arial">Final Drive Data</font><font face="Times New Roman"><font face="Arial"> window is accessed from the <b>Driveline</b></font></font> menu selected by clicking the <u><b><u>Driveline icon</u></b></u><b></b> in the data icons tool-bar or selecting <b>Driveline</b> from the main window menu-bar pull down menu <b>Data</b>.<br>
<br>
The window is used to enter and modify the specification of the final drive/transmission system. The user is able to specify the drive layout, the inertia<font face="Times New Roman"><font face="Arial">s of the main rotating components and the transmission ratio and efficiencies.<br>
</font></font><br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<b>Final Drive Data Variables</b><br>
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The following data is available for editing by the user : <br>
<br>
<b>Drive Type</b> : The user may select between :<br>
<b>1. Front Wheel Drive<br>
2. Rear Wheel Drive</b><br>
<b>3. Four Wheel Drive<br>
</b><br>
<b>Front and Rear Wheel Inertia (kg.m2)</b> : The combined inertia of the wheel, tyre and rotating brakes etc. These are for a single wheel. Two wheels are assumed to be fitted.<br>
<b>Drive Shaft Inertia (kg.m2)</b> : The rotary inertia of the axle/drive shaft. This is the total inertia if two drive shafts are fitted.<br>
<b>Prop Shaft Inertia (kg.m2)</b> : Total rotary inertia of the prop shaft. If not fitted, set to zero.<br>
<b>Final Drive Ratio<br>
Final Drive Efficiency (0-1)</b> : Maximum efficiency of the final drive used by transmission efficiency calculations. <br>
<b>Final Drive Efficiency Mode</b> : The user may choose between two different efficiency models :<br>
<b>1. Efficiency fixed to maximum (entered value)<br>
2. Efficiency modelled as a function of speed and load</b><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></b><font size="4">Gearbox Data - Introduction</font><font size="3"><br>
</font><font size="2"><br>
The powertrain systems are connected to the vehicle final drive via the gearbox system. To enter or review data for the gearbox, select the <u><b><u>Gearbox Icon</u></b></u></font><b></b> from the icon panel. Alternatively, select <u>Data / Gearbox</u> from the main window menu bar or press <b>F5</b>. <br>
<br>
This brings up the gearbox menu from which the user can select from the following sub-window options:<br>
<br>
<u><b>Specification</b></u><b> </b>: where gearbox transmission type and ratios are entered<br>
<u><b>Gear Losses</b></u><b></b> : to enter detailed information on the system efficiency<br>
<u><b>Shift Strategy</b></u><b></b> : to enter information on the system operating strategy<br>
<u><b>Cascade</b></u><b></b> : to display a graphical representation of the drive force vs. Vehicle speed and road load<br>
<u><b>Gradability</b></u><b></b> : A calculation tool to assess the vehicle<font face="Times New Roman"><font face="Arial">s capabilities on inclines.<br>
</font></font><u><b>Max. Speed</b></u><b></b> : A similar tool to assess the Vehicle system<font face="Times New Roman"><font face="Arial">s maximum speed<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Gearbox Specification</font></b><font size="3"><br>
</font><font size="2"><br>
This display allows the user to review the gearbox ratios, efficiencies and inertia</font><font face="Times New Roman"><font face="Arial">s and other system variables.<br>
<br>
To access the gearbox specification window, select <b>Gearbox Specification </b></font></font>from the <b>Gearbox </b>sub-menu assessed from the Icon panel or main window drop down menu.<br>
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This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
The window displays the following data entry sections:<br>
<br>
<b>Number of Ratios<br>
</b><br>
This specifies the number of ratios in the transmission. To initially set the number change the number from zero to the required number of ratios. This activates the spreadsheet and allows entry of data for each ratio.<br>
<br>
To increase the number increase the number of ratios in the data box. This will add the required number to the bottom of the spreadsheet. To reduce the number repeat the process with the new number and those ratios above this will be greyed out.<br>
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<b>Maximum Gearbox Input Torque<br>
<br>
</b>This sets the maximum gearbox input torque. This is used by the gearbox efficiency calculations. If 0.0 is used, the calculation uses engine maximum torque.<br>
<b><br>
Maximum Gearbox Input Speed<br>
<br>
</b>This sets the gearbox maximum input speed. This is used by the gearbox efficiency calculations. If 0.0 is used, the calculation uses engine maximum speed.<br>
<b><br>
Gearbox Efficiency Model<br>
<br>
</b>This pop-down menu sets the model used to calculate the gearbox efficiency. Two options are presently available :<br>
<br>
<b>Fixed</b> : using the specified efficiency for each ratio<br>
<b>Function</b> : defining efficiency as a function of speed and load - using Lotus developed models.<br>
<b><br>
System Data Spreadsheet</b><br>
<br>
The spreadsheet is used to enter data for the characteristics of each gear ratio. The number of ratios in the model is set using the gearbox <font face="Times New Roman"><font face="Arial">number of ratios</font></font><font face="Times New Roman"><font face="Arial"> data box. <br>
<br>
The three variables for each gear are as follows:<br>
<br>
</font></font><b>Ratio</b> : Specifies the ratio of input to output speed for each ratio.<b><br>
Efficiency</b> : Specifies the efficiency of each ratio as a fraction of 1.0.<b><br>
Inertia</b> : Specifies the rotational inertia of each ratio (kg.m2)<br>
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<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Gear Losses</font></b></font><font size="3"><br>
</font><font size="2"><br>
This window displays the specified gear loss curves if entered by the user. The losses are described as curves for torque loss in Nm vs. gearbox input speed (rpm) for each of up to 10 torque fractions (assumed to be the engine torque fraction) and for each gear specified in the model.<br>
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This data can also be entered directly into the <u><b>*.car file</b></u></font><b></b> through the available text editor.<br>
<br>
The data variables are summarised below :<br>
<br>
<b>Gear Loss Map Title</b> - Users notes<br>
<b>Number of Gear Loss Speeds</b> - Maximum if 20<br>
<b>Number of Torque Fractions</b> - Maximum of 10<br>
<b>Torque Fractions (0-1.0)</b>- Up to the number of fractions specified. These are assumed to be the engine torque fraction<br>
<b>Gearbox input speeds (rpm) </b>- for each gear at each torque fraction<br>
<b>Gearbox torque loss (Nm)</b> - for each gear and speed at each torque fraction <br>
<br>
<b>Switching On the Gear Losses System</b><br>
<br>
To enter data for the gear losses, switch the spreadsheet and associated data entry boxes by selecting <font face="Times New Roman"><b><font face="Arial">on</font></b></font><font face="Times New Roman"><b><font face="Arial"> </font></b></font>from the <b>options </b>pop-up menu (Note that the user must have already specified the gearbox specification).<br>
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<b>Entering Gear Loss Data for the First Time in a Model</b><br>
<br>
After switching the loss spreadsheet on, the user must first select a gear for which data is to be entered. This is done by pressing the right arrow in the <font face="Times New Roman"><font face="Arial">gear number</font></font><font face="Times New Roman"><font face="Arial"> window. The display should then display </font></font><font face="Times New Roman"><font face="Arial">1 of </font></font><font face="Times New Roman"><font face="Arial">N</font></font><font face="Times New Roman"><font face="Arial"> </font></font><font face="Times New Roman"><font face="Arial"> where </font></font><font face="Times New Roman"><font face="Arial">N</font></font><font face="Times New Roman"><font face="Arial"> is the number of gears in the model.<br>
</font></font><br>
The number of speeds for which the currently displayed gear is to have loss data entered for is then entered in the adjacent data window. This will then permit data to be entered for the loss fractions.<br>
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<b>Adding Gear Loss Load Fractions</b><br>
<br>
Add the first load fraction by selecting <font face="Times New Roman"><b><font face="Arial">Add Fraction</font></b></font><font face="Times New Roman"><b></b></font> from the pull-down menu in the top left. The user can modify the absolute value of this fraction by changing the displayed fraction in the data box at the bottom left of the window. To add additional fractions select this <b><font face="Arial">Add Fraction</font></b><font face="Times New Roman"><b></b></font> until the required number of fractions is reached. <br>
<br>
<b>Inserting Gear Loss Fractions</b><br>
<br>
To insert additional fractions to a gear loss dataset, select <b><font face="Arial">Insert Fraction</font></b><font face="Times New Roman"><b><font face="Arial"> </font></b></font>from the pull-down menu. A fraction will be inserted before the currently displayed fraction and the other fractions shuffled as required.<br>
<br>
<b>Deleting Gear Loss Fractions</b><br>
<br>
To delete fractions select <font face="Times New Roman"><b><font face="Arial">Delete Fraction</font></b></font><font face="Times New Roman"><b></b></font> from the pull-down menu. This will remove the currently displayed fraction.<br>
<br>
<b>Gear Loss Data </b><br>
<br>
Data should be entered as torque loss (Nm) vs. gearbox input speed (rpm). After entering data, selecting <b>Update</b> will convert all torque losses into power (kW). <br>
<br>
A text entry window is available to enter a label to describe the source of the data or other notes.<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font></b><font size="4">Shift Strategy</font><font size="3"><br>
</font><font size="2"><br>
This window is used to specify the user gear shift strategies. The user is able to specify up to a maximum of 10 different shift strategies, which can be selected at the calculation window.<br>
<br>
A shift strategy map is entered as an array of change up and change down data for each gear ratio across a 2-D map of a speed variable vs. a load variable. <br>
<br>
This data can also be entered directly into the <u><b>*.car file</b></u></font><b></b> through the available text editor.<br>
<br>
The variables are as follows :<br>
<br>
<b>Number of shift maps</b> - must be equal or greater than 1 (Add a map using the top left pull-down menu functions).<br>
<b>Title of Shift Map</b> - A user defined label eg. <font face="Arial">FTP 75 Shift Schedule</font><font face="Times New Roman"><font face="Arial"><br>
<b>Number of Torque Fractions</b></font></font> - Add using the pull-down menu functions, flip through using the arrows.<br>
<b>Torque Fraction</b> - Change by selecting the data entry box and typing in required value.<br>
<b>Load Fraction Variable</b> - Select from any of the map parameters for which data is detailed in the <font face="Times New Roman"><b><font face="Arial">Engine Map</font></b></font><font face="Times New Roman"><b></b></font> window.<br>
<b>Speed Variable</b> - Select from the four speed variables available :<br>
<b>1.</b> Engine Speed (RPM)<br>
<b>2.</b> Propshaft Speed (RPM)<br>
<b>3.</b> Vehicle Speed (KPH)<br>
<b>4.</b> Vehicle Speed (MPH) <br>
<b>Shift Mode </b>- Specifies shifting mode from two options:<br>
<b>1. </b>Forced mode - obeys shifting strategy detailed<br>
<b>2.</b> Free- Pre-Optimum - Sets shifting mode to minimise the map parameter set in the <b><font face="Arial">Engine Optimum</font></b><font face="Times New Roman"><b><font face="Arial"> </font></b></font>window using the pre-calculated curve.<br>
<b>3.</b> Free <font face="Times New Roman"><font face="Arial"> Inst-Optimum </font></font><font face="Times New Roman"><font face="Arial"> Uses an instantaneous calculation to decide the optimum gear position using defined map.<br>
</font></font><b>Kickdown Mode</b> - Sets whether the transmission kicks down under acceleration<br>
<br>
<b>Switching the Displayed Shift Maps and Adding, Deleting and Inserting Load Fractions</b><br>
<br>
The method of switching between displayed shift maps and adding, deleting and inserting maps and load fractions matches the method described in <font face="Times New Roman"><b><font face="Arial">Gear Losses</font></b></font><font face="Times New Roman"><b></b></font>.<br>
<br>
<b>Graphically Displaying the Gearbox Shift Strategy</b><br>
<br>
To view the shift strategy at each load fraction select the <b><font face="Arial">Graph Button</font></b><font face="Times New Roman"><b></b></font>. This displays the map and provides functions such as zoom and autoscale, accessible from the pull down menu at the top left of the graph window.<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><font face="Arial"><b><font size="4">Gearbox Cascade Diagram<br>
</font></b></font><font size="2"><br>
This window displays the tractive load diagram for the vehicle system at each drive ratio vs. the combined aerodynamic and tyre loads and vehicle speed. <br>
<br>
<b>Cascade Graphing Functions</b></font><br>
<br>
Functions such as zoom, autoscale and data pick are available from the pull-down menu at the top left of the display.<br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Gradability Tool</font></b><font size="3"><br>
</font><font size="2"><br>
The gearing gradability tool allows the user to view LOTUS VEHICLE SIMULATION calculations for the vehicle performance on inclines. Various tools are available to adjust the displayed ratios, increase the total vehicle mass (by adding towed mass), and the road gradient.<br>
<br>
<b>Setting the Gradability Optimised Gear Ratios to be the Model Gear Ratios</b></font><br>
<br>
After adjusting ratios to the users satisfaction, the ratios may be transferred to become the main vehicle ratios by selecting <font face="Times New Roman"><b><font face="Arial">Set as Gears</font></b></font><font face="Times New Roman"><b></b></font>.<br>
<br>
To revert the changed ratios back to the initial values before adjustment select <b><font face="Arial">Revert</font></b><font face="Times New Roman"><b></b></font>.<br>
<br>
<b>Calculating Gradability with Locked or Unlocked Torque Converter</b><br>
<br>
If using an automatic transmission, the user can lock or unlock the torque converter by toggling the <b><font face="Arial">Locked / Unlocked</font></b><font face="Times New Roman"><b></b></font> button.<br>
<br>
<b>Calculating Gradability based on Road Gradient, Vehicle Speed or Gear Ratio</b><br>
<br>
The user can decide which variable should remain fixed during on-screen calculation using the <b><font face="Arial">Update</font></b><font face="Times New Roman"><b></b></font> pull-down menu at the top left of the window. The user may select from grade velocity, road gradient or gear ratio.<br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Maximum Speed Tool<br>
</font></b><font size="2"><br>
The user may view LOTUS VEHICLE SIMULATION basic theory calculations for maximum speed using the </font><b><font face="Arial">Max. Speed</font></b><font face="Times New Roman"><b></b></font> tool from the <b>Gearbox</b> menu.<br>
<br>
The user may change the ratios, vehicle speed and engine speed variables by manipulation of the spreadsheet data. To re-calculate the data select <b><font face="Arial">Update</font></b><font face="Times New Roman"><b></b></font>. <br>
<br>
<b>Setting the User Modified Maximum Speed Ratios as the Model Ratios</b><br>
<br>
To transfer the adjusted gear ratios to the main model select <b><font face="Arial">Set as Gears</font></b><font face="Times New Roman"><b></b></font>. To reset the gears to the values before adjustment select <b><font face="Arial">Revert</font></b><font face="Times New Roman"><b></b></font>.<br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Engine</font></b> <b>Data</b><font size="3"><br>
</font><font size="2"><br>
The engine data section forms the primary data screens for data entry to define the central powertrain unit. Currently facilities are primarily aimed at the modelling of I.C. engines. <br>
<br>
The user brings up the engine system menu by selecting the <u>Engine icon</u></font> on the main menu tool bar. This displays the following options :<br>
<br>
<u><b>Engine</b></u><b></b> : Data for the I.C. Engine specification, inertia and full-load performance.<b><br>
<u>Engine Scaling</u></b><b></b> : Advanced tool to adjust engine specification via scaling functions.<b><br>
<u>Engine Maps</u></b><b></b> : Data window for full and part load fuel economy, emissions and engine operating condition.<b><br>
<u>Optimum</u></b><b></b> : Tool to calculate optimum load-speed profile to minimise any selected map parameter - can then be used to drive shift strategy.<b><br>
</b><u>Catalyst</u><b> </b>: Data window for catalyst light-off characteristics and emissions after-treatment efficiency.<b><br>
<u>Warm-up</u></b><b></b> : Data window for engine-out emissions and fuel economy during warm-up phase and engine acceleration.<b><br>
<u>Auxiliaries</u></b><b> </b>: Data window for specification and load characteristics of powertrain mounted auxiliary devices.<b><br>
<u>Grid Analysis</u></b><b></b> : Data window for creation of a zone system for cumulative analysis of vehicle system operation across powertrain load-speed range.<b><br>
</b><u>Primary Drive</u><b></b> : Data window for specification of engine primary drive, inertia and efficiency.<b><br>
<u>Units</u></b><b></b> : Window for selection of preferred displayed units<br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><b><font size="4">Engine<br>
</font></b><font size="2"><br>
This window is selected from the </font><b><font face="Arial">Engine</font></b><font face="Times New Roman"><b></b></font> options menu accessed by selecting <b><font face="Arial">Engine</font></b><font face="Times New Roman"><b><font face="Arial"> </font></b></font>from the engine menu.<br>
<br>
The window is used to review or adjust data for the following variables :<br>
<br>
<b>Engine Type</b> : Currently restricted to I.C. engine.<br>
<b>Cycle Type</b> : 2 or 4-stroke types supported. <br>
<b>Compression Ratio</b> : Only required for engine scaling functions.<br>
<b>Bore (mm)</b> : Engine cylinder bore. Must be specified.<br>
<b>Stroke (mm)</b> : Engine piston stroke. Must be specified.<br>
<b>No. of Cylinders</b> : Total number of cylinders in engine. Must be specified.<br>
<b>Idle Speed (rpm)</b> : Engine minimum speed. If not specified uses torque curve lowest speed.<br>
<b>Maximum Speed (rpm)</b> : Engine maximum speed. If not specified uses torque curve highest speed. This can be set for each gear separately. See Extended options.<br>
<b>Engine Inertia (Kg.m2)</b> : Rotating inertia of engine - May be set to zero. <br>
<b>Number of Speeds</b> : Specifies number of speeds over which torque curve is detailed.<br>
<b>Engine Speed (rpm)</b> : At each data point.<br>
<b>BMEP or Torque (Nm)</b> : Maximum BMEP or torque at each data/speed point. Alternative BMEP curves can be defined for each gear, select the <font face="Times New Roman"><font face="Arial">Limit in Each Gear</font></font><font face="Times New Roman"><font face="Arial"> option.<br>
</font></font><br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<b>Factoring the Engine Torque Curve</b><br>
<br>
Features are also available to scale the torque curve in terms of speed and torque by using the <font face="Times New Roman"><b><font face="Arial">Factor</font></b></font><font face="Times New Roman"><b></b></font> tool selected from the pull-down menu in the top left of the window.<br>
<br>
<b>Displaying the Engine Torque Curve Graphically</b><br>
<br>
The torque curve can be displayed graphically using the <u><b><u>graph icon</u></b></u><b></b> at the top right of the window. This includes features for zoom, autoscaling, data pick and printing accessed from the pull-down menu at the top right of the graph window.<br>
<br>
<b>Increasing/Reducing the Number of Engine Torque Curve Points</b><br>
<br>
To increase the number of engine torque curve data points, increase the number of speeds entered in the data box. To reduce the number of engine torque curve data points, reduce the number of engine speeds in the data box.<br>
<br>
<b>Engine Over-run FMEP coefficients.<br>
<br>
</b>The coefficients used to calculate the engine friction during the overrun phase can be modified via the <font face="Arial">advanced</font><font face="Times New Roman"><font face="Arial"> menu item. An additional torque </font></font><font face="Times New Roman"><font face="Arial">scalar</font></font><font face="Times New Roman"><font face="Arial"> can also be defined here.<br>
</font></font><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Engine Scaling<br>
</font></b><font size="2"><br>
This window provides features to modify the entered engine performance and map data through a range of scaling functions related to changes from the base engine geometry to a new proposed specification.<br>
<br>
The user is required to enter data for the new engine geometry and enter estimates for the relative effects on power, engine operating speed range and thermal efficiency based on empirical or judgement data. For instance current I.C. engines typically demonstrate an improvement in thermal efficiency of around 3% per increase in compression ratio (Though this is only a broad approximation!). The user can enter the new compression ratio, giving a factor of 1.03 for change in th with C.R. The scaling tool also includes models for engine friction, allowing the effect of engine design to be incorporated - this makes use user estimates of the Lotus subroutine </font><font face="Times New Roman"><font face="Arial">FRIC</font></font><font face="Times New Roman"><font face="Arial"> which draws on many engine studies and Lotus powertrain experience.<br>
</font></font><br>
These scaling factors are then used in the calculation, thus allowing the analyst to rapidly assess the potential effects of changes in engine design. <br>
<br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<b>Switching on the Engine Scaling System</b><br>
<br>
To activate the engine scaling model, select<b> </b><font face="Times New Roman"><b><font face="Arial">On</font></b></font><font face="Times New Roman"><b></b></font> from the <b><font face="Arial">Option</font></b><font face="Times New Roman"><b></b></font> pop-down menu. To switch off engine scaling select <b><font face="Arial">Off</font></b><font face="Times New Roman"><b></b></font> from the same menu.<br>
<br>
The data variables are summarised below :<br>
<br>
<b>New Engine Bore (mm) <br>
New Engine Stroke (mm) </b><br>
<b>New Engine Compression Ratio <br>
Sensitivity of thermal to Change in Bore (%/mm) </b>: Typically negative.<b><br>
Sensitivity of thermal to Change in Stroke (%/mm) </b>: Typically close to zero.<b><br>
Sensitivity of thermal to Change in Compression Ratio (%/C.R.) </b>: Typically positive.<b><br>
Sensitivity of engine speed range to Change in Bore (%/mm)</b> : Typically close to zero.<b><br>
Sensitivity of engine speed range to Change in Stroke (%/mm)</b> : Typically positive.<b><br>
</b><br>
The overall factor of each change is presented in the box at the far right of each sub-section. <br>
<br>
If engine speed range is scaled and the user wishes to change the maximum and minimum speed range of the engine, this must be entered directly into the model *.car file using the <b><font face="Arial">Edit Data</font></b><font face="Times New Roman"><b></b></font> option from the main window <b><font face="Arial">File</font></b><font face="Times New Roman"><b></b></font> pop-down menu.<br>
<br>
<p><hr><p>
<b>Friction scaling</b><br>
<br>
To display the window for engine friction changes select <b><font face="Arial">Friction Scaling</font></b><font face="Times New Roman"><b></b></font>. This sub-window displays options for model type. To select from the available options activate the <b><font face="Arial">Options</font></b><font face="Times New Roman"><b></b></font> pop-down menu which provides options for :<br>
<br>
<b>1. User Defined</b> : A spreadsheet of n data points with speed vs. current engine friction and the friction of the new engine (Friction in FMEP).<b><br>
2. Single Model</b> : A Lotus developed FRIC model which relates the engine design variables to empirical and developed models for friction.<br>
<b>3. Two Models</b> : A Lotus developed FRIC model for the current and proposed engine specifications relating engine design variables to empirical and developed models for friction.<br>
<br>
<b>Friction Model Default Data</b><br>
<br>
If data is not available for the modelled engine design, estimates for typical bearing sizes are available:<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>Inline engines</b> : Enter 9999.0 for bearing sizes<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>V-engines with single cylinder per pin</b> : Enter 9998.0 for bearing sizes<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>V-engines with two cylinders per pin</b>: Enter 9997.0 for bearing sizes<br>
<b>For cam bearings, enter 9999.0 for diameter and widths</b><br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Engine Map Data<br>
</font></b><font size="2"><br>
The engine map data entry window is accessed using the </font><b><font face="Arial">Map Data</font></b><font face="Times New Roman"><b></b></font> option from the <b><font face="Arial">Engine</font></b><font face="Times New Roman"><b></b></font> menu accessed by selecting the <b><font face="Arial">Engine Icon</font></b><font face="Times New Roman"><b></b></font> from the data toolbar or man window pull-down menu.<br>
<br>
The window is designed to permit easy entry of data for the engine fuel economy, emissions and operating characteristics over the load-speed range.<br>
<br>
All maps used must share a common load-speed format.<br>
<br>
The grid is specified first, and does not need to be regular, but a complete grid must be provided - hence extrapolation of data above the full load BMEP at each speed is necessary. This extrapolation does not affect the calculated results.<br>
<br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<b>Switching on the Engine Maps</b><br>
<br>
To switch on the map system, the user selects <b><font face="Arial">On</font></b><font face="Times New Roman"><b></b></font> from the <b><font face="Arial">Options</font></b><font face="Times New Roman"><b></b></font> pop-down menu. This activates the spreadsheets and map functions.<br>
<br>
<b>Adding, Deleting and Inserting Engine Maps</b><br>
<br>
To add an engine map or delete and insert maps the user selects options from the <b><font face="Arial">Functions</font></b><font face="Times New Roman"><b></b></font> pop-down menu.<br>
<br>
<b>Cycling through the Engine Maps</b><br>
<br>
To cycle through the maps, use the arrows within the map number panel<br>
<br>
<b>Graphically displaying the Engine Maps, Zoom, Data-picking and Printing<br>
<br>
</b>To graphically display the map currently in the Engine map window, select the <b><font face="Arial">Graph Icon</font></b><font face="Times New Roman"><b></b></font> in the top right of the window. This includes features for zoom, autoscaling, data-picking and printing. This is selected from the pull-down menu at the top-right of the graph window.<br>
<br>
<b>Engine Map Data Variables</b><br>
<br>
The various data variables to be specified are as follows :<br>
<br>
<b>Map Number</b> : Change map number using the arrows in the map number panel.<br>
<b>Map Type</b> : Select map type from the following available :<br>
<b>1. Fuel Consumption<br>
2. Air Consumption</b><br>
<b>3. Hydrocarbon Emissions</b><br>
<b>4. NOx Emissions</b><br>
<b>5. CO Emissions</b><br>
<b>6. CO2 Emissions</b><br>
<b>7. O2 Emissions</b><br>
<b>8. Particulate Emissions</b><br>
<b>9. User Flow</b><br>
<b>10. Spark Timing</b><br>
<b>11. Throttle Position</b><br>
<b>12. Manifold Air Pressure (Bar)</b><br>
<b>13. Air-Fuel Ratio&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b><br>
<b>14. Exhaust Temperature<br>
15. Heat to Coolant (0-1)<br>
16. Heat to Oil (0-1)</b><br>
<b><br>
</b>Map Units : For map types 1-9 the unit options are :<br>
<b>g/s</b> - grams per second<b><br>
</b>g/h - grams per hour <br>
<b>g/kW.h</b> - grams per kilowatt hour<br>
<b>g/h/l</b> - grams per hour per litre of engine capacity<br>
<b><br>
</b>Overrun : Overrun map option determines values of map at idle and zero load (coasting)<br>
<b>Lowest Load</b> : uses the values at the lowest load point of the map<b><br>
</b>Zero : uses zero for map variable at idle and zero load<br>
<b>User Defined </b>: uses user specified data entered in the <b>Overrun</b> column. For map types 1-9, the overrun units are g/s when map units are 1 or 2. For map units in specifics 3 or 4, overun units are g/s/l. <br>
<br>
<b>Note </b>: The overrun map value specified for the first map speed is used when the engine is at idle (unless auxiliaries or a torque converter are specified).<br>
<b><br>
</b>Fuel Specific Gravity (kg/l) : Typically 0.75-0.76 for gasoline, 0.84 for diesel.<br>
<b>Fuel Calorific Value (kJ/kg) </b>: Typically 42000kJ/kg for gasoline.<br>
<b>Scale Factor </b>: Used to make global changes to the data.<br>
<b>Number of Map Speeds</b> : For all specified maps.<br>
<b>Number of Map Loads</b> : For all specified maps.<br>
<b>Spreadsheet</b> : Data entry area for speed-load data.<br>
<br>
<b>Increasing/Reducing the Number of Map Speed Points</b><br>
<br>
To add, insert or delete map speed points, change the number of points in the data box. This adds or deletes speeds from the maximum speed end of the map.<br>
<br>
<b>Increasing/Reducing the Number of Map Load Points<br>
</b><br>
To add, insert or delete map load points, change the number of points in the data box. This adds or deletes loads from the maximum load end of the map.<br>
<br>
<b>Using the Engine Map Spreadsheet Tools</b><br>
<br>
By clicking with the left mouse button in the spreadsheet, the cell under the pointer is selected and the data for that point may be changed. By selecting a range of cells and clicking the right mouse button a range or cut,copy and paste functions are available. These operate in the same manner as common Windows spreadsheets.<br>
<br>
{button ,AL(`list10',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Optimum<br>
</font></b><font size="2"><br>
The </font><font face="Arial">optimum</font><font face="Times New Roman"><font face="Arial"> window is accessed using the <b>Optimum</b></font></font> option on the <b>Engines</b> menu bar. This is accessed by selecting the <u><b><u>Engine Icon</u></b></u><b></b> or choosing <b>Engine</b> from the <b>Data </b>pull-down menu on the main window menu-bar.<br>
<br>
The optimum window is used to define a strategy for the gearbox shift strategy as related to engine operating conditions.<br>
<br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<b>Switching on the Optimum Model</b><br>
<br>
To switch on the Optimum model, select <font face="Times New Roman"><b><font face="Arial">On</font></b></font><font face="Times New Roman"><b></b></font> from the <b><font face="Arial">Options</font></b><font face="Times New Roman"><b></b></font> pop-down menu. To switch off select <b><font face="Arial">Off</font></b><font face="Times New Roman"><b></b></font>.<br>
<br>
<b>Using the Optimum Model</b><br>
<br>
To use the optimum model, the user must either specify a map parameter to be minimised (To work correctly, the map must have previously been defined in <b><font face="Arial">Engine - Map Data</font></b><font face="Times New Roman"><b></b></font>), or else specify a curve of optimum torque vs. engine speed.<br>
<br>
<b>Using a Pre-specified Engine Map for the Optimum Model</b><br>
<br>
To use a map previously specified in the <b><font face="Arial">Engine - Map Data</font></b><font face="Times New Roman"><b></b></font> window, select the <b><font face="Arial">Optimum Type</font></b><font face="Times New Roman"><b></b></font> pop-down menu and enter the required map number in the <b><font face="Arial">Map No.</font></b><font face="Times New Roman"><b><font face="Arial"> </font></b></font>box. This will calculate the minimum level of the map parameter at each engine speed point and display the results in the spreadsheet. (The map No. should the map type identification No. and not the map order No.).<br>
<br>
<b>Using a User Defined Optimum Curve for the Optimum Model</b><br>
<br>
To enter a user defined curve for the optimum model, select <font face="Times New Roman"><b><font face="Arial">User Specified</font></b></font><font face="Times New Roman"><b></b></font> in the <b><font face="Arial">Optimum Type</font></b><font face="Times New Roman"><b></b></font> pop-down menu. The user then enters the number of points to be defined and enters the engine speed and power (kw) into the spreadsheet. To view the calculated Torque in Nm and BMEP after a change click the <b><font face="Arial">Update</font></b><font face="Times New Roman"><b></b></font> button.<br>
<br>
<b>To Graphically Display the Optimum Curve</b><br>
<br>
To view graphically the current <font face="Arial">Optimum</font><font face="Times New Roman"><font face="Arial"> curve to be used by the model, press the <u><b><u>Graphics Icon</u></b></u></font></font><b></b> in the top right of the window. This displays the <b>Graphics </b>window and provides features for autoscaling, zoom, printing and data-picking, accessed using the pull-down menu in the top-left of the window. <br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Catalyst<br>
</font></b><font size="2"><br>
The </font><font face="Times New Roman"><font face="Arial">Catalyst</font></font><font face="Times New Roman"><font face="Arial"> window is accessed using the <b>Catalyst</b></font></font> option on the <b>Engines</b> menu bar. This is accessed by selecting the <u><b><u>Engine Icon</u></b></u><b></b> or choosing <b>Engine</b> from the <b>Data </b>pull-down menu on the main window menu-bar.<br>
<br>
The window allows the user to enter and review information for the catalyst model. A catalyst if used, models a reduction in vehicle out-emissions and the transient <font face="Times New Roman"><font face="Arial">light-off</font></font><font face="Times New Roman"><font face="Arial"> phase after cold start during which emissions conversion efficiency is reduced. <br>
</font></font><br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<b>Using the Catalyst Model</b><br>
<br>
To model a catalyst in the vehicle, the user must switch it on by selecting <font face="Times New Roman"><b><font face="Arial">On</font></b></font><font face="Times New Roman"><b></b></font> from the <b><font face="Arial">Options</font></b><font face="Times New Roman"><b></b></font> pop-down menu in the window. To remove the model, similarly select <b><font face="Arial">Off</font></b><font face="Times New Roman"><b></b></font>.<br>
<br>
<b>Catalyst Data Variables</b><br>
<br>
Three variables are used to model curves of catalyst light-off charactersitics and max conversion efficiency. These are :<br>
<br>
<b>1. Maximum Catalyst Efficiency (For HC, NOx and CO)</b> : The conversion efficiency of the catalyst operating at optimum conditions.<br>
<b>2. Time to Maximum Efficiency (For HC, NOx and CO) </b>: Time from start of cycle for catalyst to reach maximum efficiency.<br>
<b>3. Warming Time (s) (For HC, NOx and CO)</b> : Time for catalyst to warm-up from ambient conditions to maximum efficiency operating temperature.<br>
<br>
<b>Displaying the Catalyst Characteristics Graphically<br>
<br>
</b>The user may view the catalyst operating strategy graphically by selecting the <u><b><u>Graphics Icon</u></b></u><b></b> at the top right of the window. This displays the <b>Graphics </b>window and provides features for autoscaling, zoom, printing and data-picking, accessed using the pull-down menu in the top-left of the window. <br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><font face="Arial"><b><font size="4">Warm Up<br>
</font></b></font><font size="2"><br>
The </font><font face="Times New Roman"><font face="Arial">Warm-up</font></font><font face="Times New Roman"><font face="Arial"> window is accessed using the <b>Warm-up</b></font></font> option on the <b>Engines</b> menu bar. This is accessed by selecting the <u><b><u>Engine Icon</u></b></u><b></b> or choosing <b>Engine </b>from the <b>Data </b>pull-down menu on the main window menu-bar.<br>
<br>
The window allows the user to enter and review information for the warm-up model. This models a ramp down (or up) in engine-out emissions over a user specified time period after startup until the engine has reached it<font face="Times New Roman"><font face="Arial">s steady state operating condition. The model also allows the user to model the effect of engine transients (due to acceleration) on emissions. The same approach is also used to factor the fuel consumption during the warm-up phase.<br>
</font></font><br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<b>Using the Warm-up Model</b><br>
<br>
To model the warm-up phase, the user must switch the model on by selecting <font face="Times New Roman"><b><font face="Arial">On</font></b></font><font face="Times New Roman"><b></b></font> from the <b><font face="Arial">Options</font></b><font face="Times New Roman"><b></b></font> pop-down menu in the window. To remove the model, similarly select <b><font face="Arial">Off</font></b><font face="Times New Roman"><b></b></font>.<br>
<br>
<b>Warm-up Data Variables</b><br>
<br>
Three variables are used to model curves of the warm-up and transient engine characteristics. These are :<br>
<br>
<b>1. Warm-up Factor (For HC, NOx, CO and Fuel)</b> : The engine out emissions factor at the start of the cycle (when engine is generally at it<font face="Arial">s lowest temperature). <br>
<b>2. Factor Time (s) (For HC, NOx, CO and Fuel) </b></font>: Time from start of cycle for engine to reach normal operating temperatures and emissions to reach steady state values.<br>
<b>3. Acceleration Factor (s2/m) (For HC, NOx, CO and Fuel)</b> : Emissions acceleration factor based on the following formula : <b>Emissions = Steady State Emission + ABS(</b><font face="Times New Roman"><b><font face="Arial">Accelfactor</font></b></font><font face="Times New Roman"><b><font face="Arial"> x acceleration x S.S.Emissions)</font></b></font><br>
<br>
<b>Displaying the Warm-up Characteristics Graphically<br>
<br>
</b>The user may view the warm-up characteristics graphically by selecting the <u><b><u>Graphics Icon</u></b></u><b></b> at the top right of the window. This displays the <b>Graphics </b>window and provides features for autoscaling, zoom, printing and data-picking, accessed using the pull-down menu in the top-left of the window. <br>
<br>
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<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Auxiliaries<br>
</font></b></font><font size="2"><br>
The </font><font face="Times New Roman"><font face="Arial">Auxiliaries</font></font><font face="Times New Roman"><font face="Arial"> window is accessed using the <b>Auxiliaries</b></font></font> option on the <b>Engines</b> menu bar. This is accessed by selecting the <u><b><u>Engine Icon</u></b></u><b></b> or choosing <b>Engine</b> from the <b>Data </b>pull-down menu on the main window menu-bar.<br>
<br>
The window allows the user to enter and review information for any auxiliaries used in the powertrain system. These may be units such as Power-steering pumps, air-conditioning compressors or generators, mounted at some point in the system and being directly driven through some form of gearing.<br>
<br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<b>Using the Auxiliaries Model</b><br>
<br>
To model auxiliaries, the user must switch the model on by selecting <font face="Times New Roman"><b><font face="Arial">On</font></b></font><font face="Times New Roman"><b></b></font> from the <b><font face="Arial">Options</font></b><font face="Times New Roman"><b></b></font> pop-down menu in the window. To remove the model, similarly select <b><font face="Arial">Off</font></b><font face="Times New Roman"><b></b></font>.<br>
<br>
<b>Auxiliaries Data Variables<br>
<br>
</b>An auxiliary is modelled as a power-taking devices driven directly from some point in the powertrain. To model a unit, the user must specify the mounting position, the drive ratio, relative to the rotational speed of the take-off point, the rotary inertia and a curve for the auxiliary rotary speed vs. the torque driving the unit after any drive speed conversion. The user can then view the calculated power by clicking the <b><font face="Arial">Update</font></b><font face="Times New Roman"><b></b></font> button.<br>
<br>
Note : There is no model available in the current version of <b>LOTUS VEHICLE SIMULATION</b> to reduce the absorbed power relative to engine load.<br>
<br>
The variables for input are defined below :<br>
<br>
<b>Auxiliary Label</b> : A note area for the user to define the modelled unit.<br>
<b>Mounting Position for Unit </b>:<b> </b>The user may choose from the following options :<b><br>
</b>1. Engine Mounted (eg. From the drivebelts of flywheel)<br>
2. Gearbox Input Shaft Mounted<br>
3. Propshaft Mounted<br>
4. Axle/Drive Shaft Mounted<br>
Auxiliary Drive Ratio : The ratio between auxiliary and mounting point shaft speeds.<br>
<b>Auxiliary Rotary Inertia (kg.m2)</b> : The inertia of the unit and associated transmission system (Not that of the mounted unit).<br>
<b>Number of Speeds</b> : The number of speeds with which the characteristic curve is defined.<br>
<b>Spreadsheet</b> : A spreadsheet is used to define the characteristics in terms of :<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>Speed (rpm)</b> : The auxiliary rotational speed<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>Torque (Nm)</b> : The auxiliary absorbed torque <br>
<br>
<b>Adding, Deleting or Inserting Auxiliary Units</b><br>
<br>
To add, delete or insert auxiliary units (assuming the system has previously been <b>switched on</b>), use the pull-down menu from the menu-bar at the top left of the window.<br>
<br>
<b>Displaying the Auxiliary Characteristics Graphically<br>
<br>
</b>The user may view the auxiliary characteristics graphically by selecting the <u><b><u>Graphics Icon</u></b></u><b></b> at the top right of the window. This displays the <b><font face="Arial">Graphics</font></b><font face="Times New Roman"><b><font face="Arial"> </font></b></font>window and provides features for autoscaling, zoom, printing and data-picking, accessed using the pull-down menu in the top-left of the window. <br>
<br>
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<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Grid Analysis<br>
</font></b></font><font size="2"><br>
The </font><font face="Times New Roman"><font face="Arial">Grid Analysis</font></font><font face="Times New Roman"><font face="Arial"> window is accessed using the <b>Grid Analysis</b></font></font> option on the <b>Engines</b> menu bar. This is accessed by selecting the <u><b><u>Engine Icon</u></b></u><b></b> or choosing <b>Engine</b> from the <b>Data </b>pull-down menu on the main window menu-bar.<br>
<br>
The window allows the user to specify a network of engine loads and speeds with which the engine load-speed map is sub-divided. On running a cycle of any kind, the calculation system will log the total time, total and mean consumption within each zone of the map and provide analysis in the *.crs file for the utility of each zone. This is particularly useful for analyses relating engine operating condition and efficiencies to drive-cycle utility. <br>
<br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<b>Using the Grid Analysis Model</b><br>
<br>
To use the grid analysis feature, the user must switch the system on by selecting <font face="Times New Roman"><b><font face="Arial">On</font></b></font><font face="Times New Roman"><b></b></font> from the <b><font face="Arial">Options</font></b><font face="Times New Roman"><b></b></font> pop-down menu in the window. To remove the system, similarly select <b><font face="Arial">Off</font></b><font face="Times New Roman"><b></b></font>.<br>
<br>
<b>Specifying a Grid</b><br>
<br>
To set up a grid, enter the number of speeds and loads with which the grid is to be formed and then detail each load and speed point in the appropriate spreadsheets provided in the window.<b> <br>
</b><br>
Note that to obtain full information for the full load characteristics, the map must extend to the maximum full load torque level. The zones at this level which extend above the full load torque curve at other speeds will not affect the analysis. <br>
<b><br>
Displaying the Specified Grid Graphically<br>
<br>
</b>The user may view the specified grid graphically by selecting the <u><b><u>Graphics Icon</u></b></u><b></b> at the top right of the window. This displays the <b>Graphics </b>window and provides features for autoscaling, zoom, printing and data-picking, accessed using the pull-down menu in the top-left of the window. <br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><font face="Arial"><b><font size="4">Primary Drive<br>
</font></b></font><font size="2"><br>
The </font><font face="Times New Roman"><font face="Arial">Primary Drive</font></font><font face="Times New Roman"><font face="Arial"> window is accessed using the <b>Primary Drive</b></font></font> option on the <b>Engines</b> menu bar. This is accessed by selecting the <u><b><u>Engine Icon</u></b></u><b></b> or choosing <b>Engine</b> from the <b>Data </b>pull-down menu on the main window menu-bar.<br>
<br>
The window allows the user to specify a drive ratio for the primary drive take-off transmission from engine crank-shaft/flywheel to the gearbox input shaft.<br>
<br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<b>Using the Primary Drive Model</b><br>
<br>
To enable the Primary Drive model, the user must switch the system on by selecting <font face="Times New Roman"><b><font face="Arial">On</font></b></font><font face="Times New Roman"><b></b></font> from the <b><font face="Arial">Options</font></b><font face="Times New Roman"><b></b></font> pop-down menu in the window. To remove the system, similarly select <b><font face="Arial">Off</font></b><font face="Times New Roman"><b></b></font>.<br>
<b><br>
Primary Drive Data</b><br>
<br>
The user must first switch the Primary Drive option <b><font face="Arial">On</font></b><font face="Times New Roman"><b></b></font>, then enter the drive ratio and efficiency of the primary drive transmission.<br>
<br>
<b>Drive Ratio</b> : The transmission ratio between output shaft and crankshaft speed.<br>
<b>Drive Efficiency (0-1)</b> : The efficiency of the drive transmission.<br>
<b>Efficiency Mode</b> : There are presently two options available :<br>
<b>1. Flat Efficiency Mode</b> : Efficiency is fixed at the entered value irrespective of engine load.<br>
<b>2. Function Efficiency Mode</b> : The model uses a calculation to relate the entered maximum efficiency to efficiency as a function of engine speed and load.<br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><font face="Arial"><b><font size="4">Units<br>
</font></b></font><font size="2"><br>
The </font><font face="Times New Roman"><font face="Arial">Units</font></font><font face="Times New Roman"><font face="Arial"> window is accessed using the <b>Units</b></font></font> option on the <b>Engines</b> menu bar. This is accessed by selecting the <u><b><u>Engine Icon</u></b></u><b> </b>or choosing <b>Engine</b> from the <b>Data </b>pull-down menu on the main window menu-bar.<br>
<br>
This window allows the user to select preferred units for variables entry and display. The options are currently for load and speed :<br>
<br>
<b>1. Engine Speed (Rpm or Rps)</b><br>
<b>2. Engine Load (Nm or BMEP (Bar))</b><br>
<br>
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<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Standard Hybrid Model Data Variables<br>
</font></b></font><font size="2"><br>
The </font><font face="Times New Roman"><font face="Arial">Hybrid</font></font><font face="Times New Roman"><font face="Arial"> window is accessed using the <u><b><u>Hybrid Icon</u></b></u></font></font><b></b> on the data tool bar or choosing <b>Hybrid</b> \ <b>Standard </b>from the <b>Data </b>pull-down menu on the main window menu-bar.<br>
<br>
The Hybrid model allows modelling of the standard hybrid vehicle. The model is capable of absorbing energy from and returning it to the drivetrain system. The program will always preferentially drive the vehicle with the hybrid motor, any excess energy requirements and or battery charging being provided by the main engine.<br>
<br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<b>Using the Standard Hybrid Model</b><br>
<br>
To enable the Hybrid model, the user must switch the system on by selecting <font face="Times New Roman"><b><font face="Arial">On</font></b></font><font face="Times New Roman"><b></b></font> from the <b><font face="Arial">Options</font></b><font face="Times New Roman"><b></b></font> pop-down menu in the window. To remove the system, similarly select <b><font face="Arial">Off</font></b><font face="Times New Roman"><b></b></font>.<br>
<b><br>
Standard Hybrid Data Variables</b><br>
<br>
The hybrid system is modelled using the following variables :<br>
<br>
<b>System Mounting Point</b> : The hybrid motor mounting point, from three available :<br>
<b>1. Engine Flywheel Mounted<br>
2. Gearbox Mounted</b><br>
<b>3. Drive Shaft Mounted</b><br>
<b>Idle Charging Strategy</b> : Options for the system when the engine is at idle :<br>
<b>1. No Charging<br>
2. Storage system charges when engine at idle</b><br>
<b>Maximum Energy Storage Capacity (kW.h)</b> : If the system reaches a maximum, no more charging is allowed, only power output.<br>
<b>Minimum Allowable Energy Level in Storage Device (kW.h)</b> : If the system reaches a minimum, no power output is allowed, only charging.<br>
<b>Motor Maximum Output Torque (Nm)</b> : The maximum output torque from the electric motor. If the requirement exceeds this, the extra is provided by the engine.<br>
<b>Maximum Input Torque (Nm)</b> : The maximum torque for charging. The system can not exceed this value, hence charging rate is limited.<br>
<b>Output Efficiency (0-1)</b> : The efficiency of the storage/motor output system.<br>
<b>Input Efficiency (0-1)</b> : The efficiency of the storage/regeneration input system.<br>
<b>Capacity at Start (kW.h)</b> : The energy held by the storage device at the start of the cycle.<br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Extended Hybrid Component Performance<br>
</font></b><font size="2"><br>
This extended </font><font face="Arial">Hybrid</font><font face="Times New Roman"><font face="Arial"> data window is accessed from the 'extended' menu on the <u>standard hybrid data</u></font></font> window or choosing <b>Hybrid</b> \ <b>Extended Hybrid Performance </b>from the <b>Data </b>pull-down menu on the main window menu-bar.<br>
<br>
The extended Hybrid model allows a more sophisticated model of a hybrid vehicle to be defined than that achievable with the 'standard' model. The model can include the following hybrid components, generator, drive motor, drive regenerator and battery. Each component has a performance curve for both peak and continuous operation, an operating temperature model, (except battery), to establish the maximum allowable operating performance between these two performance curves at a particular operating condition.<br>
<br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<b>Using the Extended Hybrid Model</b><br>
<br>
To enable the extended Hybrid model, the user must switch the system on by selecting <font face="Times New Roman"><b><font face="Arial">On</font></b></font><font face="Times New Roman"><b></b></font> from the <b><font face="Arial">Option</font></b><font face="Times New Roman"><b></b></font> pull-down menu in the window. To remove the system, similarly select <b><font face="Arial">Off</font></b><font face="Times New Roman"><b></b></font>. It should be noted that the extended hybrid model uses four data windows to fully define the hybrid vehicle and a number of these would need to switched 'on' and 'off' as required to correctly select or deselect an extended hybrid vehicle.<br>
<b><br>
Extended Hybrid Component Performance Data Variables</b><br>
<br>
The extended hybrid system performance is modelled for the following components :<br>
<br>
<b>1. APU Generator</b> <br>
<b>2. Drive motor</b> <br>
<b>3. Drive Regenerator</b> <br>
<b>4. Battery</b> <br>
<br>
For components 1 - 3 the performance is defined by a peak torque, a continuous torque and a heat loss ratio against component speed. Whilst for the Battery, (component 4), the performance is defined by maximum charge rate and maximum discharge rate against State of Charge (SOC), (heat loss ratio is not used for the battery component).<br>
<br>
Additional data variables are used to further define the component, these also being entered through the performance data window.<br>
<br>
For components 1 - 3 the additional data variables are :<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>Start Temperature (Co) </b>Sets the initial temperature of the component at the start of the simulation run.<b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Inertia (kg.m2) </b>Defines the rotational inertia of the component.<b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Time at Peak (s)</b> Defines the time for which the peak performance can be held before the threshold temperature is reached and the allowable performance begins to deteriorate from the peak toards the continuous. This forms part of the component heat model derivation.<b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Constant Temperature (Co) </b>Defines the temperature which the component reaches under the maximum constant performance. This defines the heat convection capability of the component.<b> <br>
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Threshold Temperature (Co) Sets the temperature at which the component performance starts to deteriorate from the peak towards the continuous.<b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Maximum Speed (rpm)</b> Sets the maximum allowable component speed.<br>
<br>
Whilst for component 4 the additional data variables are :<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>Start SOC ( 0 -1 )</b> Defines the state of charge setting for the battery at the start of the simulation.<b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Start Voltage (V)</b> Is used as the fixed battery voltage for hybrid systems that do not have the full voltage model defined. If a full voltage model is defined then this value is not used.<b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Capacity (Ah) </b>Defines the battery capacity.<br>
<br>
<b>Extended Hybrid Component Thermal Model<br>
<br>
</b>For components 1 - 3 a thermal model is used that calculates the allowable performance based on the current component temperature. The component temperature is continually updated through the cycle from its initial value by considering that time steps component performance and the heat rejection of the component at that particular speed, a portion is assumed to be radiated whilst the remainder, (should there be any), goes into heating up the component. Thus if at the current component temperature the radiated heat is greater than the amount rejected to the component the component temperature will drop. Thus through the cycle the component temperature will rise and fall with demand, which in turn defines the allowable component maximum performance which will lie between the peak performance and the continuous performance for that speed.<br>
<br>
Thus component heat model is derived from the threshold temperature, the constant temperature, the time at peak and the maximum peak and continuous performances. These are used to calculate a specific heat capacity for convection and a coefficient for heat up of the component.<br>
<br>
The transient response of the component can be reviewed by selecting from the hybrid performance window the <b>View / Transient Response</b> menu option. This opens a new window that allows the user to define a load cycle, that can be a constant load, two step load, repeat two step or a repeat saw tooth. The component temperature can be viewed for the defined load case.<br>
<b><br>
</b><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Extended Hybrid Component Efficiency<br>
</font></b><font size="2"><br>
This extended </font><font face="Arial">Hybrid</font><font face="Times New Roman"><font face="Arial"> data window is accessed from the 'extended' menu on the <u>standard hybrid data</u></font></font> window or choosing <b>Hybrid</b> \ <b>Extended Hybrid Efficiencies </b>from the <b>Data </b>pull-down menu on the main window menu-bar.<br>
<b><br>
Extended Hybrid Component Efficiency Data Variables</b><br>
<br>
The extended hybrid system efficiencies are modelled for the following components :<br>
<br>
<b>1. APU Generator</b> <br>
<b>2. Drive motor</b> <br>
<b>3. Drive Regenerator</b> <br>
<b>4. Battery, Charge<br>
5. Battery, Discharge</b> <br>
<br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
For all components the efficiency can be defined as either a single value, or as a 2D map, for speed against performance. All efficiency values are between 0 and 1. <br>
<br>
If this option is switched 'off' for a component the efficiency is set to 1. All components can be switched 'on' and 'off' independent of each other.<br>
<br>
To define a single fixed efficiency value for a component, set the 'option' to 'on', set the number of speeds and performance values to 0. This will 'grey' out the spread sheet and enable the 'fixed efficiency' entry box.<br>
<br>
To define a 2D efficiency map for a component set the 'option' to 'on', set the number of speed and performance values to the required number, and enter the efficiency values (range 0-1) into the spread sheet. The <u>graph icon</u> allows the user to view the defined map.<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Extended Hybrid Battery Model<br>
</font></b><font size="2"><br>
This extended </font><font face="Times New Roman"><font face="Arial">Hybrid</font></font><font face="Times New Roman"><font face="Arial"> data window is accessed from the 'extended' menu on the <u>standard hybrid data</u></font></font> window or choosing <b>Hybrid</b> \ <b>Extended Hybrid Battery Model </b>from the <b>Data </b>pull-down menu on the main window menu-bar.<br>
<b><br>
Extended Hybrid Battery Model Data Variables</b><br>
<br>
The extended hybrid battery model defines the voltage model of the battery component under both charge and discharge at a range of charge rates and state of charges. This allows for a non constant voltage model to be implemented using interpolation of the defined curves.<br>
<br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
The battery voltage is defined for both charge and discharge as two separate sets of curves. When this option is set to 'on' it is assumed that both charge and discharge curves will be entered. <br>
<br>
To define a voltage model for the battery set the 'option' to 'on', select either 'charge' or 'discharge', set the number of charge or discharge curves and the number of State of Charge levels. Then enter for each charge rate the charge value (note +ve for both charge and discharge maps), and the values for SOC and voltage at this charge rate. Repeat for all charge rate value. The <u>graph icon</u> allows the user to view the defined curves.<br>
<br>
To enable the voltage model to interpolate the curves correctly a voltage curve should be entered for a zero current in both the charge and discharge curves. This ensures suitable voltage values are identified for low rates of charge and discharge.<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Extended Hybrid Control Strategy<br>
</font></b><font size="2"><br>
This extended </font><font face="Times New Roman"><font face="Arial">Hybrid</font></font><font face="Times New Roman"><font face="Arial"> data window is accessed from the 'extended' menu on the <u>standard hybrid data</u></font></font> window or choosing <b>Hybrid</b> \ <b>Extended Hybrid Control </b>from the <b>Data </b>pull-down menu on the main window menu-bar.<br>
<b><br>
Extended Hybrid Control Data Variables</b><br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
1) Target for SOC minimum level (0-1)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
2) Target for SOC maximum level (0-1)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
3) Max APU speed acceleration allowable (rpm/s) (+ve number)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
4) Max APU speed deceleration allowable (rpm/s) (-ve number)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
5) Power value for target curve between min and max target SOC<font face="Times New Roman"><font face="Arial">s<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
6) History length for establishing mean power demand<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
7) APU start status, </font></font><font face="Times New Roman"><font face="Arial">off</font></font><font face="Times New Roman"><font face="Arial"> or </font></font><font face="Times New Roman"><font face="Arial">on</font></font><font face="Times New Roman"><font face="Arial"><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
8) Battery SOC level to switch APU </font></font><font face="Times New Roman"><font face="Arial">off</font></font><font face="Times New Roman"><font face="Arial"> (0-1)<br>
</font></font>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
9) Battery SOC level to switch APU <font face="Times New Roman"><font face="Arial">on</font></font><font face="Times New Roman"><font face="Arial"> (0-1)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
10) APU ratio of maximum APU available for switching </font></font><font face="Times New Roman"><font face="Arial">on</font></font><font face="Times New Roman"><font face="Arial"> (0-1)<br>
</font></font><br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<br>
<b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Control Procedure Description:<br>
</b><br>
1)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Find maximum APU power output available, varies as a function of component temperature. PMAXAPU<br>
<br>
2)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Find minimum APU power output, based on idle speed. PMINAPU<br>
<br>
3)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Establish demand from APU based on a mean value of <font face="Times New Roman"><font face="Arial">n</font></font><font face="Times New Roman"><font face="Arial"> history values, and a term based on current SOC when compared to the min/max targets. PDEMAND<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
PDEMAND = PMEAN + ( 1 - SOCRATIO ) x PMAXAPU<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
where;<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
SOCRATIO = ( SOC - SOCTARGET MIN ) / ( SOCTARGET MAX - SOCTARGET MIN )<br>
</font></font><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
SOCRATIO = SOCRATIO **POWER&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
( SOCRATIO limited to 0 - 1 )<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
( PDEMAND limited to &gt; PMINAPU and &lt; PMAXAPU )<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
PMEAN is based on the average of the last <font face="Times New Roman"><font face="Arial">n</font></font><font face="Times New Roman"><font face="Arial"> steps demand<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
PMAXAPU is the maximum APU power output<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
<br>
4)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Match APU speed to match APU demand.<br>
<br>
5)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Check change in APU speed does not exceed allowable speed change limits in either acceleration or deceleration, as appropriate.<br>
<br>
6)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
If battery SOC &gt; SOCOFF and PDEMAND is less than PMINAPU then switch </font></font><font face="Times New Roman"><font face="Arial">off</font></font><font face="Times New Roman"><font face="Arial"><br>
</font></font><br>
7)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
If battery SOC &lt; SOCON and PDEMAND is greater than PMINAPU then switch <font face="Times New Roman"><font face="Arial">on</font></font><font face="Times New Roman"><font face="Arial"><br>
8)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
If PDEMAND is greater than APURATIO ON x PMAXAPU then switch </font></font><font face="Times New Roman"><font face="Arial">on</font></font><font face="Times New Roman"><font face="Arial"> <br>
<br>
<br>
<b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Control Procedure Discussion:<br>
<br>
</b></font></font>Thus the battery charge rate at a particular time step can be <font face="Times New Roman"><font face="Arial">set</font></font><font face="Times New Roman"><font face="Arial"> or </font></font><font face="Times New Roman"><font face="Arial">controlled</font></font><font face="Times New Roman"><font face="Arial"> by a number of the control variables. <br>
<br>
Delay in response to demand can come from the speed change limitations or suppressed by the use of a large history number.<br>
</font></font><br>
The setting for the target SOC values is more likely to control the battery charge rates particularly as the battery SOC approaches the target maximum SOC value since at this point the demand due to the SOC state will become 0.0, (since socratio tends to 0) such that the demand is based purely on the mean demand. After a number of steps the mean demand will drop and so if the shut down SOC value is greater than the target maximum SOC the charge rate from target max SOC to SOC shut down will just be the charge rate at idle of the APU.<br>
<br>
Trying to increase the tendency of the control system to maintain the state of charge at its maximum target SOC by using the power term, whilst it increases the <font face="Times New Roman"><font face="Arial">aggressiveness</font></font><font face="Times New Roman"><font face="Arial"> of the charge regime it will not tend to increase the frequency of APU </font></font><font face="Times New Roman"><font face="Arial">shut downs</font></font><font face="Times New Roman"><font face="Arial"> if the SOC switch off setting is higher than the SOC maximum target.<br>
<br>
Thus the probable control strategy that utilises APU shut down would have an APU shut of SOC slightly lower than the SOC target maximum, the frequency of APU shut down could then be controlled by a combination of the SOC charge power value and the SOC target minimum value. <br>
</font></font><br>
It is also probable that the SOC switch <font face="Times New Roman"><font face="Arial">on</font></font><font face="Times New Roman"><font face="Arial"> value would be greater than the target SOC minimum value in any APU shutdown based strategy.<br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font></font><b><font size="4">Driver Data Variables<br>
</font></b><font size="2"><br>
The </font><font face="Times New Roman"><font face="Arial">Driver</font></font><font face="Times New Roman"><font face="Arial"> window is accessed using the <u><b><u>Driver Icon</u></b></u></font></font><b></b> on the data tool bar or choosing <font face="Times New Roman"><b><font face="Arial">Driver</font></b></font><font face="Times New Roman"><b></b></font> from the <b><font face="Arial">Data</font></b><font face="Times New Roman"><b><font face="Arial"> </font></b></font>pull-down menu on the main window menu-bar.<br>
<br>
The driver window provides access to the simple driver model. This window allows the user to determine the variables representing the driver braking, cornering, gear shifting and accuracy of cycle matching.<br>
<br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<b>Using the Driver Model</b><br>
<br>
To enable the Driver model and allow the user to override the program default driver data, the user must switch the system on by selecting <font face="Times New Roman"><b><font face="Arial">On</font></b></font><font face="Times New Roman"><b></b></font> from the <b><font face="Arial">Options</font></b><font face="Times New Roman"><b></b></font> pop-down menu in the window. To remove the user model and revert to defaults, similarly select <b><font face="Arial">Off</font></b><font face="Times New Roman"><b></b></font>.<br>
<br>
<b>Driver Data Variables</b><br>
<br>
The following variables are available for editing by the user :<br>
<br>
<b>Cornering Efficiency</b> : This defines the maximum cornering speed of the vehicle as a fraction of the maximum theoretical speed. This is used only for track/course simulations.<br>
<b>Braking Efficiency</b> : The maximum braking force as a fraction of the maximum theoretical force. Used in track and course simulations.<br>
<b>Brake Balance (0-1)</b> : Defined as fraction of braking force applied to front wheels.<br>
<b>Gear Shift Time (s)</b> : The time to disengage the gearbox, select the new gear and re-engage drive. Default is 0.1s<br>
<b>Minimum Shift Interval (s)</b> : This is the minimum time allowable between individual gear shifts.<br>
<b>Cycle Fit Type</b> : This defines how accurately the drive cycle is driven, from two available options :<br>
<b>1. Exact<br>
2. Smoothed</b><br>
<br>
{button ,AL(`list10',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><font face="Arial"><b><font size="4">Extended Aerodynamic Data Variables<br>
</font></b></font><font size="2"><br>
The </font><font face="Times New Roman"><font face="Arial">Extended Aerodynamic</font></font><font face="Times New Roman"><font face="Arial"> window is accessed either from the menu option at the top of the vehicle data screen, or choosing </font></font><font face="Times New Roman"><b><font face="Arial">Vehicle / Extended Aerodynamics</font></b></font><font face="Times New Roman"><b></b></font> from the <b><font face="Arial">Data</font></b><font face="Times New Roman"><b><font face="Arial"> </font></b></font>pull-down menu on the main window menu-bar.<br>
<br>
The extended aerodynamic window provides access to the enhanced aerodynamic model. This window allows the user to define the variables representing the drag and lift of the vehicle using coefficients or data splines. These values being represented by fixed values in the <font face="Times New Roman"><font face="Arial">simple</font></font><font face="Times New Roman"><font face="Arial"> model.<br>
</font></font><br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
<b>Using the Aerodynamic Model</b><br>
<br>
To use the Aerodynamic model and allow the user to define non-linear values for drag and lift, select from the top three buttons on the aerodynamic data screen the required variable, (i.e. <font face="Times New Roman"><font face="Arial">CD - Drag Coeff</font></font><font face="Times New Roman"><font face="Arial">, </font></font><font face="Times New Roman"><font face="Arial">CLF - Front Lift coeff</font></font><font face="Times New Roman"><font face="Arial"> or </font></font><font face="Times New Roman"><font face="Arial">CLR - Rear lift Coeff</font></font><font face="Times New Roman"><font face="Arial">). From the lower set of three buttons chose the required definition method for the selected variable.<br>
</font></font><br>
The user can chose to define the aerodynamic variable as a constant, or a constant plus five polynomial coefficients, or a series of spline values. Selecting the required button will thus set the definition method for that variable. The appropriate data values should then be entered and the process repeated for the other two aerodynamic variables.<br>
<br>
Selecting a definition type to be other than <font face="Times New Roman"><font face="Arial">constant</font></font><font face="Times New Roman"><font face="Arial"> will disable the edit box for that variables constant value in the vehicle data screen.<br>
</font></font><br>
The <font face="Times New Roman"><font face="Arial">constant</font></font><font face="Times New Roman"><font face="Arial"> definition type is exactly the same as the current </font></font><font face="Times New Roman"><font face="Arial">simple</font></font><font face="Times New Roman"><font face="Arial"> model, where CD, CLF and CLR are fixed with vehicle speed.<br>
<br>
The </font></font><font face="Times New Roman"><font face="Arial">coefficients</font></font><font face="Times New Roman"><font face="Arial"> definition type allows a constant value plus five power terms which when summed together produce a curve that varies with vehicle speed.<br>
<br>
The </font></font><font face="Times New Roman"><font face="Arial">value list</font></font><font face="Times New Roman"><font face="Arial"> definition type allows up to 40 points to be entered to define the variable</font></font><font face="Times New Roman"><font face="Arial">s variation with vehicle speed. The user specifies the number of points and then the speed and value of the variable at each speed point.<br>
</font></font><br>
{button ,AL(`list10',0,&quot;&quot;,`main')} <u>Related Topics</u><font face="Times New Roman"><br>
<br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Extended Tyre Data Variables<br>
</font></b></font><font size="2"><br>
The </font><font face="Times New Roman"><font face="Arial">Extended Tyre</font></font><font face="Times New Roman"><font face="Arial"> window is accessed either from the menu option at the top of the tyre data screen, or choosing </font></font><font face="Times New Roman"><b><font face="Arial">Tyre / Extended Tyre</font></b></font><font face="Times New Roman"><b></b></font> from the <b><font face="Arial">Data</font></b><font face="Times New Roman"><b><font face="Arial"> </font></b></font>pull-down menu on the main window menu-bar.<br>
<br>
The extended tyre window provides access to the enhanced tyre model. This window allows the user to define a variable representation for the rolling radius of the tyre using coefficients or data splines. This value being represented by a fixed value in the <font face="Times New Roman"><font face="Arial">simple</font></font><font face="Times New Roman"><font face="Arial"> model.<br>
</font></font><br>
This data can also be entered directly into the <u><b>*.car file</b></u><b></b> through the available text editor.<br>
<br>
The tyre rolling radius defined using either the coefficients or by list can be edited using the spline list and edit function that is available through the <u>spline edit icon</u>. This provides a tool for listing and editing the spline in different units, any changes can be saved back in to the tyre data window in the correct units.<br>
<br>
<u>{<center><img data="bm0.shg" title="bm0.shg"></u><br>
</center>
<br>
<b>Using the Extended Tyre Model</b><br>
<br>
To use the extended tyre model and allow the user to define non-linear values for rolling radius, select from the top buttons on the extended tyre data screen the required variable, (currently only 'rolling radius'). From the lower set of three buttons chose the required definition method for the selected variable.<br>
<br>
The user can chose to define the tyre variable as a constant, or a constant plus five polynomial coefficients, or a series of spline values. Selecting the required button will thus set the definition method for that variable. The appropriate data values should then be entered.<br>
<br>
Selecting a definition type to be other than <font face="Times New Roman"><font face="Arial">constant</font></font><font face="Times New Roman"><font face="Arial"> will disable the edit box for that variables constant value in the tyre data screen.<br>
<br>
The </font></font><font face="Times New Roman"><font face="Arial">constant</font></font><font face="Times New Roman"><font face="Arial"> definition type is exactly the same as the current </font></font><font face="Times New Roman"><font face="Arial">simple</font></font><font face="Times New Roman"><font face="Arial"> model, where Rolling Radius is fixed with vehicle speed.<br>
<br>
The </font></font><font face="Times New Roman"><font face="Arial">coefficients</font></font><font face="Times New Roman"><font face="Arial"> definition type allows a constant value plus five power terms which when summed together produce a curve that varies with vehicle speed.<br>
</font></font><br>
The <font face="Times New Roman"><font face="Arial">value list</font></font><font face="Times New Roman"><font face="Arial"> definition type allows up to 40 points to be entered to define the variable</font></font><font face="Times New Roman"><font face="Arial">s variation with vehicle speed. The user specifies the number of points and then the speed and value of the variable at each speed point.<br>
<br>
As with the standard tyre data the non-linear rolling radius can be defined as either 'common' or defined separately for 'front' and 'rear' tyres. Setting 'common', 'front' or 'rear' will display the current tyre data and options associated with that tyre. It must be remembered that setting the option to have different tyre properties means that different tyre properties must also be entered for the <u>'standard tyre data'</u></font></font>, since this option is directly linked with the standard tyre data window, such that changing the setting in one window is automatically reflected in the other.<br>
<br>
{button ,AL(`list10',0,&quot;&quot;,`main')} <u>Related Topics</u><font face="Times New Roman"><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Data Status Window<br>
</font></b></font><font size="2">Overview</font><font face="Times New Roman"><br>
<br>
<font face="Arial">The data status window provides a single window that can be used to identify not only which data options are switched 'on' and any data errors associated with that data section, but also a method of switching individual data options 'on' and 'off', and a way of opening (or closing) the specific data option's window.<br>
<br>
This window contains a scrollable list where each line identifies a particular data 'option', i.e. 'extended tyre'. The text describing the data option is coloured coded to identify it as being either; compulsory (in <font color="#ff0000">red)</font></font></font>, optional (in <font color="#00ff00">green</font>) and a controller (in <font color="#0000ff">blue</font>). (note that the controllers are also optional).<br>
<br>
Adjacent to the text a number of icons are used to identify wether the option is 'off', 'on' and if 'on' whether any data errors have been identified.<br>
<br>
{button ,AL(`list17',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></font><font face="Arial"><b><font size="4">Opening the Data Status Window<br>
</font></b></font><font size="2"><br>
</font>To display the data status window select the menu item <u>Data</u> / <u>Status</u>. When this window is opened it will be updated to display the current status of data settings and associated errors.<br>
<br>
{button ,AL(`list2',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<b><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></b><font size="4">Closing the Data Status Window<br>
</font><font size="2"><br>
To close the data status window select either the </font><font face="Times New Roman"><font face="Arial">close</font></font><font face="Times New Roman"><font face="Arial"> icon at the top right corner of the data status window, the data status window menu at the top left or alternatively select the menu item <u>Functions</u></font></font> / <u>Close</u> from the data status window menubar.<b><br>
</b><br>
{button ,AL(`list17',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<b><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></b><font size="4">Using the Data Status Window<br>
</font><font size="2"><br>
This window contains a scrollable list where each line identifies a particular data 'option', i.e. 'extended tyre'. The text describing the data option is coloured coded to identify it as being either; compulsory (in <font color="#ff0000">red)</font></font>, optional (in <font color="#00ff00">green</font>) and a controller (in <font color="#0000ff">blue</font>). (note that the controllers are also optional). The text description can be selected with the mouse to either 'open' or 'close' the relevant data window, (if already open it will be closed and if closed it will be opened).<br>
<br>
A list of the individual data sections is given below;<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Vehicle<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Standard data&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(compulsory)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Extended Aerodynamics<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Extended Suspensions<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Dyno<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Standard data<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Tyre<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Standard data&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(compulsory)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Extended data<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Driveline<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Clutch<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Torque Converter<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
TC lock-up<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
TC idle<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Final Drive&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(compulsory)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gearbox<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Specification&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(compulsory)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gear Losses<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Shift strategy&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(controller)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Engine<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Engine data&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(compulsory)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Engine scaling<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Map data<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Optimum<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Catalyst<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Warm-up<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Auxiliaries<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Grid analysis<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Primary drive<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Hybrid<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Standard data<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Extended Hybrid Performance<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
APU Generator<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Drive Motor<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Drive Regenerator<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Battery<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Extended Hybrid Efficiencies<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
APU Generator<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Drive Motor<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Drive Regenerator<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Battery - Charge<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Battery - Discharge<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Extended Hybrid Battery Model<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Extended Hybrid Control &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(controller)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Driver<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Standard Data&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(controller) <br>
<br>
Adjacent to each options text up to two icons are displayed. They are used to identify whether the option is 'off', 'on' and if 'on' whether any data errors have been identified. The relevant icons are;<br>
<br>
<b><center>off </b> <u><img data="bm1.bmp" title="bm1.bmp"></u><br>
</center>
<b><center>on </b> <u><img data="bm2.bmp" title="bm2.bmp"></u><br>
</center>
<b><center>errors </b> <u><img data="bm3.bmp" title="bm3.bmp"></u><br>
</center>
<br>
The 'off' or 'on' icon can be selected to turn that specific data section on and off. The icon displayed changing to indicate the new state. Should the 'errors' icon be displayed, selecting this will open the <u>'data checking'</u> wizard.<br>
<br>
On the menubar at the top of the data status window the menu option <u>Functions</u> / <u>Update</u> will allow the user to update the data status display, such that it reflects any data changes that may have been made. Some functions such as loading a new file automatically update the data status display.<br>
<br>
{button ,AL(`list17',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<b><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></b><font size="4">How to use the Spline List / Edit Tool<br>
</font><font size="2"><br>
A number of data windows have data variables that are defined using coefficients or data lists. They are normally displayed in fixed units. The spline list / edit tool allows these variables to be edited in other relevant units, and a list of the variable over a user defined range in these units to be viewed. The data can be edited in these units and changes saved back to the original data window. <br>
<br>
The spline list function can be opened either through a <u>List</u></font> pull-down menu option on the data window, (if one exists), or through the <u>spline edit icon</u>. <br>
<br>
<u>{<center><img data="bm4.shg" title="bm4.shg"></u><br>
</center>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Direct Editing of the Data File<br>
</font></b></font><font size="2">Overview<br>
</font><br>
The LOTUS VEHICLE SIMULATION models are generated as a <u><b>*.car file</b></u><b></b>, which is simply an ASCII text file viewable through any word-processor or the available <b>File Editor</b>, accessible from the <font face="Times New Roman"><b><font face="Arial">File</font></b></font><font face="Times New Roman"><b></b></font> pull-down menu on the main window.<br>
<br>
The user is free to enter and create model files directly through this approach. Typically when attempting to draw large sections of data together from many sources it would be inconvenient to complete all the data-processing through the graphical user interface. This section is designed to provide an insight into the structure of the *.car file and the arrangement of the variables which define a model.<br>
<br>
{button ,AL(`list11',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Data System in the *.car file<br>
</font></b><font size="2"><br>
<font face="Arial">The &quot;*.car&quot; input file is structured in a way that allows the user to easily add new options to an existing model. A &quot;keyword&quot; data input format is used. An option is invoked by the inclusion of a &quot;keyword&quot; anywhere in the input file. Data required for that option are then read immediately following the &quot;keyword&quot;.<br>
<br>
The &quot;keywords&quot; are;<br>
<br>
<b>1. <u>VEHICLE</u></b></font></font><b></b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>*<br>
2. <u>DYNO</u></b><b><br>
3. <u>TYRE</u></b><b></b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>*<br>
4. <u>DRIVETRAIN</u></b><b></b>&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>*<br>
</b> 5. <u>CLUTCH</u><b><br>
6. <u>TORQUE CONVERTER</u></b><b><br>
7. <u>GEARBOX</u></b><b><br>
8. <u>GSHIFT</u></b><b><br>
9. <u>GLOSS</u></b><b></b><br>
<b> 10. <u>ENGINE</u></b><b></b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>*<br>
11. <u>ENG_SCALE</u></b><b><br>
12. <u>MAP</u></b><b><br>
13. <u>OPTIMUM</u></b><b><br>
14. <u>CATALYST</u></b><b><br>
15. <u>WARM-UP</u></b><b><br>
16. <u>AUXILLARIES</u></b><b><br>
17. <u>GRID</u></b><b><br>
18. <u>PDRIVE</u></b><b><br>
19. <u>HYBRID</u></b><b><br>
20. <u>DRIVER</u></b><b></b><br>
<b> 21. <u>AERODYNAMICS</u></b><b></b><br>
<b> 23. <u>HYBPOWER</u></b><b></b><br>
<b> 22. <u>HYBLOSS</u></b><b></b><br>
<b> 24. <u>HYBBATTERY</u></b><b></b><br>
<b> 25. <u>HYBCONTROL</u></b><b></b><br>
<b> 26. <u>XTYRE</u></b><b></b><br>
<b><br>
</b><br>
<br>
The keywords marked by an * are the minimum required to run the model. <br>
<br>
{button ,AL(`list11',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Model File Titles<br>
</font></b><font size="2"><br>
The first three lines of the &quot;*.car&quot; file contain;<br>
<br>
Line<br>
<br>
1. <b>MAIN TITLE</b></font> (80 CHARACTERS MAXIMUM)<br>
<br>
2. <b>SUB TITLE</b> (80 CHARACTERS MAXIMUM)<br>
<br>
3. <b>TEST NUMBER</b> (80 CHARACTERS MAXIMUM), and <b>DATA FILE VERSION No.</b> (currently 3.01)<br>
<br>
The test number controls the naming of the input file and all results files<br>
<br>
The data file version number is used by the reader to correctly interpret the file data<br>
<br>
{button ,AL(`list11',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Vehicle data<br>
</font></b><font size="2"><br>
This option specifies basic vehicle dimensions.<br>
<br>
*.Car file format;<br>
<br>
<b>VEHICLE</b></font> (keyword)<br>
<b>WEIGHT<br>
FAREA, CD, PAREA, CLF, CLR, RHO<br>
WHBASE, TRACKF, TRACKR, DCOG, HCOG</b><br>
<br>
Where<br>
<br>
<b>WEIGHT&nbsp;
</b>Vehicle test weight (kg).This is the total weight including occupants.<br>
<br>
<b>FAREA</b>&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Vehicle frontal area (m2).<br>
<br>
<b>CD</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Aerodynamic drag coefficient.<br>
<br>
<b>PAREA</b>&nbsp;&nbsp;
Vehicle plan area (m2).<br>
<br>
<b>CLF</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Aerodynamic lift coefficient at front wheels. A negative lift coefficient produces downforce.<br>
<br>
<b>CLR&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Aerodynamic lift coefficient at rear wheels. A negative lift coefficient produces downforce.<br>
<br>
<b>RHO&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Atmospheric air density (kg/m3). For example RHO = 1.205 kg/m3 at 20 C and 1013 kpa.<br>
<br>
<b>WHBASE&nbsp;
</b>Vehicle wheelbase (m)<br>
<br>
<b>TRACKF</b>&nbsp;
Front track (m). This is only used to calculate maximum cornering speed in track simulation.<br>
<br>
<b>TRACKR</b>&nbsp;
Rear track (m). This is only used to calculate maximum cornering speed in track simulation.<br>
<br>
<b>DCOG</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance behind the front wheels of the centre of gravity (m).<br>
<br>
<b>HCOG&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Height of centre of gravity above the ground (m).<br>
<br>
The following lines show an example of the VEHICLE option<br>
<br>
VEHICLE<br>
1205.<br>
1.950 .3800 2.000 -.1300 -.2000<br>
1.205<br>
2.450 1.000 1.000 .8860 .6000<br>
<br>
{button ,AL(`list11',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Dyno data<br>
</font></b><font size="2"><br>
This option tells the program that the vehicle is mounted on a chassis dynomometer.<br>
<br>
*.Car file format;<br>
<br>
<b>DYNO</b></font> (keyword)<br>
<b>DYNM, ADYN , BDYN , CDYN</b><br>
<br>
Where<br>
<br>
<b>DYNM</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Chassis dynomometer effective mass (inertia) (kg)<br>
<br>
<b>ADYN&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Brake constant (N).<br>
<br>
<b>BDYN</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Brake constant (N/m/s).<br>
<br>
<b>CDYN</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Brake constant (N/(m/s)2).<br>
<br>
<br>
Where the brake constants form the equation that describes the chassis dynamometer load at the roller periphery.<br>
<br>
Brake Force = ADYN +<br>
BDYN*( Velocity (m/s) ) +<br>
CDYN*( Velocity (m/s) )2<br>
<br>
The following lines show an example of the DYNO option<br>
<br>
DYNO<br>
1250. 345.0 .0000E+00 .8000E-01<br>
<br>
{button ,AL(`list11',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Tyre Data<br>
</font></b><font size="2"><br>
This option provides the rolling radius and rolling resistance curve for the tyres.<br>
<br>
*.Car file format;<br>
<br>
<b>TYRE</b></font> (keyword)<br>
<b> ITYREND<br>
<br>
</b>IF(ITYREND.GT.1)THEN<br>
<b> RTYRE(2), RTYRE(3)<br>
</b> <b>ITOPT<br>
COEFFS(2), TYDEF(2)</b><br>
<b> COEFFS(3), TYDEF(3)</b><br>
IF ( ITOPT.EQ.2 ) THEN<br>
<b> TYR1(2), TYR2(2), TYR3(2), TYR4(2), TYR5(2), TYR6(2)</b><br>
<b> TYR1(3), TYR2(3), TYR3(3), TYR4(3), TYR5(3), TYR6(3)</b><br>
ENDIF<br>
<br>
ELSE<br>
<br>
<b> RTYRE(1)<br>
</b> <b>ITOPT, COEFFS(1), TYDEF(1)</b><br>
<b> </b> IF ( ITOPT.EQ.2 ) THEN<br>
<b> TYR1(1), TYR2(1), TYR3(1), TYR4(1), TYR5(1), TYR6(1)</b><br>
<b> </b> ENDIF<br>
<br>
ENDIF<br>
<br>
Where<br>
<br>
<b>ITYREND&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Flag to identify if common or separate tyre properties are to be used for front and rear tyres.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
1 = common tyre properties<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
2 or 3 = different tyre properties for front and rear tyres<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
( Bracketed indices (1), (2) and (3) imply, common, front and rear) <br>
<br>
<b>RTYRE&nbsp;&nbsp;
</b>Tyre rolling radius (m). This can be obtained from the ETRTO tables<br>
<br>
<b>ITOPT&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Rolling resistance equation option<br>
1 = use default rolling resistance curve<br>
2 = user specified rolling resistance curve<br>
<br>
<b>COEFFS&nbsp;
</b>Coefficient of friction between tyre and road.<br>
Typically in range 0.8 to 1.05.<br>
<br>
<b>TYDEF&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Tyre transmission efficiency. Typically 0.95<br>
<br>
<br>
<b>TYR1, TYR2, TYR3, TYR4, TYR5, TYR6<br>
</b> Tyre rolling resistance curve coefficients<br>
<br>
Where<br>
<br>
COEFFR = ( TYR1 + ( TYR2 * UM )<br>
&gt; + ( TYR3 * UM * UM )<br>
&gt; + ( TYR4 * UM * UM * UM )<br>
&gt; + ( TYR5 * UM * UM * UM * UM )<br>
&gt; + ( TYR6 * UM * UM * UM * UM * UM ) )/1000.0<br>
<br>
UM - vehicle velocity m/s<br>
<br>
COEFFR - coefficient of rolling resistance N/1000 N<br>
<br>
The following lines show two examples of the TYRE option.<br>
<br>
TYRE<br>
1<br>
.2810<br>
2 1.000 0.95<br>
10.00 -.6418E-01 .4274E-02 .000 .000 .000<br>
<br>
<br>
TYRE<br>
2<br>
0.2810 0.320<br>
2 <br>
1.000 0.95<br>
1.000 0.96<br>
10.00 -.6418E-01 .4274E-02 .000 .000 .000<br>
12.00 -.5330E-01 .3461E-02 .000 .000 .000<br>
<br>
{button ,AL(`list11',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Drivetrain data<br>
</font></b><font size="2"><br>
This option specifies the drive type, the inertia of the wheels, the inertia of the drive shafts and the final drive gear ratio and efficiency.<br>
<br>
*.Car file format;<br>
<br>
<b>DRIVETRAIN</b></font> (keyword)<br>
<b> IDOPT<br>
RIFWHL, RIBWHL<br>
RIPAXL, RIPROP<br>
GRFD, EFFD, IFDEFF<br>
</b><br>
Where<br>
<br>
<b>IDOPT&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Drivetrain type<br>
1 = front wheel drive<br>
2 = rear wheel drive<br>
3 = four wheel drive<br>
<br>
<b>RIFWHL</b> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Rotating inertia of a front wheel (kg.m2). Two front wheels are assumed to be fitted to the vehicle.<br>
<br>
<b>RIBWHL</b>&nbsp;
Rotating inertia of a rear wheel (kg.m2). Two rear wheels are assumed to be fitted to the vehicle.<br>
<br>
<b>RIPAXL</b>&nbsp;
Rotating inertia of axle/drive shaft (kg.m2). This is the total inertia if two drive shafts are fitted.<br>
<br>
<b>RIPROP</b>&nbsp;
Rotating inertia of prop shaft (kg.m2). If not fitted set equal to 0.0.<br>
<br>
<b>GRFD</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Final drive ratio<br>
<br>
<b>EFFD</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Maximum efficiency of final drive. This should in the range 0-1.<br>
<br>
<b>IFDEFF</b>&nbsp;
Final drive efficiency switch<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
1 = Efficiency fixed at EFFD<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
2 = Efficiency as function of speed and load<br>
<br>
The following lines show an example of the DRIVETRAIN option.<br>
<br>
DRIVE<br>
2<br>
.6770 .6770<br>
.0000E+00 .0000E+00<br>
3.742 .9600<br>
<br>
{button ,AL(`list11',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Clutch Data<br>
</font></b><font size="2"><br>
`This option tells the program that a clutch is fitted between the engine and the gearbox input shaft. Note that a clutch and a torque converter cannot be specified in the same model.<br>
<br>
*.Car file format<br>
<br>
<b>CLUTCH</b></font> (keyword)<br>
<b>IUNIT, UDCLTCH</b><br>
<br>
<br>
where<br>
<br>
<b>IUNIT</b>&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Flag that indicates the units of the declutch speed<br>
1 = declutch speed entered in km/h<br>
2 = declutch speed entered in mph<br>
<br>
<b>UDCLTCH</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Road speed at which the clutch is engaged.<br>
<br>
Note - if the CLUTCH option is not set and the TORQUE CONVERTER option is also not set then the program will assume a clutch is fitted and will automatically set the clutch engagement speed to that produced by the engine idle speed in first gear.<br>
<br>
The following lines show an example of the CLUTCH option<br>
<br>
CLUTCH<br>
1 5.000<br>
<br>
{button ,AL(`list11',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Torque Converter Data<br>
</font></b><font size="2"><br>
This option tells the program that a torque converter is fitted between the engine and the gearbox input shaft. Note that a clutch and a torque converter cannot be specified in the same model.<br>
<br>
*.Car file format:<br>
<br>
<b>TORQUE CONVERTER</b></font> (keyword)<br>
<b>NPTC</b><br>
( <b>SPRATIO(J)</b>, J = 1,NPTC )<br>
( <b>TORATIO(J)</b>, J = 1,NPTC )<br>
( <b>FCIN(J)</b>, J = 1,NPTC )<br>
<b>NTLOCK, ILOCKL, ILOCKS</b><br>
-----&gt;<br>
ntlock <b>LPARAM</b>, ( (<b>SLOW(IG), SHIGH(IG)</b>) IG = 1, NGRS)<br>
times<br>
&lt;------<br>
<b>ILIDLE (SRIDLE)</b><br>
<br>
<br>
Where<br>
<br>
<b>NPTC&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Number of point on torque converter characteristic curve (maximum = 20)<br>
<br>
<b>SPRATIO</b> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Torque converter speed ratios at which the torque ratios and input capacity factors are provided. <br>
SPRATIO = OUTPUT SPEED/INPUT SPEED<br>
<br>
<b>TORATIO</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Torque ratio at this speed ratio<br>
TORATIO = OUTPUT TORQUE/INPUT TORQUE<br>
<br>
<b>FCIN&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Torque converter input capacity factor at this speed ratio. (rad/s/sqrt(N.m))<br>
<br>
<b>NTLOCK</b>&nbsp;
Number of load parameters in torque converter lock-up map. Set NTLOCK=0 if torque converter lock-up is not available.<br>
<br>
<b>ILOCKL&nbsp;
</b>Load parameter used to define lock-up map (range 0-14)<br>
0 = Torque fraction<br>
1-14 = Map type No., i.e. 5 = CO emissions<br>
<br>
<b>ILOCKS&nbsp;
</b>Speed parameter used to define lock-up map. (range 1 - 4)<br>
1 = shift speeds specified in ENGINE SPEED (RPM)<br>
2 = shift speeds specified in PROPSHAFT SPEED (RPM)<br>
3 = shift speeds specified in ROAD SPEED (KPH)<br>
4 = shift speeds specified in ROAD SPEED (MPH)<br>
<br>
<b>LPRAM&nbsp;&nbsp;
</b>Torque fraction/map value for this set of lock-up speeds<br>
<br>
<b>SLOW(IG)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Speed at which lock-up is engaged in this gear.<br>
<br>
<b>SHIGH(IG)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Speed at which lock-up is released in this gear<br>
<br>
<b>ILIDLE&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>torque converter mode at idle<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
0 = Normal Idle, (i.e. gearbox remains in drive)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
1 = Full Neutral Idle, (i.e. gearbox placed in neutral and hence no drag torque on gearbox)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
3 = Semi-Neutral Idle, (i.e. gearbox placed in so called semi-neutral where ther remains a speed ratio between converter input and output speed)<br>
<br>
<b> SRIDLE&nbsp;
</b>Speed ratio to be used for semi-neutral idle (range 0 - 1). This data is only entered if ILIDLE = 2<br>
<br>
The following lines show an example of the TORQUE CONVERTER option<br>
<br>
TORQUE CONVERTER<br>
11<br>
.0000000E+00 .1000000 .2000000 .3000000 .4000000<br>
.5000000 .6000000 .7000000 .8000000 .9000000<br>
1.000000<br>
2.280000 2.120000 1.960000 1.800000 1.640000<br>
1.480000 1.320000 1.160000 1.000000 1.000000<br>
1.000000<br>
23.30000 23.40000 23.60000 23.80000 24.10000<br>
24.80000 25.80000 27.10000 29.30000 37.40000<br>
100.000<br>
1 0 1<br>
1.000 6000. 6000. 3200. 3200.<br>
2050. 2050. 1400. 1400.<br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Gearbox Data<br>
</font></b><font size="2"><br>
This option specifies the gearbox gear ratios.<br>
<br>
*.car file format;<br>
<br>
<b>GEARBOX</b></font> (keyword)<br>
<b>NGRS, UTMAXG, USMAXG, IGBEFF</b><br>
------&gt;<br>
<font size="1">NGRS<font size="2"> <br>
</font></font><b>GRATIO(J), GREFF(J), GEARIP(J)<br>
</b> <font size="1">TIMES<font size="2"><br>
&lt;-----<br>
<br>
Where<br>
<br>
<b>NGRS&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b></font></font>Number of gears (maximum = 10)<br>
<br>
<b>UTMAXG</b>&nbsp;
Maximum gearbox input torque (Nm). This is used by the gear efficiency equations. If UTMAXG is set equal to 0.0 then the maximum engine torque is used.<br>
<br>
<b>USMAXG</b>&nbsp;
Maximum gearbox input speed (rpm). This is used by the gear efficiency function equations. If USMAXG is set equal to 0.0 then the maximum engine speed is used.<br>
<br>
<b>IGBEFF</b> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gearbox efficiency switch<br>
1 = Efficiency fixed at GREFF(J) for each gear<br>
2 = Efficiency as function of speed and load<br>
<br>
<b>GRATIO(J)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gearbox gear ratio for gear J<br>
<br>
<b>GREFF(J)</b> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gearbox maximum transmission efficiency in gear J.<br>
<br>
<b>GEARIP(J)</b> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gearbox rotating inertia at gearbox input speed (kg.m2).<br>
<br>
The following lines show an example of the GEARBOX option.<br>
<br>
GEARBOX<br>
4 440.0 6500 2<br>
3.027 .9800 .4330E-01<br>
1.619 .9800 .4470E-01<br>
1.000 .9800 .7520E-01<br>
.6940 .9800 .7870E-01<br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Gear Shift Data<br>
</font></b><font size="2"><br>
This option specifies the user gear shift strategies.<br>
<br>
*.car file format;<br>
<br>
<b>GSHIFT</b></font> (keyword)<br>
<br>
<b>NSHIFT</b><br>
---------------&gt;<br>
nshift <br>
times| <b>TITSHFT(IS)</b><br>
| <b>NTORS(IS), ISOPTL(IS), ISOPTS(IS)<br>
</b> | ----------------&gt;<br>
| ntors <b>LPARAM(IS),</b> ( (<b>SLOW(IG), SHIGH(IG)</b>) IG = 1, NGRS)<br>
| times<br>
| ----------------&lt;<br>
| <b>ISMODE, IKDOWN</b><br>
&lt;------<br>
<br>
Where<br>
<br>
<b>NSHIFT</b> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Number of user shift maps (maximum = 10)<br>
<br>
<b>TITSHIFT(IS)</b>&nbsp;&nbsp;&nbsp;
Title of shift map IS. (maximum = 80 characters)<br>
<br>
<b>NTORS(IS)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Number of load fractions in shift map (maximum = 15)<br>
<br>
<b>ISOPTL(IS)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Load parameter used to define shift map (range 0-17)<br>
0 = Torque fraction<br>
1-17 = Map type No.(i.e. 5 = CO emissions)<br>
<br>
<b>ISOPTS(IS)</b> &nbsp;&nbsp;&nbsp;&nbsp;
Speed parameter used to define shift map. (range 1 - 4)<br>
1 = shift speeds specified in ENGINE SPEED (RPM)<br>
2 = shift speeds specified in PROPSHAFT SPEED (RPM)<br>
3 = shift speeds specified in ROAD SPEED (KM/H)<br>
4 = shift speeds specified in ROAD SPEED (MPH)<br>
<br>
<b>LPRAM(IS)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Torque fraction/map value for this set of shift speeds<br>
<br>
<b>SLOW(IG)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Lowest speed allowed in this gear. This is the same as the shift down speed.<br>
<br>
<b>SHIGH(IG)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Highest speed allowed in this gear. This is the same as the shift up speed.<br>
<br>
<b>ISMODE(IS)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Shift mode<br>
1 = FREE - gear shifts will be made to minimise the parameter specified in the OPTIMUM option.<br>
2 = FORCED - gear shifts will only occur when a shift line is crossed.<br>
<br>
<b>IKDOWN(IS)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Controls <font face="Times New Roman"><font face="Arial">kick down</font></font><font face="Times New Roman"><font face="Arial"> mode under acceleration<br>
</font></font>0 = OFF - Kick down disabled<br>
1 = ON - kick down enabled<br>
<br>
The following lines show an example of the GSHIFT option<br>
<br>
GSHIFT<br>
1<br>
Title - this shift map used the M.A.P. map<br>
6 12 1<br>
0.8000e-01<br>
600.0 1367.<br>
658.0 1505.<br>
808.0 2250.<br>
1451.0 6200.<br>
.1000<br>
600.0 1538.<br>
658.0 1787.<br>
1039. 2366.<br>
1491. 6200.<br>
.2000<br>
600.0 1880.<br>
658.0 2211.<br>
1154. 2770.<br>
1608. 6200.<br>
.3000<br>
600.0 2393.<br>
658.0 2822.<br>
1269. 4500.<br>
1648. 6200.<br>
.6000<br>
600.0 3931.<br>
658.0 4139.<br>
1962. 6200.<br>
3923. 6200.<br>
1.000<br>
600.0 6200.<br>
2822. 6200.<br>
3578. 6200.<br>
4000. 6200.<br>
2 1<br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Gear Loss Data<br>
</font></b><font size="2"><br>
This option allows the user to specify the gearbox torque losses (spin losses).<br>
<br>
*.car file format;<br>
<br>
<b>GLOSS</b></font> (keyword)<br>
<br>
<b>TITGLOS</b><br>
<br>
-----------------&gt;<br>
ngrs<br>
times<br>
| <b>NGLOS(IG), NGLOT(IG)<br>
</b> |<br>
| <b>GLSPD(IS)</b> IS = 1, NGLOS<br>
| <b>GLTFR(IT)</b> IT = 1, NGLOT<br>
| ---------------------&gt;<br>
| nglot <b>GLTOR(IS,IT)</b> IS = 1, NGLOS<br>
| times<br>
| ---------------------&lt;<br>
---------&lt;<br>
<br>
Where<br>
<br>
<br>
<b>TITGLOS</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gear loss data title. (maximum = 80 characters)<br>
<br>
<b>NGLOS(IG)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Number of gearbox input speeds for gear loss curves in this gear (maximum 20)<br>
<br>
<b>NGLOT(IG)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Number of torque fractions for which gear loss curves are supplied in this gear (maximum 10)<br>
<br>
<b>GLSPD(IS)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gearbox input speeds (rpm)<br>
<br>
<b>GLTFR(IT)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gearbox input torque fractions (0- 1.0). This is assumed to be the same as engine torque fraction<br>
<br>
<b>GLTOR(IS,IT)</b>&nbsp;&nbsp;&nbsp;
Gearbox torque loss (Nm) for input speed IS and torque fraction IT<br>
<br>
The following lines show an example of the GLOSS option.<br>
<br>
GLOSS<br>
Spin Loss Title<br>
6 3<br>
600. 1000. 2000. 3000. 4500. 6500.<br>
.5000 .8000 1.000<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
4.531 5.175 5.413 5.526 5.876 6.328<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
5.876 7.345 9.831 12.20 13.33 14.80<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
7.119 8.701 10.85 12.54 14.01 15.93<br>
6 3<br>
600. 1000. 2000. 3000. 4500. 6500.<br>
.5000 .8000 1.000<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
3.108 3.187 3.390 3.684 4.362 5.254<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
4.859 5.424 5.311 6.215 7.684 9.639<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
5.989 6.328 6.102 6.667 7.910 9.639<br>
6 3<br>
600. 1000. 2000. 3000. 4500. 6500.<br>
.5000 .8000 1.000<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
3.808 3.582 3.684 4.068 5.108 6.486<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
5.537 5.989 5.424 5.876 7.684 10.09<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
6.441 6.780 6.328 6.554 8.136 10.25<br>
6 3<br>
600. 1000. 2000. 3000. 4500. 6500.<br>
.5000 .8000 1.000<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
3.605 3.526 3.661 4.249 5.130 6.305<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
6.215 6.441 6.215 7.232 11.19 11.19<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
6.893 8.701 7.006 8.136 11.75 11.75<br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Engine Specification Data<br>
</font></b><font size="2"><br>
This option specifies the engine details and torque curve.<br>
<br>
*.Car file format;<br>
<br>
<b>ENGINE</b></font> (keyword)<br>
<b> IETYPE<br>
BORE, STROKE, CR, NCYL, ICYC, RIENG<br>
SPIDLE, SPEMAX<br>
NSPC<br>
</b> -----&gt;<br>
nspc <b>SPDPC(I), BMEPC(I)</b><br>
times<br>
&lt;-----<br>
<br>
Where<br>
<br>
<b>IETYPE&nbsp;
</b>Engine type (must = 1)<br>
1 = Internal combustion engine<br>
<br>
<b>BORE&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Engine bore (mm)<br>
<br>
<b>STROKE</b>&nbsp;
Engine stroke (mm)<br>
<br>
<b>CR</b> &nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Compression Ratio, (only used in conjunction with engine scaling)<br>
<br>
<b>NCYL</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Number of cylinders<br>
<br>
<b>ICYC</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Cycle type<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
2 = Two stroke<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
4 = Four stroke<br>
<br>
<b>RIENG&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Rotating inertia of engine (kg.m2)<br>
<br>
<b>SPIDLE&nbsp;
</b>Engine idle speed (rpm)<br>
<br>
<b> SPEMAX</b>&nbsp;
Maximum engine speed (rpm)<br>
<br>
<b> NSPC&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Number of points used to define power curve ( maximum = 20 )<br>
<br>
<b>SPDPC(I)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Engine speed at point I (rpm)<br>
<br>
<b>BMEPC(I)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Maximum BMEP at this engine speed (bar).<br>
<br>
The following lines show an example of the ENGINE option<br>
<br>
<br>
ENGINE<br>
1<br>
77.00 79.00 10 4 4 .1261<br>
850. 6500.<br>
16<br>
850.0 7.370<br>
1000. 7.620<br>
1400. 8.210<br>
1800. 8.800<br>
2200. 9.130<br>
2600. 9.880<br>
3000. 10.05<br>
3400. 9.800<br>
3800. 9.800<br>
4200. 10.14<br>
4600. 10.22<br>
5000. 9.800<br>
5400. 9.630<br>
5800. 9.130<br>
6200. 8.290<br>
6500. 7.120<br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Engine Scaling Data<br>
</font></b><font size="2"><br>
This option allows the user to scale the engine performance and consumption maps by factors which scale with bore and stroke.<br>
<br>
*.Car file format;<br>
<br>
<b>ENG_SCALE</b></font>(keyword)<br>
<br>
<b> BSCALE, SSCALE, CRSENS<br>
TEBORE, TESTROKE,TECR<br>
SPBORE, SPSTROKE<br>
ESSMIN, ESSMAX<br>
IFRIC<br>
</b><br>
IF ( IFRIC.EQ.1 ) THEN ENTER FRICTION CURVES <br>
<b>NFRIC</b><br>
nfric ----------&gt;<br>
times | <b>FRICSP(I), FMEPOLD(I), FMEPNEW(I)</b><br>
-----------&lt;<br>
ELSE IF ( IFRIC.EQ.2 ) READ FRICTION MODEL DATA <br>
<b> NMAIN <br>
DMAIN,WMAIN<br>
DBIG,WBIG<br>
ICTYPE,IFTYPE,NVALVE,VLIFT<br>
DCAM,WCAM<br>
</b> ELSE IF ( IFRIC.EQ.3 ) READ FRICTION MODEL FOR EACH ENGINE<br>
<b> NMAIN<br>
DMAIN,WMAIN<br>
DBIG,WBIG<br>
ICTYPE,IFTYPE,NVALVE,VLIFT<br>
DCAM,WCAM<br>
NMAIN2<br>
DMAIN2,WMAIN2<br>
DBIG2,WBIG2<br>
ICTYPE2,IFTYPE2,NVALVE2,VLIFT2<br>
DCAM2,WCAM2<br>
</b><br>
<br>
Where<br>
<br>
<b>BSCALE&nbsp;
</b>Engine bore to which input data is to be scaled (mm)<br>
<br>
<b>SSCALE&nbsp;
</b>Engine stroke to which input data is to be scaled (mm)<br>
<br>
<b>CRSENS&nbsp;
</b>Compression ratio change per mm increase in bore (1/mm)<br>
<br>
<b>TEBORE</b>&nbsp;
% change in thermal efficiency per mm increase in bore (%/mm). This number is normally negative.<br>
<br>
<b>TESTROKE&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>% change in thermal efficiency per mm increase in stroke (%/mm). This number is normally 0.0<br>
<br>
<b>TECR&nbsp;&nbsp;&nbsp;
</b>% change in thermal efficiency per unit increase in compression ratio.<br>
<br>
<b>SPBORE&nbsp;
</b>% change in speed data per mm increase in bore. The number is normally 0.0<br>
<br>
<b>SPSTROKE</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
% change in speed data per mm increase in stroke. This number is usually -ve.<br>
<br>
<b>ESSMIN&nbsp;
</b>Minimum engine speed (i.e. idle speed) to be set after speed scaling. If ESSMIN is 9999.0 then the scaled minimum is used.<br>
<br>
<b>ESSMAX&nbsp;
</b>Maximum engine speed to be set after speed scaling. If ESSMAX is 9999.0 then the scaled maximum is used.<br>
<br>
<b>IFRIC</b>&nbsp;&nbsp;
Friction model option <br>
1 = enter mechanical friction data for original and scaled engine<br>
2 = use friction model to estimate change in friction with changes in bore and stroke<br>
3 = use friction model to estimate change in friction with specified changes in bearings and valve train.<br>
<br>
<b>FRICSP(I)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Engine speed at which mechanical friction data will be specified (rpm)<br>
<br>
<b>FMEPOLD(I)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Mechanical friction in BAR of original engine<br>
<br>
<b>FMEPNEW(I)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Mechanical friction in BAR of scaled engine<br>
<br>
<b>NMAIN/NMAIN2&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Number of main bearing<br>
<br>
<b>DMAIN/DMAIN2&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Diameter of main bearings (mm)<br>
IF DMAIN = 9999.0 Estimate bearing sizes for an inline engine DMAIN = 0.68*BORE <br>
IF DMAIN = 9998.0 Estimate bearing sizes for an V cyl per pin engine DMAIN = 0.7*BORE <br>
IF DMAIN = 9997.0 Estimate bearing sizes for an V 2 cyl per pin engine DMAIN = 0.62*BORE <br>
<br>
<b>WMAIN/WMAIN2&nbsp;&nbsp;&nbsp;
</b>Width of main bearings (mm)<br>
IF WMAIN = 9999.0 Estimate bearing sizes for an inline engine WMAIN = 0.36*BORE <br>
IF WMAIN = 9998.0 Estimate bearing sizes for an V cyl per pin engine WMAIN = 0.35*BORE <br>
IF WMAIN = 9997.0 Estimate bearing sizes for an V 2 cyl per pin engine WMAIN = 0.40*BORE <br>
<br>
<b>DBIG /DDIG2</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Diameter of big end bearings (mm)<br>
IF DBIG = 9999.0 Estimate bearing sizes for an inline engine DBIG = 0.57*BORE <br>
IF DBIG = 9998.0 Estimate bearing sizes for an V cyl per pin engine DBIG = 0.6*BORE <br>
IF DBIG = 9997.0 Estimate bearing sizes for an V 2 cyl per pin engine DBIG = 0.57*BORE <br>
<br>
<b>WBIG/WBIG2&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Width of big end bearings (mm)<br>
IF WBIG = 9999.0 Estimate bearing sizes for an inline engine WBIG = 0.35*BORE <br>
IF WBIG = 9998.0 Estimate bearing sizes for an V cyl per pin engine WBIG = 0.36*BORE <br>
IF WBIG = 9997.0 Estimate bearing sizes for an V 2 cyl per pin engine WBIG = 0.39*BORE <br>
<br>
<b>ICTYPE/ICTYPE2</b>&nbsp;
Valve train type<br>
1 = OHV pushrod with rockers<br>
2 = DOHC<br>
3 = SOHC<br>
4 = SOHC with rockers<br>
5 = DOHC with rockers<br>
<br>
<b>NVALVE/NVALVE2&nbsp;
</b>Number of valves per cylinder<br>
<br>
<b>VLIFT/VLIFT2</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Maximum valve lift (mm)<br>
<br>
<b>DCAM/DCAM2</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Diameter of cam bearings (mm)<br>
If DCAM = 9999.0 diameter set = 0.34*BORE<br>
<br>
<b>WCAM/WCAM2</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Width of cam bearing (mm)<br>
If WCAM = 9999.0 width set = 0.66*DCAM<br>
<br>
The following lines show three examples of the ENG_SCALE option<br>
<br>
This example uses IFRIC=1 where the change in mechanical friction is specified<br>
<br>
ENG_SCALE<br>
81.60 86.00 .0000E+00<br>
.0000E+00 .0000E+00 10.00 <br>
.0000E+00 .0000E+00<br>
600.0 6500. <br>
1<br>
8<br>
600.0 .9016 .8964 <br>
1400. .9665 .9553 <br>
2400. 1.175 1.156 <br>
3200. 1.369 1.342 <br>
4000. 1.575 1.541 <br>
4800. 1.791 1.749 <br>
5600. 2.016 1.965 <br>
6500. 2.278 2.217 <br>
<br>
This example uses IFRIC=2 where the bearings are all scaled from the bore dimension<br>
<br>
ENG_SCALE<br>
80.50 88.20 .0000E+00<br>
.8750E-01 .0000E+00 10.00 <br>
.0000E+00 -1.150 <br>
600.0 6500. <br>
2<br>
5<br>
9999. 9999. <br>
9999. 9999. <br>
2 3 4 9.000 <br>
28.00 17.00 <br>
<br>
This example shows how the effect of bearing dimensions can be examined<br>
<br>
ENG_SCALE<br>
81.60 86.00 .0000E+00<br>
.0000E+00 .0000E+00 10.00 <br>
.0000E+00 .0000E+00<br>
600.0 6500. <br>
3<br>
5<br>
58. 21. <br>
49. 20. <br>
2 3 4 9.000 <br>
28.00 17.00 <br>
5<br>
52.5 21. <br>
47. 20. <br>
2 3 4 9.000 <br>
28.00 17.00 <br>
<br>
{button ,AL(`list11',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Engine Map Data<br>
</font></b><font size="2"><br>
This option specifies the engine economy, emission and operating maps as required. The maps are all specified on a common grid of speed and load points. This grid is first specified, followed by the map data. The grid does not have to be regular, but a complete grid must be provided. Thus some extrapolation of data above the full load BMEP is required to satisfy the input requirements. The accuracy of the extrapolated data will not effect the calculated results.<br>
<br>
*.Car file format;<br>
</font><br>
<b>MAP</b> (keyword)<br>
<b>NSPMAP</b><br>
<b>SPDMAP(K)</b>,K = 1,NSPMAP<br>
<b>NLDMAP</b><br>
<b>BMEPMAP(J)</b>,J = 1,NLDMAP<br>
<b>NMAP</b><br>
-----------------&gt;<br>
nmap<br>
times<br>
| <b>IMAP, IMUNIT, (SG), (CALVAL), (FACT)</b><br>
| -----------------&gt;<br>
| nspmap<br>
| times <b>DATMAP(J,K)</b>,J = 1,NLDMAP<br>
| -----------------&lt;<br>
| <b>IORUN</b><br>
| (<b>DORUN(K)</b>, K = 1, NSPMAP)<br>
|<br>
----------------&lt;<br>
<br>
Where<br>
<br>
<b>NSPMAP&nbsp;
</b>Number of speeds used to define maps ( maximum = 40 )<br>
<br>
<b>SPDMAP(J</b>)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Engine speed at K map point (rpm).<br>
<br>
<b>NLDMAP</b>&nbsp;
Number of loads used to define maps ( maximum = 40 )<br>
<br>
<b>BMEPMAP(J)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Engine BMEP at J map point (bar).<br>
<br>
<b>NMAP</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Number of maps to be defined ( maximum = 14 )<br>
<br>
<b>IMAP&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Map type. The map types available are;<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
1 = Fuel consumption<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
2 = Air consumption<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
3 = Hydrocarbon emissions<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
4 = NOx emissions<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
5 = CO emissions<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
6 = CO2 emissions<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
7 = O2 emissions<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
8 = Particulate emissions<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
9 = user flow<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
10 = spark timing<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
11 = throttle position<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
12 = manifold air pressure (bar)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
13 = air fuel ratio<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
14 = Exhaust temp<br>
<br>
<b>IMUNIT&nbsp;
</b>Units flag<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
For map type 1 - 9 the unit options are<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
0 = GMS/S<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
1 = GMS/HR<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
2 = GMS/KW.HR<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
3 = GMS/HR/LITRE<br>
<br>
<b>SG</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Specific gravity of fuel (0.75-gasoline 0.84-diesel).This should only be entered if IMAP=1<br>
<br>
<b>CALVAL&nbsp;
</b>Calorific value of fuel (kJ/kg). This should only be entered in IMAP=1<br>
<br>
<b>FACT&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Scaling factor for map data. This can be used to make global changes to the map data.<br>
<br>
<b>DATMAP(J,K)&nbsp;&nbsp;&nbsp;&nbsp;
</b>Map data at BMEP J and speed K<br>
<br>
<b>IORUN</b>&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Overrun map option. This tells the program which map values to use when the engine is being motored by the vehicle inertia.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
0 = set overrun map value to lowest load value<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
1 = set overrun map value to zero<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
2 = user will specify overrun values<br>
<br>
Note that the overrun map value specified for the first speed is that used when the engine is at idle (unless auxiliaries or a torque converter are specified).<br>
<br>
<b>DORUN(K)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
user specified overrun map values at speed K.<br>
The units for DORUN are g/s for map type 1-9 when IMUNIT = 0 or 1 and g/s/l when IMUNIT = 2 or 3<br>
<br>
The following lines show an example of the MAP option in which a fuel consumption map is entered.<br>
<br>
MAPS<br>
16<br>
850.0 1000. 1400. 1800. 2200.<br>
2600. 3000. 3400. 3800. 4200.<br>
4600. 5000. 5400. 5800. 6200.<br>
6500.<br>
12<br>
.1000E-01 .8380 1.676 2.514 3.352<br>
4.190 5.028 5.866 6.704 7.542<br>
8.380 9.218<br>
1<br>
1 2 .7500 .4200E+05 1.00 FUEL G/KW.H<br>
.6975E+05 1008. 572.9 504.1 406.7<br>
368.3 351.8 368.3 376.6 408.3<br>
440.1 471.9<br>
.5929E+05 816.2 462.1 381.1 340.1<br>
313.1 299.1 313.1 320.1 347.1<br>
374.1 401.1<br>
.4782E+05 747.9 461.9 374.0 313.0<br>
299.0 292.0 286.0 286.0 299.0<br>
326.0 353.0<br>
.3865E+05 680.0 449.0 367.0 313.0<br>
299.0 279.0 270.0 265.0 270.0<br>
299.0 312.0<br>
.3651E+05 653.1 435.1 353.0 299.0<br>
292.0 279.0 270.0 265.0 270.0<br>
286.0 300.0<br>
.3701E+05 748.0 476.0 367.0 306.0<br>
292.0 286.0 279.0 265.0 265.0<br>
279.0 299.0<br>
.3798E+05 748.0 476.0 353.0 313.0<br>
299.0 286.0 279.0 272.0 265.0<br>
286.0 313.0<br>
.3874E+05 680.1 449.0 367.0 319.0<br>
313.0 292.0 279.0 279.0 286.0<br>
313.0 313.0<br>
.3871E+05 653.0 449.0 381.0 340.0<br>
326.0 326.0 340.0 326.0 326.0<br>
313.0 313.0<br>
.3872E+05 748.0 517.0 408.0 394.0<br>
374.0 347.0 353.0 340.0 326.0<br>
319.0 313.0<br>
.5478E+05 789.1 639.0 544.0 476.0<br>
435.0 394.0 367.0 360.0 353.0<br>
340.0 333.0<br>
.6827E+05 952.0 789.0 585.0 489.0<br>
476.0 428.0 421.0 401.0 381.0<br>
367.0 381.0<br>
.7977E+05 1292. 816.0 639.0 530.0<br>
517.0 476.0 462.0 449.0 408.0<br>
394.0 408.0<br>
.9117E+05 1400. 856.1 666.0 612.0<br>
544.0 503.0 476.0 469.0 442.0<br>
428.0 442.0<br>
.9118E+05 1496. 952.0 693.0 666.0<br>
598.0 544.0 530.0 476.0 476.0<br>
476.0 496.0<br>
.9952E+05 1577. 982.9 710.9 672.7<br>
600.3 543.8 526.9 472.7 470.7<br>
469.0 486.7<br>
2<br>
.5661E-01 .5661E-01 .5661E-01 .5661E-01 .5661E-01<br>
.5661E-01 .5661E-01 .5661E-01 .5661E-01 .5661E-01<br>
.5661E-01 .5661E-01 .5661E-01 .5661E-01 .5661E-01<br>
.5661E-01<br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Optimum Data<br>
</font></b><font size="2"><br>
This option specifies the engine speed/power line that produces either optimum(maximum) performance or optimum(minimum) economy/emissions.<br>
<br>
*.Car file format;<br>
<br>
<b>OPTIMUM</b></font> (keyword)<br>
<b>IOPT</b><br>
IF ( IOPT.EQ.1 ) THEN<br>
<b>NOPTU</b><br>
<b>SPOPTU(J), PWOPTU(J)</b>, J = 1,NOPTU<br>
ELSE IF ( IOPT.EQ.2 )<br>
<b>IMOPT</b><br>
ENDIF<br>
<br>
Where<br>
<br>
<b>IOPT</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Optimum line option<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
1 = user specified optimum line<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
2 = optimum line calculated to minimise map parameter<br>
<br>
<b>NPOTU</b>&nbsp;&nbsp;
Number of speeds in user specified speed/power line.( maximum = 20 )<br>
<br>
<b>SPOPTU(J)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Engine speed at which optimum power is specified (rpm).<br>
<br>
<b>PWOPTU(J)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Optimum engine power at this engine speed (kW).<br>
<br>
<b>IMOPT&nbsp;&nbsp;
</b>Map number for which the optimum line is calculated.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
IMOPT must be greater than 0 and less than or equal to 17 (i.e. 5 = CO emissions), (map type must be defined)<br>
<br>
Note - If the optimum option is not specified then the optimum power line is set equal to the power curve.<br>
<br>
The following lines show an example of the OPTIMUM option<br>
<br>
OPTIMUM<br>
1<br>
12<br>
1000. .1000<br>
1000. 4.000<br>
1200. 7.000<br>
1800. 11.00<br>
2000. 15.00<br>
2800. 25.00<br>
3000. 28.00<br>
3800. 42.00<br>
4600. 48.00<br>
5000. 52.00<br>
5400. 59.00<br>
5800. 65.80<br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Catalyst Data<br>
</font></b><font size="2"><br>
This option specifies the maximum conversion efficiency and warm-up times for a catalyst fitted to the vehicle.<br>
<br>
*.Car file format;<br>
<br>
<b>CATALYST</b></font> (keyword)<br>
<b>CATEF-HC, CATT1-HC, CATT2-HC<br>
CATEF-NOX, CATT1-NOX, CATT2-NOX<br>
CATEF-CO, CATT1-CO, CATT2-CO</b><br>
<br>
Where<br>
<br>
<b>CATEF-HC</b><br>
<b>CATEF-NOX&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Maximum catalyst conversion efficiency for HC, NOX<br>
<b>CATEF-CO&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>and CO emissions respectively. (range 0-1)<br>
<br>
<b>CATT1-HC</b><br>
<b>CATT1-NOX&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Time from start of cycle to point at which catalyst<br>
<b>CATT1-CO&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>starts to warm up (seconds).<br>
<br>
<b>CATT2-HC</b><br>
<b>CATT2-NOX&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Time from start of cycle to point at which catalyst<br>
<b>CATT2-CO</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
has reached its maximum conversion efficiency (seconds).<br>
<br>
The following lines show an example of the CATALYST option<br>
<br>
CATALYST<br>
.9500 100.0 20.00<br>
.9800 80.00 20.00<br>
.9600 120.0 20.00<br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Warm-Up Data<br>
</font></b><font size="2"><br>
This option allows the user to specify the increase in the 3 primary emissions at startup and how these ramp down to their steady state value with time. This option also allows the user to specify the transient increase in these emissions during accelerations and decelerations.<br>
<br>
*.Car file format<br>
<br>
<b>WARM-UP</b></font> (keyword)<br>
<b>WARMF-HC, WARMT-HC, WACFACT-HC<br>
WARMF-NOX, WARMT-NOX, WACFACT-NOX<br>
WARMF-CO, WARMT-CO, WACFACT-CO</b><br>
<br>
Where<br>
<br>
<b>WARMF-HC</b><br>
<b>WARMF-NOX&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Engine out emissions factor for HC, NOX and CO<br>
<b>WARMF-CO&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>at start of cycle. (typically between 1 and 5)<br>
where Emissions = (WARMF-* + 1 ) * Steady state emission<br>
<br>
<b>WARMT-HC</b><br>
<b>WARMT-NOX&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Time during which the above emissions factors<br>
<b>WARMT-CO&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>reduce to 1.0 (seconds). This could be interpreted<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
as the warm-up time.<br>
<br>
<b>WACFACT-HC</b><br>
<b>WACFACT-NOX&nbsp;&nbsp;&nbsp;&nbsp;
</b>Emissions acceleration factor.(s2/m)<br>
<b>WACFACT-CO&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Where Emissions = Steady state emissions + ABS(WAFACT*acceleration*Steady state emissions)<br>
<br>
The following lines show an example of the WARM-UP option.<br>
<br>
WARM-UP<br>
4.000 80.00 .8000E-01<br>
.0000E+00 .0000E+00 .0000E+00<br>
1.000 80.00 .0000E+00<br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Auxiliaries Data<br>
</font></b><font size="2"><br>
This option allows the user to simulate the effect of power consumed by auxiliaries fitted to the engine, for example the air conditioning unit.<br>
<br>
*.Car file format;<br>
<br>
<b>AUXILIARIES</b></font> (keyword) <br>
<br>
<b>NAUX</b><br>
------------&gt;<br>
naux<br>
times<br>
|<br>
| <b>TITAUX(IA)</b><br>
| <b>IPAUX(IA)&nbsp;&nbsp;&nbsp;&nbsp;
NPAUX(IA)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
DRAUX(IA)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
DIAUX(IA)</b><br>
| -------&gt;<br>
| naux<br>
| times&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>AUSPD(IP,IA)&nbsp;&nbsp;&nbsp;&nbsp;
AUTOR(IP,IA)</b><br>
| --------&lt;<br>
--------&lt;<br>
<br>
Where<br>
<br>
<b>NAUX</b> &nbsp;&nbsp;
Number of auxiliaries fitted to the vehicle (maximum 5)<br>
<br>
<b>TITAUX</b> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Title for auxiliary IA (Maximum 30 characters)<br>
<br>
<b>IPAUX(IA)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Mounting position of auxiliary (1-4)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
1 = Engine Mounted Auxiliary<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
2 = Gearbox Input Mounted Auxiliary<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
3 = Propshaft Mounted Auxiliary<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
4 = Axle Mounted Auxiliary<br>
<br>
<b>NPAUX(IA)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Number of Points on auxiliary loss curve<br>
<br>
<b>DRAUX(IA)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Auxiliary Drive Ratio<br>
<br>
<b>DIAUX(IA)</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Auxiliary Rotating Inertia (kg.m2)<br>
<br>
<b>AUSPD(IP,IA)</b> &nbsp;&nbsp;
Auxiliary Speed (rpm)<br>
<br>
<b>AUTOR(IP,IA)</b>&nbsp;&nbsp;&nbsp;
Auxiliary Torque (Nm)<br>
<br>
The following lines show an example of the AUXILIARIES option<br>
<br>
AUXILARIES<br>
1<br>
PS PUMP<br>
1 5 1.170 .1000E-02<br>
1000. 1.358<br>
2000. 1.375<br>
3000. 1.455<br>
4000. 1.536<br>
5000. 1.569 <br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Grid Analysis Data<br>
</font></b><font size="2"><br>
This option provides the user with the facility to perform a grid analysis of the engines operation over the calculated cycle. This provides a summary of the time spent, fuel/emissions consumed, and mean map variables in user defined segments of the engines speed/load envelope.<br>
<br>
*.Car file format;<br>
<br>
<b>GRID</b></font> (keyword)<br>
<b> NSGRID, NBGRID</b><br>
<b>SGRID(I)</b>, I=1,NSGRID<br>
<b>BGRID(J)</b>, J=1,NBGRID<br>
<br>
Where<br>
<br>
<b>NSGRID</b>&nbsp;
Number of engine speeds used to define grid, (minimum = 2, maximum = 20)<br>
<br>
<b>NBGRID</b>&nbsp;
Number of BMEP's used to define grid,(minimum = 2, maximum = 20)<br>
<br>
<b>SPGRID(I)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Engine speed for grid point I (rpm)<br>
<br>
<b>BGRID(J)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Engine BMEP for grid point J (bar)<br>
<br>
The following lines show an example of the GRID option<br>
<br>
GRID<br>
7 12<br>
.0000E+00 1000. 2000. 3000. 4000.<br>
5000. 6000.<br>
.0000E+00 1.000 2.000 3.000 4.000<br>
5.000 6.000 7.000 8.000 9.000<br>
13.00 14.00<br>
<br>
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<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Primary Drive Data<br>
</font></b><font size="2"><br>
This option provides the user with the facility to define a drive ratio for the primary take-off transmission from engine crankshaft/flywheel to the gearbox input shaft.<br>
<br>
*.Car file format;<br>
<br>
<b>PRDIVE</b></font> (keyword)<br>
<b>GRPD, EFPD, IPDEFF</b><br>
<br>
Where<br>
<br>
<b>GRPD</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Drive ratio<br>
<br>
<b>EFPD</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Drive Efficiency (0 - 1)<br>
<br>
<b>IPDEFF</b>&nbsp;
Efficiency Mode<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
1 = Fixed<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
2 = Function of load and speed<br>
<br>
The following lines show an example of the PDRIVE option<br>
<br>
PDRIVE<br>
0.98 0.88 1<br>
<br>
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<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Standard Hybrid Data<br>
</font></b><font size="2"><br>
This option allows the user to model the standard HYBRID vehicle system. The HYBRID is capable of absorbing energy from, and returning energy to the drivetrain system. The program will always preferentially drive the vehicle with HYBRID motor, any excess energy requirements and or charging being provided by the engine.<br>
<br>
*.Car file format<br>
<br>
<b>HYBRID</b></font> (keyword)<br>
<b>IHOPT<br>
STSMAX, STSMIN<br>
STRIN, STEFIN<br>
STROUT, STEFOUT<br>
STSENG, ISTIDLE<br>
</b><br>
Where<br>
<br>
<b>IHOPT&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Indicates the position of the HYBRID motor<br>
1 = Engine Flywheel mounted<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
2 = Gearbox mounted<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
3 = Drive shaft mounted<br>
<br>
<b>STSMAX</b>&nbsp;
Maximum energy that can be stored by the HYBRID (kW.h). If the current energy stored in the HYBRID matches STSMAX then no more regeneration is permitted only power output is allowed.<br>
<br>
<b>STSMIN&nbsp;
</b>Minimum energy permitted for HYBRID (kW.h). If the current energy stored in the HYBRID matches STSMIN then no more energy can be taken from the HYBRID only regeneration is allowed.<br>
<br>
<b>STRIN&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Max HYBRID motor input torque (NM). This is when energy is removed from the drivetrain and stored in the HYBRID.<br>
<br>
<b>STEFIN&nbsp;
</b>Efficiency of HYBRID energy input (0-1).<br>
<br>
<b>STROUT&nbsp;
</b>Max HYBRID motor output torque (NM). This is when energy is provided to the drivetrain by the HYBRID motor.<br>
<br>
<b>STEFOUT&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Efficiency of HYBRID energy output (0-1).<br>
<br>
<b>STSENG&nbsp;
</b>Energy available in HYBRID at start of cycle (kW.h)<br>
<br>
<b>ISTIDLE&nbsp;
</b>Hybrid charging at IDLE option.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
0 = No charging of the HYBRID at idle<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
1 = Hybrid is charged when engine is at idle.<br>
<br>
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<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Driver Data<br>
</font></b><font size="2"><br>
This option provides a very simple driver model, that describes the gear shift times, braking efficiency and brake balance being employed by this driver.<br>
<br>
*.Car file format<br>
<br>
<b>DRIVER</b></font> (keyword)<br>
<b>DCEFFY, DBEFFY , DBBAL, TGSHIFT, TGSHIFTINT, CYCACC</b><br>
<br>
Where<br>
<br>
<b>DCEFFY&nbsp;
</b>Driver cornering efficiency (fraction 0-1). This defines the maximum cornering speed as a fraction of the maximum theoretical speed. This is only used in track simulations.<br>
<br>
<b>DBEFFY&nbsp;
</b>Driver braking efficiency (fraction 0-1). This defines the maximum braking force as a fraction of the maximum theoretical force. This is only used in the track simulations.<br>
<br>
<b>DBBAL</b>&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Driver brake balance - defined as the fraction of the total braking effort on the front wheels (fraction 0-1).<br>
<br>
<b>TGSHIFT</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gear shift time (seconds). If the DRIVER option is not specified then TGSHIFT is set to 0.1 seconds.<br>
<br>
<b>TGSHIFTINT</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Minimum Shift Interval (seconds). If no interval required then is set to zero.<br>
<br>
<b>CYCACC</b>&nbsp;
Accuracy with which cycle is driven.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
0 = Exact Fit<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
1 = Smoothed<br>
<br>
The following lines show an example of the DRIVER option<br>
<br>
DRIVER<br>
0.900 0.800 .5000 .4000 .25 0<br>
<br>
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<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">*.Car Format for the Aerodynamic Data<br>
</font></b></font><font size="2"><br>
This option provides the extended aerodynamic model, allowing non-linear coefficients to be used for vehicle drag and lift. The coefficients being functions of vehicle speed.<br>
<br>
*.Car file format<br>
<br>
<b>AERODYNAMICS</b></font> (keyword)<br>
<b>ICD, ICLF, ICLR<br>
</b><br>
for ICD = 1<br>
<b> COEFF_CD(I)</b>, I=1,6<br>
for ICD = 2<br>
<b> NCD<br>
XCD(I),YCD(I)</b>, I=1,NCD<br>
<br>
for ICLF = 1<br>
<b> COEFF_CLF(I)</b>, I=1,6<br>
for ICLF = 2<br>
<b> NCLF<br>
XCLF(I),YCLF(I)</b>, I=1,NCLF<br>
<br>
for ICLR = 1<br>
<b> COEFF_CLR(I)</b>, I=1,6<br>
for ICLR = 2<br>
<b> NCLR<br>
XCLR(I),YCLR(I)</b>, I=1,NCLR<br>
<br>
<br>
Where<br>
<br>
<b> ICD&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Definition method for coefficient of drag.<br>
<b> ICLF&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Definition method for coefficient of front lift.<br>
<b> ICLR&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Definition method for coefficient of rear lift.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
0 = Constant<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
1 = Constant + five power terms.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
2 = List of values.<br>
<br>
<b> COEFF_CD&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Vehicle drag curve coefficients<br>
<br>
Such that<br>
<br>
CD = COEFF_CD(1) <br>
&gt; + ( COEFF_CD(2) * UM )<br>
&gt; + ( COEFF_CD(3) * UM * UM )<br>
&gt; + ( COEFF_CD(4) * UM * UM * UM )<br>
&gt; + ( COEFF_CD(5) * UM * UM * UM * UM )<br>
&gt; + ( COEFF_CD(6) * UM * UM * UM * UM * UM )<br>
<br>
UM - vehicle velocity m/s<br>
<br>
<br>
<b> NCD&nbsp;&nbsp;&nbsp;&nbsp;
</b>No of points used to define the variation of CD with vehicle speed.<br>
<br>
<b>XCD</b>&nbsp;&nbsp;&nbsp;&nbsp;
The list of vehicle speeds (m/s) used to define the CD curve.<br>
<br>
<b>YCD</b>&nbsp;&nbsp;&nbsp;&nbsp;
The list of Drag Coefficients used to define the CD curve.<br>
<br>
<b> COEFF_CLF &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>As for COEFF_CD above but for front lift coefficient.<b><br>
NCLF &nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>As for NCD above but for front lift coefficient.<b><br>
XCLF &nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>As for XCD above but for front lift coefficient.<b><br>
YCLF &nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>As for YCD above but for front lift coefficient.<b><br>
COEFF_CLR &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>As for COEFF_CD above but for rear lift coefficient.<b><br>
NCLR &nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>As for NCD above but for rear lift coefficient.<b><br>
XCLR &nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>As for XCD above but for rear lift coefficient.<b><br>
</b> YCLR &nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
As for YCD above but for rear lift coefficient.<br>
<br>
The following lines show an example of the AERODYNAMICS option<br>
<br>
AERODYNAMICS<br>
2 0 1<br>
9<br>
28.22 0.3100<br>
33.92 0.3095<br>
39.91 0.3080<br>
45.12 0.3085<br>
51.53 0.3075<br>
57.22 0.3070<br>
61.69 0.3055<br>
67.18 0.3060<br>
72.26 0.3070<br>
-0.1 0.02 0.0003 0.0 0.0 0.0<br>
<br>
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<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Extended Hybrid Performance<br>
</font></b><font size="2"><br>
This option provides an extension to the </font><font face="Times New Roman"><font face="Arial">simple</font></font><font face="Times New Roman"><font face="Arial"> hybrid model by allowing an extended component performance to be defined. The hybrid components catered for are the auxiliary power unit generator, the drive motor, the drive regenerator, the battery charge and the battery discharge. <br>
<br>
All component performances are optional, (i.e. the </font></font><font face="Times New Roman"><font face="Arial">simple</font></font><font face="Times New Roman"><font face="Arial"> hybrid model can be used), but once one component is selected as </font></font><font face="Times New Roman"><font face="Arial">on</font></font><font face="Times New Roman"><font face="Arial"> then to correctly run a hybrid model all relevant components should be switched on.<br>
</font></font><br>
For each component the continuous and peak performances are defined through its speed range, together with data that define a simple heat rejection / heat build-up model to simulate the drop from peak to continuous performance.<br>
<br>
*.Car file format<br>
<br>
<b>HYBPOWER</b> (keyword)<br>
<b>NHYB<br>
NHYB3(1), NHYB3(2), NHYB3(3), NHYB3(4), NHYB3(5)<br>
</b>------------&gt;<br>
nhyb<br>
times<br>
IF NHYB3(J) = 1<br>
<b>PTHYB3(J), TCHYB3(J), TTHYB3(J), TSHYB3(J), RIHYB3(J), SMXHYB3(J)</b><br>
<b> NSPHYB3(J)<br>
</b> ------------&gt;<br>
nsphyb3(j)<br>
times<br>
<b> SPDHYB3(J,I), AMP1HYB3(J,I), AMP2HYB3(J,I), PERCHYB3(J,I)</b><br>
--------&lt;<br>
--------&lt;<br>
<br>
<br>
Where<br>
<br>
<b>NHYB&nbsp;&nbsp;&nbsp;
</b>Number of hybrid components defined, (at version 3.01e this is 5).Where 1 is the apu generator, 2 is the drive motor, 3 is the drive regenerator, 4 is the battery and 5 is not currently used.<br>
<br>
<b>NHYB3&nbsp;&nbsp;
</b>The on / off flags to control the inclusion of the hybrid components into the model. 0 = off 1 = on. Values are given in component order 1 to 5, see above. Component 5 is not used and should be set to 0<br>
<br>
<b>PTHYB3</b>&nbsp;&nbsp;
Time at peak, (s). This defines the time for which the peak performance can be held before the threshold temperature is reached and the allowable performance begins to deteriorate from the peak toards the continuous. This forms part of the component heat model derivation. For the battery component no heat model is used and this value sets the total battery capacity, (Ah).<br>
<br>
<b>TCHYB3</b>&nbsp;&nbsp;
Constant temperature of the component, (Co). This defines the temperature at which the component reaches under the maximum constant performance. This defines the heat convection capability of the component. (note not used for the battery component, enter dummy value 0.0)<br>
<br>
<b>TTHYB3</b>&nbsp;&nbsp;
Threshold temperature of the component, (Co). This sets the temperature at which the component performance starts to deteriorate from the peak towards the continuous. (note not used for the battery component, enter dummy value 0.0)<br>
<br>
<b>TSHYB3</b>&nbsp;&nbsp;
Start temperature of the component, (Co). For the battery component this value sets the initial state of charge (SOC), (0-1).<br>
<br>
<b>RIHYB3</b>&nbsp;&nbsp;
Hybrid components rotational inertia, (kg.m2). For the battery component this value sets the start voltage of the system (V), but only applies when the detailed battery voltage model is not used.<br>
<br>
<b>SMXHYB3</b>&nbsp;
Maximum allowable component speed (rpm). (note not used for the battery component, enter dummy value 0.0)<br>
<br>
<b>NSPHYB3</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Number of speed values for this components power curve.<br>
<br>
<b>SPDHYB3</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Speed values for this hybrid components performance curve (rpm). To minimise extrapolation errors these speed values should span the component operating range.<br>
<br>
<b>AMP1HYB3</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Peak performance values for the hybrid component at each component speed. Units depend on component and are <font face="Times New Roman"><font face="Arial">Nm</font></font><font face="Times New Roman"><font face="Arial"> for the generator, motor and regenerator and for the battery the units are </font></font><font face="Times New Roman"><font face="Arial">A</font></font><font face="Times New Roman"><font face="Arial"> (amps). This curve defines maximum attainable performance of the component. For the battery component this defines the maximum charge rate.<br>
</font></font><br>
<b>AMP2HYB3</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Continuous performance values for the hybrid component at each component speed. Units depend on component and are <font face="Times New Roman"><font face="Arial">Nm</font></font><font face="Times New Roman"><font face="Arial"> for the generator, motor and regenerator and for the battery the units are </font></font><font face="Times New Roman"><font face="Arial">A</font></font><font face="Times New Roman"><font face="Arial"> (amps). This curve defines the continuous performance that the component can achieve. The temperature model is used to define the actual allowable which would normally lie somewhere between the peak and the continuous performance. For the battery component this defines the maximum discharge rate.<br>
</font></font><br>
<b>PERCHYB3</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
The ratio of output power that goes to heat, (0 -1). Defines the heat energy going in to components heat-up model as a function of speed. The battery model does not have a heat model associated with it and these values should be set to 0.0 for that component.<br>
<br>
<br>
The following lines show an example of the HYBPOWER option<br>
<br>
HYBPOWER<br>
5<br>
1 1 1 1 0<br>
<br>
4.000 100.0 75.00 0.0000E+00 0.2000E-01 0.1600E+05<br>
16<br>
1000. 200.0 120.0 0.1000<br>
1500. 200.0 120.0 0.1000<br>
2000. 200.0 120.0 0.1000<br>
3000. 180.0 110.0 0.1000<br>
4000. 130.0 100.0 0.1000<br>
5000. 120.0 90.00 0.1000<br>
6000. 100.0 80.00 0.1000<br>
7000. 85.00 70.00 0.1000<br>
8000. 78.00 63.00 0.1000<br>
9000. 67.00 62.00 0.1000<br>
0.1000E+05 64.00 60.00 0.1000<br>
0.1100E+05 63.00 59.00 0.1000<br>
0.1200E+05 61.00 58.00 0.1000<br>
0.1300E+05 58.00 54.00 0.1000<br>
0.1400E+05 56.00 52.00 0.1000<br>
0.1600E+05 60.00 59.00 0.1000<br>
<br>
4.000 100.0 75.00 0.0000E+00 0.2000E-01 7500.<br>
8<br>
1000. 225.0 150.0 0.5000E-01<br>
1500. 225.0 150.0 0.5000E-01<br>
2500. 225.0 150.0 0.5000E-01<br>
3500. 150.0 82.00 0.5000E-01<br>
4500. 115.0 60.00 0.5000E-01<br>
5500. 90.00 53.00 0.5000E-01<br>
6500. 75.00 47.00 0.5000E-01<br>
7500. 75.00 46.00 0.5000E-01<br>
<br>
4.000 120.0 80.00 0.0000E+00 0.2000E-01 6000.<br>
2<br>
1000. 200.0 150.0 0.1000<br>
6000. 100.0 80.00 0.2000<br>
<br>
20.00 0.0000E+00 0.0000E+00 0.8500 230.0 0.0000E+00<br>
5<br>
0.0000E+00 300.0 150.0 0.0000E+00<br>
0.2500 295.0 280.0 0.0000E+00<br>
0.5000 290.0 290.0 0.0000E+00<br>
0.7500 280.0 295.0 0.0000E+00<br>
1.000 150.0 300.0 0.0000E+00<br>
<br>
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<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Extended Hybrid Efficiencies<br>
</font></b><font size="2"><br>
This option provides an extension to the </font><font face="Times New Roman"><font face="Arial">simple</font></font><font face="Times New Roman"><font face="Arial"> hybrid model by allowing a component efficiency map to be defined. The hybrid components catered for are the auxiliary power unit generator, the drive motor, the drive regenerator, the battery charge and the battery discharge.<br>
All component efficiency maps are optional, with if required default values of 1.0 being used when no map is defined, alternatively a single efficiency value can be defined. Efficiency maps are defined as a series of efficiency values, (0 - 1), for a range of component speeds and loads. <br>
</font></font><br>
*.Car file format<br>
<br>
<b>HYBLOSS</b> (keyword)<br>
<b>NHYB<br>
NHYB2(1), NHYB2(2), NHYB2(3), NHYB2(4), NHYB2(5)<br>
</b> ------------&gt;<br>
nhyb<br>
times<br>
IF NHYB2(J) = 1<br>
<b> NSPHYB(J)<br>
SPDHYB(J,I)</b>, I=1,NSPHYB(J)<br>
<b> NAMPHYB(J)<br>
AMBHYB(J,I)</b>, I=1,NAMPHYB(J)<br>
IF NSPHYB(J)=0 AND NAMPHYB(J)=0<br>
<b>EFFHYB(1,1)<br>
</b>ELSE<br>
------------&gt;<br>
nsphyb times<br>
<b>EFFHYB(J,I),</b> I=1,NAMPHYB(J)<br>
--------&lt;<br>
--------&lt;<br>
<br>
<br>
Where<br>
<br>
<b>NHYB&nbsp;&nbsp;&nbsp;
</b>Number of hybrid components defined, (at version 3.01e this is 5).Where 1 is the apu generator, 2 is the drive motor, 3 is the drive regenerator, 4 is the battery charging and 5 is the battery discharging.<br>
<br>
<b>NHYB2&nbsp;&nbsp;
</b>The on / off flags to control the inclusion of the hybrid components into the model. 0 = off 1 = on. Values are given in component order 1 to 5, see above.<br>
<br>
<b>NSPHYB</b>&nbsp;
Number of speed values for this components efficiency map. 0 is used in conjunction with Namhyb to force a single fixed efficiency value to be used.<br>
<br>
<b>SPDHYB</b>&nbsp;
Speed values for this hybrid components efficiency map (rpm). To minimise extrapolation errors these speed values should span the component operating range. This line is omitted if the number of speed values is 0<br>
<br>
<b>NAMHYB</b>&nbsp;
Number of load values for this components efficiency map. 0 is used in conjunction with Nsphyb to force a single fixed efficiency value to be used.<br>
<br>
<b>AMPHYB</b>&nbsp;
Load values for this hybrid components efficiency map (rpm). To minimise extrapolation errors these speed values should span the component operating range. This line is omitted if the number of load values is 0<br>
<br>
<b>EFFHYB</b>&nbsp;
Efficiency map values, (0 -1).<br>
<br>
<br>
The following lines show an example of the HYBLOSS option<br>
<br>
HYBLOSS<br>
5<br>
1 1 1 1 1<br>
8<br>
2000. 4000. 6000. 8000. 0.1000E+05 0.1200E+05 0.1400E+05 0.1600E+05<br>
7<br>
5.000 10.00 20.00 30.00 40.00 50.00 60.00<br>
0.4400 0.5500 0.6400 0.6300 0.5700 0.5200 0.4900<br>
0.3000 0.5000 0.6000 0.5800 0.5500 0.5000 0.4700<br>
0.1500 0.3800 0.4800 0.5000 0.4900 0.4800 0.4400<br>
0.1100 0.2000 0.4200 0.4500 0.4600 0.4500 0.4200<br>
0.1000 0.1600 0.3200 0.3900 0.4100 0.4100 0.3900<br>
0.8000 0.1400 0.2400 0.3100 0.3400 0.3600 0.3700<br>
0.6000 0.1200 0.1800 0.2500 0.2800 0.3000 0.3000<br>
0.5000 0.9000 0.1500 0.1900 0.2200 0.2600 0.2800<br>
8<br>
1000. 2000. 3000. 4000. 5000. 6000. 7000. 7500.<br>
7<br>
25.00 50.00 75.00 100.0 150.0 200.0 225.0<br>
0.8500 0.8850 0.8780 0.8600 0.8600 0.7800 0.7600<br>
0.8650 0.9000 0.9030 0.9000 0.8800 0.8400 0.8260<br>
0.9050 0.9250 0.9250 0.9250 0.9100 0.8650 0.8540<br>
0.9300 0.9400 0.9400 0.9320 0.9200 0.8800 0.8630<br>
0.8650 0.9120 0.9230 0.9150 0.9200 0.8820 0.8660<br>
0.8800 0.9100 0.9200 0.9200 0.9200 0.8840 0.8690<br>
0.8250 0.8950 0.9050 0.9000 0.9200 0.8860 0.8700<br>
0.8200 0.9000 0.9030 0.9100 0.9200 0.8880 0.8830<br>
0<br>
0<br>
0.8800<br>
0<br>
0<br>
0.8000<br>
0<br>
0<br>
<br>
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<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Extended Hybrid Battery<br>
</font></b><font size="2"><br>
This option provides an extension to the fixed voltage battery model that can be defined in the extended hybrid component performance. A voltage map is defined at a series of battery states of charge (SOC) and varying charge / discharge rates. Two maps are used one for charging and a second for discharging.<br>
<br>
*.Car file format<br>
<br>
<b>HYBBATTERY</b></font> (keyword)<br>
<b>NCURHYB4(1), NSOCHYB4(1)<br>
</b>IF Ncurhyb4(1) is greater than 0 and Nsochyb4(1) is greater than 0 then<b><br>
</b> DSOCHYB4(J,1) J=1,NSOCHYB4(1)<b><br>
</b> ------------&gt;<br>
ncurhyb4(1)<br>
times<br>
<b> DCURHYB4(J,1)</b><br>
<b> DVOLHYB4(I,J,1),</b> I=1,NSOCHYB4(1)<b><br>
</b>--------&lt;<br>
<br>
<b>NCURHYB4(2), NSOCHYB4(2)<br>
</b>IF Ncurhyb4(2) is greater than 0 and Nsochyb4(2) is greater than 0 then<b><br>
DSOCHYB4(J,2) </b> J=1,NSOCHYB4(2)<b><br>
</b> ------------&gt;<br>
ncurhyb4(2)<br>
times<br>
<b> DCURHYB4(J,1)</b><br>
<b> DVOLHYB4(I,J,2),</b> I=1,NSOCHYB4(2)<b><br>
</b>--------&lt;<br>
<br>
<br>
Where<br>
<br>
<b>NCURHYB4&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Number of current charge levels the battery voltage map is defined for. The index 1 implies charging whilst the index 2 implies discharging.<br>
<br>
<b>NSOCHYB4&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Number of battery state of charge levels the battery voltage map is defined for. The index 1 implies charging whilst the index 2 implies discharging.<br>
<br>
<b>DSOCHYB4</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
The battery state of charge values for the battery voltage map, (0-1). Again the index 1 implies charging whilst the index 2 implies discharging.<br>
<br>
<b>DCURHYB4</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
The charge values for the battery voltage map (Amps). Again the index 1 implies charging whilst the index 2 implies discharging.<br>
<br>
<b>DVOLHYB4</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
The battery voltage map values, (Volts). The index 1 implies charging whilst the index 2 implies discharging.<br>
<br>
<br>
The following lines show an example of the HYBBATTERY option<br>
<br>
HYBBATTERY<br>
4 6<br>
0.0 0.2000 0.4000 0.6000 0.8000 1.000<br>
0.0<br>
190.0 200.0 210.0 220.0 230.0 240.0<br>
120.0<br>
180.0 190.0 200.0 210.0 220.0 230.0<br>
220.0<br>
170.0 180.0 190.0 200.0 210.0 220.0<br>
320.0<br>
135.0 165.0 175.0 185.0 195.0 205.0<br>
4 6<br>
0.0 0.2000 0.4000 0.6000 0.8000 1.000<br>
0.0<br>
190.0 200.0 210.0 220.0 230.0 240.0 <br>
120.0<br>
180.0 190.0 200.0 210.0 220.0 230.0<br>
220.0<br>
170.0 180.0 190.0 200.0 210.0 220.0<br>
320.0<br>
135.0 165.0 175.0 185.0 195.0 205.0<br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Extended Hybrid Control Strategy<br>
</font></b><font size="2"><br>
This option controls the manner in which the hybrid system operates. It controls the APU generator shut down, its rate of speed change and target minimum and maximum levels for the battery state of charge.<br>
<br>
*.Car file format<br>
<br>
<b>HYBCONTROL</b></font> (keyword)<br>
<b>NHISTORY, RNPOWER<br>
RMIN_RATE, RMAX_RATE<br>
SOCMIN, SOCMAX</b><br>
<b>NSTHYB5<br>
SOCON, SOCOFF, SOCRAT<br>
</b><br>
<br>
Where<br>
<br>
<b>NHISTORY&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Number of previous calculation steps to use in establishing the mean power demand from the APU. The larger this integer number is the greater the delay of the APU to any sudden change in load demand. It can be thought of as a damping factor.<br>
<br>
<b>RNPOWER&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the power value used in establishing the required APU demand that is added to the mean demand. This second term itself being a function of the current state of charge compared to the target minimum and maximum state of charge values. The greater the number the more aggressive is the battery charging philosophy.<br>
<br>
<b>RMIN_RATE</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the allowable deceleration rate of the APU, (rad/s/s). It should be entered as a negative number. The greater this negative number is made the greater the tendency for the APU to decelerate in-line with demand.<br>
<br>
<b>RMAX_RATE</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the allowable acceleration rate of the APU, (rad/s/s). It should be entered as a positive number. The greater this positive number is made the greater the tendency for the APU to accelerate in-line with demand.<br>
<br>
<b>SOCMIN</b>&nbsp;&nbsp;
Defines the target minimum state of charge value for the battery. Together with Socmax and Rnpower they control the portion of the APU demand that is a function of battery state of charge.<br>
<br>
<b>SOCMAX</b>&nbsp;&nbsp;
Defines the target maximum state of charge value for the battery. Together with Socmin and Rnpower they control the portion of the APU demand that is a function of battery state of charge.<br>
<br>
<b>NSTHYB5</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the start condition of the APU generator as either 'on' or 'off'. For 'on' set Nsthyb5 to 1 whilst for 'off' set to 0.<br>
<br>
<b>SOCON</b>&nbsp;&nbsp;
Sets the battery state of charge value (0-1), at which the APU generator will be switched 'on' if it is currently 'off'. This together with Socoff and Socrat control the APU shutdown strategy. The APU generator will only switch 'on' if the current APU demand is greater than the demand available at the APU idle speed.<br>
<br>
<b>SOCOFF</b>&nbsp;
Sets the battery state of charge value (0-1), at which the APU generator will be switched 'off' if it is currently 'on'. This together with Socoff and Socrat control the APU shutdown strategy. The APU generator will only switch 'off' if the current APU demand is less than the demand available at the APU idle speed.<br>
<br>
<b>SOCRAT</b>&nbsp;
Sets the APU load ratio at which the APU will switch 'on' irrespective of the current battery state of charge, (0-1). If this value is set high then provided the battery state of charge is within acceptable limits, the APU would only switch 'on' under high demand conditions such as heavy accelerations and extended hill climbing.<br>
<br>
The following lines show an example of the HYBBATTERY option<br>
<br>
HYBCONTROL<br>
10 1.000<br>
-39.90 9.948<br>
0.4000 0.8000<br>
0<br>
0.8 0.9 0.5<br>
<br>
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<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">*.Car Format for the Extended Tyre Data<br>
</font></b><font size="2"><br>
This option provides the extended tyre model, allowing non-linear values to be used for tyre rolling radius. The value being a function of vehicle speed.<br>
<br>
*.Car file format<br>
<br>
<b>XTYRE</b></font> (keyword)<br>
<b>IRTYRE(1), IRTYRE(2), IRTYRE(3), ITYREND<br>
</b><br>
for IRTYRE(1) = 1 and ITYREND = 1<br>
<b> COEFF_RTYRE(I,1)</b>, I=1,6<br>
for IRTYRE(1) = 2 and ITYREND = 1<br>
<b> NRTYRE(1)<br>
XRTYRE(I,1), YRTYRE(I,1)</b>, I=1,NRTYRE(1)<br>
<br>
for IRTYRE(2) = 1 and ITYREND &gt; 1<br>
<b> COEFF_RTYRE(I,2)</b>, I=1,6<br>
for IRTYRE(2) = 2 and ITYREND &gt; 1<br>
<b> NRTYRE(2)<br>
XRTYRE(I,2), YRTYRE(I,2)</b>, I=1,NRTYRE(2)<br>
<br>
for IRTYRE(3) = 1 and ITYREND &gt; 1<br>
<b> COEFF_RTYRE(I,3)</b>, I=1,6<br>
for IRTYRE(3) = 2 and ITYREND &gt; 1<br>
<b> NRTYRE(3)<br>
XRTYRE(I,3), YRTYRE(I,3)</b>, I=1,NRTYRE(3)<br>
<br>
<br>
Where<br>
<br>
<b>ITYREND&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Flag to identify if common or separate tyre properties are to be used for front and rear tyres. (note this should be set to the same value as used in the 'tyre' data block)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
1 = common tyre properties<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
2 or 3 = different tyre properties for front and rear tyres<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
( Bracketed indices (1), (2) and (3) imply, common, front and rear) <br>
<br>
<b> IRTYRE&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Definition method for tyre rolling radius.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
0 = Constant<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
1 = Constant + five power terms.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
2 = List of values.<br>
<br>
<b> COEFF_RTYRE&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Tyre rolling radius curve coefficients<br>
<br>
Such that<br>
<br>
RTYRE = COEFF_RTYRE (1) <br>
&gt; + ( COEFF_RTYRE(2) * UM )<br>
&gt; + ( COEFF_RTYRE (3) * UM * UM )<br>
&gt; + ( COEFF_RTYRE(4) * UM * UM * UM )<br>
&gt; + ( COEFF_RTYRE(5) * UM * UM * UM * UM )<br>
&gt; + ( COEFF_RTYRE(6) * UM * UM * UM * UM * UM )<br>
<br>
UM - vehicle velocity m/s<br>
<br>
<br>
<b> NRTYRE&nbsp;
</b>No of points used to define the variation of rolling radius with vehicle speed.<br>
<br>
<b>XRTYRE</b>&nbsp;
The list of vehicle speeds (m/s) used to define the rolling radius curve.<br>
<br>
<b>YRTYRE</b>&nbsp;
The list of Drag Coefficients used to define the rolling radius curve.<br>
<br>
<br>
The following lines show examples of the XTYRE option<br>
<br>
XTYRE<br>
2 0 0 1<br>
4<br>
0.0 0.2350<br>
20.0 0.2360<br>
40.0 0.2380<br>
80.0 0.2430<br>
<br>
<br>
XTYRE<br>
1 0 2 2<br>
0.32 0.02 0.0 0.0 0.0 0.0<br>
4<br>
0.0 0.2350<br>
20.0 0.2360<br>
40.0 0.2380<br>
80.0 0.2430<br>
<br>
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<p><hr><p>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Examples and Validation<br>
</font></b><font size="2">Overview</font><br>
<br>
The aim of this chapter is provide example input files that the new user can copy to quickly create new simulation models. With each input file the calculated results and the accompanying measured results are provided. Notes are given as to the acceptable range for some of the more difficult to define input variables such as gear efficiencies, tyre coefficient of friction and overrun fuelling.<br>
<br>
Examples are provided for the 4 main calculation types<br>
<br>
<b> 1. <u>Acceleration</u></b><b></b> - for a naturally aspirated and turbocharged manual gearbox vehicle.<br>
<br>
<b>2. <u>Economy</u></b><b></b> - for an automatic vehicle with auxiliaries on a rolling road.<br>
<br>
<b> 3. <u>Emissions</u></b><b></b> - for a naturally aspirated, manual, research vehicle<br>
<br>
<b>4. <u>Track</u></b><b></b> - for a turbocharged manual vehicle<br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Vehicle Acceleration - Example<br>
</font></b><font size="2"><br>
Input files for the Lotus Elan when fitted with the naturally aspirated and turbocharged engines are available here :<br>
<br>
</font><u><b>Vehicle acceleration example data files </b></u><u><img data="bm5.bmp" title="bm5.bmp"></u><br>
<br>
The calculated results for a wide open throttle acceleration from rest, as provided by LOTUS VEHICLE SIMULATION are presented here :<br>
<br>
<u><b>Vehicle acceleration example results file </b></u><u><img data="bm5.bmp" title="bm5.bmp"></u><br>
<br>
A comparison of the measured and calculated accelerations are shown on the following table and graphically in the figure below :<br>
<br>
<table border="2">
<tr><td><b>SPEED RANGE</b></td>
<td><center>NATURALLY ASPIRATED</td>
</center>
<td><center>TURBOCHARGED</td>
</tr>
</center>
</center>
<tr><td> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</td>
<td><center>MEASURED</td>
</center>
<td><center>CALCULATED</td>
</center>
<td><center>MEASURED</td>
</center>
<td><center>CALCULATED</td>
</tr>
</center>
<tr><td><center>(MPH) </td>
</center>
<td><center>(SEC)</td>
</center>
<td><center>(SEC)</td>
</center>
<td><center>(SEC)</td>
</center>
<td><center>(SEC)</td>
</tr>
</center>
<tr><td><center>0 - 30</td>
</center>
<td><center>2.9</td>
</center>
<td><center>2.88</td>
</center>
<td><center>2.4</td>
</center>
<td><center>2.60</td>
</tr>
</center>
<tr><td><center>0 - 40</td>
</center>
<td><center>4.4</td>
</center>
<td><center>4.43</td>
</center>
<td><center>3.7</td>
</center>
<td><center>3.79</td>
</tr>
</center>
<tr><td><center>0 - 50</td>
</center>
<td><center>6.2</td>
</center>
<td><center>6.3</td>
</center>
<td><center>5.0</td>
</center>
<td><center>5.09</td>
</tr>
</center>
<tr><td><center>0 - 60</td>
</center>
<td><center>8.3</td>
</center>
<td><center>8.36</td>
</center>
<td><center>6.5</td>
</center>
<td><center>6.54</td>
</tr>
</center>
<tr><td><center>0 - 70</td>
</center>
<td><center>11.3</td>
</center>
<td><center>11.32</td>
</center>
<td><center>8.7</td>
</center>
<td><center>8.6</td>
</tr>
</center>
<tr><td><center>0 - 80</td>
</center>
<td><center>14.8</td>
</center>
<td><center>14.77</td>
</center>
<td><center>10.9</td>
</center>
<td><center>10.84</td>
</tr>
</center>
<tr><td><center>0 - 90</td>
</center>
<td><center>19.6</td>
</center>
<td><center>18.93</td>
</center>
<td><center>13.5</td>
</center>
<td><center>13.66</td>
</tr>
</center>
<tr><td><center>0 - 100</td>
</center>
<td><center>26.5</td>
</center>
<td><center>25.98</td>
</center>
<td><center>17.5</td>
</center>
<td><center>17.4</td>
</tr>
</center>
<tr><td><center>0 - 110</td>
</center>
<td></td>
</center>
<td></td>
</center>
<td><center>22.2</td>
</center>
<td><center>22.12</td>
</tr>
</center>
<tr><td><center>0 - 120</td>
</center>
<td></td>
</center>
<td></td>
</center>
<td><center>29.6</td>
</center>
<td><center>29.89</td>
</tr>
</center>
<br>
<tr><td><u><b>Vehicle acceleration correlation graph </b></u><u><img data="bm6.bmp" title="bm6.bmp"></u><br>
<br>
The following notes are provided for the users reference.<br>
<br>
<b>1.</b> Gearbox transmission efficiencies typically lie in the range 0.95-0.99. If in doubt the user should use 0.97. These values can often be tuned to achieve good correlation between measured and predicted performance.<br>
<br>
<b>2. </b>The coefficient of friction at the tyre contact patch is typically in the range 0.98 - 1.05. Obviously for wet conditions a lower value is appropriate.<br>
<br>
<b>3.</b> Engine rotating inertia is often not readily available. Users can use the <u><b>Engine Inertia curve</b></u><b></b> provided for an appropriate value.<br>
<br>
<b>4.</b> For vehicle accelerations the gear shift time is typically set to 0.1 seconds. This may appear small, but often these tests are performed by drivers who do not de-clutch during a gear shift. It should also be remembered that there is no engine inertia energy transfer during a gear change. A small shift time is therefore required to balance the effect of this assumption.<br>
<br>
<b>5.</b> Lotus experience is that it is often difficult to achieve good acceleration correlation for vehicle speeds below 30 MPH. The reason for this is at present not understood, but believed to be in part attributable to the transfer of the engines rotational energy to the vehicle as the driver dumps the clutch.<br>
<br>
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<br>
<p><hr><p>
</td>
</tr>
</table>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Vehicle Economy - Example<br>
</font></b><font size="2"><br>
The input file for an 1.5L 4 door saloon fitted with an automatic transmission is provided here:<br>
<br>
<u><b>Vehicle economy example data file </b></u></font><u><img data="bm5.bmp" title="bm5.bmp"></u><br>
<br>
This model was created as part of a fuel economy improvement program where the load of the air conditioning unit was found to significantly deteriorate economy. The AUXILIARIES option is therefore included in this file.<br>
<br>
<u><b>Vehicle economy example results file </b></u><u><img data="bm5.bmp" title="bm5.bmp"></u><br>
<br>
The comparison of measured and calculated fuel consumption are shown on the following table and graphically in the figure below :<br>
<br>
<table border="2">
<tr><td><b><center>AIR CONDITIONING OFF </b></td>
</center>
<td><center>MEASURED</td>
</center>
<td><center>CALCULATED</td>
</center>
<td><center>% ERROR</td>
</tr>
</center>
<tr><td><center>IDLE (g/h) </td>
</center>
<td><center>950</td>
</center>
<td><center>936</td>
</center>
<td><center>-1.2</td>
</tr>
</center>
<tr><td><b><center>40 km/h (km/l) </b></td>
</center>
<td><center>14.78</td>
</center>
<td><center>14.74</td>
</center>
<td><center>-0.3</td>
</tr>
</center>
<tr><td><b><center>60 km/h (km/l) </b></td>
</center>
<td><center>N/A</td>
</center>
<td><center>18.59</td>
</center>
<td><center>N/A</td>
</tr>
</center>
<tr><td><b><center>80 km/h (km/l) </b></td>
</center>
<td><center>18.56</td>
</center>
<td><center>18.25</td>
</center>
<td><center>-1.7</td>
</tr>
</center>
<tr><td><b><center>100km/h (km/l) </b></td>
</center>
<td><center>17.22</td>
</center>
<td><center>17.06</td>
</center>
<td><center>-0.9</td>
</tr>
</center>
<tr><td><b><center>10 MODE (km/l) </b></td>
</center>
<td><center>8.39</td>
</center>
<td><center>8.17</td>
</center>
<td><center>-2.6</td>
</tr>
</center>
<br>
<tr><td><b><center>AIR CONDITIONING ON</b></td>
</center>
<td><center>MEASURED</td>
</center>
<td><center>CALCULATED</td>
</center>
<td><center>% ERROR</td>
</tr>
</center>
<tr><td><center>IDLE (g/h) </td>
</center>
<td><center>1331</td>
</center>
<td><center>1332</td>
</center>
<td><center>+0.08</td>
</tr>
</center>
<tr><td><b><center>40 km/h (km/l) </b></td>
</center>
<td><center>11.71</td>
</center>
<td><center>11.45</td>
</center>
<td><center>-2.2</td>
</tr>
</center>
<tr><td><b><center>60 km/h (km/l) </b></td>
</center>
<td><center>15.33</td>
</center>
<td><center>15.08</td>
</center>
<td><center>-1.6</td>
</tr>
</center>
<tr><td><b><center>80 km/h (km/l) </b></td>
</center>
<td><center>15.91</td>
</center>
<td><center>15.12</td>
</center>
<td><center>-5.0</td>
</tr>
</center>
<tr><td><b><center>100km/h (km/l) </b></td>
</center>
<td><center>14.81</td>
</center>
<td><center>14.38</td>
</center>
<td><center>-2.9</td>
</tr>
</center>
<tr><td><b><center>10 MODE (km/l) </b></td>
</center>
<td><center>6.30</td>
</center>
<td><center>6.26</td>
</center>
<td><center>-0.6</td>
</tr>
</center>
<br>
<tr><td><u><b>Vehicle Economy Correlation Graph </b></u><u><img data="bm6.bmp" title="bm6.bmp"></u><br>
<br>
The following notes are made for the users reference.<br>
<br>
1. The most important part of emission cycle calculations is to ensure that the idle fuel flow rate is correct. If the user does not have measured data for the engine being used then the figure of 53 g/h/litre/100rpm can be used as a rough guide.<br>
<br>
2. Most modern engine management systems employ overrun fuel cut-off. This stops the flow of fuel when the engine undergoes a prolonged period of overrun. It is therefore tempting to specify no fuel flow in the overrun condition in the input data to the model. Lotus experience in using this model however, is that best results are obtained when some flow of fuel during overrun is specified. The reasons for this are twofold, (a) the period of time before cut-off is employed is often a significant part of a deceleration in an emission cycle and (b) fuel enrichment is often employed following an overrun to provide good drivability. Fuel enrichment is not catered for in the steady state maps. Thus overrun fuelling can be used to compensate for this simplification. Typically the overrun flow rate is half that of the lowest load.<br>
<br>
3. The simulation in this section was performed on a chassis dynamometer. During the above study it was found that the loads experienced by the engine on the chassis dynamometer were significantly different to those found on the road. The reasons for this were twofold, (a) the load characteristic if the Clayton Dyno. did not replicate the road load curve of the vehicle through the speed range and (b) the rolling resistance of the tyres on the small rollers was significantly higher than that found on the road. The latter effect being caused by high tyre distortion on the small diameter rollers. The above problems/errors are removed/reduced by modern large diameter chassis dynamometers with programmable road load curves.<br>
<br>
Often results of acceptable accuracy can be obtained by performing the emissions cycle calculations on the &quot;ROAD&quot; (i.e. without using the chassis dynamometer option).<br>
<br>
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<br>
<p><hr><p>
</td>
</tr>
</table>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Vehicle Emissions - Example<br>
</font></b><font size="2"><br>
The input file for an 1.6L 2 door saloon fitted with a manual transmission is provided.<br>
<br>
<u><b>Vehicle emissions example data file </b></u></font><u><img data="bm5.bmp" title="bm5.bmp"></u><br>
<br>
This model was created as part of the Lotus funded LEV research project where calculations to determine the required catalyst light off time were performed. This file demonstrates the quantity of engine data required to perform these calculations.<br>
<br>
The measured and calculated emissions over the FTP75 test are summarised in the following table, detailed in the results file and presented graphically in the three figures.<br>
<br>
<b>PRE CATALYST EMISSIONS</b><br>
Test No. 113593 C Date 1 Sep 1993 Test type EPA 75<br>
<br>
<u><b>Vehicle emissions example results file </b></u><u><img data="bm5.bmp" title="bm5.bmp"></u><br>
<br>
<table border="2">
<tr><td><b><center>EMISSION </b></td>
</center>
<td><center>MEASURED</td>
</center>
<td><center>CALCULATED</td>
</center>
<td><center>% ERROR</td>
</tr>
</center>
<tr><td><center>T.HC (g) </td>
</center>
<td><center>33.8</td>
</center>
<td><center>33.27</td>
</center>
<td><center>-1.6</td>
</tr>
</center>
<tr><td><b><center>(g/mile) </b></td>
</center>
<td><center>3.08</td>
</center>
<td><center>3.13</td>
</center>
<td><center>+1.6</td>
</tr>
</center>
<tr><td><b><center>CO (g) </b></td>
</center>
<td><center>86.8</td>
</center>
<td><center>85.21</td>
</center>
<td><center>-1.8</td>
</tr>
</center>
<tr><td><b><center>(g/mile) </b></td>
</center>
<td><center>7.91</td>
</center>
<td><center>7.82</td>
</center>
<td><center>-1.1</td>
</tr>
</center>
<tr><td><b><center>NOx (g) </b></td>
</center>
<td><center>30.4</td>
</center>
<td><center>30.61</td>
</center>
<td><center>+0.7</td>
</tr>
</center>
<tr><td><b><center>(g/mile) </b></td>
</center>
<td><center>2.77</td>
</center>
<td><center>2.72</td>
</center>
<td><center>-1.8</td>
</tr>
</center>
<tr><td><b><center>CO2 (g) </b></td>
</center>
<td><center>2656</td>
</center>
<td><center>2832</td>
</center>
<td><center>+6.6</td>
</tr>
</center>
<tr><td><b><center> (2935 POST.CAT)</b></td>
</tr>
</center>
<tr><td><center>(g/mile)</td>
</center>
<td><center>242</td>
</center>
<td><center>258.4</td>
</center>
<td><center>+6.8</td>
</tr>
</center>
<br>
<tr><td><u><b>Vehicle emissions correlation graph - Cumulative emissions &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b></u><u><img data="bm6.bmp" title="bm6.bmp"></u><br>
<br>
<u><b>Vehicle acceleration correlation graph - Engine out emissions &nbsp;&nbsp;
</b></u><u><img data="bm6.bmp" title="bm6.bmp"></u><br>
<br>
<u><b>Vehicle acceleration correlation graph - Emissions error &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b></u><u><img data="bm6.bmp" title="bm6.bmp"></u><br>
<br>
<br>
Overall the correlation is generally good. The reason why the CO2 results are high are not fully understood at present, although it is worth noting that the post catalyst results are significantly higher than the pre catalyst levels.<br>
<br>
The following notes are made for the users reference :<br>
<br>
<b>1.</b> The largest discrepancies between the measured and calculated data when using the raw test bed emissions data were found with the hydrocarbon emissions. Both the warm-up and transient models were employed to achieve the above correlation. The input file shows the factors used in this simulation.<br>
<br>
<b>2. </b>No corrections have been made to either the NOx or CO2 emissions.<br>
<br>
<b>3. </b>Users wishing to repeat the above correlation should employ the following sequence to obtain best results.<br>
<br>
<b>a.</b> ensure that all emissions at hot idle are correct<br>
<br>
<b>b.</b> modify overrun levels to those observed during test<br>
<br>
<b>c. </b>tune transient factor for HC emissions<br>
<br>
<b>d. </b>apply warm-up corrections for cold start.<br>
<br>
<b>4.</b> To date the above correlation has only been attempted on one vehicle. Further work is recommended to identify the level of correlation and transient factors required for other vehicles and/or calibrations.<br>
<br>
{button ,AL(`list12',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
</td>
</tr>
</table>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Track Performance - Example<br>
</font></b><font size="2"><br>
The input file for a Lotus ESPRIT SE is provided.<br>
<br>
<u><b>Track performance example data file </b></u></font><u><img data="bm5.bmp" title="bm5.bmp"></u><br>
<br>
The results file from a simulation of the operation of this vehicle around the Lotus test track at maximum speed is provided here :<br>
<br>
<u><b>Track performance example results file </b></u><u><img data="bm5.bmp" title="bm5.bmp"></u><br>
<br>
The fastest lap for this vehicle is believed to be 85 seconds. This compares well with the calculated time of 84.5. <br>
<br>
{button ,AL(`list12',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><b><font size="4">LOTUS VEHICLE SIMULATION - Program Overview<br>
</font></b><font size="2"><br>
LOTUS VEHICLE SIMULATION is a simulation program capable of predicting the complete performance of a vehicle system. The program can be used to calculate,<br>
<br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Straight line acceleration and top speed</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Fuel economy and emissions (both in steady state or across any drive-cycle)</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Track or course performance</font></font></span><font face="Times New Roman"><br>
</font><font face="Arial"><br>
</font>0&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
LOTUS VEHICLE SIMULATION is designed to run on a desktop PC with Windows 95 but offers the speed of a UNIX based simulation. The user interface is based on the standard <u>LOTUS</u> software<font face="Times New Roman"><font face="Arial">look-and-feel</font></font><font face="Times New Roman"><font face="Arial"> and offers the same intuitive approach as other popular Windows applications, assisting learning and speed of use.<br>
<br>
1&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Using the simulation program typically follows the procedure below, <br>
<br>
</font></font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">The user constructing the simulation model enters the vehicle specification. This includes data for :</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Vehicle mass and centre of gravity</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Vehicle dimensions, and aerodynamics</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Tyre performance (grip and rolling resistance characteristics)</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Final drive system</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Gearbox or transmission system and shifting strategies</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Prime-mover details eg. I.C. engine or hybrid powertrain</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Performance (torque/power capabilities)</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Fuel economy</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">System-out Emissions</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Emissions after-treatment systems</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Driver performance</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">The user selects the appropriate test for analysis. For instance, this often involves predicting the performance of the vehicle in terms of emissions and fuel economy over a government legislated drive-cycle.</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">The calculation cycle is carried out. The user can display the key information on the vehicle and powertrain operating condition during the cycle using the calculation screen.</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Calculation results are available to the user both in the form of a report quality summary sheet and through a quick-to-use graph plotting system.</font></font></span><font face="Times New Roman"><br>
</font><font face="Arial"><br>
</font>0&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
LOTUS VEHICLE SIMULATION has been applied extensively by world-wide clients and validated thoroughly at LOTUS over a wide range of vehicle types and conditions. The program is capable of simulating all existing and projected vehicle systems and is continually updated by LOTUS in co-operation with it<font face="Times New Roman"><font face="Arial">s partners.<br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></font></font><sup>A</sup><b><font size="4">PROGRAM OVERVIEW <u></u></font></b><u><font size="1"><img data="bm7.bmp" title="bm7.bmp"></font></u><b><font size="4"><br>
</font></b><font size="2"><br>
0&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
LOTUS VEHICLE SIMULATION is split into three sub-sections:<br>
<br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u><font face="Arial"><font size="2">Pre-processor</font></font></u></span> - for data-entry and model generation<br>
<span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Calculation system - for solution of desired analysis<br>
</font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Post-processor - for analysis of calculated results<br>
</font></font></span><br>
The three sections are only notionally split and all three modules run together as a single application.<br>
<br>
The <font face="Times New Roman"><font face="Arial">front-end</font></font><font face="Times New Roman"><font face="Arial"> of the application is presented here, illustrating the features displayed on start-up:<br>
</font></font><br>
<br>
<b>THE PRE-PROCESSOR<br>
</b><br>
The pre-processing system allows the user to enter data, read in or <u>save</u> models, create new models and adjust data in existing models. <u><img data="bm8.bmp" title="bm8.bmp"></u><br>
<br>
Icons representing the various vehicle-powertrain subsystems allow the user to view the data for that section of the model and adjust, add or delete data from the model. Graphical features allow the user to view the results of changes to the specific data-set and adjust data as fit. <br>
<br>
The following illustrate the typical appearance of the main screen<br>
<p><hr><p>
<sup>#</sup>Contact Details<br>
Lotus Engineering<br>
Hethel<br>
Norwich<br>
NR14 8EZ<br>
Tel: (01953) 608000<br>
Fax: (01953) 608157<br>
<br>
<br>
<p><hr><p>
<p><hr><p>
<sup>#</sup><b>Results Text Viewer Icon</b><br>
<br>
<u><img data="bm9.bmp" title="bm9.bmp"><br>
</u><br>
<p><hr><p>
<sup>#</sup><b>Data Checking Wizard Icon</b><br>
<br>
<u><img data="bm10.bmp" title="bm10.bmp"></u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>#</sup></font><font face="Arial"><b>Data Icons</b></font><br>
<br>
<b>vehicle</b> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u><img data="bm11.bmp" title="bm11.bmp"></u> <br>
<b>dyno</b> &nbsp;&nbsp;
<u><img data="bm12.bmp" title="bm12.bmp"></u> <br>
<b>tyre</b> &nbsp;&nbsp;
<u><img data="bm13.bmp" title="bm13.bmp"></u> <br>
<b>driveline</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u><img data="bm14.bmp" title="bm14.bmp"></u> <br>
<b>gearbox</b> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u><img data="bm15.bmp" title="bm15.bmp"></u> <br>
<b>engine</b>&nbsp;
<u><img data="bm16.bmp" title="bm16.bmp"></u> <br>
<b>hybrid</b>&nbsp;
<u><img data="bm17.bmp" title="bm17.bmp"></u> <br>
<b>driver</b>&nbsp;
<u><img data="bm18.bmp" title="bm18.bmp"> <br>
</u><br>
<p><hr><p>
<sup>#</sup><b>Results Graph Viewer Icon</b><br>
<br>
<u><img data="bm19.bmp" title="bm19.bmp"></u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>#</sup></font><font face="Arial"><b>Specify Graph Icon</b></font><br>
<br>
<u><img data="bm20.bmp" title="bm20.bmp"></u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>#</sup></font><font face="Arial"><b>Axis Scales Icon</b></font><br>
<br>
<u><img data="bm21.bmp" title="bm21.bmp"></u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>#</sup></font><font face="Arial"><b>Cross Plot Status Icon</b></font><br>
<br>
<u><img data="bm22.bmp" title="bm22.bmp"><br>
</u><br>
<p><hr><p>
<sup>#</sup><b>File Browser Icon</b><br>
<br>
<u><img data="bm23.bmp" title="bm23.bmp"></u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>#</sup></font><font face="Arial"><b>Solve Set-up Icon</b></font><br>
<br>
<u><img data="bm24.bmp" title="bm24.bmp"></u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>#</sup></font><font face="Arial"><b>Calculate Run Icon</b></font><br>
<br>
<u><img data="bm25.bmp" title="bm25.bmp"></u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>#</sup></font><font face="Arial"><b>Calculate Stop Icon</b></font><br>
<br>
<u><img data="bm26.bmp" title="bm26.bmp"></u><br>
<font face="Times New Roman"><br>
<br>
<p><hr><p>
<sup>#</sup></font><font face="Arial"><b>Calculate Display Icon</b></font><br>
<br>
<u><img data="bm27.bmp" title="bm27.bmp"></u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>#</sup></font><font face="Arial"><b>Video Icons</b></font><br>
<br>
<b>pause</b> &nbsp;
<u><img data="bm28.bmp" title="bm28.bmp"></u> <br>
<b>play</b> &nbsp;&nbsp;
<u><img data="bm29.bmp" title="bm29.bmp"></u> <br>
<b>scan</b>&nbsp;&nbsp;&nbsp;
<u><img data="bm30.bmp" title="bm30.bmp"></u> <br>
<b>ffwd</b> &nbsp;&nbsp;
<u><img data="bm31.bmp" title="bm31.bmp"></u> <br>
<b>step</b> &nbsp;&nbsp;
<u><img data="bm32.bmp" title="bm32.bmp"></u> <br>
<br>
<p><hr><p>
<sup>#</sup><b>Display Setting Icons</b><br>
<br>
<b>velocity large</b> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u><img data="bm33.bmp" title="bm33.bmp"></u> <br>
<b>bmep large</b> &nbsp;&nbsp;&nbsp;&nbsp;
<u><img data="bm34.bmp" title="bm34.bmp"></u> <br>
<p><hr><p>
<sup>#</sup><b>Vehicle Data Icon</b><br>
<br>
<u><img data="bm11.bmp" title="bm11.bmp"></u> <br>
<br>
<p><hr><p>
<sup>#</sup><b>Dyno Data Icon</b><br>
<br>
<u><img data="bm12.bmp" title="bm12.bmp"></u> <br>
<br>
<p><hr><p>
<sup>#</sup><b>Tyre Data Icon</b><br>
<br>
<u><img data="bm13.bmp" title="bm13.bmp"></u> <br>
<br>
<p><hr><p>
<sup>#</sup><b>Driveline Data Icon</b><br>
<br>
<u><img data="bm14.bmp" title="bm14.bmp"></u> <br>
<br>
<br>
<p><hr><p>
<sup>#</sup><b>Gearbox Data Icon</b><br>
<br>
<u><img data="bm15.bmp" title="bm15.bmp"></u> <br>
<br>
<p><hr><p>
<sup>#</sup><b>Engine Data Icon</b><br>
<br>
<u><img data="bm16.bmp" title="bm16.bmp"></u> <br>
<br>
<p><hr><p>
<sup>#</sup><b>Hybrid Data Icon</b><br>
<br>
<u><img data="bm17.bmp" title="bm17.bmp"></u> <br>
<p><hr><p>
<sup>#</sup><b>Driver Data Icon</b><br>
<br>
<u><img data="bm18.bmp" title="bm18.bmp"> <br>
<p><hr><p>
<sup>#</sup></u><b>Data Graph Icon</b><br>
<br>
<u><img data="bm35.bmp" title="bm35.bmp"> <br>
</u><br>
<p><hr><p>
<sup>#</sup><b>Open File Icon</b><br>
<br>
<u><img data="bm36.bmp" title="bm36.bmp"> <br>
</u><br>
<p><hr><p>
<sup>#</sup><b>New File Icon</b><br>
<br>
<u><img data="bm37.bmp" title="bm37.bmp"> <br>
</u><br>
<br>
<p><hr><p>
<sup>#</sup><b>Save File Icon</b><br>
<br>
<u><img data="bm38.bmp" title="bm38.bmp"> <br>
</u><br>
<p><hr><p>
<sup>#</sup><b>Save As File Icon</b><br>
<br>
<u><img data="bm8.bmp" title="bm8.bmp"> <br>
</u><br>
<p><hr><p>
<sup>#</sup><b>Cross Icon</b><br>
<br>
<u><img data="bm3.bmp" title="bm3.bmp"> <br>
<br>
<p><hr><p>
<sup>#</sup></u><b>Question Mark Icon</b><br>
<br>
<u><img data="bm39.bmp" title="bm39.bmp"> <br>
</u><br>
<p><hr><p>
<sup>#</sup><b>Tick Icon</b><br>
<br>
<u><img data="bm2.bmp" title="bm2.bmp"> <br>
<br>
<p><hr><p>
<sup>#</sup></u><b>Vehicle Acceleration Correlation<br>
</b><br>
<u>{<center><img data="bm40.bmp" title="bm40.bmp"></u><br>
</center>
<u><br>
<p><hr><p>
<sup>#</sup></u><b>Vehicle Economy Correlation<br>
</b><br>
<u>{<center><img data="bm41.bmp" title="bm41.bmp"></u><br>
</center>
<u><br>
<p><hr><p>
<sup>#</sup></u><b>Vehicle Emissions Correlation<br>
</b><br>
<u>{<center><img data="bm42.bmp" title="bm42.bmp"></u><br>
</center>
<u><br>
<p><hr><p>
<sup>#</sup></u><b>Vehicle Emissions Correlation<br>
</b><br>
<u>{<center><img data="bm43.bmp" title="bm43.bmp"></u><br>
</center>
<u><br>
<p><hr><p>
<sup>#</sup></u><b>Vehicle Emissions Correlation<br>
</b><br>
<u>{<center><img data="bm44.bmp" title="bm44.bmp"><br>
</u></center>
<br>
<p><hr><p>
<sup>#</sup><b>Calculation Sequence<br>
</b><br>
<u>{<center><img data="bm45.bmp" title="bm45.bmp"></u><br>
</center>
<u><br>
<p><hr><p>
<sup>#</sup></u><b>Cornering Notation<br>
</b><br>
<u>{<center><img data="bm46.bmp" title="bm46.bmp"></u><br>
</center>
<u><br>
<p><hr><p>
<sup>#</sup></u><b>Tyre Rolling Resistance<br>
</b><br>
<u>{<center><img data="bm47.bmp" title="bm47.bmp"></u><br>
</center>
<u><br>
<p><hr><p>
<sup>#</sup></u><b>Tyre Longitudinal Slip<br>
</b><br>
<u>{<center><img data="bm48.bmp" title="bm48.bmp"></u><br>
</center>
<u><br>
<p><hr><p>
<sup>#</sup></u><b>Gear Efficiency<br>
</b><br>
<u>{<center><img data="bm49.bmp" title="bm49.bmp"></u><br>
</center>
<u><br>
<p><hr><p>
<sup>#</sup></u><b>Gear Shift Map - Road Speeds<br>
</b><br>
<u>{<center><img data="bm50.bmp" title="bm50.bmp"></u><br>
</center>
<u><br>
<p><hr><p>
<sup>#</sup></u><b>Gear Shift Map - Throttle Positions<br>
</b><br>
<u>{<center><img data="bm51.bmp" title="bm51.bmp"></u><br>
</center>
<u><br>
<p><hr><p>
<sup>#</sup></u><b>Catalyst Model<br>
</b><br>
<u>{<center><img data="bm52.bmp" title="bm52.bmp"></u><br>
<p><hr><p>
<sup>#</sup></center>
<b>Warm-up Model<br>
</b><br>
<u>{<center><img data="bm53.bmp" title="bm53.bmp"></u><br>
<p><hr><p>
<sup>#</sup></center>
<b>Engine Scaling Friction<br>
</b><br>
<u>{<center><img data="bm54.bmp" title="bm54.bmp"></u><br>
</center>
<u><br>
<br>
<p><hr><p>
<sup>#</sup></u><b>Results 3d Viewer Icon</b><br>
<br>
<u><img data="bm55.bmp" title="bm55.bmp"> <br>
<br>
<br>
<p><hr><p>
<sup>#</sup></u><b>Data Graph Viewer Icon</b><br>
<br>
<u><img data="bm35.bmp" title="bm35.bmp"> <br>
<br>
<p><hr><p>
<sup>#</sup></u><b>Parametric Open Window Icon</b><br>
<br>
<u><img data="bm56.bmp" title="bm56.bmp"> <br>
<br>
<br>
<p><hr><p>
<sup>#</sup></u><b>Parametric Current Value Icon</b><br>
<br>
<u><img data="bm57.bmp" title="bm57.bmp"> <br>
<br>
<br>
<p><hr><p>
<sup>#</sup></u><b>Parametric List Edit Icon</b><br>
<br>
<u><img data="bm5.bmp" title="bm5.bmp"> <br>
<br>
<p><hr><p>
<sup>#</sup></u><b>Spline List / Edit Icon</b><br>
<br>
<u><img data="bm5.bmp" title="bm5.bmp"> <br>
<br>
<br>
<p><hr><p>
<sup>$</sup><sup>#</sup><sup>&gt;</sup></u><b><font size="4">System Operating Requirements<br>
</font></b><font size="2"><br>
The code has been developed for windows 95 32bit only, on a range of machine specifications, and has shown reasonable speed on machines down to only 8mb of ram and 75Mhz processor speed. It is envisaged that the speed of future releases will be improved through code restructuring.<br>
<br>
The windows display settings that work best with this program is 'Small fonts', 'high colour 16 bit/24 bit' and min 800 x 600 desktop area, (256 colour mode will work with some loss of graphics). The use of 'large fonts'</font><font face="Times New Roman"><font face="Arial"> is also supported.<br>
</font></font><br>
<p><hr><p>
<sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">System Variables<br>
</font></b><font size="2"><br>
LOTUS VEHICLE SIMULATION requires the setting of several environment variables in order to locate the Bitmaps and 'dll' graphics libraries at and during run time. The install program should create these in the 'autoexec.bat' during a full installation, whilst updates assume these variables are already set and will thus not make any changes to the 'autoexec.bat' file.<br>
<br>
The following lists the environment variables set.<br>
</font>LESOFT&nbsp;&nbsp;
Contains the program files and associated bitmaps, default C:\LeSoft<br>
GINO&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Contains the graphics libraries, dll's and configuration file, default C:\Gino<br>
COMPUTERNAME&nbsp;&nbsp;&nbsp;&nbsp;
Identifies the individual node name for licensing, user specific<br>
<br>
In addition the directory for the graphics files (default C:\GINO) needs to on the 'PATH' string in the 'autoexec.bat' file.<br>
<br>
(A successful 'new' installation will create all these environment variables)<br>
<br>
<p><hr><p>
<sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Backdrop Bitmap<br>
</font></b><font size="2"><br>
LOTUS VEHICLE SIMULATION displays a 256 colour, 680x500 pixels windows bitmap as a back drop. A default file is shipped with a full installation. The default file is called 'carps_back.bmp' and is located in the 'LESOFT\BMP' directory. Users may substitute the default backdrop with their own by simply replacing the default file with their own bitmap file. The backdrop function can be disabled by renaming or deleting the default file.<br>
<p><hr><p>
<sup>$</sup><sup>#</sup><sup>&gt;</sup></font><b><font size="4">Licensing Errors<br>
</font></b><font size="2"><br>
During program start-up a number of system checks are made to locate files and perform licensing checks, if any files are missing or irregularities identified these are reported and the program start-up will cease. The error message should be reported to your software vendor.</font><font face="Times New Roman"><br>
<font face="Arial"><br>
<p><hr><p>
<sup>$</sup><sup>#</sup><sup>&gt;</sup></font></font><b><font size="4">Auto-Updating Old Data File Versions<br>
</font></b><font size="2"><br>
When </font><font face="Times New Roman"><font face="Arial">*.car</font></font><font face="Times New Roman"><font face="Arial"> data files are loaded from either the viewer or the browser a check is made on the file version number. There are number of differences between the data files of the different software versions the majority of which are automatically handled and do not require any user intervention.<br>
<br>
One change that cannot be automatically handled is the change in the map numbering approach used for torque converter lock-up map No</font></font><font face="Times New Roman"><font face="Arial">s, gearshift load map No</font></font><font face="Times New Roman"><font face="Arial">s and engine optimum map No.. This was introduced with the beta release of version 3.0. Unfortunately no change in data file version number was added to enable this to be identified, the data file version number change being introduced with the release of version 3.01. Thus </font></font><font face="Times New Roman"><font face="Arial">*.car</font></font><font face="Times New Roman"><font face="Arial"> files created with version of 3.0b would be identified as being from the earlier DOS version and any auto update function would change these map numbers unnecessarily.<br>
</font></font><br>
Pre-windows versions used the map file entry No. (i.e. their position in the file, 1st map, 2nd map, 3rd map etc.), this meant that should the file be edited and the engine map order changed, the three data variables given above could now point to the wrong maps.<br>
<br>
For the Windows version the data file was changed for the three map related variables to be map type No., where 0 = torque fraction, 1 = fuel consumption, 2 = air consumption, 3 = HC emissions etc. thus data file editing could be carried out safely without loss of the load map identity.<font face="Times New Roman"><br>
</font><br>
<font face="Arial">Due to the potential for incorrect auto-correction of data files created by v3.0b the auto-correct on map No</font><font face="Times New Roman"><font face="Arial">s has been given a yes/no prompt. All data files generated by the Dos versions should be corrected, whilst data files created with v3.0b should not.<br>
<br>
<p><hr><p>
<sup>$</sup><sup>#</sup><sup>&gt;</sup></font></font><b><font size="4">Front Sheet Start-up<br>
</font></b><font size="2"><br>
At program start-up a option to run the DataFile wizard is given. This dialog box also contains options to open a new file, or open an existing file. This dialog box can be disabled for subsequent program startups by setting the check box 'Dont show this box at start'.<br>
<br>
The <b>.car file wizard</b></font> provides a simple route to generating a new data file, where the user can select from presented options the data type they require.<br>
<font face="Times New Roman"><br>
<font face="Arial">The <b>New blank .car file</b></font></font> option will open Lotus Vehicle Simulation with a new empty data file.<br>
<br>
The <b>Open an existing .car file</b> option will open the file browser to allow the user to locate the required file.<br>
<br>
Selecting the cancel button will close this dialog box and leave Lotus Vehicle Simulation open with a new empty data file. Thus selecting cancel is equivalent to the 'New blank .car file' option.<br>
<br>
This dialog box is intended to help new users get started by providing a route to the .car file wizard. Should this option have been switched 'off' it can be reinstated by selecting the <u>Start Wizard</u> menu option from the main window menubar under <u>Setup</u> / <u>Start Options</u>. Subsequent Lotus Vehicle Simulation start-ups will then display the start up dialog box.<br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Overview<br>
</font></b><font size="2">Introduction<br>
</font><br>
LOTUS VEHICLE SIMULATION is a simulation program capable of predicting the complete performance of a vehicle system. The program can be used to calculate,<br>
<br>
<span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Straight line acceleration and top speed</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Fuel economy and emissions (both in steady state or across any drive-cycle)</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Track or course performance</font></font></span><font face="Times New Roman"><br>
</font><font face="Arial"><br>
</font>0&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
LOTUS VEHICLE SIMULATION is designed to run on a desktop PC with Windows but offers the speed of a UNIX based simulation. The user interface is based on the standard <u>LOTUS</u> software <font face="Times New Roman"><font face="Arial">look-and-feel</font></font><font face="Times New Roman"><font face="Arial"> and offers the same intuitive approach as other popular Windows applications, assisting learning and speed of use.<br>
<br>
1&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Using the simulation program typically follows the procedure below, <br>
<br>
</font></font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">The user constructing the simulation model enters the vehicle specification. This includes data for :</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Vehicle mass and centre of gravity</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Vehicle dimensions, and aerodynamics</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Tyre performance (grip and rolling resistance characteristics)</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Final drive system</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Gearbox or transmission system and shifting strategies</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Prime-mover details eg. I.C. engine or hybrid powertrain</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Performance (torque/power capabilities)</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Fuel economy</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">System-out Emissions</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Emissions after-treatment systems</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Driver performance</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">The user selects the appropriate test for analysis. For instance, this often involves predicting the performance of the vehicle in terms of emissions and fuel economy over a government legislated drive-cycle.</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">The calculation cycle is carried out. The user can display the key information on the vehicle and powertrain operating condition during the cycle using the calculation screen.</font></font></span><font face="Times New Roman"><br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">Calculation results are available to the user both in the form of a report quality summary sheet and through a quick-to-use graph plotting system.</font></font></span><font face="Times New Roman"><br>
</font><font face="Arial"><br>
</font>0&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
LOTUS VEHICLE SIMULATION has been applied extensively by world-wide clients and validated thoroughly at LOTUS over a wide range of vehicle types and conditions. The program is capable of simulating all existing and projected vehicle systems and is continually updated by <u>LOTUS</u> in co-operation with it<font face="Times New Roman"><font face="Arial">s partners.<br>
</font></font><br>
0&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
A series of tutorials are available to assist new users learn the features of the code. <u>Open Tutorial</u><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Structure<br>
</font></b><font size="2">Introduction<br>
</font><br>
0&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
LOTUS VEHICLE SIMULATION is split into three sub-sections:<br>
<br>
<span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u><font face="Arial"><font size="2">Data module</font></font></u></span> - data-entry and model generation<br>
<span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u><font face="Arial"><font size="2">Solve module</font></font></u></span> - solution of desired analysis<br>
<span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u><font face="Arial"><font size="2">Results module</font></font></u></span> - analysis of calculated results<br>
<br>
The three sections are only notionally split and all three modules run together as a single application.<br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Structure - Data Module<br>
</font></b><font size="2"><br>
The data module allows the user to enter data, read in or save models, create new models and adjust data in existing models.<br>
<br>
Icons representing the various vehicle-powertrain subsystems allow the user to view the data for that section of the model and adjust, add or delete data from the model. Graphical features allow the user to view the results of changes to the specific data-set and adjust data as fit. <br>
<br>
The vehicle system model sub-components and relevant icons are:<br>
</font><br>
<u><b><u>Vehicle</u></b></u><b></b> Data<br>
<b><br>
</b>Dyno<b></b> Data<br>
<b><br>
</b>Tyre<b></b> Data<br>
<b><br>
</b>Driveline<b></b> Data<br>
<b><br>
</b>Gearbox<b></b> Data<br>
<b><br>
</b>Engine<b></b> Data<br>
<b><br>
</b>Hybrid Drive System<b></b> Data<br>
<b><br>
</b>Driver<b></b> Data<br>
<br>
When an icon is selected the relevant data entry window is displayed with various vehicle and powertrain parameters available for editing.<br>
<br>
{button ,AL(`list10',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Structure - Solve Module</font></b><font size="3"> <b><font size="4"><br>
</font></b></font><font size="2">The solve module is used to run calculations of which a range of types are available. These are:<br>
<br>
</font><u><b>Steady State</b></u><b><br>
<u>Acceleration</u></b><b><br>
<u>Drive Cycle</u></b><b><br>
<u>Track</u></b><b></b><br>
<br>
During calculations, the user is able to display certain vehicle parameters while the calculation runs on the Calculation telemetry window. This displays :<br>
<br>
<b>Drive Cycle (Vehicle speed vs. Time with colour for gear number)<br>
Current Gear <br>
Vehicle Speed (Dial)<br>
Engine Speed (Dial)<br>
Engine Speed vs. Engine Load (BMEP vs. Engine Speed)</b><br>
<br>
To run calculations significantly faster, the user may choose to close this window resulting in a large reduction in calculation time. After the calculation is complete, the user can review the calculated data using the <u>results module</u>. <br>
<br>
The module also offers interactive build modules for rapid generation of new track and cycle files for analysis.<br>
<br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Structure - Results Module<br>
</font></b><font size="2"><br>
The results module is used to perform all post-processing of calculated data. It provides the following features:<br>
<br>
</font><b>Plotting of datasets - Up to five runs simultaneously<br>
Plotting of multiple data-channels eg. Vehicle fuel consumption and <br>
forward speed vs. time - up to 4 sets <br>
Cross plotting of datasets and channels on a single multi-axis graph<br>
Zoom and pick functions<br>
</b><br>
The Windows environment also allow frame grabbing of graphs as bitmaps for pasting into other Windows applications.<br>
<br>
{button ,AL(`list7',0,&quot;&quot;,`main')} <u>Related Text Results Topics</u><br>
<br>
{button ,AL(`list8',0,&quot;&quot;,`main')} <u>Related Graph Results Topics</u><br>
<br>
<b><font size="3"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font></b><font size="4">Program Structure - Additional Features</font><font size="3"><br>
</font><font size="2"><br>
Additional tools are provided to perform specific functions these include;<br>
<br>
</font>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u><b>Data Checking Wizard,</b></u><b></b> to check the validity of the data<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u><b>Interactive Track Builder,</b></u><b> </b>to build or edit a user defined track<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u><b>Interactive Cycle Builder,</b></u><b></b> to create or edit a user defined drive cycle<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u><b>Column Write Wizard,</b></u><b> </b> to write out chosen results data into a specified file format<b><font size="3"><br>
<p><hr><p>
<sup>#</sup></font></b><font size="2">Position</font><br>
Up to five graphical results files can be held at any one time, these are identified in the cross plot status dialog box. Each of these files is held in a <b>position</b>, and these <b>position</b> numbers are used to identify individual properties and settings, as well as providing a means of cross plotting different analysis runs.<br>
<p><hr><p>
<sup>#</sup><b>Rolling Radius</b><br>
Sets the variable type for the extended tyre model as 'Rolling Radius'. (note only one variable currently exists for extended tyre).<br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>#</sup></font><font face="Arial"><b>Constant</b></font><br>
Sets the selected tyre variable as a constant value. This is identical to the simple tyre model.<br>
<p><hr><p>
<sup>#</sup><b>Coefficients</b><br>
Sets the selected tyre variable to be defined by a constant term plus up to five polynomial terms of increasing power.<br>
<p><hr><p>
<sup>#</sup><b>Value List</b><br>
Sets the selected tyre variable to be defined by a look up table that uses linear interpolation/extrapolation to identify the current value based on vehicle speed.<br>
<p><hr><p>
<sup>#</sup><b>Display Graph</b><br>
Opens the graph window to graphically display the currently selected variable.<br>
<p><hr><p>
<sup>#</sup><b>Different Tyre Option</b><br>
Sets the option for either a common tyre or different tyre front to rear. This also changes the displayed data and options for the selected tyre. The data displayed in the 'standard tyre window' is also changed to reflect this selection.<br>
<p><hr><p>
<sup>#</sup><b>Y units</b><br>
The available units are displayed here. Selecting the required units will update the displayed data and future listings will also use these units.<br>
<p><hr><p>
<sup>#</sup><b>Update Listing</b><br>
This button updates the list using the currently displayed data for the current min/max and increment settings. They will be displayed in the currently selected units.<br>
<p><hr><p>
<sup>#</sup><b>X Values</b><br>
The current x-values are listed in this side of the spread sheet. They can be edited and the results viewed using the update listing button. If relevant they will be displayed in the selected units. To save any changes back to the original data window close the spline listing using the menu option <u>File</u> / <u>Close (save changes)</u>. To ignore any data changes close the spline listing with either the alternative menu option, or any other window close technique.<br>
<p><hr><p>
<sup>#</sup><b>Y Values</b><br>
The current y-values are listed in this side of the spread sheet. They can be edited and the results viewed using the update listing button. If relevant they will be displayed in the selected units. To save any changes back to the original data window close the spline listing using the menu option <u>File</u> / <u>Close (save changes)</u>. To ignore any data changes close the spline listing with either the alternative menu option, or any other window close technique.<br>
<p><hr><p>
<sup>#</sup><b>Listing settings</b><br>
The spline listing is controlled by these values. They define the start and end values of the list, (in the appropriate units), and the increment between values.<br>
<p><hr><p>
<sup>#</sup><b>Listing Results</b><br>
The spline listing results are displayed here. They are define the start and end values shown in the calculate settings boxes and in the chosen units.<br>
<b><font size="3"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font></b><font size="4">Results Module<br>
</font><font size="2">Overview<br>
</font><font face="Times New Roman"><br>
<font face="Arial">When Lotus Vehicle Simulation calculations are performed it creates a number of results files, the extensions of which identify the type of results file it is.<br>
<br>
</font></font>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Text results files have the form &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
*_n.crs<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Graphical results files have the form&nbsp;&nbsp;&nbsp;
*_n.grs<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Grid text results files have the form&nbsp;&nbsp;&nbsp;
*_n.grd<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Where; n is the <i>Plot File Counter</i> number which is incremented for each calculation, and the <font face="Times New Roman"><font face="Arial">*</font></font><font face="Times New Roman"><font face="Arial"> is the <i>Test No.</i></font></font> string supplied by the user, both are displayed in the vehicle data window.<br>
<br>
The <i>Result File Viewer</i> is a scrollable text window that allows the user to load, read and print the text results files. A specific command allow the current results to be loaded directly without requiring the file browser.<br>
<br>
The <i>Results Graph </i>Viewer is a graphics window that allows the user to display the graphical results files on up to 4 different graphs, (with a common x-axis), that can be either separate graphs or overlayed. Five different results files can be loaded and displayed together to enable rapid cross-plotting to be employed.<br>
<br>
The graph axes can be specified from the available list of 77 results variables. <br>
<br>
Graph axes scales can be user defined or use the autoscale or zoom functions to set the desired graph area. A list function allow the values for individual points to be interrogated, whilst printing is performed using the standard Windows printer dialogue boxes.<br>
<br>
The <i>Results 3D Viewer</i> is a 3d environment through which the analysis results can be animated. It is primarily aimed at track simulation runs, providing a unique visualisation tool that shows vehicle attitude, speed and acceleration together with engine rpm and current gear, animated as its proceeds through the solution. It will also display the results from the steady speed, acceleration and emissions cycles.<br>
<br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Results Text File Viewer <br>
</font></b></font><font size="2">Overview<br>
</font><br>
The <i>Result File Viewer</i> is a scrollable resizable text window that allows the user to load, read and print the Lotus Vehicle Simulation text results files. These text results files contain a summary of the input data, the solution type and the major results pertinent to the solution run.<br>
<br>
Text results files have the form <font face="Times New Roman"><font face="Arial">*_n.crs</font></font><font face="Times New Roman"><font face="Arial"> here; n is the <i>Plot File Counter</i></font></font> number which is incremented for each calculation, and the <font face="Times New Roman"><font face="Arial">*</font></font><font face="Times New Roman"><font face="Arial"> is the <i>Test No.</i></font></font> string supplied by the user, both are displayed in the vehicle data window.<br>
<br>
Because results files have an incremental counter they are not over written and thus can be re-read at any time.<br>
<br>
When a Lotus Vehicle Simulation solution is performed the results files are automatically written but they are not loaded into the viewer. If the user requires to view the text results the viewer must be opened and the appropriate text results file loaded.<br>
<br>
A specific file can be loaded through the <i>open </i>command that uses the conventional file browser dialogue box, alternatively if the results of the latest run are required, a specific command allow the current results to be loaded directly without requiring the file browser.<br>
<br>
The currently displayed text results file can be printed directly from the viewer window menu options, using the standard Windows printer dialogue boxes.<br>
<br>
The entire contents or a portion of the viewer display can be copied into another application such as Word or notepad by use of the right mouse button functionality. <br>
<br>
{button ,AL(`list7',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Opening the Text Results File Viewer </font></b></font><br>
<font face="Times New Roman"><font size="2"><br>
<font face="Arial">To open the text results file viewer, select the menu item <u>Results</u></font></font></font><i> / </i><u>Results Viewer</u> from the main menubar. Alternatively the <u>Text Results Viewer Icon</u> can be selected from either the top toolbar or the side panel, depending on the data module set-up. <br>
<br>
When the viewer is open the icon remains indented and the pull down menu item is <font face="Times New Roman"><font face="Arial">ticked</font></font><font face="Times New Roman"><font face="Arial">. <br>
<br>
On initially opening the viewer no text results are displayed, these must be loaded into the display, see <u>Loading a text results file</u></font></font> and <u>Loading the current text results file</u>.<br>
<br>
{button ,AL(`list7',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Closing the Text Results File Viewer </font></b></font><br>
<font face="Times New Roman"><font size="2"><br>
<font face="Arial">To close the text results file viewer select either the menu item <u>Results</u></font></font></font><i> / </i><u>Results Viewer</u> from the main menubar, the <font face="Times New Roman"><font face="Arial">close</font></font><font face="Times New Roman"><font face="Arial"> icon at the top right corner of the viewer, the results file viewer window menu at the top left or alternatively the <u>Text Results Viewer Icon</u></font></font> can be un-selected from either the top toolbar or the side panel, depending on the data module set-up. <br>
<br>
Closing the results file viewer does not lose the display contents. Upon re-opening the viewer the original text and position in the text is retained. <br>
<br>
{button ,AL(`list7',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Loading a Text Results File </font></b></font><br>
<font face="Times New Roman"><font size="2"><br>
<font face="Arial">To load a text results file into the viewer, with the viewer open select the <u>File/ Open</u></font></font></font> option from the viewer window menubar. This will bring up the standard file browser with the default file filter being *.crs.<br>
<br>
Browse for the required file and select <font face="Times New Roman"><font face="Arial">open</font></font><font face="Times New Roman"><font face="Arial">, this file is then loaded into the viewer, and will replace the existing contents. <br>
<br>
{button ,AL(`list7',0,&quot;&quot;,`main')} <u>Related Topics</u></font></font><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Loading the Current Text Results File </font></b><br>
<font face="Times New Roman"><font size="2"><br>
<font face="Arial">To load the <u>current text results file</u></font></font></font> into the viewer, with the viewer open select the <u>File / Load Current</u> option from the viewer window menubar. If this menu option is <font face="Times New Roman"><font face="Arial">greyed</font></font><font face="Times New Roman"><font face="Arial"> out it means that no solution has been run since the application was opened.<br>
<br>
The current file is then loaded into the viewer, and will replace the existing contents. <br>
<br>
{button ,AL(`list7',0,&quot;&quot;,`main')} <u>Related Topics</u></font></font><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Printing the Text Results File </font></b><br>
<font face="Times New Roman"><font size="2"><br>
<font face="Arial">To print the displayed text results file, with the viewer open select the <u>File / Print</u></font></font></font> option from the viewer window menubar. If this menu option is <font face="Times New Roman"><font face="Arial">greyed</font></font><font face="Times New Roman"><font face="Arial"> out it means that no text results file has been loaded into the viewer.<br>
<br>
The standard Windows print dialogue boxes are then employed to perform the printing task. <br>
<br>
{button ,AL(`list7',0,&quot;&quot;,`main')} <u>Related Topics</u></font></font><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Copying the Text Buffer to External Applications </font></b><br>
<font face="Times New Roman"><font size="2"><br>
<font face="Arial">The entire contents or a portion of the currently displayed text results file can be copied and pasted into other external applications via the right mouse button functionality.<br>
<br>
To copy the entire text results file from the viewer, with the viewer open and the required file loaded, click on the viewer with the right mouse button and chose <i>Select <u>A</u></i></font></font></font><i>ll</i>. This will highlight the entire file and now when clicking on the viewer with the right mouse button the <i><u>C</u></i><i>opy</i> option is available, select copy. The file is now held in the copy/paste buffer and changing to the target application the buffer can be <i>Pasted</i> in using the appropriate application specific commands.<br>
<br>
To copy a portion of a text results file from the viewer, with the viewer open and the required file loaded, click on the viewer with the left mouse button highlight via a click and drag the required portion of the file. Then clicking on the viewer with the right mouse button select the <i><u>C</u></i><i>opy</i> option. The highlighted text is now held in the copy/paste buffer and changing to the target application the buffer can be <i>Pasted</i> in using the appropriate application specific commands.<br>
<br>
Typical external windows applications that this works with are Word, PowerPoint, Exchange and Notepad.<br>
<br>
{button ,AL(`list7',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Text Results File Data Contents<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">The text results files contain a copy of the major data items and a summary of the results that are applicable to both the solution run and the data options selected.<br>
<br>
The input data sections summarised within the text results file mimic those of the Lotus Vehicle Simulation data modules, i.e.<br>
</font></font></font>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u><b><u>Vehicle</u></b></u><b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Dynamometer</b><b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Tyre</b><b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Driveline</b><b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gearbox ( + Driver)</b><b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Engine</b><b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Hybrid</b><b><br>
<br>
</b>Depending on the solution type selected, one of the following results sections will be present,<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u><b><u>Steady speed simulation, (user defined gear and speed)</u></b></u><b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Steady speed simulation, (user defined shift map and speed)</b><b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Vehicle acceleration from rest, (slip start)</b><b><br>
</b><b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Vehicle acceleration from rest, (idle start)</b><b><br>
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
In gear acceleration<b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
User defined acceleration</b><b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Emissions cycle simulation</b><b> </b>(where <font face="Times New Roman"><font face="Arial">emissions cycle</font></font><font face="Times New Roman"><font face="Arial"> is the name of the cycle)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u><b><u>Circuit track simulation</u></b></u></font></font><b></b> (where <font face="Times New Roman"><font face="Arial">circuit</font></font><font face="Times New Roman"><font face="Arial"> is the name of the track)<b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Verdana"><br>
</font></b></font></font><br>
{button ,AL(`list7',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>#</sup></font><font face="Arial"><b>Current text results file</b></font><br>
This is the *.crs file created for the last solution run performed. This setting is lost when the application is closed. Thus on initially opening the application no file is deemed to be <i>Current</i>. <p><hr><p>
<sup>#</sup><b>Vehicle Data in Text Results File- </b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Weight (kg)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Frontal Area (m2)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Plan Area (m2)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Air Density (kg/m3)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Drag Coefficient<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Front Lift Coefficient<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Rear Lift Coefficient<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Wheelbase (m)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Track (m)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
C of G to Front Axle (m)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
C of G to Ground (m)<br>
<p><hr><p>
<sup>#</sup><b>Dynamometer Data in Text Results File- </b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Dyno Inertia Weight (kg)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Load A Constant<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Load B x Velocity Constant<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
load C x Velocity2 Constant&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<p><hr><p>
<sup>#</sup><b>Tyre Data in Text Results File- </b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Rolling Radius (m)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Coefficient of Friction<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Source of Rolling Resistance Coefficients, (default or user defined) <br>
<p><hr><p>
<sup>#</sup><b>Driveline Data in Text Results File- </b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Drive Type (Front, Rear, 4wd)&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Total Inertia of Front wheels (kg.m2)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Total Inertia of Rear wheels (kg.m2)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Driven Axle Inertia (kg.m2)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Prop Shaft Inertia (kg.m2)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Final Drive Ratio<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Final Drive Efficiency<br>
<p><hr><p>
<sup>#</sup><b>Gearbox Data in Text Results File- </b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Manual or Automatic&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Number of Ratios<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gear Change Time (s)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Minimum Time Between Shifts (s)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Maximum Gearbox Torque (Nm)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Maximum Gearbox Speed (Nm)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gear Ratios<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gear Efficiency<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gear Inertia (kg.m2)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Overall Ratio<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Overall Efficiency<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
MPH/1000 rpm<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Torque Converter Stall Speed (rpm)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
or Vehicle De-clutch Speed (kmh)<br>
<p><hr><p>
<sup>#</sup><b>Engine Data in Text Results File- </b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Engine type&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Number of Cylinders<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Cycle Type<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Bore (mm)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Stroke (mm)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Swept Volume (l)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Rotating Inertia (kg.m2)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Idle Speed (rpm)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Maximum Engine Speed (rpm)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Maximum Power (kW)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Maximum Power Speed (rpm)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Maximum Torque (Nm)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Maximum Torque Speed (rpm)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Primary Drive Ratio<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Primary Drive Efficiency<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Auxiliaries Present<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Power / Weight Ratio<br>
<p><hr><p>
<sup>#</sup><b>Hybrid Data in Text Results File- </b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Drive Position&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Maximum Store Capacity (kw.h)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Minimum Store Capacity (kw.h)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Maximum Input Rate (Nm)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Input Efficiency<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Maximum Output Rate (Nm)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Output Efficiency<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Starting Capacity (kw.h)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Idle Store Option on / off<br>
<p><hr><p>
<sup>#</sup><b>Results in Text Results File for Steady Speed in Defined Gear </b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Road Speed (mph or km/h)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Total Cycle Time (s)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (m)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (km)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (miles)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Mean Power Developed (kW)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Shift Map Used<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
No of Gear Changes<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
User Defined Gear No<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Fuel Map Defined</u><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Emissions Map Defined</u>, (for each emissions map)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Hybrid Defined</u><br>
<p><hr><p>
<sup>#</sup><b>Results in Text Results File for Steady Speed with User Defined Shift Map </b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Road Speed (mph or km/h)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Total Cycle Time (s)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (m)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (km)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (miles)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Mean Power Developed (kW)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Shift Map Used<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
No of Gear Changes<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
User Defined Gear No<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Fuel Map Defined</u><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Emissions Map Defined</u>, (for each emissions map)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Hybrid Defined</u><br>
<p><hr><p>
<sup>#</sup><b>Results in Text Results File for Vehicle Acceleration from Rest (Slip Start)</b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Total Cycle Time (s)&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (m)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (km)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (miles)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Mean Power Developed (kW)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Shift Map Used<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
No of Gear Changes<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Time to Speeds, 0 <font face="Times New Roman"><font face="Arial"> MPH, Time (s). Ratio:1 RPM<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Time to Speeds, 0 </font></font><font face="Times New Roman"><font face="Arial"> KMH, Time (s), Ratio:1, RPM<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Time to Distance, 400M Mile, Kilometre, Mile<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Time (s), Ratio:1, RPM, MPH, KMH<br>
</font></font>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance in Time, In 3.0 (s), In 5.0 (s)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gear Change Points,<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance (m), Time (s), Ratio:1, RPM, MPH, KMH<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Fuel Map Defined</u><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Emissions Map Defined</u>, (for each emissions map)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Hybrid Defined</u><br>
<p><hr><p>
<sup>#</sup><b>Results in Text Results File for Vehicle Acceleration from Rest (Idle Start)</b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Total Cycle Time (s)&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (m)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (km)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (miles)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Mean Power Developed (kW)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Shift Map Used<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
No of Gear Changes<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Time to Speeds, 0 <font face="Times New Roman"><font face="Arial"> MPH, Time (s). Ratio:1 RPM<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Time to Speeds, 0 </font></font><font face="Times New Roman"><font face="Arial"> KMH, Time (s), Ratio:1, RPM<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Time to Distance, 400M Mile, Kilometre, Mile<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Time (s), Ratio:1, RPM, MPH, KMH<br>
</font></font>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance in Time, In 3.0 (s), In 5.0 (s)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Gear Change Points,<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance (m), Time (s), Ratio:1, RPM, MPH, KMH<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Fuel Map Defined</u><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Emissions Map Defined</u>, (for each emissions map)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Hybrid Defined</u><br>
<p><hr><p>
<sup>#</sup><b>Results in Text Results File for In Gear Acceleration</b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
User Defined Gear No&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Total Cycle Time (s)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (m)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (km)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (miles)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Mean Power Developed (kW)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Shift Map Used<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
No of Gear Changes<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Incremental Acceleration Times, MPH <font face="Times New Roman"><font face="Arial"> MPH, Time (s)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Incremental Acceleration Times, KMH </font></font><font face="Times New Roman"><font face="Arial"> KMH, Time (s)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Fuel Map Defined</u></font></font><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Emissions Map Defined</u>, (for each emissions map)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Hybrid Defined</u><br>
<p><hr><p>
<sup>#</sup><b>Results in Text Results File for User Defined Acceleration </b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Total Cycle Time (s)&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (m)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (km)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (miles)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Mean Power Developed (kW)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Shift Map Used<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
No of Gear Changes<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Incremental Acceleration Times, MPH <font face="Times New Roman"><font face="Arial"> MPH, Time (s)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Incremental Acceleration Times, KMH </font></font><font face="Times New Roman"><font face="Arial"> KMH, Time (s)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Fuel Map Defined</u></font></font><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Emissions Map Defined</u>, (for each emissions map)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Hybrid Defined</u><br>
<p><hr><p>
<sup>#</sup><b>Results in Text Results File for Emissions Test</b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Emissions Test Name&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Total Cycle Time (s)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (m)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (actual) (m)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (km)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (actual) (km)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (miles)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (actual) (miles)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Mean Power Developed (kW)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Shift Map Used<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
No of Gear Changes<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Fuel Map Defined</u><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Emissions Map Defined</u>, (for each emissions map)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Hybrid Defined</u><br>
<p><hr><p>
<sup>#</sup><b>Results in Text Results File for Track Test</b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Track Name&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Total Cycle Time (s)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (m)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (km)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Distance Travelled (nominal) (miles)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Mean Power Developed (kW)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Shift Map Used<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
No of Gear Changes<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Fuel Map Defined</u><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Emissions Map Defined</u>, (for each emissions map)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<u>If Hybrid Defined</u><br>
<p><hr><p>
<sup>#</sup><b>Fuel Consumption Results in Text Results File- </b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Fuel Consumption Map No.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Fuel Consumption in;<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Litres per 100 km<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Km per Litre<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Miles per Imperial Gallon<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Miles per US Gallon<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Grams per Test<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Grams per KM<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Grams per Mile<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Mean Consumption (g/h)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Mean Specific Consumption (g/kw.h)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Overall Cycle Efficiency (%)<br>
<p><hr><p>
<sup>#</sup><b>Emissions Results in Text Results File- </b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Emissions Map No.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Emissions in;<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Grams per Test<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Grams per KM<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Grams per Mile<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Mean Consumption (g/h)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Mean Specific Consumption (g/kw.h)<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Also Given for Post Catalyst<br>
<p><hr><p>
<sup>#</sup><b>Hybrid Results in Text Results File- </b><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Energy at Start (kw.h)&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Energy at End (kw.h)<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Results Graph Viewer <br>
</font></b><font size="2">Overview<br>
</font><br>
The <i>Result Graph Viewer</i> is a resizable graphics window that allows the user to load, plot and print the Lotus Vehicle Simulation graphical results files that contain up to 77 calculated variables. Within the window a maximum of four graphs can be plotted, either as individual plots or overlayed on a single graph. All graphs are plotted against a single common x-axis variable. Cross plotting of up to five graphical results can be employed to enable rapid presentation of trends and differences to be performed.<br>
<br>
Graphical results files have the form <font face="Times New Roman"><font face="Arial">*_n.grs</font></font><font face="Times New Roman"><font face="Arial"> here; n is the <i>Plot File Counter</i></font></font> number which is incremented for each calculation, and the <font face="Times New Roman"><font face="Arial">*</font></font><font face="Times New Roman"><font face="Arial"> is the <i>Test No.</i></font></font> string supplied by the user, both are displayed in the vehicle data window.<br>
<br>
Because results files have an incremental counter they are not over written and thus can be re-read at any time.<br>
<br>
When a Lotus Vehicle Simulation solution is performed the results files are automatically written but they are not loaded into the viewer. If the user requires to view the graphical results the graph viewer must be opened and the appropriate graph results file loaded. These can be loaded as <font face="Times New Roman"><font face="Arial">exclusive</font></font><font face="Times New Roman"><font face="Arial"> (i.e. the only results file), or into a selected position, from 1 to 5, within the cross plot status.<br>
</font></font><br>
A specific file can be loaded through the <i>Load Results (exclusive), </i>the <i>Load Results (shuffle) </i>or the <i>Load Results (position) </i>commands that use the conventional file browser dialogue box, alternatively if the results of the latest run are required, a specific command allow the current results to be loaded directly without requiring the file browser.<br>
<br>
All currently displayed graphs can be printed directly from the viewer window menu options, using the standard Windows printer dialogue boxes, whilst the data values can also be saved into an ASCII column file using the <u>Column Write Wizard</u>.<br>
<br>
The axis settings for the graphs can be set individually by the user, or the autoscale and zoom functions used to define the graph settings.<br>
<br>
The appearance of fonts, colours linetypes etc within the plot can be modified by the user using the <u></u><font face="Times New Roman"><u> set-up</u></font><font face="Arial"><u> option.<br>
<br>
Apart from the graph viewer window, control of the graphs and their display uses three other set-up windows, namely the <i>Specify Graph</i></u></font><i><u></u></i><u> window to define the axes variables, the <i>Axis Scales</i></u><i><u></u></i><u> window to set the axis minimum and maximum values and finally, the <i>Cross Plot Status</i></u><i></i><u> window to control the varies files used within a cross plot.<br>
</u><br>
{button ,AL(`list8',0,&quot;&quot;,`main')} Related Topics<u> <br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></u><b><font size="4">Opening the Results Graph Viewer <br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To open the results graph viewer, select the menu item <u>Results</u></font></font></font><i> / </i><u>Results Graph</u> from the main menubar. Alternatively the <u>Results Graph Viewer Icon</u> can be selected from either the top toolbar or the side panel, depending on the data module set-up. <br>
<br>
When the viewer is open the icon remains indented and the pull down menu item is <font face="Times New Roman"><font face="Arial">ticked</font></font><font face="Times New Roman"><font face="Arial">. <br>
<br>
On initially opening the viewer no graphical results are displayed, these must be loaded into the display, see <u>Loading a graphical results file</u></font></font> and <u>Loading the current graphical results file</u>.<br>
<br>
{button ,AL(`list8',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Closing the Results Graph Viewer <br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To close the results graph viewer select either the menu item <u>Results</u></font></font></font> / <u>Results Graph</u> from the main menubar, the <font face="Times New Roman"><font face="Arial">close</font></font><font face="Times New Roman"><font face="Arial"> icon at the top right corner of the viewer, the results graph viewer window menu at the top left or alternatively the <u>Results Graph Viewer Icon</u></font></font> can be un-selected from either the top toolbar or the side panel, depending on the data module set-up. <br>
<br>
Closing the results graph viewer does not lose the display contents or setting. Upon re-opening the graph viewer the original graphs and set-up is retained. <br>
<br>
{button ,AL(`list8',0,&quot;&quot;,`main')} <u>Related Topics</u> <br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Loading a Graphical Results File <br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To load a graphical results file into the results graph viewer, with the graph viewer open select from the graph viewer menubar either, <u>File / Load Results (exclusive)</u></font></font></font>, <u>File / Load Results (shuffle)</u>, or <u>File / Load Results (position 1 -5)</u>. (note that results can also be loaded in as <font face="Times New Roman"><font face="Arial">current</font></font><font face="Times New Roman"><font face="Arial"> when appropriate, or through the <u><i>Cross Plot Status</i></u></font></font><i></i> window).<br>
<br>
All three menu options will then proceed to display the standard file browser through which the required file may be selected, however depending on which load menu item was chosen the files data will be loaded into a different <font face="Times New Roman"><font face="Arial">cross plot</font></font><font face="Times New Roman"><font face="Arial"> position.<br>
</font></font><br>
Up to five results file can be held by the graph viewer at any one time, and they are stored in positions 1 to 5.<br>
<br>
<font face="Times New Roman"><font face="Arial"><i>Load Results (exclusive) </i></font></font>will load the selected file into position 1, overwriting any values previously stored in position 1 and removing any data from the other positions 2 to 5.<br>
<br>
<font face="Times New Roman"><font face="Arial"><i>Load Results (shuffle) </i></font></font>will load the selected file into position 1, shuffling down one position any files currently held in positions 1 to 4. Any data held in position 5 is lost by this shuffling process.<br>
<br>
<font face="Times New Roman"><font face="Arial"><i>Load Results (position) </i></font></font>will load the selected file into the chosen position, overwriting any values currently held in that position. All other positions remain unaltered.<br>
<br>
{button ,AL(`list8',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Loading the Current Graphical Results File <br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To load the current graphical results file into the results graph viewer, with the graph viewer open select from the graph viewer menubar either, <u>File / Load Current (exclusive)</u></font></font></font>, <u>File / Load Current (shuffle)</u>, or <u>File / Load Current (position 1 -5)</u>. If these menu options are <font face="Times New Roman"><font face="Arial">greyed</font></font><font face="Times New Roman"><font face="Arial"> out it means that no solution has been run since the application was opened.<br>
<br>
All three menu options will then proceed to load the current graphical results file data, however depending on which <i>load current</i></font></font> menu item was chosen the files data will be loaded into a different <font face="Times New Roman"><font face="Arial">cross plot</font></font><font face="Times New Roman"><font face="Arial"> position.<br>
</font></font><br>
Up to five results file can be held by the graph viewer at any one time, and they are stored in positions 1 to 5.<br>
<br>
<font face="Times New Roman"><font face="Arial"><i>Load Current (exclusive) </i></font></font>will load the current file into position 1, overwriting any values previously stored in position 1 and removing any data from the other positions 2 to 5.<br>
<br>
<font face="Times New Roman"><font face="Arial"><i>Load Current (shuffle) </i></font></font>will load the current file into position 1, shuffling down one position any files currently held in positions 1 to 4. Any data held in position 5 is lost by this shuffling process.<br>
<br>
<font face="Times New Roman"><font face="Arial"><i>Load Current (position) </i></font></font>will load the current file into the chosen position, overwriting any values currently held in that position. All other positions remain unaltered.<br>
<br>
{button ,AL(`list8',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Specifying the Graph Axes in the Results Graphs<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">The </font></font></font><font face="Times New Roman"><font face="Arial">Specify Graph</font></font><font face="Times New Roman"><font face="Arial"> dialogue box enables the user to select the required common x-axis and up to 4 different y-axis from the 77 results variables. In addition this dialogue box also contains </font></font><font face="Times New Roman"><font face="Arial">buttons</font></font><font face="Times New Roman"><font face="Arial"> to switch individual y-axes </font></font><font face="Times New Roman"><font face="Arial">on</font></font><font face="Times New Roman"><font face="Arial"> and </font></font><font face="Times New Roman"><font face="Arial">off</font></font><font face="Times New Roman"><font face="Arial">, switch </font></font><font face="Times New Roman"><font face="Arial">in</font></font><font face="Times New Roman"><font face="Arial"> and </font></font><font face="Times New Roman"><font face="Arial">out</font></font><font face="Times New Roman"><font face="Arial"> of overlay mode, </font></font><font face="Times New Roman"><font face="Arial">autoscale</font></font><font face="Times New Roman"><font face="Arial"> the plots and </font></font><font face="Times New Roman"><font face="Arial">refresh</font></font><font face="Times New Roman"><font face="Arial"> the displayed graphs.<br>
</font></font><br>
To open the <font face="Times New Roman"><font face="Arial">Specify Graph</font></font><font face="Times New Roman"><font face="Arial"> dialogue box select the menu item <u>Results</u></font></font> / <u>Specify Graph</u> from the main menubar. alternatively the <u>Specify Graph Icon</u> can be selected from either the top toolbar or the side panel, depending on the data module set-up. <br>
<br>
The dialogue box contains four switches to set individual y-axes as either <font face="Times New Roman"><font face="Arial">on</font></font><font face="Times New Roman"><font face="Arial"> or </font></font><font face="Times New Roman"><font face="Arial">off</font></font><font face="Times New Roman"><font face="Arial">, this buttons cannot be set to </font></font><font face="Times New Roman"><font face="Arial">on</font></font><font face="Times New Roman"><font face="Arial"> until a variable has been selected from the adjacent list box.<br>
</font></font><br>
Each axis has its own list box that the user can select the required axis variable from, these currently list 77 different calculated variables, from <font face="Times New Roman"><font face="Arial">Time</font></font><font face="Times New Roman"><font face="Arial"> through to </font></font><font face="Times New Roman"><font face="Arial">Post Cat CO Emissions</font></font><font face="Times New Roman"><font face="Arial">.<br>
<br>
{button ,AL(`list8',0,&quot;&quot;,`main')} <u>Related Topics</u></font></font><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Specifying the Axis Scales in the Results Graphs<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">The </font></font></font><font face="Times New Roman"><font face="Arial">Axis Scales</font></font><font face="Times New Roman"><font face="Arial"> dialogue box enables the user to control the required minimum and maximum axis values for each individual graph, (with the restriction of a common x-axis), the No. of increments on each axis and the No. of decimal points used both on the axes and used for the list facility. In addition this dialogue box also contains </font></font><font face="Times New Roman"><font face="Arial">buttons</font></font><font face="Times New Roman"><font face="Arial"> to </font></font><font face="Times New Roman"><font face="Arial">autoscale</font></font><font face="Times New Roman"><font face="Arial"> the plots and </font></font><font face="Times New Roman"><font face="Arial">refresh</font></font><font face="Times New Roman"><font face="Arial"> the displayed graphs.<br>
</font></font><br>
To open the <font face="Times New Roman"><font face="Arial">Axis Scales</font></font><font face="Times New Roman"><font face="Arial"> dialogue box select the menu item <u>Results</u></font></font> / <u>Axis Scales</u> from the main menubar. alternatively the <u>Axis Scales Icon</u> can be selected from either the top toolbar or the side panel, depending on the data module set-up. <br>
<br>
The dialogue box contains value entries for the minimum, maximum and increments for each axis, the user should set these to the required values. The <font face="Times New Roman"><font face="Arial">zoom</font></font><font face="Times New Roman"><font face="Arial"> and </font></font><font face="Times New Roman"><font face="Arial">autoscale</font></font><font face="Times New Roman"><font face="Arial"> functions will re-set these values as required. <br>
</font></font><br>
The No. of decimal places for each y-axis can also be defined this controls the number used not just on the graph axes but also the number of decimal places given when <u>listing values.</u><br>
<br>
The <font face="Times New Roman"><font face="Arial">force fit</font></font><font face="Times New Roman"><font face="Arial"> toggles can be used to overide the internal routines that attempt to round up the minimum and maximum axis to achieve a </font></font><font face="Times New Roman"><font face="Arial">better</font></font><font face="Times New Roman"><font face="Arial"> scale, such that when </font></font><font face="Times New Roman"><font face="Arial">ticked</font></font><font face="Times New Roman"><font face="Arial"> the axis will be set exactly as defined by the minimum/maximum/increments values, (this effectively already happens when a plot is zoomed with the exception of the no of increments).<br>
</font></font><br>
{button ,AL(`list8',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Using Zoom in the Results Graphs<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">The zoom a graph, with the graph results viewer open and the required graph displayed, select from the graph results viewer menubar the menu item <u>View / Zoom</u></font></font></font>. The cursor will change to a full screen cross-hair, then with the mouse select one corner of the required area with the left mouse button, then drag the rubber band box and select the other corner, again with the left mouse button. The display is then redrawn showing the selected area. Using the right mouse button for either of the selections cancels the zoom action.<br>
<br>
If multiple y-axis graphs are displayed then the zoom function can be used in two different ways. Since the x-axis is common between the graphs setting the x-axis on one graph will also effect the other open graphs. In addition if the cursor picks are on both on the one graph that graphs y-axis values will be changed to reflect the zoom area picked. If the two cursor picks are on different graphs the y-axis values are ignored and only the x-axis is <font face="Times New Roman"><font face="Arial">zoomed</font></font><font face="Times New Roman"><font face="Arial">.<br>
</font></font><br>
{button ,AL(`list8',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Autoscaling the Results Graphs<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To autoscale the displayed graphs select the </font></font></font><font face="Times New Roman"><font face="Arial">Autoscale</font></font><font face="Times New Roman"><font face="Arial"> option from one of the following dialogue boxes or window menus. <br>
</font></font>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
The <u><i>Specify Graph</i></u><i></i> dialogue box<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
The <u><i>Axis Scales</i></u><i></i> dialogue box<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
The <u><i>Cross Plot Status</i></u><i> </i>dialogue box<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
and the <i>Results Graph</i> window menubar<br>
<br>
This will autoscale all the displayed graphs and refresh the display. <br>
<br>
{button ,AL(`list8',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Controlling the Cross Plot Status in the Results Graphs <br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">Within the results graph viewer up to five different files can be displayed at any one time. These files could have been loaded through the <u>graph viewer window menu</u></font></font></font>, or they can be loaded into specific positions using the <i>Cross Plot Status</i> dialogue box.<br>
<br>
To open the <font face="Times New Roman"><font face="Arial">Cross Plot Status</font></font><font face="Times New Roman"><font face="Arial"> dialogue box select the menu item <u>Results</u></font></font> / <u>Cross Plot Status</u> from the main menubar. alternatively the <u>Cross Plot Status Icon</u> can be selected from either the top toolbar or the side panel, depending on the data module set-up. <br>
<br>
The cross plot status dialogue box shows the current files names loaded into the five positions. A blank entry implies no file is currently loaded. The <u>file browser icon</u>adjacent to each text box can be used to open the Windows file browser to locate and load the required <font face="Times New Roman"><font face="Arial">*.grs</font></font><font face="Times New Roman"><font face="Arial"> file.<br>
<br>
Currently the required filename cannot be typed directly into the text entry, but must be loaded through one of the methods identified.<br>
<br>
The visibility of individual cross plot files is controlled by the buttons to the left of the text entries in the cross plot status dialogue box. <br>
</font></font><br>
Within the graphs the lines from each cross plot have a specific colour, the default colours are defined as; <br>
Position 1: <font color="#ff0000">Red</font> <br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Position 2: <font color="#ffff00">Yellow</font><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Position 3: <font color="#00ff00">Green</font><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Position 4: <font color="#00ffff">Cyan</font><br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Position 5: <font color="#0000ff">Blue</font><br>
<br>
These settings can be re-defined by the user through the <u>results graph set-up</u>.<br>
<br>
The cross plot status dialogue box also contains autoscale and refresh buttons.<br>
<br>
{button ,AL(`list8',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Listing Points on the Results Graphs<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To list the x and y value of a point displayed on a graph, with the graph results viewer open and the required graph displayed, select from the graph results viewer window menubar the <u>View / List Point</u></font></font></font> menu option. The cursor will change to a full screen cross-hair and the user can then pick the point of interest from the graphs using the left mouse button.<br>
<br>
The actual x and y values of the nearest point to the picked screens x-position is listed at the bottom of the window for all open graphs. If more than one line is cross plotted only the values for the line in the first active position are given. <br>
<br>
The pick function remains active such that the user can continue to pick alternative points, the values for each pick overwriting the previous ones. <br>
<br>
To cancel the pick action use the right mouse button <br>
<br>
To change the Number of decimal places that are given on a list use the <u><i>Axis Scales</i></u><i></i> dialogue box to set the required accuracy. <br>
<br>
{button ,AL(`list8',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Listing Lines on the Results Graphs<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To list the x and y values of a line displayed on a graph, with the graph results viewer open and the required graph displayed, select from the graph results viewer window menubar the <u>View / List Line(s)</u></font></font></font> menu option. This will open a scrollable text window that displays the x and y values for the current graph line and position.<br>
<br>
The currently displayed line or position can be changed by selecting from the line list menu bar the required graph and/or the required position.<br>
<br>
If no data exists for the selected graph line or position this is indicated on the display.<br>
<br>
The displayed list can be <font face="Times New Roman"><font face="Arial">cut</font></font><font face="Times New Roman"><font face="Arial"> and </font></font><font face="Times New Roman"><font face="Arial">pasted</font></font><font face="Times New Roman"><font face="Arial"> using the right mouse button functionality.<br>
<br>
This window must be </font></font><font face="Times New Roman"><font face="Arial">closed</font></font><font face="Times New Roman"><font face="Arial"> before you can return to the main application. <br>
<br>
{button ,AL(`list8',0,&quot;&quot;,`main')} <u>Related Topics</u></font></font><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Using Overlay on Results Graphs<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">The default display method for a graph display with multiple y-axis, is that each will have its own separate graph within the viewer. These can be overlayed such that they share a common single graph.<br>
<br>
To switch between </font></font></font><font face="Times New Roman"><font face="Arial">separate</font></font><font face="Times New Roman"><font face="Arial"> and </font></font><font face="Times New Roman"><font face="Arial">overlay</font></font><font face="Times New Roman"><font face="Arial"> modes use the <i>Overlay </i></font></font>switch on the <u>Specify Graph</u> dialogue box. <br>
<br>
{button ,AL(`list8',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Printing Results Graphs<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To print the displayed graphs, with graph results viewer open and the required graphs displayed, select the <u>View / Print Graph</u></font></font></font> option from the graph viewer window menubar.<br>
<br>
The standard Windows print dialogue boxes are then employed to perform the printing task. <br>
<br>
{button ,AL(`list8',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Results 3D Viewer<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial"><b>Overview<br>
</b></font></font></font><br>
The <i>Results 3D Viewer</i> provides a 3d visualisation tool that animates the results of a vehicle simulation. It is primarily intended for track simulations, but will also animate any of the other simulation types.<br>
<br>
The 3d view of the track from the drivers perspective, animates the vehicles progress around the track, with <font face="Times New Roman"><font face="Arial">head-up</font></font><font face="Times New Roman"><font face="Arial"> type displays showing vehicle accelerations, vehicle speed and the current position of the vehicle on the circuit. Engine speed is also displayed in a similar manner, as can the current gear.<br>
</font></font><br>
The user can <font face="Times New Roman"><font face="Arial">stop</font></font><font face="Times New Roman"><font face="Arial">, </font></font><font face="Times New Roman"><font face="Arial">play</font></font><font face="Times New Roman"><font face="Arial">, </font></font><font face="Times New Roman"><font face="Arial">scan</font></font><font face="Times New Roman"><font face="Arial">, </font></font><font face="Times New Roman"><font face="Arial">ffwd</font></font><font face="Times New Roman"><font face="Arial"> and </font></font><font face="Times New Roman"><font face="Arial">step</font></font><font face="Times New Roman"><font face="Arial"> the animation through the simulation sequence to view the results at the required time and pace. <br>
<br>
A facility exists to copy the contents of the display to the clipboard, and hence available for inclusion as an image in to many </font></font><font face="Times New Roman"><font face="Arial">standard</font></font><font face="Times New Roman"><font face="Arial"> windows packages.<br>
<br>
{button ,AL(`list15',0,&quot;&quot;,`main')} <u>Related Topics</u></font></font><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Opening the Results 3D Viewer <br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To open the results 3d viewer, select the menu item <u>Results</u></font></font></font><i> / </i><u>3d Viewer</u> from the main menubar. Alternatively the <u>Results 3d Viewer Icon</u> can be selected from either the top toolbar or the side panel, depending on the data module set-up. <br>
<br>
When the viewer is open the icon remains indented and the pull down menu item is <font face="Times New Roman"><font face="Arial">ticked</font></font><font face="Times New Roman"><font face="Arial">. <br>
<br>
On initially opening the viewer no picture is displayed unless data has already been loaded into the results graph viewer. <br>
</font></font><br>
The results graph viewer and the 3d viewer share the same results files, thus any file loaded via one of them is automatically available to the other.<br>
<br>
To load additonal results file into the display, see <u>Loading a 3d graphical results file</u> and <u>Loading the current 3d graphical results file</u>.<br>
<br>
The current results files are identified in the <u>Cross plot status</u> dialog box. The 3D viewer can only display one results file at a time, the particular <u>position</u> being displayed is indicated at the lower left of the 3d viewer screen. The results file position used for the 3d viewer is controlled by the cross plot status dialog box, the displayed file being the first one in the list (1 - 5 ), which is both <font face="Times New Roman"><font face="Arial">on</font></font><font face="Times New Roman"><font face="Arial"> and has data associated with it. <br>
</font></font><br>
{button ,AL(`list15',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Closing the Results 3D Viewer <br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To close the results graph viewer select either the menu item <u>Results</u></font></font></font> / <u>3D viewer</u> from the main menubar, the <font face="Times New Roman"><font face="Arial">close</font></font><font face="Times New Roman"><font face="Arial"> icon at the top right corner of the viewer, the 3d viewer window menu at the top left or alternatively the <u>Results 3D Viewer Icon</u></font></font> can be un-selected from either the top toolbar or the side panel, depending on the data module set-up. <br>
<br>
Closing the results 3d viewer does not lose the display contents or setting. Upon re-opening the 3d viewer the original display and set-up is retained, although the time step displayed will have been re-set to zero. <br>
<br>
{button ,AL(`list15',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Loading a 3D Graphical Results File <br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To load a 3d graphical results file into the results 3d viewer, with the 3d viewer open select from the 3d viewer menubar either, <u>File / Load Results (exclusive)</u></font></font></font>, <u>File / Load Results (shuffle)</u>, or <u>File / Load Results (position 1 -5)</u>. (note that results can also be loaded in as <font face="Times New Roman"><font face="Arial">current</font></font><font face="Times New Roman"><font face="Arial"> when appropriate, or through the <u><i>Cross Plot Status</i></u></font></font><i></i> window).<br>
<br>
All three menu options will then proceed to display the standard file browser through which the required file may be selected, however depending on which load menu item was chosen the files data will be loaded into a different <font face="Times New Roman"><font face="Arial">cross plot</font></font><font face="Times New Roman"><font face="Arial"> position.<br>
</font></font><br>
Up to five results file can be held by the 3d viewer at any one time, and they are stored in positions 1 to 5.<br>
<br>
<font face="Times New Roman"><font face="Arial"><i>Load Results (exclusive) </i></font></font>will load the selected file into position 1, overwriting any values previously stored in position 1 and removing any data from the other positions 2 to 5.<br>
<br>
<font face="Times New Roman"><font face="Arial"><i>Load Results (shuffle) </i></font></font>will load the selected file into position 1, shuffling down one position any files currently held in positions 1 to 4. Any data held in position 5 is lost by this shuffling process.<br>
<br>
<font face="Times New Roman"><font face="Arial"><i>Load Results (position) </i></font></font>will load the selected file into the chosen position, overwriting any values currently held in that position. All other positions remain unaltered.<br>
<br>
Note; this is functionally identical to loading results for the graphical results viewer, and since both share common data, loading it a file via the 3D viewer will automatically make it available for both the 3d viewer and the results graph viewer.<br>
<br>
{button ,AL(`list15',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Loading the Current 3D Graphical Results File <br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To load the current 3d graphical results file into the results 3d viewer, with the 3d viewer open select from the 3d viewer menubar either, <u>File / Load Current (exclusive)</u></font></font></font>, <u>File / Load Current (shuffle)</u>, or <u>File / Load Current (position 1 -5)</u>. If these menu options are <font face="Times New Roman"><font face="Arial">greyed</font></font><font face="Times New Roman"><font face="Arial"> out it means that no solution has been run since the application was opened.<br>
<br>
All three menu options will then proceed to load the current graphical results file data, however depending on which <i>load current</i></font></font> menu item was chosen the files data will be loaded into a different <font face="Times New Roman"><font face="Arial">cross plot</font></font><font face="Times New Roman"><font face="Arial"> position.<br>
</font></font><br>
Up to five results file can be held by the 3d viewer at any one time, and they are stored in positions 1 to 5.<br>
<br>
<font face="Times New Roman"><font face="Arial"><i>Load Current (exclusive) </i></font></font>will load the current file into position 1, overwriting any values previously stored in position 1 and removing any data from the other positions 2 to 5.<br>
<br>
<font face="Times New Roman"><font face="Arial"><i>Load Current (shuffle) </i></font></font>will load the current file into position 1, shuffling down one position any files currently held in positions 1 to 4. Any data held in position 5 is lost by this shuffling process.<br>
<br>
<font face="Times New Roman"><font face="Arial"><i>Load Current (position) </i></font></font>will load the current file into the chosen position, overwriting any values currently held in that position. All other positions remain unaltered.<br>
<br>
Note; this is functionally identical to loading results for the graphical results viewer, and since both share common data, loading it a file via the 3D viewer will automatically make it available for both the 3d viewer and the results graph viewer.<br>
<br>
{button ,AL(`list15',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Setting 3D Viewer Visibility</font></b><font face="Times New Roman"><b><font face="Arial">s <br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">Individual items within the 3d viewer can be switched on and off to both clarify the display and in some cases speed up the animation sequence.<br>
<br>
The individual items are listed under the <u>Visibility</u></font></font></font> menu option in the 3d viewer menubar. The particular items are;<br>
<br>
<b>Time</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Controls the display of the solution run time /lap time numerical display.<br>
<b>Distance</b> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Controls the display of the solution distance numerical display.<br>
<b>Vehicle Speed</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Controls the display of the vehicle speed dial on the <font face="Times New Roman"><font face="Arial">head-up</font></font><font face="Times New Roman"><font face="Arial"> display.<br>
</font></font><b>Engine RPM</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Controls the display of the engine speed dial on the <font face="Times New Roman"><font face="Arial">head-up</font></font><font face="Times New Roman"><font face="Arial"> display.<br>
<b>Gear No.</b></font></font>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Controls the display of the current gear graphic.<br>
<font face="Times New Roman"><b><font face="Arial">G</font></b></font><font face="Times New Roman"><b><font face="Arial"> Circle</font></b></font>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Controls the display of the display of the vehicle lateral and longitudinal acceleration diagram, shown as a <font face="Times New Roman"><font face="Arial">g</font></font><font face="Times New Roman"><font face="Arial"> circle.<br>
<b>Circuit Map/ Speed</b></font></font> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Controls the display of the circuit map for track runs or the vehicle speed profile for other runs.<br>
<b>Kerbs</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Controls the visibility of the red/white corner kerbs, switching <font face="Times New Roman"><font face="Arial">off</font></font><font face="Times New Roman"><font face="Arial"> can improve the animation speed on slower machines. <br>
<b>Centre Dashes&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b></font></font>Controls the visibility of the yellow track centre dashes, again switching <font face="Times New Roman"><font face="Arial">off</font></font><font face="Times New Roman"><font face="Arial"> can improve animation speeds.<br>
<b>Corner Boards</b></font></font>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
For track simulations the visibility of the 100m and 50m corner board graphics can be controlled.<br>
<br>
The visibility settings are retained when the 3d viewer is closed. They are also on a normal exit, <br>
saved to the .INI file such that the settings will be the same the next time the application is run. <br>
<br>
{button ,AL(`list15',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Controlling the 3D Animation<br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">The animation sequence within the 3d viewer is controlled by the five </font></font></font><font face="Times New Roman"><font face="Arial">video</font></font><font face="Times New Roman"><font face="Arial"> style buttons, that allow the user to </font></font><font face="Times New Roman"><font face="Arial">play</font></font><font face="Times New Roman"><font face="Arial"> the animation sequence at normal speed, to </font></font><font face="Times New Roman"><font face="Arial">scan</font></font><font face="Times New Roman"><font face="Arial"> through the sequence at x3 speed and also to </font></font><font face="Times New Roman"><font face="Arial">fast forward</font></font><font face="Times New Roman"><font face="Arial"> at x7 speed. Selecting the </font></font><font face="Times New Roman"><font face="Arial">still</font></font><font face="Times New Roman"><font face="Arial"> button will stop the animation sequence, which will then activate the </font></font><font face="Times New Roman"><font face="Arial">step</font></font><font face="Times New Roman"><font face="Arial"> button such that the user can view the sequence one frame at a time.<br>
</font></font><br>
If any menu options or icons are selected outside of the 3d viewer the animation sequence will stop at the current position. The <font face="Times New Roman"><font face="Arial">play</font></font><font face="Times New Roman"><font face="Arial"> button would then need to be re-pressed to continue the animation sequence. Note this also applies to resizing the 3d viewer.<br>
<br>
To restart the animation sequence from the start either close and re-open the 3d viewer then select </font></font><font face="Times New Roman"><font face="Arial">play</font></font><font face="Times New Roman"><font face="Arial"> in the normal way, or re-select the results file from the cross plot status dialog box. <br>
</font></font><br>
The smoothness of the animation display can be improved by avoiding the use of single large angle track sections. For example instead of using a single track section to define a 180 degree constant radius turn break it up into four or six sections. This then allows the 3d viewer the opportunity when drawing ahead the chance to draw a reduced amount of superfluous track.<br>
<br>
{button ,AL(`list15',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Setting the 3D View<br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">Some of the properties of the 3d view can be manipulated by the user, these are accessed via the <u>View / Settings</u></font></font></font> menu option from the 3d viewer menubar. The dialog box contains six sliders that each control a view function.<br>
<br>
The individual view functions are listed below<br>
<br>
<b>Draw ahead distance&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>This sets the track distance in front of the current position for which the track sections are drawn. <b><br>
Look ahead distance&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>This defines the distance in front of the current position of the point at which the driver looks.<b><br>
</b>Zoom factor&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
This defines a zoom value, which together with view radius control the feeling of height and distance <b><br>
Horizon angle&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>This controls the vertical horizon angle, such that the driver looks up / down.<b><br>
Interrupt frequency&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>This sets the frequency at which the animation sequence is interrupted to check for any menu or widget presses. The greater the setting the smoother the animation but the slower the response to any menu selections.<b><br>
</b>View radius &nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Together with zoom factor this controls the feeling of height and distance.<br>
<br>
The view settings are retained when the 3d viewer is closed. They are also on a normal exit, <br>
saved to the .INI file such that the settings will be the same the next time the application is run. <br>
<br>
To reset the view settings to the default values select the <u>View / Reset</u> menu option from the 3d viewer menubar.<br>
<br>
{button ,AL(`list15',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Copying the 3D Display to the Clipboard <br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To copy the displayed picture from the 3d viewer to the clipboard select the <u>View / Copy to Clipboard</u></font></font></font> menu option from the 3d viewer menubar. The image can then be pasted from the clipboard into a number of proprietary windows applications, e.g. Powerpoint.<br>
<br>
{button ,AL(`list15',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Set-up - Display Modules<br>
</font></b><font size="2"><br>
Overview</font><font face="Times New Roman"><br>
<br>
<font face="Arial">The icon toolbars on the main window can be arranged to suit the current module of interest, from either Data, Solve or Results. Changing the current displayed module will move the relevant small icons from along the top of the main window and display them in large icon buttons down the left hand side of the main screen. <br>
<br>
Changing the display module is purely a convenience function, it does not change the menu items available, nor is it necessary to do so to be able to proceed from data entry to solving. <br>
</font></font><br>
<b>Setting the Display Module Icons<br>
<br>
</b>To change the display module select the menu item <u>Setup</u> /<u> Module</u><b> </b>from the main window and chose either <u>Data,</u> <u>Solve</u> or <u>Results</u> as required. The current selection being identified by the tick.<br>
<br>
<b>Saving the Display Module<br>
<br>
</b>On a normal exit from Lotus Vehicle Simulation the display module setting is saved in the Lotus Vehicle Simulation.ini file, such that on application start-up this setting will be restored.<font face="Times New Roman"><br>
<p><hr><p>
<sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Set-up - Data Entry Window Mode<br>
</font></b></font><font size="2"><br>
Window Modes</font><font face="Times New Roman"><br>
<br>
<font face="Arial">The data entry windows can be displayed singularly, such that opening a data window will close any other currently open data window, only one being displayed at a time. The <i>single</i></font></font> window mode is is the default setting. (note that this does not include solve and results windows). Alternatively the <i>multi</i> window mode may be employed, where any number of the data entry windows can be open together.<br>
<br>
<b>Setting the Window Mode<br>
<br>
</b>To change from single window mode to multi window mode select the menu item <u>Setup</u> /<u> Window</u><b> </b>from the main window and chose either <u>Multi</u> or <u>Single</u> as required. The current selection being identified by the tick.<br>
<br>
<b>Saving the Window Mode<br>
<br>
</b>On a normal exit from Lotus Vehicle Simulation the window mode setting is saved in the Lotus Vehicle Simulation.ini file, such that on application start-up this setting will be restored.<br>
<p><hr><p>
<sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Set-up - Input Data Graphs<br>
</font></b><font size="2"><br>
Input data Graphs<br>
</font><br>
The properties and appearance of the input data graphs can be set by the user through the <font face="Times New Roman"><font face="Arial">set-up</font></font><font face="Times New Roman"><font face="Arial"> option. To open the </font></font><font face="Times New Roman"><font face="Arial">set-up</font></font><font face="Times New Roman"><font face="Arial"> dialog box select the </font></font><font face="Times New Roman"><font face="Arial">set-up</font></font><font face="Times New Roman"><font face="Arial"> option from the pull down menu at the top left hand corner of the data graph, or use the shortcut key command Ctrl+S.<br>
<br>
The user can control text, text colour, text font, text width, axes scales, axis fit, decimal points, line colours, line types, symbol types, symbol colours and visibility settings. Each individual item is discussed below by panel.<br>
</font></font><br>
Panel 1 - <font face="Times New Roman"><font face="Arial">Plot text</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>Title</b></font></font>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the text used for the graph title.<br>
<b>X-Label&nbsp;
</b>Defines the text used for the x-axis.<br>
<b>Y-Label</b>&nbsp;
Defines the text used for the y-axis.<br>
<b>Font</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the individual text label font types.<br>
<b>Colour&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the individual text label colours.<br>
<b>Width</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line width/weight to be used for text and axis lines on screen.<br>
<b>h/c Width</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line width/weight to be used for text and axis lines on hard copy.<br>
<b>Grid Vis</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the visibility of the graph's grid. Check this box to make visible.<br>
<b>Grid Fill</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the colour used to fill the background of the graph plotting region.<br>
<br>
Panel 2 - <font face="Times New Roman"><font face="Arial">Plot axes</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>X-axis&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b></font></font>Identify values as being for the x-axis.<br>
<b>Y-axis</b>&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Identify values as being for the y-axis.<br>
<b>Minimum</b> Sets the minimum value for the axis.<br>
<b>Maximum</b>&nbsp;
Sets the maximum value for the axis.<br>
<b>Increments</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the number of increments on the axis.<br>
<b>Decimal Pls&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the number of decimal places to be used on the axis and listing.<br>
<b>Fit&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Forces the axes to use the defined min, max and increments exactly.<br>
<br>
Panel 3 - <font face="Times New Roman"><font face="Arial">Plot lines</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>Label</b></font></font>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines a line label, (currently not used).<br>
<b>Line</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Identify values as being for the line.<br>
<b>Symbol</b>&nbsp;&nbsp;
Identify values as being for the symbol.<br>
<b>Colour&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the colour for the line or symbol.<br>
<b>Type</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line type or symbol type.<br>
<b>Visibility&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Switches the line or symbol visibility.<b><br>
Width</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line width/weight to be used for lines and symbols on screen.<br>
<b>h/c Width</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line width/weight to be used for lines and symbols on hard copy.<br>
<br>
The <u>graph icon</u> is provided to enable the graph to be redrawn/updated without the requirement to close the set-up dialog box down.<br>
<br>
Each data graph has its own set-up thus changing a setting in one does not affect any other data graphs.<br>
<br>
The input data graph settings are saved in the Lotus Vehicle Simulation.ini file, such that on application start-up these settings will be restored.<br>
<p><hr><p>
<sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Set-up - Results Graphs<br>
</font></b><font size="2"><br>
Results Graph<br>
</font><br>
The properties and appearance of the results graphs can be set by the user through the <font face="Times New Roman"><font face="Arial">set-up</font></font><font face="Times New Roman"><font face="Arial"> option. To open the </font></font><font face="Times New Roman"><font face="Arial">set-up</font></font><font face="Times New Roman"><font face="Arial"> dialog box select the </font></font><font face="Times New Roman"><font face="Arial">set-up</font></font><font face="Times New Roman"><font face="Arial"> option from the pull down menu at the top left hand corner of the results graph, or use the shortcut key command Ctrl+S.<br>
<br>
The user can control text, text colour, text font, text width, line colours, line types, symbol types, symbol colours and visibility settings. Each individual item is discussed below by panel.<br>
</font></font><br>
Panel 1 - <font face="Times New Roman"><font face="Arial">Plot text</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>Title</b></font></font>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Identify values as being for the graph title.<br>
<b>X-Axis&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Identify values as being for the x-axis.<br>
<b>Y-Axis</b>&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Identify values as being for the current y-axis.<br>
<b>Text&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the individual text labels.<br>
<b>Font</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the individual text label font types.<br>
<b>Colour&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the individual text label colours.<br>
<b>X-org&nbsp;&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the plot x position for the lower left corner, (frame is 0.0 to 1.0).<br>
<b>Y-org&nbsp;&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the plot y position for the lower left corner, (frame is 0.0 to 1.0).<br>
<b>X-size&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the plot x size for the current plot, (frame is 0.0 to 1.0).<br>
<b>Y-size&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the plot y size for the current plot, (frame is 0.0 to 1.0).<br>
<b>X-leg&nbsp;&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the legend lower left x position relative to its x-org.<br>
<b>Y-leg&nbsp;&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the legend lower left y position relative to its y-org.<br>
<b>Legend vis</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the visibility of the plots legend box.<br>
<b>Legend size</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the unit size of the current plots legend box.<br>
<b>Width</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line width/weight to be used for text and axis lines on screen.<br>
<b>h/c Width</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line width/weight to be used for text and axis lines on hard copy.<br>
<b>Auto pos</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Controls the user positioning/ auto positioning of the graphs.<br>
<b>Text Scale</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines a height scaling factor for plot labels, title and annotation.<br>
<b>Symbol Scale</b>&nbsp;&nbsp;&nbsp;&nbsp;
Defines a scaling factor for symbols plot size.<br>
<b>Grid Vis</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the visibility of the graph's grid. Check this box to make visible.<br>
<b>Grid Fill</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the colour used to fill the background of the graph plotting region.<br>
<br>
Panel 2 - <font face="Times New Roman"><font face="Arial">Plot lines</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>Y1</b></font></font>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Identify values as being for the y1-line.<br>
<b>Y2</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Identify values as being for the y2-line.<br>
<b>Y3</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Identify values as being for the y3-line.<br>
<b>Y4</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Identify values as being for the y4-line.<br>
<b>Label&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Defines the <u>position</u> label used on the legends<br>
<b>Line Colour&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the colour for the lines.<br>
<b>Line Type</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line types.<br>
<b>Vis&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Switches the line visibility.<b><br>
Line Colour&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the colour for the lines.<br>
<b>Line Type</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line types.<br>
<b>Vis&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Switches the symbol visibility.<b><br>
Width</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line width/weight to be used for lines and symbols on screen.<br>
<b>h/c Width</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line width/weight to be used for lines and symbols on hard copy.<br>
<b>Symbol limit&nbsp;&nbsp;&nbsp;&nbsp;
</b>Switches on the clipping limit for the maximum number of symbols to be plotted for a single line, (limit = 20).<br>
<br>
The <u>graph icon</u> is provided to enable the graph to be redrawn/updated without the requirement to close the set-up dialog box down.<br>
<br>
Each <font face="Times New Roman"><u><font face="Arial"><u>position</u></font></u></font><font face="Times New Roman"><u></u></font><font face="Arial"> has its own distinct set of properties for its lines. Thus changing a setting for one position does not affect any other data position. <br>
<p><hr><p>
<sup>$</sup><sup>#</sup><sup>&gt;</sup></font><b><font size="4">Set-up - Engine Performance Input Data Graph<br>
</font></b><font size="2"><br>
Input data Graph - Engine Performance<br>
</font><br>
The properties and appearance of the engine performance input data graph can be set by the user through the <font face="Times New Roman"><font face="Arial">set-up</font></font><font face="Times New Roman"><font face="Arial"> option. To open the </font></font><font face="Times New Roman"><font face="Arial">set-up</font></font><font face="Times New Roman"><font face="Arial"> dialog box select the </font></font><font face="Times New Roman"><font face="Arial">set-up</font></font><font face="Times New Roman"><font face="Arial"> option from the pull down menu at the top left hand corner of the data graph, or use the shortcut key command Ctrl+S.<br>
<br>
The user can control text, text colour, text font, text width, axes scales, axis fit, decimal points, line colours, line types, symbol types, symbol colours and visibility settings. Each individual item is discussed below by panel.<br>
</font></font><br>
Panel 1 - <font face="Times New Roman"><font face="Arial">Plot text</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>Title</b></font></font>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the text used for the graph title.<br>
<b>X-Label&nbsp;
</b>Defines the text used for the x-axis.<br>
<b>Font</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the individual text label font types.<br>
<b>Colour&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the individual text label colours.<br>
<b>Width</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line width/weight to be used for text and axis lines on screen.<br>
<b>h/c Width</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line width/weight to be used for text and axis lines on hard copy.<br>
<b>Grid Vis</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the visibility of the graph's grid. Check this box to make visible.<br>
<b>Grid Fill</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the colour used to fill the background of the graph plotting region.<br>
<br>
Panel 2 - <font face="Times New Roman"><font face="Arial">X axes</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>Minimum</b></font></font> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the minimum value for the x-axis.<br>
<b>Maximum</b>&nbsp;
Sets the maximum value for the x-axis.<br>
<b>Increments</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the number of increments on the x-axis.<br>
<b>Decimal Pls&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the number of decimal places to be used on the x-axis and listing.<br>
<b>Fit&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Forces the x-axes to use the defined min, max and increments exactly.<br>
<br>
Panel 3 - <font face="Times New Roman"><font face="Arial">Y axes</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>Visibility</b></font></font>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the visibility of the current y-axis. Three y-axis are used to display 1=BMEP, 2=Torque and 3=Power. The left and right arrow buttons move between them, their specific details being displayed in this panel.<br>
<b>Label</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the y-axis label of the current y-axis.<br>
<b>Font</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the y-axis label font type for the current y-axis.<br>
<b>Colour&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the y-axis label colour for the current y-axis.<br>
<b>Minimum</b> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the minimum value for the y-axis of the current y-axis.<br>
<b>Maximum</b>&nbsp;
Sets the maximum value for the y-axis of the current y-axis.<br>
<b>Increments</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the number of increments on the y-axis of the current y-axis.<br>
<b>Decimal Pls&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the number of decimal places to be used on the y-axis and listing of the current y-axis.<br>
<b>Fit&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Forces the y-axes to use the defined min, max and increments exactly for the current y-axis.<br>
<b>Position&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Defines by origin, length side and units the settings of the current y-axis.<br>
<b>Origin</b>&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the start position of the current y-axis origin. This value should be between 0 and 1 where 0 is the origin of the plottable region and 1 is the top of this region. The defined axes minimum value will be positioned here.<br>
<b>Length</b>&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the length of the current y-axis origin. This value should be between 0 and 1. Where 1 is the total length of the plottable region. This is added to the origin position to define the upper point of the current y-axis. The defined axes maximum value will be positioned here.<br>
<b>Side</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the current y-axis as being positioned to the left or the right of the plottable region.<br>
<b>Units</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the displayed units for the current y-axis. For BMEP select from; bar, psi or mPa. For Torque select from; Nm, lbft or kgm. For Power select from; kw, hp or Ps.<br>
<b>Line</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Identify values as being for the line.<br>
<b>Symbol</b>&nbsp;&nbsp;
Identify values as being for the symbol.<br>
<b>Colour&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the colour for the line or symbol.<br>
<b>Type</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line type or symbol type.<br>
<b>Visibility&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Switches the line or symbol visibility.<b><br>
Width</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line width/weight to be used for lines and symbols on screen.<br>
<b>h/c Width</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line width/weight to be used for lines and symbols on hard copy.<br>
<br>
The <u>graph icon</u> is provided to enable the graph to be redrawn/updated without the requirement to close the set-up dialog box down.<br>
<br>
The engine performance data graph settings are saved in the Lotus Vehicle Simulation.ini file, such that on application start-up these settings will be restored.<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Solve Module<br>
</font></b><font size="2">Overview<br>
</font><font face="Times New Roman"><br>
<font face="Arial">The solve module controls which particular calculation run is performed from the available options. The user can specify a steady speed test, an acceleration test, an emissions test and a track test, with sub-options available with each. Sub solution options included setting the required shift map, identifying the particular emissions cycle or selecting the target acceleration.<br>
<br>
Prior to running a calculation the validity of the current data is checked by automatically invoking the<u> data checking wizard</u></font></font>, any errors, warnings or comments are reported.<br>
<br>
During the calculation either a simple progress bar is displayed or the <u>calculation telemetry screen</u> can be used to graphically show, engine speed, gear, vehicle speed, the test cycle and the engine load map via animation, as they vary throughout the cycle run.<br>
<br>
When Lotus Vehicle Simulation calculations are performed a number of results files are created, the extensions identifying the type of results file. i.e. :<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Text results files have the form &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
*_n.crs<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Graphical results files have the form&nbsp;&nbsp;&nbsp;
*_n.grs<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Grid text results files have the form&nbsp;&nbsp;&nbsp;
*_n.grd<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Where; n is the <i>Plot File Counter</i> number which is incremented for each calculation, and the <font face="Times New Roman"><font face="Arial">*</font></font><font face="Times New Roman"><font face="Arial"> is the <i>Test No.</i></font></font> string supplied by the user, both are displayed in the vehicle data window.<br>
<br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Solution Run Types<br>
</font></b></font><font size="2">Overview<br>
</font><br>
Lotus Vehicle Simulation can perform a number of different calculation types, the user identifies through the <u><i>Calculation Set-up</i></u><i></i> dialogue box the required calculation. <br>
<br>
Each basic calculation types can have a number of sub-options, some of which require additional solution values to be set. A list is given below of each calculation option and their sub-options.<br>
<br>
1) <u>Steady Speed</u><br>
i) User Defined Gear and Speed<br>
Set Speed Units<br>
Set Speed Value<br>
Set Gear No.<br>
ii) User Defined Shift Map and Speed<br>
Set Speed Units<br>
Set Speed Value<br>
Set Shift Schedule<br>
<br>
2) <u>Acceleration</u><br>
i) Standing Start<br>
Set Launch Type<br>
Set Shift Schedule<br>
ii) In Gear<br>
Set Gear No.<br>
iii) User Defined<br>
Set Speed Units<br>
Set Start Speed Value<br>
Set End Speed Value<br>
Set Shift Schedule<br>
<br>
3) <u>Emissions Cycle</u><br>
i) U.S.A - Federal FTP75 Drive Cycle<br>
Shift Schedule<br>
ii) U.S.A - Federal Highway Cycle<br>
Shift Schedule<br>
iii) U.S.A - Federal FTP06 Drive Cycle<br>
Shift Schedule<br>
iv) Europe - EURO <br>
Normal Power or Under powered<br>
Shift Schedule<br>
v) Europe - EUDC<br>
Normal Power or Under powered<br>
Shift Schedule<br>
vi) Europe - EURO + EUDC <br>
Normal Power or Under powered<br>
Shift Schedule<br>
vii) Japan - Japanese 15 Mode<br>
Shift Schedule<br>
viii) User Defined<br>
Shift Schedule<br>
<br>
4) <u>Track Simulation</u><br>
i) Simple Oval<br>
Shift Schedule<br>
ii) Lotus Test Track<br>
Shift Schedule<br>
iii) Snetterton Race Circuit, Norfolk<br>
Shift Schedule<br>
iv) User Defined <br>
Shift Schedule<br>
<br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Solution Run Types - Steady Speed<br>
</font></b><font size="2"><br>
</font>Steady Speed<br>
i) User Defined Gear and Speed<br>
Set Speed Units<br>
Set Speed Value<br>
Set Gear No.<br>
ii) User Defined Shift Map and Speed<br>
Set Speed Units<br>
Set Speed Value<br>
Set Shift Schedule<br>
<br>
The steady speed run type performs the calculations at a user defined speed with either a user defined gear No. or a user defined shift schedule.<br>
<br>
The available gears and shift schedules are as defined by the Gearbox and Transmissions data windows.<br>
<br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Solution Run Types - Acceleration<br>
</font></b></font><font size="2"><br>
</font>Acceleration<br>
i) Standing Start<br>
Set Launch Type<br>
Set Shift Schedule<br>
ii) In Gear<br>
Set Gear No.<br>
iii) User Defined<br>
Set Speed Units<br>
Set Start Speed Value<br>
Set End Speed Value<br>
Set Shift Schedule<br>
<br>
The acceleration run type performs the calculations for one of three acceleration events.<br>
<br>
The first is a standing start acceleration that can use either a slip /start or an idle start, this effects the launch characteristics. The user needs to define the shift schedule as being either the <u>default shift map</u> or as one of the currently user defined shift schedules.<br>
<br>
The second is an in gear acceleration run for which the user defines the required gear. The acceleration is then performed from <i>idle speed</i> through to <i>maximum engine speed</i>, as defined in the engine data window.<br>
<br>
The third class of acceleration run type is a user defined acceleration between two velocity values. The user, as for standing start accelerations, needs to define the shift schedule as being either the <u>default shift map</u> or as one of the currently user defined shift schedules.<br>
<br>
The available gears and shift schedules are as defined by the Gearbox and Transmissions data windows.<br>
<br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Solution Run Types - Emissions Cycle<br>
</font></b><font size="2"><br>
</font>Emissions Cycle<br>
i) U.S.A - Federal FTP75 Drive Cycle<br>
Shift Schedule<br>
ii) U.S.A - Federal Highway Cycle<br>
Shift Schedule<br>
iii) U.S.A - Federal FTP06 Drive Cycle<br>
Shift Schedule<br>
iv) Europe - EURO <br>
Normal Power or Under powered<br>
Shift Schedule<br>
v) Europe - EUDC<br>
Normal Power or Under powered<br>
Shift Schedule<br>
vi) Europe - EURO + EUDC <br>
Normal Power or Under powered<br>
Shift Schedule<br>
vii) Japan - Japanese 15 Mode<br>
Shift Schedule<br>
viii) User Defined<br>
Shift Schedule<br>
<br>
Seven standard emissions cycles can be selected from U.S.A, Europe or Japan. These cycles contain the time, speed and gear information that defines the cycle. Similar information can be defined and used for a user specified cycle. These can be created using the Lotus Vehicle Simulation <u>cycle builder toolCYCLE_BUILD_OVER</u>.<br>
<br>
The user needs to define the shift schedule as being either the <u>default shift map</u> or as one of the currently user defined shift schedules.<br>
<br>
The available shift schedules are as defined by the Gearbox and Transmissions data windows.<br>
<br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Solution Run Types - Track Simulation<br>
</font></b><font size="2"><br>
</font>Track Simulation<br>
i) Simple Oval<br>
Shift Schedule<br>
ii) Lotus Test Track<br>
Shift Schedule<br>
iii) Snetterton Race Circuit, Norfolk<br>
Shift Schedule<br>
iv) User Defined <br>
Shift Schedule<br>
<br>
By default three standard tracks are given as examples of how to construct a track simulation. These simulations are defined by a series of individual track segments the dimensions and speed restriction, (if any), being specified for each segment. Similar information can be defined and used for a user specified track. These can be created using the Lotus Vehicle Simulation <u>track builder tool</u>.<br>
<br>
The user needs to define the shift schedule as being either the <u>default shift map</u> or as one of the currently user defined shift schedules.<br>
<br>
The available shift schedules are as defined by the Gearbox and Transmissions data windows.<br>
<br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>#</sup></font><font face="Arial"><b>Default Shift Map<br>
</b></font>The default shift map is purely based on engine rpm and tractive effort, in that gear shift points are based on either the rpm limits of the engine, or the ability of a particular gear to give the greatest acceleration level. On emissions cycles the default shift map implies the gear values as identified by the cycle specification.<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Opening the Calculation Set-up Screen<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To open the calculation set-up dialogue box, select the menu item <u>Solve</u></font></font></font><i> / </i><u>Setup</u> from the main menubar. Alternatively the <u>Solve Setup Icon</u> can be selected from either the top toolbar or the side panel, depending on the data module set-up. In addition the <font face="Times New Roman"><font face="Arial">F9</font></font><font face="Times New Roman"><font face="Arial"> function key can be used as a shortcut to open this screen<br>
<br>
When the calculation screen is open the icon remains indented and the pull down menu item is </font></font><font face="Times New Roman"><font face="Arial">ticked</font></font><font face="Times New Roman"><font face="Arial">.<br>
</font></font><br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Closing the Calculation Set-up Screen</font></b></font><br>
<font face="Times New Roman"><font size="2"><br>
<font face="Arial">To close the calculation set-up dialogue box select either the menu item <u>Solve</u></font></font></font> /<i> </i><u>Setup</u> from the main menubar, the <font face="Times New Roman"><font face="Arial">close</font></font><font face="Times New Roman"><font face="Arial"> icon at the top right corner of the calculation screen, the calculation set-up screen window menu at the top left or alternatively the <u>Solve Set-up Icon</u></font></font> can be un-selected from either the top toolbar or the side panel, depending on the data module set-up. In addition the <font face="Times New Roman"><font face="Arial">F9</font></font><font face="Times New Roman"><font face="Arial"> function key can be used as a shortcut to close this screen.<br>
</font></font><br>
The set-up screen does not actually have to be <font face="Times New Roman"><font face="Arial">open</font></font><font face="Times New Roman"><font face="Arial"> to perform a calculation, since alternative icons and commands can be used to <u>start the calculation run</u></font></font>.<br>
<br>
Closing the calculation set-up screen does not lose any of the settings. Upon re-opening the screen the original options and values are retained. <br>
<br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Setting the Calculation Run Type</font></b></font><br>
<font face="Times New Roman"><font size="2"><br>
<font face="Arial">To define a calculation run type, <u>open the calculation run set-up</u></font></font></font> screen, any current run type settings are displayed in the selection boxes together with any relevant value boxes.<br>
<br>
The selection boxes are arranged such that a run type is defined from the top selection box downwards. Thus the top selection box identifies the run type as being a steady speed run, an acceleration run, an emissions test or a cycle simulation. Selecting the required option from this list clears the current settings and switches of the calculation button, (assuming it was <font face="Times New Roman"><font face="Arial">on</font></font><font face="Times New Roman"><font face="Arial">)<br>
</font></font><br>
Depending on the run type chosen different selection choices are displayed in the second selection box. The user should select the required option from this second box. Again depending on the solution run the user may be required to make further selections or enter values for speeds.<br>
<br>
The user should continue to make selections and enter values until the <u>calculate run icon</u> is displayed in the lower right hand corner of the calculation set-up screen.<br>
<br>
At this stage the lower panel of the calculation set-up window will display, depending on the run type, either the current gear selected or the current shift map selected. Using the two <font face="Times New Roman"><font face="Arial">arrow</font></font><font face="Times New Roman"><font face="Arial"> icons the user can selected the required gear or shift map.<br>
</font></font><br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Checking the Data at Run Time</font></b></font><br>
<font face="Times New Roman"><font size="2"><br>
<font face="Arial">When a calculation is run the <u>Data checking wizard</u></font></font></font> is automatically invoked to check the validity of the current data. It does not open the main data checking wizard window, but merely produces a summary of any the numbers of Errors, Warnings or Comments that it has found in a simple dialogue box. If no data irregularities are identified no message is displayed and the user would be unaware that the data checking wizard had been invoked.<br>
<br>
<u>Three fail types</u> are used by the data checker of varying levels of severity.<br>
<br>
If problems are identified the user can chose to either abort the run, retry or ignore the messages. Whilst it may be perfectly valid to ignore Comments identified, it is unlikely that ignoring Errors will prove acceptable.<br>
<br>
To find out further details about the identified irregularities the user should chose to abort the run and <u>open the data checking wizard</u>. <u><br>
</u><br>
Because of the complexity of the data requirements, the validity of which can vary depending on the run type selected, some warnings and particularly some Comments could be safely ignored if they refer to unrelated data variables, or are simply a data variable that is outside the default limits.<br>
<br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Starting the Calculation<br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To start the calculation select the <u>calculate run icon</u></font></font></font>. If the icon is not visible or is <font face="Times New Roman"><font face="Arial">greyed</font></font><font face="Times New Roman"><font face="Arial"> out then the calculation run set up has not been completed.The icon is displayed in the lower right hand corner of the calculation set-up screen, and also in the top toolbar or the side panel depending on the data module set-up, it also is located at the bottom of the calculation telemetry screen. The calculation can also be started using the menu item <u>Solve</u></font></font> / <u>Calculate</u> from the main menubar or finally with the <font face="Times New Roman"><font face="Arial">F11</font></font><font face="Times New Roman"><font face="Arial"> key.<br>
</font></font><br>
Once the calculation has started either the progress bar will be displayed identifying the solution progress, or if the calculation telemetry screen is open, the progress is identified on this screen via animated dials and graphical display.<br>
<br>
Once started the calculation can only be stopped prior to its completion with the <u>stop icon</u> on the telemetry screen.<br>
<br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">The Calculation Telemetry Screen<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial"><b>Overview<br>
</b></font></font></font><font face="Times New Roman"><br>
<font face="Arial">The calculation telemetry screen provides a graphical display of the calculation run as it proceeds. It displays on x-y graphs the target velocity profile, (or track position), the engine load speed map and via animated dials the engine speed, vehicle speed and current gear.<br>
<br>
The user can control the speed the simulation proceeds at, including stopping the run altogether and </font></font><font face="Times New Roman"><font face="Arial">stepping</font></font><font face="Times New Roman"><font face="Arial"> through each solution time step.<br>
<br>
The calculation run can also be aborted via the telemetry screen.<br>
</font></font><br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Opening the Calculation Telemetry Screen<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To open the calculation telemetry screen, select the menu item <u>Solve</u></font></font></font><i> / </i><u>Display</u> from the main menubar. Alternatively the <u>Solve Display Icon</u> can be selected from either the top toolbar or the side panel, depending on the data module set-up. In addition the <font face="Times New Roman"><font face="Arial">F12</font></font><font face="Times New Roman"><font face="Arial"> function key can be used as a shortcut to open this screen<br>
<br>
When the calculation telemetry screen is open the icon remains indented and the pull down menu item is </font></font><font face="Times New Roman"><font face="Arial">ticked</font></font><font face="Times New Roman"><font face="Arial">.<br>
</font></font><br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Closing the Calculation Telemetry Screen</font></b></font><br>
<font face="Times New Roman"><font size="2"><br>
<font face="Arial">To close the calculation telemetry screen select either the menu item <u>Solve</u></font></font></font> /<i> </i><u>Display</u> from the main menubar, the <font face="Times New Roman"><font face="Arial">close</font></font><font face="Times New Roman"><font face="Arial"> icon at the top right corner of the telemetry screen, the calculation telemetry screen window menu at the top left or alternatively the <u>Solve Display Icon</u></font></font> can be un-selected from either the top toolbar or the side panel, depending on the data module set-up. In addition the <font face="Times New Roman"><font face="Arial">F12</font></font><font face="Times New Roman"><font face="Arial"> function key can be used as a shortcut to close this screen.<br>
</font></font><br>
The calculation telemetry screen does not actually have to be <font face="Times New Roman"><font face="Arial">open</font></font><font face="Times New Roman"><font face="Arial"> to perform a calculation, since alternative icons and commands can be used to <u>start the calculation run</u></font></font>, and the solution runs far quicker without the overhead of drawing the animated displays.<br>
<br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Running the Calculation from the Telemetry Screen</font></b><br>
<font face="Times New Roman"><font size="2"><br>
<font face="Arial">To start the calculation run from the telemetry screen simply select the <u>calculate run icon</u></font></font></font> displayed at the bottom of the telemetry screen. If the icon is not visible or is <font face="Times New Roman"><font face="Arial">greyed</font></font><font face="Times New Roman"><font face="Arial"> out then the calculation run set up has not been completed.<br>
<br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u></font></font><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Aborting the Calculation from the Telemetry Screen</font></b><br>
<font face="Times New Roman"><font size="2"><br>
<font face="Arial">To abort the current calculation run from the telemetry screen simply select the <u>stop icon</u></font></font></font> on the telemetry screen.<br>
<br>
Since the calculation run will not have finished the use of the <font face="Times New Roman"><font face="Arial">load current</font></font><font face="Times New Roman"><font face="Arial"> functionality should be avoided to prevent errors trying to read partial file records.<br>
<br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u></font></font><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Controlling the Calculation Telemetry Display and Speed</font></b><br>
<font face="Times New Roman"><font size="2"><br>
<font face="Arial">The speed at which any calculation proceeds with the telemetry screen open can be controlled via a series of <u>video player style icons</u></font></font></font>, that provide play, scan ffwd, pause and step functions. They are displayed at the bottom of the telemetry screen.<br>
<br>
The step icon is <font face="Times New Roman"><font face="Arial">greyed</font></font><font face="Times New Roman"><font face="Arial"> out until the calculation run is </font></font><font face="Times New Roman"><font face="Arial">paused</font></font><font face="Times New Roman"><font face="Arial">, the user can then proceed to step through the run.<br>
<br>
The two graphs shown on the telemetry screen, one small and one large, can be swapped in position. The default setting is for the large graph to be the velocity time history for speed based runs and the for the large graph to be the track for track simulations, in both cases the small graph is the engine load and speed map. This can be reversed using the <u>display setting icons</u></font></font> that are displayed at the bottom of the telemetry screen.<br>
<br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Copying the Telemetry Screen Display to the Clipboard <br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To copy the displayed picture from the telemetry screen to the clipboard select the <u>View / Copy to Clipboard</u></font></font></font> menu option from the telemetry screen menubar. The image can then be pasted from the clipboard into a number of proprietary windows applications, e.g. Powerpoint.<br>
<br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Parametric Analysis<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial"><b>Overview<br>
</b></font></font></font><font face="Times New Roman"><br>
<br>
<font face="Arial">The parametric analysis option allows the user to rapidly analyses the influence of <u>one, two or three</u></font></font> data variables on a calculated result. The data variables altered can be a single number, such as vehicle weight, a spline , such as engine power or a map, such as a fuel consumption. The range that these variables are analysed over can be defined by value, by shift or by scale. This variation being defined by either, start and end values with a number of increments, or by a list of the variations.<br>
<br>
The results are plotted as a simple x-y plot for the 1D analysis, (i.e 1 variable), for 2D analysis (i.e. 2 variables), as either a contour map or a contoured surface, whilst 3D analysis (i.e. 3 variables), as a series of 2d contour maps.<br>
<br>
The results can be selected from either the <u>'.crs' file</u> variables or the <u>'.grs' file</u> variables. The grs results can further be requested at either the end of the cycle or at some user selected time during the cycle.<br>
<br>
The results options listed in the .crs selection list are controlled by the current solution setting and also by the current input data. The required solution run should be set up before the parametric window is opened.<br>
<br>
{button ,AL(`list18',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Opening the Parametric Analysis Screen<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To open the parametric analysis screen, select the menu item <u>Solve</u></font></font></font><i> / </i><u>Parametric</u> from the main menubar. Alternatively the <u>Parametric Analysis Icon</u> can be selected from either the top toolbar or the side panel, depending on the data module set-up.<br>
<br>
When the parametric analysis screen is open call backs from all other windows are ignored, thus it is important that the required data file is already loaded and the required analysis run type set.<br>
<br>
{button ,AL(`list18',0,&quot;&quot;,`main')} <u>Related Topics</u><font face="Times New Roman"><br>
<font face="Arial"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font></font><b><font size="4">Setting the Number of Parametric Variables<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">Parametric analysis can be performed with either 1,2 or 3 variables. The buttons at the top of parametric analysis screen control labelled as '1D', '2D' and '3D' control the number of analysis variables used. Selecting the required button will set the appropriate entry boxes as either 'on' or 'greyed-out', allowing definition of the data variables.<br>
<br>
This setting is saved on both closing the parametric window and exiting the program.</font></font></font><font face="Times New Roman"><br>
<font face="Arial"><br>
{button ,AL(`list18',0,&quot;&quot;,`main')} <u>Related Topics</u></font></font><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Defining a Parametric Analysis Variable<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">A parametric analysis variable is selected from a pre-defined list that contains over 70 of the major Lotus Vehicle Simulation data file values. This list includes items that are either, single values, (such as wheelbase), splines ( such as engine power), or 2d maps (such as fuel consumption).<br>
<br>
Each parametric variable has its own selection box from which the required variable should be picked. Three buttons then allow each variable to be individually varied by one of three methods, by value, by shift and by scale.<br>
</font></font></font><br>
When a data variable is picked, (or when the parametric window is opened), the variable is checked against the current data to determine whether it is a valid choice. An example of this would be selecting gear ratio 6 when the gear box is defined to have only 5. If any errors are detected a warning is given.<br>
<br>
'By Value', is used to specifically define the variable using actual values, that must be in the units appropriate to that variable. The current value setting for the variable can be found by selecting the <u>question mark icon.</u> By value can only be used on variables that are a single value. If a variable that is a spline or a 2D map is selected the 'by value' button is disabled. The actual values themselves are defined by the 'min' 'max' and 'no of steps' value entries, this would perform the calculations from the 'min' value to the 'max' value with the defined number of equal step sizes between them. As an alternative all the required points can be defined as a list of numbers, by selecting the 'by list' button and entering in the values via the <u>edit icon</u><br>
<br>
'By Shift', is used to define the variable as a series of shifts from its currently defined value. As for 'by value' this can be defined using either the min / max values or the 'by list' option. A negative shift will decrease the current value whilst a positive shift will increase the current value. 'By shift' can be applied to all data variable types.<br>
<br>
'By Scale', is used to define the variable as a series of scaled points from its currently defined value. As for 'by value' this can be defined using either the min / max values or the 'by list' option. A scale value less than one will decrease the variable from the current value whilst a scale value greater than one will increase the variable from current. 'By scale' can be applied to all data variable types.<br>
<br>
All the variable settings are saved on both closing the parametric window and exiting the application.<br>
<br>
{button ,AL(`list18',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Controlling the Parametric Analysis Type<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">Parametric analysis can be carried out over any of the standard Lotus Vehicle Simulation run types. The required analysis type should be defined prior to <u>opening the parametric window</u></font></font></font> since once open all other windows are ignored.<br>
<br>
{button ,AL(`list18',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Defining the Parametric Analysis Result<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">The parametric analysis result can be any relevant calculated result from either the .grs or .crs files. The user should select the required file by checking the appropriate check box, and then select from the list the required result. Up to 10 different results can be defined.<br>
<br>
The contents of the .crs list box will vary depending on both the current data file and the current analysis run type. For any .grs result it can be determined at either the end of the run or at a user defined time during the run, this option is disabled for .crs results.<br>
</font></font></font><br>
To set the number of y results required enter the number into the 'No of Y results' value entry box, the arrow icons can then be used to step through each y-result in turn and set the selections to the required values. Any mix of results is permissible, even down to the same y-result but at different time points through the cycle.<br>
<br>
The arrow icons can also be used to step through the displayed graphical results once an parametric run has been completed.<br>
<br>
{button ,AL(`list18',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Running the Parametric Analysis<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To run the parametric analysis, with the parametric window open select either the <u>Solve</u></font></font></font> / <u>Update</u> menu item or the <u>calculate icon.</u><br>
<u><br>
</u>As the analysis proceeds a twin progress bar window is displayed that shows the percentage completed of the current solution step and of the whole parametric analysis run.<br>
<br>
The analysis can be stopped at any time by selecting the <u>cancel icon</u><br>
<br>
As the calculation progresses the results are written to the scrollable text region and at appropriate points the graphical results display is updated.<br>
<br>
{button ,AL(`list18',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Parametric Text Results<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">As a parametric analysis is run the results are listed into the scrollable text region on the window. The results list the value of the x variables and the calculated y result. Note that the listed x-values will only be real numbers if the variable is of single value type. For splines and 2d maps variables the listed x-values will be the shift or scale setting.<br>
<br>
The contents of the text display can be saved to a file using the menu option <u>Text</u></font></font></font> / <u>Save to File</u> or printed directly using the menu option <u>Text</u> / <u>Print</u>. As will all Lotus Vehicle Simulation multi line text entries the right mouse button can be used to perform 'cut and paste' type operations between Lotus Vehicle Simulation and other applications.<br>
<br>
{button ,AL(`list18',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Analysing the Parametric Results<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">Some simple analysis tools are provided for reviewing the parametric analysis results. The minimum and maximum results value found and their associated x-values can be listed using the menu option <u>Solve</u></font></font></font> / <u>Summary</u>, whilst the results of least squares fits to the results can be listed using the menu option <u>Solve</u> / <u>Sensitivities</u>. <br>
<br>
The sensitivity numbers are unitized over the range to enable direct comparisons to be made. The larger the sensitivity number the greater that variable has on the result. A negative sensitivity number implies that increasing the variable results in a reduction of the result. Both the minimum and maximum sensitivity numbers are given for each variable.<br>
<br>
Parametric analysis with two variables also includes cross sensitivity values.<br>
<br>
{button ,AL(`list18',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Controlling the Parametric Graphical Display<br>
</font></b><font size="2"><br>
The graphical display of the parametric results can be controlled using the <u>graph set-up options</u></font>. The set-up window is opened using the menu option <u>Graph</u> / <u>Setup</u> or using the Ctrl + S keyboard combination.<br>
<br>
The graph display size can be set to either large or small by using the menu option <u>Graph</u> / <u>Size</u> or cycled between large and small using the <u>graph icon</u><br>
<br>
For 3d graphical images the view orientation can be set not only through the set-up menu option, but also dynamically using Ctrl + arrow keys to rotate around and up and down.<br>
<br>
If multiple y-results have been requested the displayed result is changed by using the arrow icons on the Results panel. Note that the graphical display is disabled, (i.e. not redrawn) if any changes are made to the data, since the results would be no longer valid for the displayed information.<br>
<br>
{button ,AL(`list18',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Parametric Results Graph Set-up<br>
</font></b><font size="2"><br>
Parametric Results Graphs<br>
</font><br>
The properties and appearance of the parametric calculations results graphs can be set by the user through the <font face="Times New Roman"><font face="Arial">set-up</font></font><font face="Times New Roman"><font face="Arial"> option. To open the </font></font><font face="Times New Roman"><font face="Arial">set-up</font></font><font face="Times New Roman"><font face="Arial"> dialog box select the </font></font><font face="Times New Roman"><font face="Arial">set-up</font></font><font face="Times New Roman"><font face="Arial"> option from the pull down menu at the top left hand corner of the data graph, or use the shortcut key command Ctrl+S.<br>
<br>
The user can control text, text colour, text font, text width, axes scales, axis fit, decimal points, line colours, line types, symbol types, symbol colours and visibility settings. Each individual item is discussed below by panel. In addition parametric results can be displayed as x-y plots 2d contours, 3d surface or a combination of these types.<br>
</font></font><br>
The display properties are set in seven different property sheets. <br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Std 1D&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Controls the conventional x-y plot appearance<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Ext. View&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Controls the extended plot types for multi variable parametric results<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
3D View&nbsp;
Settings for the surface plot view<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Contour Levels&nbsp;&nbsp;
User definable contour level values and colours<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
3D Labels&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Surface plot label settings<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
2D Contours&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Contour plot settings<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
3D Surface&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Surface plot settings<br>
<br>
Property Sheet 1 - 'Std 1D', Panel 1 - <font face="Times New Roman"><font face="Arial">Plot text</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>Title</b></font></font>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the text used for the graph title.<br>
<b>X-Label&nbsp;
</b>Defines the text used for the x-axis.<br>
<b>Y-Label</b>&nbsp;
Defines the text used for the y-axis.<br>
<b>Font</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the individual text label font types.<br>
<b>Colour&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the individual text label colours.<br>
<b>Width</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line width/weight to be used for text and axis lines on screen.<br>
<b>h/c Width</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line width/weight to be used for text and axis lines on hard copy.<br>
<b>Grid Vis</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the visibility of the graph's grid. Check this box to make visible.<br>
<b>Grid Fill</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the colour used to fill the background of the graph plotting region.<br>
<br>
Property Sheet 1 - 'Std 1D', Panel 2 - <font face="Times New Roman"><font face="Arial">Plot axes</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>X-axis&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b></font></font>Identify values as being for the x-axis.<br>
<b>Y-axis</b>&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Identify values as being for the y-axis.<br>
<b>Minimum</b> Sets the minimum value for the axis.<br>
<b>Maximum</b>&nbsp;
Sets the maximum value for the axis.<br>
<b>Increments</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the number of increments on the axis.<br>
<b>Decimal Pls&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the number of decimal places to be used on the axis and listing.<br>
<b>Fit&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Forces the axes to use the defined min, max and increments exactly.<br>
<br>
Property Sheet 1 - 'Std 1D', Panel 3 - <font face="Times New Roman"><font face="Arial">Plot lines</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>Label</b></font></font>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines a line label, (currently not used).<br>
<b>Line</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Identify values as being for the line.<br>
<b>Symbol</b>&nbsp;&nbsp;
Identify values as being for the symbol.<br>
<b>Colour&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the colour for the line or symbol.<br>
<b>Type</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line type or symbol type.<br>
<b>Visibility&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Switches the line or symbol visibility.<b><br>
</b>Width&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line width/weight to be used for lines and symbols on screen.<br>
<b>h/c Width</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the line width/weight to be used for lines and symbols on hard copy.<br>
<br>
Property Sheet 2 - 'Ext. View', Panel 1 - <font face="Times New Roman"><font face="Arial">2D Contour Type</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>Off</b></font></font>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Switches 2D contour display off, only relevant if plotting a surface and you don't want to display the 2d contour as well.<br>
<b>Wire Frame</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Switches 2D contour display on, displaying the contour lines only.<br>
<b>Filled&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Switches 2D contour display on, displaying the contour lines drawn over a single fill colour<br>
<b>Coloured Contours</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Switches 2D contour display on, displaying the contour lines with each contour band having a unique fill colour.<br>
<br>
Property Sheet 2 - 'Ext. View', Panel 2 - <font face="Times New Roman"><font face="Arial">3D Surface Type</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>Off</b></font></font>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Switches 3D surface display off.<br>
<b>Wire Frame</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Switches 3D surface display on, displaying the surface grid in wire frame only.<br>
<b>Filled</b>&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Switches 3D surface display on, displaying the surface grid in wire frame drawn over a single fill colour.<br>
<b>Coloured Contours</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Switches 3D surface display on, displaying the surface grid in wire frame, and showing each contour band having a unique colour.<br>
<br>
Property Sheet 3 - '3D. View'<br>
<b>View Plane Angle</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the 3d view angle around the vertical Z-axis, (note that this value can be changed directly from the parametric window using the Ctrl + left/right arrow keys).<br>
<b>View Radius&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the 3d view spherical radius that contains the plot, (program automatically calculates this number).<br>
<b>View Elevation Angle</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the 3d view angle relative to the x-y plane, (note that this value can be changed directly from the parametric window using the Ctrl + up/down arrow keys)..<br>
<b>Axis Values Text Height</b>&nbsp;
Sets the height of the 3d-axis labels.<br>
<b>Axis Values Text Width</b>&nbsp;&nbsp;
Sets the width of the 3d-axis labels.<br>
<b>Height to Base Axis Ratio</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the ratio between the lengths of the plot height and the plot base. Numbers &gt;1 produce a tall narrow picture, whilst numbers &lt;1 produce a low squat plot..<br>
<b>X/Y Axis Length Ratio</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the ratio between the x-axis length and the y-axis length. For a ratio of 1 the x-y plane is square. For ratios &gt;1 the x-axis is longer than the y-axis, whilst for ratios &lt;1, the y-axis is longer that the x-axis..<br>
<b>User Defined Z Limits</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
To control the minimum and maximum z-axis values set this check box to on. (If this option is set to off, the minimum and maximum z values are set to the minimum and maximum z-values contained in the results).<br>
<b>Z-axis Minimum</b>&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the minimum z-axis value.<br>
<b>Z-axis Maximum&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the maximum z-axis value.<br>
<b>Z-axis Increments&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the number of increments on the z-axis.<br>
<b>User Defined 2D Contour Z Height</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
To control the z-position of the 2D contour plot on a 3d surface plots set this check box to on. (If this option is set to off, the 2d contour is positioned at the minimum z-axis position).<br>
<b>2D Contour Z Height</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the z-axis value for the 2d contour plot to be displayed at.<br>
<br>
Property Sheet 4 - 'Contour Levels'<br>
<b>User Defined Levels</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
To define the values for the contour levels set this check box to on. (if this option is set to off, the contour levels will be eqi-spaced between the minimum and maximum Z results, using the current number of contours).<br>
<b>No of Levels</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the number of contour levels to use.<br>
<b>Value</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the value for the transition from one contour level to the next.<br>
<b>Colour</b>&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the colour for the contour level.<br>
<br>
Property Sheet 5 - '3D Labels, Panel 1 - <font face="Times New Roman"><font face="Arial">3D Label Settings</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>Title&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b></font></font>Identify values as being for the title.<br>
<b>X-axis&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Identify values as being for the x-axis.<br>
<b>Y-axis&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Identify values as being for the y-axis.<br>
<b>Z-axis&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Identify values as being for the z-axis.<br>
<b>Visibility</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets label visibility, set check box to on for visible.<br>
<b>X Position</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets label x position, where graph is 0 to 1.<br>
<b>Y Position</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets label y position, where graph is 0 to 1.<br>
<b>Angle&nbsp;&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets label angle to the horizontal, in degrees, 0=horizontal.<br>
<b>Width&nbsp;&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets label text width.<br>
<b>Height&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets label text height.<br>
<br>
Property Sheet 5 - '3D Labels, Panel 2 - <font face="Times New Roman"><font face="Arial">Z-Axis Plot Text</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>Title&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b></font></font>Identify values as being for the title.<br>
<b>Text&nbsp;&nbsp;&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Defines the z-axis label.<br>
<b>Font</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the font type for the z-axis label.<br>
<b>Colour&nbsp;&nbsp;
</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Sets the label colour for the z-axis label.<br>
<br>
Property Sheet 6 - '2D Contours, Panel 1 - <font face="Times New Roman"><font face="Arial">2D Annotation</font></font><font face="Times New Roman"><font face="Arial"><br>
</font></font><b>Visibility&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Set visibility of 2D contour annotation, set check box to on for visible.<br>
<b>Label Colour&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Set annotation label colour.<br>
<b>No. of Decimal Points&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Defines the No. of decimal points used for contour label values.<br>
<b>Label Overall Field Width&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Defines the field width fro the contour labels, max 9 digits.<br>
<b>Label Text Height&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the contour labels text height.<br>
<b>Label Text Gap&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the allowable gap between adjacent contour labels.<br>
<b>Contour Line Label Skipping&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the no. of contour lines to skip between labelling, i.e. 0= none skipped..<br>
<b>Labelled Contour Lines Colour&nbsp;&nbsp;&nbsp;
</b>Line colour for labelled contour lines.<br>
<b>Skipped Contour Lines Colour&nbsp;&nbsp;&nbsp;&nbsp;
</b>Line colour for non-labelled (skipped) contour lines.<br>
<br>
Property Sheet 6 - '2D Contours, Panel 2 - <font face="Times New Roman"><font face="Arial">2D Grid</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>Visibility&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b></font></font>Set visibility of 2D contour grid, set check box<br>
to on for visible.<br>
<b>Colour&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Set the colour of the of 2D contour grid.<br>
<br>
Property Sheet 6 - '2D Contours, Panel 3 - <font face="Times New Roman"><font face="Arial">2D Fill</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>2D Contour Filled Colour&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b></font></font>Sets the colour of the of the background fill for the contoured region of the graph when using 2D plot type of filled contour.<br>
<br>
Property Sheet 6 - '3D Surface, Panel 1 - <font face="Times New Roman"><font face="Arial">3D Grid Setup</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>No. of X Grids&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b></font></font>Defines the x-axis grid density for the interpolation of the results.<br>
<b>No. of X Grids Skipped&nbsp;&nbsp;
</b>Sets the No. of x-grid lines to skip when drawing the fitted surface.<br>
<b>No. of Y Grids&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Defines the y-axis grid density for the interpolation of the results.<br>
<b>No. of Y Grids Skipped&nbsp;&nbsp;
</b>Sets the No. of y-grid lines to skip when drawing the fitted surface.<br>
<b>X Base Fill&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Defines the colour used to fill the x-axis base.<br>
<b>Y Base Fill&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Defines the colour used to fill the y-axis base.<br>
<b>Z Base Fill&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Defines the colour used to fill the z-axis base.<br>
<b>Axis line&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Defines the colour used for plot axes and labels.<br>
<b>Upper Surface&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Defines the colour used for the upper surface grid lines.<br>
<b>Visible Edge&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Defines the colour used for the visible edges of the surface plot.<br>
<b>Base Vertical Grid Style&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the drawing style used for the plot base, as being either, no lines, or vertical lines. (vert+style option not used).<br>
<b>Projection Section Lines&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the drawing style used for the surface grid lines, as being either, x and y, x only or y only.<br>
<b>Surface Style&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the drawing style used for the surface, as being either, top and side, top only, top and bottom or bottom only. This controls the visibility of the parts of the surface.<br>
<br>
Property Sheet 6 - '3D Surface, Panel 2 - <font face="Times New Roman"><font face="Arial">3D Axis Display</font></font><font face="Times New Roman"><font face="Arial"><br>
<b>X1&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b></font></font>Identifies the values as being for the X1 axis, (axis 1 is the l.h.s axis).<br>
<b>Y1&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Identifies the values as being for the Y1 axis, (axis 1 is the l.h.s axis).<br>
<b>Z1&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Identifies the values as being for the Z1 axis, (axis 1 is the l.h.s axis).<br>
<b>X2&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Identifies the values as being for the X1 axis, (axis 2 is the r.h.s axis).<br>
<b>Y2&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Identifies the values as being for the Y1 axis, (axis 2 is the r.h.s axis).<br>
<b>Z2&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Identifies the values as being for the Z1 axis, (axis 2 is the r.h.s axis).<br>
<b>Axis Style&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the axis drawing style as being either, none, axis, grid or axis and grid. This controls the visibility of the various elements of the specific axis.<br>
<b>Suppression&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b>Sets the axis end value suppression, as being either, none, low high or low and high. This controls the visibility of the end value labels of the specific axis.<br>
<br>
The <u>graph icon</u> is provided to enable the graph to be redrawn/updated without the requirement to close the set-up dialog box down.<br>
<br>
The parametric results graph settings are saved in the Lotus Vehicle Simulation.ini file, such that on application start-up these settings will be restored.<br>
<br>
{button ,AL(`list18',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Closing the Parametric Analysis Screen<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To close the parametric analysis screen screen select either the menu item <u>File</u></font></font></font> /<i> </i><u>Close Parametrics</u> from the window menubar, the <font face="Times New Roman"><font face="Arial">close</font></font><font face="Times New Roman"><font face="Arial"> icon at the top right corner of the parametrics window, or the parametrics window menu at the top left.<br>
<br>
{button ,AL(`list18',0,&quot;&quot;,`main')} <u>Related Topics</u></font></font><font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Batch Analysis<br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial"><b>Overview<br>
</b></font></font></font><font face="Times New Roman"><br>
<br>
<font face="Arial">The batch analysis option allows the user to define a series of different tests that can be run in one go without the need to redefine the test settings between tests. These 'batch' settings are saved in the Lotus Vehicle Simulation '.ini' file and thus once a number of standard tests have been defined any subsequent Lotus Vehicle Simulation run and data file can re-run the same standard tests.<br>
<br>
The results can be selected from either the <u>'.crs' file</u></font></font> variables or the <u>'.grs' file</u> variables. The grs results can further be requested at either the end of the cycle, at a user selected time, a user selected distance or a user selected velocity during the cycle. A number of different results can also be defined for each test case.<br>
<br>
The results are listed into a scrollable text widget, the contents of which can be printed or saved to a file.<br>
<br>
The solution settings for each batch test are defined using the normal style calculation setting buttons, the displayed settings being updated for each test as you step through the tests.<br>
<br>
(this section of the help file will be extended at future releases)<br>
<br>
{button ,AL(`list18',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><sup>A</sup><b><font size="4">Program Theory - Overview<br>
</font></b><font size="2"><br>
The aim of this chapter is to document the fundamental equations used within the simulation and describe the assumptions that are used. As far as possible the variable names used in the data entry section have been maintained.<br>
<br>
<u>Summary of the calculation sequence;<b> </b></u></font><u><img data="bm58.bmp" title="bm58.bmp"></u><br>
<br>
This is obviously a simplistic flow chart. Special options are invoked during gear changing and during a track simulation.<br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Theory - Vehicle Acceleration Dynamics<br>
</font></b><font size="2"><br>
Given that V2 and V1 are the vehicle speeds at this and the previous time steps respectively, and that <b>TSTEP</b></font> is the time step. Then the acceleration is defined as;<br>
<br>
<i><center> <b> V2 - V1<br>
AC = -------<br>
TSTEP<br>
</b></i></center>
<b><br>
</b>The forces acting on the vehicle are;<br>
<br>
<b>Force to produce acceleration<br>
<br>
</b><i><center>Fa = WEIGHT x AC<br>
</i></center>
<b><br>
Force due to aerodynamic drag<br>
<br>
</b><i><center>VM = 0.5 ( V2 + V1 )<br>
Fd = 0.5 x RHO x FAREA x CD x VM^2<br>
</i></center>
<br>
where RHO = air density<br>
<b><br>
Force due to incline<br>
<br>
</b><i><center>Fg = WEIGHT x G x SIN( A )<br>
</i></center>
<b><br>
</b>where G = 9.8107, A = incline angle<br>
<br>
<b>Force normal to the road surface<br>
<br>
</b><i><center>Fn = WEIGHT x G x COS( A )<br>
</i></center>
<br>
<b>Force due to tyre rolling resistance<br>
<br>
</b><i><center>Fr = COEFFR x Fn<br>
</i></center>
<b><br>
</b>where COEFFR = coefficient of rolling resistance<br>
<b><br>
Force to accelerate non driven wheels</b><br>
<b><br>
</b><i><center>Fi = RIWHL x AC / ( RTYRE x RTYRE )<br>
</i></center>
<br>
Therefore the <b>total tractive effort to satisfy the acceleration </b>is given by;<b><br>
<br>
</b><i><center>Ft = Fa + Fd + Fg + Fr + Fi</i><b><br>
</b></center>
<br>
In order to determine whether this force can be provided the load on the driven axle must be determined. The effects of weight transfer, aerodynamic lift and incline must be combined.<br>
<br>
The centre of aerodynamic drag is assumed to coincide with the centre of gravity. The <b>force opposing motion at the centre of gravity</b> is given by;<br>
<br>
<i><b><center>Fcg = Fa + Fd + Fg<br>
</b></i></center>
<b><br>
Forces on front and back wheels due to weight transfer</b> are<br>
<br>
<i><b><center>Ffront = ( Fcg x HCOG - Fn x ( WHBASE - DCOG ) ) / WHBASE<br>
</b></i></center>
<b><br>
</b><i><center>Frear = ( Fcg x HCOG + Fn x DCOG ) / WHBASE<br>
</i></center>
<b><br>
</b>The <b>axle forces due to aerodynamic lift</b> are<br>
<br>
<i><b><center>Faf = 0.5 x RHO x CLF x PAREA x Vm^2<br>
Far = 0.5 x RHO x CLR x PAREA x Vm^2</b></i><b><br>
</b></center>
<br>
These are simply added to the front and rear forces.<br>
<br>
The front and rear axle forces are used to calculate the wheel slip and tractive effort.<br>
<br>
When the vehicle is driven on a chassis dynamometer the weight transfer and aerodynamic forces are replaced by the force required to drive the dynamometer. Where the force is given by;<br>
<br>
<i><b><center>Fdyno = DYNM x AC + ADYN + BDYN x VM + CDYM x VM^2<br>
</b></i></center>
<br>
Tyre rolling resistance forces are reduced to those of the driven wheels only.<br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><sup>A</sup><b><font size="4">Program Theory - Vehicle Cornering Dynamics<br>
</font></b><font size="2"><br>
Vehicle cornering is assumed to be steady state ( ie. is performed at a constant road speed). The cornering speed is the minimum of -<br>
<br>
</font><b>1. THE OVERTURNING SPEED<br>
2. THE LATERAL SLIP SPEED<br>
</b> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
3. THE USER SPECIFIED MAXIMUM CORNERING SPEED<br>
<br>
<u>Vehicle Cornering Notation<b> </b></u><u><img data="bm58.bmp" title="bm58.bmp"></u><br>
<br>
The following equations show how the first two limits are calculated. <br>
<br>
The <b>centripetal force<br>
<br>
</b><i><center>Fcp</i><b> = (<i>Weight</i></b><b> x <i>VM^2</i></b><b>) <i>/ RTRACK</i></b><b><br>
</b></center>
<br>
At the limit of slip<br>
<b><br>
</b><i><center>Ft1</i><b> = <i>R1 </i></b><b>x <i>U</i></b><b> x cos( A )<br>
</b></center>
<br>
<i><center>Ft2</i><b> = <i>R2</i></b><b> x <i>U</i></b><b> x cos( A )<br>
</b></center>
<br>
where A = camber angle of road relative to horizontal<br>
<br>
Resolve <b>vertical and horizontal forces<br>
</b><br>
<i><center>R1 x sin( </i><b>A<i> ) + R2 x sin( </i></b><b>A<i> ) + R1 x U x cos( </i></b><b>A<i> ) + R2 x U x cos( </i></b><b>A<i> ) =<br>
</i></b></center>
<br>
</center>
<center>(Weight x VM^2 / RTRACK) - 0.5 x RHO x CL x VM^2 x sin( <b>A<i> )<br>
</i></b></center>
<b><br>
</b></center>
Hence,<br>
<b><center> (<i>WEIGHT x VM^2 / RTRACK) - 0.5 x RHO x CL x VM^2 x sin( </i></b><b>A<i> )<br>
</i></b></center>
<center>R1 + R2 =------------------------------------------------------------------------------------------- <br>
</center>
<center> sin( <b>A<i> ) + U x cos( </i></b><b>A<i> )</i></b><br>
</center>
and,<br>
<br>
<i><b><center>R1 x cos( A )+ R2 x cos( A ) - R1 x U x sin( A ) - R2 x U x sin( A ) =<br>
</b></i></center>
<br>
</center>
<center>WEIGHT x G - 0.5 x RHO x CL x VM^2 x cos( A )<br>
</center>
<br>
</center>
Hence,<br>
<i><b><center>WEIGHT x G - 0.5 x RHO x CL x VM^2 x cos( A )<br>
</b></i></center>
<center>R1 + R2 = ------------------------------------------------------------------------------------- <br>
</center>
<center>cos( A ) - U x sin( A )<i><br>
</i></center>
<br>
Taking moments about the centre of gravity and given that <i><b>T2 = 0.5 x TRACK</b></i><b><br>
</b><br>
<i><b><center>R2 x T2 + R2 x U x HCOG + R1 x U x HCOG = R1 x T2<br>
</b></i></center>
Hence,<br>
<i><b><center>R1 - R2 = ( R1 + R2 ) x U x HCOG / T2</b></i><b><br>
</b></center>
Let,<br>
<i><b><center>ADC = 0.5 x RHO x CL</b></i><b><br>
</b></center>
Substituting from 1,<br>
<br>
<i><b><center> (WEIGHT/RTRACK - ADC x SIN( A )) (U x HCOG x VM^2)</b></i><b><br>
</b></center>
<i><center>R1 + R2 = --------------------------------------------------------- x -------------------------<br>
</i></center>
<center> &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(SIN( A ) + U x COS( A )) T2<i><br>
</i></center>
<br>
At the point of overturning R2 = 0, therefore from 2 and 3<br>
<br>
<i><b> (WEIGHT / RTRACK - ADC x SIN( A )) (U x HCOG x VM^2)<br>
</b></i> ------------------------------------------------ x -------------------------- =<br>
(SIN( A ) + U x COS( A )) T2<br>
<br>
<i><br>
</i><b> (WEIGHT x G - ADC x VM^2 x COS( A ))<br>
</b> -----------------------------------------------------<br>
COS( A ) - U x SIN( A )<b><br>
</b> <br>
Rearranging the equation for the overturning speed is given by<br>
<br>
<i><b><span style="font-size:9pt"> WEIGHT x G<br>
</span></b></i>VM^2 = ( -------------------------------<br>
(COS( A ) - U x SIN( A )) WEIGHT (U x HCOG)<br>
--------------------------------- x ( ------------ - ADC*SIN( A ) ) - ---------------- ) - ADCxCOS( A )<br>
(SIN( A ) + U x COS( A )) RTRACK T2<font size="2"> <br>
</font><br>
From equations 1 and 2, (note these are the equations of motion at the limit of slip)<br>
<i><br>
</i><b>SIN( A ) + U x COS( A ) ( WEIGHT / RTRACK - ADC x SIN( A )) x VM^2 )<br>
</b>------------------------------- = -------------------------------------------------------------------<br>
COS( A ) - U x SIN( A ) ( WEIGHT / G - ADC x COS( A ) x VM^2 )<i><br>
</i><br>
Dividing the left hand side by <b>COS( A )</b> and using the substitution, <i><b>U = TAN( S )</b></i><br>
<br>
After rearrangement the slip speed is given by,<br>
<br>
<b> WEIGHT x G x TAN( B + S )<br>
</b>VM^2 = ------------------------------------------------------------------------- <br>
WEIGHT<br>
------------ - ADC x ( SIN<i>( A )</i><b> - TAN(B+S) x COS<i>( A )</i></b><b>I<br>
</b> RTRACK<br>
<br>
Within LOTUS VEHICLE SIMULATION the above limits are calculated for the front and rear axis independently. The weight on each axle (without weight transfer) is calculated. The height of the centre of gravity above each axis is assumed to be HCOG.<br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Theory - Tyre Rolling Resistance<br>
</font></b><font size="2"><br>
Tyre rolling resistance is produced by the work done in deforming the tyres under rolling conditions. Measurements of this resistive force are normalised by the normal load on the tyre. <br>
<br>
Thus,<br>
</font><b><center>Fr = COEFFR x Fn<br>
</b></center>
<br>
Where Fr is the rolling resistance, COEFFR the coefficient of rolling resistance and Fn the normal tyre force.<br>
<br>
The coefficient of rolling resistance is obtained at any engine speed from a polynomial curve fit. This polynomial can either be the default supplied by LOTUS VEHICLE SIMULATION or up to 6 order equation provided by the user. The default curve is compared to the band of data provided in the BOSCH automotive handbook in the graph below :<br>
<br>
<u>Tyre coefficient of rolling resistance;<b> </b></u><u><img data="bm58.bmp" title="bm58.bmp"></u><br>
<br>
This curve has been developed from the coast down and Vmax measurements made by Lotus on a number of production vehicles. Users are however encouraged to obtain more accurate data from the tyre supplier.<br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><sup>A</sup><b><font size="4">Program Theory - Longitudinal Tyre Slip<br>
</font></b><font size="2"><br>
Tyre slip is assumed to be present under all conditions at which tractive effort (either positive or negative) is developed. Slip is a continuous phenomenon up to true wheel slip. The amount of slip is calculated from the ratio of tractive effort to normal wheel force where tyre slip is defined as,<br>
<i><br>
<b> WAXLE x Ft<br>
TSLIP = 1 - --------------------</b></i></font><i><br>
<b> VM x RTYRE</b></i><i><br>
</i><br>
and,<br>
<i><br>
</i><b><center>SIGMA = -Ft / ( 28.0 x Fn )<br>
</b><i><br>
<b>TSLIP = SIGMA / ( SIGMA + 1 )</b></i><i><br>
</i></center>
<br>
the axle speed is then calculated from,<br>
<br>
<i><b><center>WAXLE = VM x ( 1 - TSLIP ) / RTYRE</b></i><i><br>
</i></center>
<br>
The resulting tyre slip curve is shown in figure 432.1. The maximum tractive effort that can be developed is limited by both the coefficient of friction and the tyre slip limit of 0.25, in such a manner that if the demanded vehicle acceleration produces a requirement that exceeds these limits then the acceleration is reduced. From the figure below, it is obvious that the maximum tractive effort is always controlled by the coefficient of friction.<br>
<br>
<u>Tyre Longitudinal Slip;<b> </b></u><u><img data="bm58.bmp" title="bm58.bmp"></u><br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Theory - Tyre Drive Efficiency<br>
</font></b><font size="2"><br>
At present the tyre is assumed to exhibit a drive efficiency of 95%. Thus the axle torque is defined as;<br>
</font><i><b><center>Taxle = Ft / ( RTYRE x 0.95 )<br>
</b></i></center>
<br>
In future releases of the program this assumption could be refined to make the drive efficiency a function of tyre slip.<br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Theory - Driveline<br>
</font></b><font size="2">The program works back along the drive line taking into account the effects of gear efficiencies and inertia requirements. The following equations summaries the calculations for rotational speed, rotational acceleration and torque at each station.<br>
<br>
<b>Wheels and axle,<br>
</b></font><br>
<i><b><center>VAXLE = VM x ( 1 - TSLIP ) / RTYRE<br>
AAXLE = AM / RTYRE<br>
TAXLE = Ft x RTYRE + WAAXLE x (RIPWHL + RIPAXL)<br>
</b></i></center>
<i><br>
</i><b>Propshaft,</b><br>
<br>
<i><b><center>VPROP = WVAXLE x GRFD<br>
APROP = WAAXLE x GRFD<br>
TPROP = TAXLE/(EFFY x GRFD) + RIPROP x WAPROP<br>
</b></i></center>
<i><br>
</i><b>Gearbox,<br>
</b><br>
<i><b><center>VGB = WVPROP x GRBX<br>
AGB = WAPROP x GRBX<br>
TGB = TPROP / (EFFY x GRBX) + ( RIBX x WAGB )<br>
</b></i></center>
<i><br>
</i><b>Primary gear,</b><br>
<br>
<i><b><center>VPD = WVGB x GRPD<br>
APD = WAGB x GRPD<br>
TPD = TGB / (GRPD x EFFY )<br>
</b></i></center>
<i><br>
</i>Where EFFY is the gear efficiency of the gear set.<br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Theory - Gear Efficiency<br>
</font></b><font size="2"><br>
The efficiency of a particular gear set can be specified as constant or may be allowed to vary with both speed and load using the following algorithm.<br>
<br>
The gear efficiency model requests the user to specify the efficiency of each gear at its maximum torque and maximum speed condition. The following equation is subsequently used to calculate the actual efficiency based on the demanded speed and torque.<br>
<br>
</font><i><b><center>CONST = (1.0/EFFMAX) - 1.0<br>
</b></i></center>
<br>
EFFICIENCY = 1.0<br>
----------------------------------------------------------------------------------<br>
( sqrt(TMAXG/TORQ) x sqrt(WGEAR/SMAXG) x CONST ) + 1.0<i> <br>
</i><br>
Where,<br>
<br>
<b>EFFMAX</b> = maximum gear efficiency (fraction)<br>
<b>TORQ</b> = transmitted torque<br>
<b>TMAXG</b> = maximum input torque<br>
<b>WGEAR</b> = gear input speed<br>
<b>SMAXG</b> = maximum speed of gear<br>
<br>
The figure below shows how the gear efficiency varies with both speed and torque ratio for two maximum gear efficiencies. The maximum speed of a gear is calculated from the rated engine speed and the lowest ratio of any gears upstream of the gear. Thus for the final drive the maximum speed is calculated from the maximum engine speed devided by the top gear ratio. The maximum torque is either specified by the user as the gearbox design torque or calculated from the torque curve. When the default design torque is used care should be taken when interpreting the results of part load calculations with different engine torque curves. The engine with the highest torque will produce the worst part load gear efficiencies.<br>
<br>
<u>Gear Efficiency;<b> </b></u><u><img data="bm58.bmp" title="bm58.bmp"></u><br>
<br>
When the four wheel drive option is selected the torque is assumed to split equally between front and rear axles for the gear efficiency calculations. It is assumed that all the torque can be transmitted through one axle, thus the torque ratio term on the four wheel drive is always low and results in worse final drive efficiencies than an equivalent two wheel drive vehicle.<br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Theory - Gear Loss Maps<br>
</font></b><font size="2"><br>
The facility to directly input the transmission losses in each gear as a function of both the speed and torque fraction is provided with the <b>Gear Loss</b></font> option. This simply subtracts the user specified torque at the current gearbox input speed and torque fraction at the current gearbox input speed and torque fraction from the torque that is transmitted through the gearbox.<br>
<br>
The interpolation of the gear loss data is linear.<br>
<br>
It the current torque ratio is either above the maximum specified torque ratio or below the minimum user specified torque ratio then the data at the maximum or minimum torque ratios is assumed (i.e. There is no extrapolation of the loss data). Thus if the user wishes to specify losses that were simply a function of gearbox speed then data for a single torque fraction should be input and this will be used for all loads.<br>
<br>
Similarly if the gearbox input speed is either above the maximum user specified speed or below the minimum user specified speed then the data at the maximum and minimum speed ratios are assumed. If the user wishes to specify losses that are simply a function of load fraction then the user should enter data for a single gearbox input speed.<br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Theory - Gear Shifts<br>
</font></b><font size="2"><br>
A gear shift sub model is employed as separate to the main calculation loop. If the model encounters a gear shift as a result of either a default or forced gear change, one of two options is invoked.<br>
<br>
If a manual transmission is used, the engine is declutched from the driveline for the duration of the gearshift. During this time the engine is assumed to be in an overrun condition. The vehicle acceleration is set to zero and the vehicle speed remains constant during the gear change. Thus it is assumed that the deceleration caused by aerodynamic drag and driveline losses during the gear change is negligible. The effect of engine inertia during gear shifting is also omitted. There is no power absorption to the engine as rotational energy, as a result of shifting down or power delivery as a result of dumping the clutch on an acceleration.<br>
</font><br>
If an automatic transmission is used, the engine speed and load at the end of the gear shift is first calculated. The assumption that the engine speed and load changes linearly from that prior to the shift is made. During the gear shift the vehicle acceleration remains fixed at the value just prior to the shift (This is effectively a power shift). <br>
<br>
Gear shifting can occur in two modes, either using the default gear shift points or using a user specified gear shift strategy.<br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Theory - Default Shift Maps<br>
</font></b><font size="2"><br>
All the calculation modes have default gear shift strategies. For emission cycles these are provided by the legislation and are coded into the program. During accelerations and track simulations gear shifting will only occur under the following 3 conditions:<br>
<br>
<b>1.</b></font> When the gear shift will increase the rate of acceleration.<br>
<br>
<b>2.</b> When the gear shift is forced by the engine speed exceeding<br>
the maximum engine speed.<br>
<br>
<b>3.</b> When the gear shift is forced by the engine speed falling<br>
below the minimum engine speed.<br>
<br>
During track simulations a special condition is invoked to force the engine speed to be as high as possible through a corner. For constant road speed simulations the user is prompted for the gear number in which the calculation is to be performed.<br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Theory - Gear Shift Maps<br>
</font></b><font size="2"><br>
Gear shifting can be controlled by the user through the use of shift maps. These define the shift up and shift down points for each gear as a function of a speed and load parameter. The figures show two typical shift maps. The first producing gear shifts at predefined road speeds, this is typical of that specified for a manual gearbox. The second producing gear shifts as a function of road speed and throttle position, this is typical of that specified for an automatic gearbox.<br>
</font><br>
<u>Gear Shift Map - Road Speeds;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<img data="bm58.bmp" title="bm58.bmp"></u><br>
<br>
<u>Gear Shift Map - Throttle Positions;&nbsp;&nbsp;&nbsp;&nbsp;
<img data="bm58.bmp" title="bm58.bmp"></u><br>
<br>
The manner in which these shift maps are used is a function of the shift mode. If the shift mode is set to FORCED then a gear shift will only occur when the shift lines are crossed. For example for the operating points shown on the second figure,<br>
<br>
<b> A - B </b> - Produces an upshift from 3rd to 4th<br>
<br>
<b> B - C </b> - Produces no change in gear<br>
<br>
<b> C - D </b> - Produces a downshift from 4th to 3rd<br>
<br>
When the shift mode is set to FREE then a gear shift can occur at any point within a particular gears operating range. The gears operating range is taken as that identified by the shift-up and shift-down speeds. In FREE mode the program will explore the use of both higher and lower gears at each time increment. If these gears are allowed by their operating range and cause the engine to operate at a point closer to the <b>OPTIMUM</b> line thereby minimising the consumption of a specified map variable, then a gear shift will be performed.<br>
<br>
<b>NOTE : SKIP SHIFTING IS NOT PERMITTED IN EITHER FREE OR FORCED MODE<br>
</b><br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Theory - Torque Converter<br>
</font></b><font size="2"><br>
The torque converter characteristics are specified by the torque amplification ratios and input capacity factors as functions of the torque converter speed ratio.<br>
<br>
The input capacity factor is defined as,<br>
<br>
</font><i><b><center>FCIN = Si / sqrt ( Ti )</b></i><br>
</center>
<br>
Where,<br>
<br>
<b>Si</b> = input speed<br>
<b>Ti</b> = input torque<br>
<br>
The <font face="Times New Roman"><font face="Arial"><b>Program Theory - Overview</b></font></font><font face="Times New Roman"><font face="Arial"><b> </b></font></font>section describes how the calculations proceed in the opposite direction to power flow. The simulation thus must determine the converter input conditions from the output conditions. The following calculations are performed :<br>
<br>
<i><b><center>To = Ti x TORATIO</b></i><i><br>
</i></center>
Where To is the output torque<br>
<br>
<i><b><center>So = Si x SPRATIO<br>
</b></i></center>
Where So is the output speed<br>
<br>
The output capacity factor is defined as :<br>
<br>
<i><b><center>FCOUT = So / sqrt ( To )<br>
</b></i></center>
<br>
<b><center>= FCIN x SPRATIO / <i>sqrt </i></b><b>( TORATIO )<br>
</b></center>
<br>
The output capacity factor is calculated as a function of the speed ratio. At a given time step the output capacity factor is known. The accompanying speed and torque ratios can therefore be interpolated from the characteristic curves, thus providing the demanded input speed and torque.<br>
<br>
Torque converter lock-up is specified through the torque converter map. Automatic lock-up for minimum economy is not yet available.<br>
<br>
<b>NOTE : THE TORQUE CONVERTER PUMP LOAD SHOULD BE ADDED AS AN AUXILIARY DEVICE<br>
</b><br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Theory - Clutch<br>
</font></b><font size="2"><br>
A very simple clutch model is employed. The user is requested to specify the road speed below which the clutch is engaged and the engine is returned to idle. If during a cycle the engine speed falls below the minimum speed in 1st gear then the clutch will be engaged automatically.<br>
<br>
Clutch slip is modelled. On wide open throttle accelerations the engine speed is set at the lowest speed at which the torque developed by the engine can just spin the wheels. This engine speed is maintained with the clutch slipping until the vehicle speed allows the clutch to lock. On drive cycles the engine speed during clutch slip is set to the lowest speed at which the torque required to produced the desired launch can be delivered. This is typically the idle speed.<br>
</font><br>
<b>NOTE : CLUTCH SLIP IS ONLY ALLOWED IN FIRST GEAR.<br>
</b><br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Theory - Emissions Cycles<br>
</font></b><font size="2"><br>
The vehicle is requested to operate over all sections of an emissions cycle. The following notes are provided for the users reference.<br>
<br>
<b>FTP75 CYCLE<br>
</b></font><br>
The hot transient phase is modelled as immediately following the first 1372 seconds. This means that the 10 minute key-off phase is ignored.<br>
<br>
Weighted emissions are calculated with the following formula :<br>
<br>
<i><b><center>WTDGKM = 0.43 x 1000.0 x (WTD(cold transient)+WTD(stabilised)) <font size="3">/<font size="2"><br>
(WTDDIST(cold transient)+WTDDIST(stabilised))<br>
<font size="3">+<font size="2"> 0.57 x 1000.0 x (WTD(hot transient)+WTD(stabilised)) <font size="3">/<font size="2"><br>
(WTDDIST(hot transient)+WTDDIST(stabilised))</font></font></font></font></font></font></b></i><br>
</center>
<br>
Where, <br>
<br>
<b>WTDGKM</b> = weighted emissions in g/km<br>
<b>WTD(phase) </b>= emissions during phase in g<br>
<b>WTDDIST(phase)</b> = distance travelled in phase in m<br>
<br>
<b>EEC CYCLES<br>
</b><br>
The first 40 seconds after key on, when emissions are not sampled are not modelled. Users employing cold start corrections should take this into account when deriving the correction constants.<br>
<br>
If desired the user may create a derivative cycle from the data and include the additional pre-sampling cycle section. The cold-start and transient models may be more directly employed in this manner.<br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Theory - Catalyst<br>
</font></b><font size="2"><br>
The catalyst efficiency during warm up is modelled using a <b>WIEBE</b></font> function;<br>
<i><b><br>
<center>EFFY = EFFMAX x ( 1.0 - EXP( -10.0 x ( FRACT^3 ) ) )<br>
</b></i></center>
where,<br>
<br>
<b>EFFY</b> = conversion efficiency<br>
<b>EFFMAX</b> = maximum conversion efficiency<br>
<b>FRACT</b> = time as a fraction of time between start of warming and maximum catalyst efficiency time<br>
<br>
If the current time is less than CATT1-CATT2 then the conversion efficiency is set = 0.0. If the current time is greater than CATT1 then the conversion efficiency is set to the maximum efficiency as specified by the user.<br>
<br>
If requested this option could be improved to allow the user to specify the conversion efficiency verses time histories obtained from test data.<br>
<br>
The data required for the catalyst model are shown graphically in the figure.<br>
<br>
<u>Catalyst Model;<b> </b></u><u><img data="bm58.bmp" title="bm58.bmp"></u><br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Theory - Warm-Up and Transient Emissions Model<br>
</font></b><font size="2"><br>
The warm-up and transient emissions model allows the user to specify the increase in the three primary emissions during cold start and during engine transients. A simple warm-up ramp function is used to increase the engine out emissions during the cold start. The transient model simply increases the emissions in direct proportion to the engine acceleration.<br>
<br>
The following formula are used;<br>
<b><br>
Warm-up factor,<br>
</b></font><center>FACT = WARMF x ( 1.0 - TIME/WARMT )<br>
</center>
<b><br>
Transient factor,<br>
</b><i><center>ADD = RAW x WACFACT(IG) x ABS(WAENG)</i><br>
</center>
<b><br>
Corrected emissions,<br>
</b><i><center>Emissions = RAW + FACT x RAW + ADD<br>
</i></center>
<br>
Where,<br>
<b>RAW </b>= the engine out emissions from the steady state emissions map<br>
<b>Emissions </b>= is the corrected emissions level<br>
<br>
The data required for the warm-up model are shown graphically in the figure.<br>
<br>
<u>Warm-up Model;<b> </b></u><u><img data="bm58.bmp" title="bm58.bmp"></u><br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Program Theory - Engine Scaling<br>
</font></b><font size="2"><br>
This option allows the user to scale the engine performance and consumption maps by factors which scale with bore and stroke. The scaling factors are wholly defined by the user.<br>
<br>
Engine fuel economy and emissions maps can be improved or deteriorated through the use of the so called thermal efficiency factors.<br>
<br>
The whole map is linearly scaled by the following formulae :<br>
<br>
The changes in thermal efficiency as a result of a change in bore and stroke are given by, <br>
<br>
</font><i><b><center>TE1 = TEBORE x (BSCALE-BOROLD) / 100.0<br>
TE2 = TESTROKE x (SSCALE-STKOLD) / 100.0 <br>
</b></i></center>
<br>
The change in compression ratio as a result of a change in bore is given by,<br>
<br>
<i><b><center>CRNEW = CROLD + (BSCALE-BOROLD) x CRSENS</b></i><br>
</center>
<br>
with the subsequent change in efficiency given by, <br>
<i><b><br>
</b></i><center>TE3 = TECR x (CRNEW-CROLD) / 100.0 <br>
</center>
<br>
The factor by which consumptions are multiplied is given by,<br>
<br>
<i><b><center>TEFACT = 1.0 + TE1 + TE2 + TE3<br>
</b></i></center>
<br>
The engine speeds used to define the BMEP curve and consumption maps can be scaled linearly through the use of the bore and stroke scaling factors. <br>
<br>
The following formulae are employed :<br>
<br>
The changes in speed terms as a result of a change in bore and stroke are given by, <br>
<br>
<b><center>SP1 = SPBORE x (BSCALE-BOROLD) / 100.0<br>
SP2 = SPSTROKE x (SSCALE-STKOLD) / 100.0</b><br>
</center>
<br>
With the factor by which the speed terms are multiplied given by,<br>
<br>
<i><b><center>SPFACT = 1.0 + SP1 + SP2<br>
</b></i></center>
<br>
As an example if we wished to keep the characteristics constant with piston speed for a stroke change of 80 to 90 mm then, <br>
<br>
<i><b><center>SPBORE = 0.0<br>
SPSTROKE = -100.0 x (1.0 - 80/90)/10 = -1.1111</b></i><br>
</center>
and, <br>
<br>
<i><b><center>SPFACT = 1.0 + 0.0 - 0.1111 = 0.88889<br>
</b></i></center>
<br>
As a result of speed scaling the minimum and maximum engine speeds could be scaled to unacceptably low or high values. Lower and higher limits can be set by the using the ESSMIN and ESSMAX values.<br>
<br>
It was recognised that some mechanism was required to modify the fuel economy and emission maps as a result of changes in mechanical friction.<br>
<br>
The principal by which this is done is shown diagramatically in the figure. The specific consumption<font face="Times New Roman"><font face="Arial">s are converted into gross flow rates verses IMEP curves at each engine speed. The new IMEP is calculated for each BMEP point based on the change in friction and the accompanying flow rate interpolated from the consumption curve.<br>
</font></font><br>
<u>Engine Scaling;Friction<b> </b></u><u><img data="bm58.bmp" title="bm58.bmp"></u><br>
<br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><sup>A</sup><b><font size="4">Program Theory - Engine Friction<br>
</font></b><font size="3"><br>
<font size="2">The following listing gives the source code for the Lotus FRIC algorithm, used to estimate the friction of an engine based on Lotus data and various published analyses. These estimates are used when applying engine scaling to the model.<br>
<br>
<font size="1"> PROGRAM FRIC<br>
C<br>
C --- The object of this program is to provide an estimate of <br>
C mechanical friction - given design parameters of the<br>
C engine.<br>
C Equations taken from <br>
C 'DEVELOPMENT AND EVALUSTION<br>
C OF A FRICTION MODEL FOR SPACK IGNITION ENGINES'<br>
</font></font></font>C K.J.PATTON R.G.NITSCHKE B.HEYWOOD SAE 890836<br>
C<br>
C Experimental analysis of total engine friction in <br>
C four stroke SI engines SAE 900223<br>
C<br>
C Written By MHS 6/2/90<br>
C<br>
C --- This version includes an additional output for <br>
C calculated friction via H.B.MOSS see simulation user <br>
C note<br>
C --- 8/4/92 performed two checks with bears output - <br>
C as results added load factors - total crank bearing<br>
C friction for the two i4 engines showed this model to <br>
C overpredict total bearing friction by +7% in each case<br>
C this was considered ok <br>
C<br>
DIMENSION ITYPE(20), IV(20), RV(20), FFACT(4), RFACT(3)<br>
DIMENSION TOTF(100), HONDA(100), HBMF(100), HONDAM(100),<br>
&gt; FMAH(100), CAFF(100), SPEED(100)<br>
C<br>
C Adjustment Factors<br>
C FFACT(1) Rotating friction multiplier<br>
C FFACT(2) Reciprocating friction multiplier<br>
C FFACT(3) Valve train friction multiplier<br>
C FFACT(4) Auxillary friction multiplier<br>
C RFACT(1) Rotating Bearing friction multi(viscosity mult?)MAINS<br>
C RFACT(2) Rotating Bearing friction multi(viscosity mult?)BIG E<br>
C RFACT(3) Rotating Bearing friction multi(viscosity mult?)CAMS <br>
C<br>
DATA FFACT / 1.0, 1.0, 1.0, 1.0 / <br>
&gt; RFACT / 1.0, 1.0, 1.0 / <br>
&gt; PI / 3.1415927 /<br>
C<br>
CHARACTER*100 STRING <br>
CHARACTER*20 SSTR(10) <br>
CHARACTER*100 FOUT, FIN, TITLE <br>
C<br>
C --- Get input and output filenames<br>
C<br>
WRITE(*,'(A)')'$PLEASE GIVE INPUT DATA FILE NAME : '<br>
READ ( * , '(A)' ) FIN <br>
OPEN (20, FILE=FIN, STATUS='OLD',FORM='FORMATTED')<br>
C<br>
WRITE(*,'(A)')'$PLEASE GIVE OUTPUT DATA FILE NAME : '<br>
READ ( * , '(A)' ) FOUT<br>
OPEN (30, FILE=FOUT, STATUS='UNKNOWN',FORM='FORMATTED')<br>
C<br>
READ(20,'(A)')TITLE<br>
C<br>
C --- Read Bore Stroke and number of cylinders <br>
C<br>
READ(20,'(A)') STRING <br>
CALL DCSTR1 ( STRING , ITYPE, IV, RV, SSTR, N, 10 ) <br>
IF ( N.LT.5 ) THEN <br>
PRINT*,' ERROR not enough points on BORE line' <br>
STOP <br>
ENDIF <br>
BORE = RV(1)/1000.0 <br>
STOK = RV(2)/1000.0 <br>
CR = RV(3)<br>
NCYL = IV(4)<br>
NBM = IV(5)<br>
NBB = NCYL<br>
VSWEPT = BORE*BORE*STOK*NCYL*0.25*PI<br>
C<br>
C --- Read Number of Main Bearings diameters and widths<br>
C<br>
READ(20,'(A)') STRING <br>
CALL DCSTR1 ( STRING , ITYPE, IV, RV, SSTR, N, 10 ) <br>
IF ( IV(1).EQ.9999 ) THEN<br>
C --- Estimate bearing sizes for an inline engine<br>
DBM = 0.60*BORE <br>
WBM= 0.37*DBM<br>
IMTYPE = 1<br>
ELSE IF ( IV(1).EQ.9998 ) THEN<br>
C --- Estimate bearing sizes for an Vee engine one cyl per pin <br>
DBM = 0.7*BORE<br>
WBM = 0.35*DBM<br>
IMTYPE = 2<br>
ELSE IF ( IV(1).EQ.9997 ) THEN<br>
C --- Estimate bearing sizes for an Vee engine two cyl per pin <br>
DBM = 0.62*BORE<br>
WBM = 0.40*DBM<br>
IMTYPE = 3<br>
ELSE<br>
DBM = RV(1)/1000.0<br>
WBM = RV(2)/1000.0<br>
IMTYPE = 0<br>
ENDIF<br>
C<br>
C --- Read Number of Big end Bearings diameters and widths<br>
C<br>
READ(20,'(A)') STRING <br>
CALL DCSTR1 ( STRING , ITYPE, IV, RV, SSTR, N, 10 ) <br>
IF ( IV(1).EQ.9999 ) THEN<br>
C --- Estimate bearing sizes for an inline engine<br>
DBB = 0.57*BORE <br>
WBB = 0.41*DBB <br>
IBTYPE = 1<br>
ELSE IF ( IV(1).EQ.9998 ) THEN<br>
C --- Estimate bearing sizes for an Vee engine one cyl per pin <br>
DBB = 0.6*BORE<br>
WBB = 0.36*DBB <br>
IBTYPE = 2<br>
ELSE IF ( IV(1).EQ.9997 ) THEN<br>
C --- Estimate bearing sizes for an Vee engine two cyl per pin <br>
DBB = 0.57*BORE<br>
WBB = 0.39*DBB <br>
IBTYPE = 3<br>
ELSE<br>
DBB = RV(1)/1000.0<br>
WBB = RV(2)/1000.0<br>
IBTYPE = 0<br>
ENDIF<br>
C<br>
C --- Valve train <br>
C<br>
READ(20,'(A)') STRING <br>
CALL DCSTR1 ( STRING , ITYPE, IV, RV, SSTR, N, 10 ) <br>
IF ( N.LT.4 ) THEN <br>
PRINT*,' ERROR not enough points on Valve line' <br>
STOP <br>
ENDIF <br>
ICTYPE = IV(1)<br>
IFTYPE = IV(2)<br>
NVAL = IV(3) * NCYL<br>
XLIFT = RV(4)/1000.0<br>
C<br>
C --- Zero initial variables<br>
C<br>
COH = 0.5<br>
CFF = 0.0<br>
CRF = 0.0<br>
COM = 0.0<br>
C<br>
IF ( ICTYPE.EQ.1 ) THEN<br>
C--- OHV PUSHROD WITH ROCKERS<br>
COM = 32.1<br>
NCS = 1<br>
IF ( IFTYPE.EQ.1 ) THEN<br>
C--- Flat follower<br>
CFF = 400 <br>
ELSE IF ( IFTYPE.EQ.2 ) THEN<br>
C--- Roller follower<br>
CRF = 0.0151<br>
ELSE <br>
PRINT*,' Error IFTYPE out of range = ',IFTYPE<br>
ENDIF<br>
C<br>
ELSE IF ( ICTYPE.EQ.2 ) THEN<br>
C--- DOHC with direct acting followers <br>
COM = 10.7<br>
NCS = 2<br>
IF ( IFTYPE.EQ.1 ) THEN<br>
C--- Flat follower<br>
CFF = 133 <br>
ELSE IF ( IFTYPE.EQ.2 ) THEN<br>
C--- Roller follower<br>
CRF = 0.0050<br>
ELSE <br>
PRINT*,' Error IFTYPE out of range = ',IFTYPE<br>
ENDIF<br>
ELSE IF ( ICTYPE.EQ.3 ) THEN<br>
C--- SOHC with direct acting followers <br>
COM = 10.7<br>
NCS = 1<br>
IF ( IFTYPE.EQ.1 ) THEN<br>
C--- Flat follower<br>
CFF = 200<br>
ELSE IF ( IFTYPE.EQ.2 ) THEN<br>
C--- Roller follower<br>
CRF = 0.0076 <br>
ELSE <br>
PRINT*,' Error IFTYPE out of range = ',IFTYPE<br>
ENDIF<br>
ELSE IF ( ICTYPE.EQ.4 ) THEN<br>
C--- SOHC with Rocker arms <br>
COM = 21.4<br>
NCS = 1<br>
IF ( IFTYPE.EQ.1 ) THEN<br>
C--- Flat follower<br>
CFF = 400<br>
ELSE IF ( IFTYPE.EQ.2 ) THEN<br>
C--- Roller follower<br>
CRF = 0.0151 <br>
ELSE <br>
PRINT*,' Error IFTYPE out of range = ',IFTYPE<br>
ENDIF<br>
ELSE IF ( ICTYPE.EQ.5 ) THEN<br>
C--- SOHC with finger followers <br>
COM = 42.8<br>
COH = 0.20<br>
NCS = 1<br>
IF ( IFTYPE.EQ.1 ) THEN<br>
C--- Flat follower<br>
CFF = 600<br>
ELSE IF ( IFTYPE.EQ.2 ) THEN<br>
C--- Roller follower<br>
CRF = 0.0227 <br>
ELSE <br>
PRINT*,' Error IFTYPE out of range = ',IFTYPE<br>
ENDIF<br>
ELSE<br>
PRINT*,' Error ICTYPE out of range(1-5) = ',ICTYPE<br>
ENDIF<br>
C<br>
C --- Read Cam Bearings diameters and widths<br>
C<br>
READ(20,'(A)') STRING <br>
CALL DCSTR1 ( STRING , ITYPE, IV, RV, SSTR, N, 10 ) <br>
IF ( IV(1).EQ.9999 ) THEN<br>
C --- Estimate bearing sizes<br>
DCM = 0.34*BORE <br>
WCM = 0.66*DCM <br>
ICTYP2 = 1<br>
ELSE<br>
DCM = RV(1)/1000.0<br>
WCM = RV(2)/1000.0<br>
ICTYP2 = 0<br>
ENDIF<br>
C<br>
C --- Engine speed range <br>
C<br>
READ(20,'(A)') STRING <br>
CALL DCSTR1 ( STRING , ITYPE, IV, RV, SSTR, N, 10 ) <br>
IF ( N.LT.3 ) THEN <br>
PRINT*,' ERROR not enough points on Engine speed line' <br>
STOP <br>
ENDIF <br>
START = RV(1)<br>
SEND = RV(2)<br>
SINC = RV(3)<br>
IF ( N.EQ.4 ) THEN <br>
FLOAD = RV(4)<br>
ELSE<br>
FLOAD = 1.0<br>
ENDIF<br>
C<br>
C --- Write data to output file<br>
C<br>
WRITE(30,1000)<br>
WRITE(30,1010)<br>
WRITE(30,1000)<br>
C<br>
WRITE(30,1030)<br>
WRITE(30,1040) TITLE(1:LENSTR(TITLE))<br>
WRITE(30,1060) BORE*1000.0, STOK*1000.0, CR, NCYL, NBM<br>
IF ( IMTYPE.EQ.0 ) THEN<br>
WRITE(30,1100)<br>
ELSE IF ( IMTYPE.EQ.1 ) THEN<br>
WRITE(30,1110)<br>
ELSE IF ( IMTYPE.EQ.2 ) THEN<br>
WRITE(30,1120)<br>
ELSE IF ( IMTYPE.EQ.3 ) THEN<br>
WRITE(30,1130)<br>
ENDIF<br>
WRITE(30,1200)DBM*1000.0,WBM*1000.0<br>
C<br>
IF ( IBTYPE.EQ.0 ) THEN<br>
WRITE(30,1140)<br>
ELSE IF ( IBTYPE.EQ.1 ) THEN<br>
WRITE(30,1150)<br>
ELSE IF ( IBTYPE.EQ.2 ) THEN<br>
WRITE(30,1160)<br>
ELSE IF ( IBTYPE.EQ.3 ) THEN<br>
WRITE(30,1170)<br>
ENDIF<br>
WRITE(30,1200)DBB*1000.0,WBB*1000.0<br>
C<br>
IF ( ICTYPE.EQ.1 ) THEN<br>
WRITE(30,1300)<br>
ELSE IF ( ICTYPE.EQ.2 ) THEN<br>
WRITE(30,1310)<br>
ELSE IF ( ICTYPE.EQ.3 ) THEN<br>
WRITE(30,1320)<br>
ELSE IF ( ICTYPE.EQ.4 ) THEN<br>
WRITE(30,1330)<br>
ELSE IF ( ICTYPE.EQ.5 ) THEN<br>
WRITE(30,1340)<br>
ENDIF<br>
IF ( IFTYPE.EQ.1 ) THEN<br>
WRITE(30,1400)<br>
ELSE IF ( IFTYPE.EQ.2 ) THEN<br>
WRITE(30,1410)<br>
ENDIF<br>
WRITE(30,1500)NVAL/NCYL,XLIFT*1000.0<br>
IF ( ICTYP2.EQ.0 ) THEN <br>
WRITE (30,1540)<br>
ELSE IF ( ICTYP2.EQ.1 ) THEN<br>
WRITE (30,1550) <br>
ENDIF<br>
WRITE (30,1200) DCM*1000.0, WCM*1000.0<br>
C<br>
WRITE(30,1560)FLOAD<br>
C<br>
WRITE(30,1600)<br>
WRITE(30,1700)<br>
WRITE(30,1710)<br>
C<br>
C --- Start of calculations<br>
C<br>
DO 100 I=1,100 <br>
C<br>
C --- Increment engine speed <br>
RPM = START + (I-1)*SINC<br>
C --- Jump out if greater than max speed<br>
IF ( RPM .GT. SEND )GO TO 200<br>
C<br>
C --- Calc rps and mean piston speed <br>
RPS = RPM/60.0<br>
SPM = 2*RPS*STOK<br>
C <br>
C --- ROTATING FRICTION<br>
C<br>
C --- Main bearing seal term (PA)<br>
AROFT = 1.22E+5 * 1.0E-6 * 1000.0 * <br>
&gt; ( DBM / ( (BORE**2) * STOK * FLOAT(NCYL) ) )<br>
C --- Main bearing hydrodynamic lubrication (PA)<br>
C comparision with bears shows that this term need an<br>
C additional load factor which is proportional to <br>
C bore area / bearing area - the 0.51 is the fiddle factor<br>
BMLOAD = 0.65 * (BORE*BORE*FLOAT(NCYL))/(DBM*WBM*FLOAT(NBM)) <br>
BROFT = 3.03E-4 * 1.0E+3 * 1000.0 * RFACT(1) * BMLOAD * <br>
&gt; ( RPM * (DBM**3) * WBM * FLOAT(NBM) ) / <br>
&gt; ( (BORE**2) * STOK * FLOAT(NCYL) )<br>
C --- Turbulent dissipation to pump fluids (PA) <br>
CROFT = 1.35E-10 * 1.0E+6 * 1000.0 *<br>
&gt; ( (DBM**2) * (RPM**2) * FLOAT(NBM)/FLOAT(NCYL) )<br>
C --- Total rotating friction (BAR)<br>
ROTF = FFACT(1) * 1.0E-5 * ( AROFT + BROFT + CROFT )<br>
C <br>
C --- RECIPORTATING FRICTION<br>
C<br>
C --- Piston friction (hydrodynamic lubrication) (pa)<br>
ARECIP = 2.94E+2 * 1.0E-3 * 1000.0 * SPM / BORE<br>
C --- Ring friction without gas load (pa)<br>
BRECIP = 4.06E+4 * 1.0E-6 * 1000.0 * <br>
&gt; ( 1 + 1000/RPM ) / (BORE**2)<br>
C --- Ring friction with gas load (pa)<br>
C note FLOAD is used in stead of PI/PA inlet pres/atmos pres<br>
B2RECIP = 6.89 * 1000.0 * FLOAD *<br>
&gt; (0.088*CR + 0.182*(CR**(1.33-2.38E-2*SPM)))<br>
C --- Big end bearings (Hydrodynamic lubrication) (pa)<br>
C again add load factor <br>
BBLOAD = 0.219 * BORE * BORE / ( DBB*WBB ) <br>
CRECIP = 3.03E-4 * 1.0E+3 * 1000.0 * RFACT(2) * BBLOAD * <br>
&gt; ( RPM * (DBB**3) * WBB * FLOAT(NBB) ) /<br>
&gt; ( (BORE**2) * STOK * FLOAT(NCYL) )<br>
C --- Total Recriprocating friction (BAR)<br>
RECIPF = FFACT(2) * 1.0E-5<br>
&gt; * ( ARECIP + BRECIP + B2RECIP + CRECIP )<br>
C<br>
C ---- VALVE TRAIN FRICTION **** DONT LIKE THIS ******<br>
C<br>
C --- Cam bearing hydrodynamic lubrication (PA)<br>
C Note 1 paper does not make clear whether constant refers to <br>
C engine speed or cam speed assume engine speed<br>
C Note 2 the constant in the paper looks wrong <br>
C have decided to use the mains constant and correct speed <br>
C Note 3 checked against cubs and found bearing friction <br>
C correction factor = 2.12<br>
C<br>
AVALVEF = 3.03E-4 * 1000.0 * 0.5 * 2.12 * 1000.0 * RFACT(3) *<br>
&gt; ( RPM * (DCM**3) * WCM * FLOAT(NBM*NCS) ) / <br>
&gt; ( (BORE**2) * STOK * FLOAT(NCYL) )<br>
C AVALVEF = 4120 + 2.44E+2 * 1000.0 * 1.0E-9 * RPM * NBM /<br>
C &gt; ( (BORE**2) * STOK * FLOAT(NCYL) )<br>
C ---- Cam friction between cam and follower(PA)<br>
C first term is for flat follower and second is roller<br>
C modified so that relationship is with flat follower diamater<br>
C assume follower dia = 4 X max lift<br>
C bore = 2.3 x follower diameter<br>
C hence BORE*BORE = 4x4x2.5x2.5xXLIFTxXLIFT<br>
BVALVEF = 1.0E-3 * 1000.0 * <br>
&gt; ( CFF*(1+1000/RPM)*FLOAT(NVAL)*XLIFT*XLIFT*100.0<br>
&gt; /(BORE*BORE*STOK*FLOAT(NCYL)) + <br>
&gt; CRF*(RPM*FLOAT(NVAL)/(STOK*FLOAT(NCYL) ) ) )<br>
C BVALVEF = 1.0E-3 * 1000.0 * <br>
C &gt; ( CFF*(1+1000/RPM)*FLOAT(NVAL)/(STOK*FLOAT(NCYL)) + <br>
C &gt; CRF*(RPM*FLOAT(NVAL)/(STOK*FLOAT(NCYL) ) ) )<br>
C ---- Valve train oscillatory friction (PA)<br>
CVALVEF = 1000.0 * <br>
&gt; ( ( COH * ((XLIFT*1000.0)**1.5) * (RPM**.5) * <br>
&gt; FLOAT(NVAL) / (BORE * STOK * NCYL * 1.0E+6 ) ) +<br>
&gt; ( COM * ( 1 + 1000/RPM ) * XLIFT * FLOAT(NVAL) / <br>
&gt; ( STOK * FLOAT(NCYL) ) ) )<br>
C --- Total valve train friction (BAR)<br>
VTF = FFACT(3) * 1.0E-5 * ( AVALVEF + BVALVEF + CVALVEF )<br>
C <br>
C ---- AUXILLARY FRICTION (BAR)<br>
C origional model <br>
C AUXF = 1000.0 * 1.0E-5 * FFACT(4) *<br>
C &gt; ( 6.23 + 5.22E-3*RPM - 1.79E-7*RPM*RPM ) <br>
C malcolm model with swept volume term <br>
ACONST = 15.0/(VSWEPT*1.E+3)<br>
IF ( ACONST.LT.0.5 ) ACONST=0.5<br>
AUXF = 1000.0 * 1.0E-5 * FFACT(4) *<br>
&gt; ( ACONST + 3.0E-3*RPM - 1.0E-7*RPM*RPM ) <br>
C <br>
C ---- TOTAL FRICTION (BAR)<br>
TOTF(I) = ROTF + RECIPF + VTF + AUXF<br>
C<br>
C ---- Now calc friction using HONDA equation <br>
C<br>
C ---- Calc mwan equivalant crank diameter <br>
CMD = ( DBM*FLOAT(NBM) + DBB*FLOAT(NBB) ) / FLOAT ( NBM + NBB )<br>
C ---- Non dimensional engine number <br>
RSDOB = SQRT ( STOK * CMD ) / BORE<br>
C ---- Calc pmf star <br>
C assume mean flow/ bore area = 0.1 and oil visc = 15 cst<br>
FLBAR = 0.1<br>
CST = 15<br>
PMFPS = 10.0 * ( (60E-9*STOK*FLBAR + 1.1E-9)*RPM*RPM <br>
&gt; + 0.0011*CST + 0.14 )<br>
C ---- Scale with non dimensional engine number <br>
HONDA(I) = PMFPS*RSDOB<br>
C ---- Modified honda <br>
HONDAM(I) = ( 2.5E-8 * RPM * RPM +<br>
&gt; 1.0E-4 * RPM + 1.1 ) * RSDOB<br>
C<br>
C ---- Friction by H.B.Moss<br>
HBMF(I) = 0.6 + 1.167E-4*RPM + 0.06*SPM<br>
C<br>
C ---- Friction by Millington &amp; Hartles<br>
FMAH(I) = ( ( CR - 4.0 )/ 14.5 ) + ( 0.48275*RPM/1000.0 )<br>
C<br>
C ---- Chen anf Flynn (pmax = 70 bar)<br>
CAFF(I) = 0.138 + 0.005*70 + 0.163*SPM <br>
C<br>
C ---- Store engine speed <br>
SPEED(I) = RPM <br>
C<br>
NS = I<br>
C<br>
WRITE(30,1800)RPM,ROTF,RECIPF,VTF,AUXF,TOTF(I)<br>
C<br>
100 CONTINUE<br>
C<br>
PRINT*,' Warning more than 100 speeds requested SMAX not reached'<br>
C<br>
200 CONTINUE<br>
WRITE(30,1005)<br>
WRITE(30,1900)<br>
WRITE(30,1910)<br>
WRITE(30,1920)<br>
DO 250 I = 1, NS<br>
FMEAN = ( HBMF(I)+FMAH(I)+HONDAM(I)+HONDA(I)+TOTF(I) ) / 5.0<br>
WRITE(30,1930) SPEED(I),HBMF(I), FMAH(I), TOTF(I), <br>
&gt; HONDA(I), HONDAM(I), FMEAN<br>
250 CONTINUE <br>
WRITE(30,1005)<br>
CLOSE(20)<br>
CLOSE(30)<br>
C<br>
C---- Format Statements<br>
C<br>
1000 FORMAT(3X,76('='))<br>
1005 FORMAT(3X,76('='))<br>
1001 FORMAT(1H1)<br>
1002 FORMAT(' ')<br>
1010 FORMAT(3X, 14X,'LOTUS ENGINE FRICTION PROGRAM - FRIC ')<br>
1030 FORMAT(3X,33X,'INPUT DATA',/,3X,33X,10('~'))<br>
1040 FORMAT(3X,8X,A)<br>
1060 FORMAT(3X,2X,'Bore . . . . . . . . .',F9.2,' mm',<br>
&gt; 4X,'Stroke . . . . . . . .',F9.2,' mm',/,<br>
&gt; 3X,2X,'Compression Ratio . .',F9.2,' ',/,<br>
&gt; 3X,2X,'No. of Cylinders . . .',I7,5X,<br>
&gt; 4X,'No. of Main Bearings .',I7,5X )<br>
C<br>
1100 FORMAT(/,5X,'Main Bearing Dimensions ',<br>
&gt; 13X,' User Specified Dimensions') <br>
1110 FORMAT(/,5X,'Main Bearing Dimensions ',<br>
&gt; 13X,' Default for Inline Engine') <br>
1120 FORMAT(/,5X,'Main Bearing Dimensions ',<br>
&gt; 13X,' Default for Vee One rod/thro Engine') <br>
1130 FORMAT(/,5X,'Main Bearing Dimensions ',<br>
&gt; 13X,' Default for Vee Two rod/thro Engine') <br>
C<br>
1140 FORMAT(/,5X,'Big End Bearing Dimensions ',<br>
&gt; 10X,' User Specified Dimensions') <br>
1150 FORMAT(/,5X,'Big End Bearing Dimensions ',<br>
&gt; 10X,' Default for Inline Engine') <br>
1160 FORMAT(/,5X,'Big End Bearing Dimensions ',<br>
&gt; 10X,' Default for Vee One rod/thro Engine') <br>
1170 FORMAT(/,5X,'Big End Bearing Dimensions ',<br>
&gt; 10X,' Default for Vee Two rod/thro Engine') <br>
C<br>
1200 FORMAT(3X,2X,'Bearing Diameter . . .',F9.2,' mm',<br>
&gt; 4X,'Bearing Width. . . . .',F9.2,' mm') <br>
C<br>
1300 FORMAT(/,5X,'Valve Gear ',<br>
&gt; 10X,' OHV Pushrod with Rocker') <br>
1310 FORMAT(/,5X,'Valve Gear ',<br>
&gt; 10X,' DOHC with Direct Acting Follower') <br>
1320 FORMAT(/,5X,'Valve Gear ',<br>
&gt; 10X,' SOHC with Direct Acting Follower') <br>
1330 FORMAT(/,5X,'Valve Gear ',<br>
&gt; 10X,' SOHC with Rocker Arm') <br>
1340 FORMAT(/,5X,'Valve Gear ',<br>
&gt; 10X,' SOHC with Finger Follower') <br>
C<br>
1400 FORMAT(5X,'Flat Follower ')<br>
1410 FORMAT(5X,'Roller Follower ')<br>
C<br>
1500 FORMAT(3X,2X,'Number of Valves/Cyl .',I7,5X, <br>
&gt; 4X,'Maximum Valve Lift . .',F9.2,' mm') <br>
1540 FORMAT(/,5X,'Cam Bearing Dimensions ',<br>
&gt; 10X,' User Specified Dimensions') <br>
1550 FORMAT(/,5X,'Cam Bearing Dimensions ',<br>
&gt; 10X,' Default Dimensions ') <br>
1560 FORMAT(/3X,2X,'Load Fraction . . . .',F9.2 ) <br>
C<br>
1600 FORMAT(/3X,'Results',/,3X,7('~'))<br>
C<br>
1700 FORMAT(/1X,'Engine Speed Rotating Recip. ',<br>
&gt; 'Valve Train Auxilary Total ' )<br>
1710 FORMAT( 1X,' (RPM) (Bar) (Bar) ',<br>
&gt; ' (Bar) (Bar) (Bar) ')<br>
1800 FORMAT(2X,F6.0,3X,2(1X,G11.4),1X,G10.4,<br>
&gt; 1X,G11.4,1X,G10.4,1X,G10.4)<br>
1810 FORMAT(1X,F6.0,7G9.4)<br>
C<br>
1900 FORMAT(/3X,2X,'Comparision of Friction Models ')<br>
1910 FORMAT(/1X,'Engine Speed H.B.MOSS M &amp; H ',<br>
&gt; 'Pat.&amp;Hey Honda Mod.Honda Mean ' )<br>
1920 FORMAT( 1X,' (RPM) (Bar) (Bar) ',<br>
&gt; ' (Bar) (Bar) (Bar) (Bar) ')<br>
1930 FORMAT(2X,F6.0,3X,2(1X,G11.4),1X,G10.4,<br>
&gt; 1X,G11.4,1X,G10.4,1X,G10.4,1X,G10.4)<br>
C<br>
STOP<br>
END<br>
C************************************************************<br>
C END OF ROUTINE<br>
C************************************************************<br>
SUBROUTINE DCSTR1 ( STR, ITYP, IV, RV, SSTR, N, MXN ) <br>
C <br>
C This Routine deciminates the string STR into arrays <br>
C of INTEGER = IV, REAL = RV, STRING = SSTR <br>
C N is returned as the number of elements returned in the array <br>
C and MXN is given as the max possible no of elements in array <br>
C <br>
CHARACTER*1 SPACE, COMMA, SCOLON <br>
CHARACTER*2 QUOTES <br>
CHARACTER*4 TERMS <br>
CHARACTER*16 NUMS <br>
CHARACTER*13 INTS <br>
C <br>
PARAMETER ( SPACE =' ', COMMA=',', SCOLON=';') <br>
PARAMETER ( QUOTES='''&quot;' ) <br>
PARAMETER ( TERMS =' ,;&lt;TAB&gt;' ) <br>
PARAMETER ( NUMS ='0123456789.-+ED ') <br>
PARAMETER ( INTS ='0123456789-+ ') <br>
C <br>
DOUBLE PRECISION RMAX1, RMINI <br>
C <br>
PARAMETER ( RMAX1=(2.0**31 - 1), RMINI=-(2.0**31) ) <br>
C <br>
C *** DUMMY ARGUMENTS <br>
C <br>
CHARACTER*(*) STR <br>
CHARACTER*(*) SSTR(MXN) <br>
C <br>
INTEGER ITYP(MXN), IV(MXN) <br>
REAL RV(MXN) <br>
C <br>
C *** LOCAL VARIABLES <br>
C <br>
CHARACTER*1 CH, LT, SQ <br>
CHARACTER*3 W <br>
LOGICAL Q, S, NS, IS, END <br>
DOUBLE PRECISION RVAL <br>
C <br>
C *** STATEMENT FUNCTIONS <br>
C <br>
LOGICAL TERM, QUOTE, NUMBER, INTEGR, ETERM, EREAD <br>
C <br>
TERM(CH) = ( INDEX ( TERMS, CH ).NE. 0 ) <br>
QUOTE(CH) = ( INDEX ( QUOTES, CH ).NE. 0 ) <br>
NUMBER(CH)= ( INDEX ( NUMS, CH ).NE. 0 ) <br>
INTEGR(CH)= ( INDEX ( INTS, CH ).NE. 0 ) <br>
ETERM(CH) = ( CH .EQ. SPACE ) <br>
EREAD(J) = ( ( (L-1).EQ.(J-1)) .OR. TERM( STR(I+J:I+J) ) ) <br>
C <br>
C *** BEGIN <br>
C <br>
L = LENSTR( STR ) <br>
C <br>
C *** INITIALISE OUTPUT ARRAYS AND WORKING VALUES <br>
C <br>
DO 10 I = 1, MXN <br>
ITYP(I)= 0 <br>
IV(I) = 0 <br>
RV(I) = 0.0 <br>
SSTR(I)= SPACE <br>
10 CONTINUE <br>
C <br>
END = .FALSE. <br>
S = .FALSE. <br>
Q = .FALSE. <br>
LT = COMMA <br>
N = 0 <br>
IL = 0 <br>
I = 0 <br>
C <br>
C *** IF STRING EMPTY RETURN <br>
C <br>
IF ( L.EQ.0 ) RETURN <br>
C <br>
C *** CHARACTER PROCESSING LOOP STARTS HERE <br>
C <br>
20 CONTINUE <br>
C <br>
C *** ADD 1 TO CHARACTER POINTER <br>
C <br>
I = I + 1 <br>
C <br>
IF ( I.GT.L ) THEN <br>
C *** HAVE REACHED END OF STRING <br>
END = .TRUE. <br>
CH = SPACE <br>
ELSE <br>
C *** THERE ARE MORE CHARACTERS IN STRING <br>
CH = STR(I:I) <br>
ENDIF <br>
C <br>
IF ( Q ) THEN <br>
C <br>
C *** CURRENTLY PASSING A QUOTE STRING <br>
C <br>
IF ( END.OR.(CH.EQ.SQ) ) THEN <br>
C *** THIS IS END OF IT <br>
Q = .FALSE. <br>
N = N+1 <br>
LT= SPACE <br>
C <br>
IF ( N.LE.MXN ) THEN <br>
C *** THERE IS ROOM TO STORE IT <br>
ITYP(N) = IB-I <br>
SSTR(N) = STR( IB:IL ) <br>
ENDIF <br>
C <br>
ENDIF <br>
C <br>
ELSE IF ( S ) THEN <br>
C <br>
C *** WE ARE PROCESSING NORMAL STRING <br>
C <br>
IF ( END.OR.TERM(CH) ) THEN <br>
C *** THIS IS THE END OF IT <br>
S = .FALSE. <br>
N = N+1 <br>
LT = CH <br>
IT = 0 <br>
C *** ASSUME NULL TYPE ( STRING REALLY ) <br>
IF ( CH .EQ. SCOLON ) END=.TRUE. <br>
C <br>
IF ( NS ) THEN <br>
C *** WE WILL TRY TO INTERPRET STRING AS A NUMBER <br>
WRITE(W,'(I3)') I-IB <br>
C <br>
IF ( IS ) THEN <br>
C *** TRY INTEGER READ FIRST <br>
IOS=0 <br>
READ(STR(IB:IL),'(I'//W//')',IOSTAT=IOS) IVAL <br>
ELSE <br>
IOS=-1 <br>
ENDIF <br>
C <br>
IF ( IOS.EQ.0 ) THEN <br>
C *** INTEGER READ GOOD <br>
IT = 1 <br>
ELSE <br>
C *** INTEGER READ FAILED TRY FORMAT <br>
IOS = 0 <br>
READ(STR(IB:IL),'(F'//W//'.0)',IOSTAT=IOS) RVAL <br>
C <br>
IF (IOS.EQ.0) THEN <br>
C *** REAL READ WAS GOOD <br>
IT = 2 <br>
C *** ASSUME INTEGER RANGE FOR THE MOMENT <br>
ELSE <br>
C *** REAL READ FAILED TRY E FORMAT <br>
C *** READ INCLUDING THE TERMINATOR AND THE NEXT ONE <br>
C *** OR TWO CHARS <br>
C *** FOR ANY CHANCE OF SUCESS THE CURRENT TERMINATOR <br>
C *** MUST BE A SPACE AND THE SECOND OR THIRD CHARACTER <br>
C *** MUST BE A TERMINATOR <br>
C <br>
IF (.NOT.END .AND. ETERM(LT) .AND..NOT.IS ) THEN <br>
IE=0 <br>
IF ( EREAD(2) ) THEN <br>
IE=2 <br>
ELSE IF ( EREAD(3) ) THEN <br>
IE=3 <br>
ENDIF <br>
C <br>
IF (IE.NE.0) THEN <br>
C *** TRY READING WITH E FORMAT <br>
WRITE(W,'(I3)')(I-IB)+IE <br>
IOS=0 <br>
READ(STR(IB:IL+IE), <br>
&gt; '(E'//W//'.0)',IOSTAT=IOS) RVAL <br>
IF (IOS.EQ.0) THEN <br>
C *** E FORMAT READ GOOD <br>
IT = 2 <br>
I = I+IE <br>
IL = I-1 <br>
IF (I.GT.L) END =.TRUE. <br>
IF ( END) LT= SPACE <br>
IF (.NOT.END) LT= STR(I:I) <br>
IF (LT.EQ.SCOLON) END = .TRUE. <br>
ENDIF <br>
ENDIF <br>
ENDIF <br>
ENDIF <br>
ENDIF <br>
ENDIF <br>
C <br>
IF (N.LE.MXN) THEN <br>
C *** THERE IS ROOM TO STORE ENTITY <br>
IF ( IT.GT.0 ) THEN <br>
C *** NUMERIC VALUE FOUND <br>
IF ( IT.EQ.1 ) THEN <br>
C *** IT WAS AN INTEGER <br>
RVAL = FLOAT ( IVAL ) <br>
C <br>
ELSE <br>
C *** IT WAS A REAL. GET THE NEAREST INTEGER VALUE <br>
C *** IF THAT WAS NOT TOO BIG <br>
IF ( (RVAL.LE.RMAXI) <br>
&gt; .AND.(RVAL.GE.RMINI) ) THEN <br>
IVAL = NINT(RVAL) <br>
ELSE <br>
C *** THE VALUE IS OUTSIDE INTEGER RANGE <br>
IVAL=0 <br>
IT = 3 <br>
ENDIF <br>
C <br>
ENDIF <br>
C <br>
ITYP(N) = IT <br>
IV(N) = IVAL <br>
RV(N) = RVAL <br>
SSTR(N) = STR(IB:IL) <br>
C <br>
ELSE <br>
C *** NUMERIC VALUE NOT FOUND <br>
ITYP(N) = IB-1 <br>
SSTR(N) = STR(IB:IL) <br>
ENDIF <br>
ENDIF <br>
C <br>
ELSE <br>
C *** IT IS NOT THE END OF THE SUBSTRING <br>
C *** CHECK IF CURRENT CHARACTER IS NUMERIC <br>
IF ( .NOT.NUMBER(CH) ) NS=.FALSE. <br>
IF ( .NOT.INTEGR(CH) ) IS=.FALSE. <br>
ENDIF <br>
C <br>
ELSE <br>
C *** WE ARE NOT PROCESSING A STRING <br>
IF ( END.OR.(CH.EQ.SCOLON)) THEN <br>
C *** THIS IS THE END <br>
END = .TRUE. <br>
C *** A FINAL COMMA INDICATES AN ADDITIONAL NULL ARGUEMENT <br>
C IF (LT.EQ.COMMA) N=N+1 <br>
C <br>
ELSE <br>
C *** THIS IS NOT THE END <br>
IF ( TERM(CH) ) THEN <br>
C *** THIS IS NOT THE START OF A NEW STRING <br>
IF (CH.EQ.COMMA) THEN <br>
C *** IF THE LAST CHARACTER WAS A COMMA <br>
C *** THIS REPRESENTS A NULL ENTITY <br>
IF ( LT.EQ.COMMA ) N=N+1 <br>
LT = COMMA <br>
C *** LAST TERMINATOR IS NOW A COMMA <br>
ENDIF <br>
ELSE <br>
C *** MUST BE START OF NEW ENTITY <br>
IF ( QUOTE(CH) ) THEN <br>
Q = .TRUE. <br>
IB = I+1 <br>
SQ = CH <br>
C *** &lt;SQ&gt; IS STARTING HERE <br>
ELSE <br>
C *** NORMAL STRING <br>
S = .TRUE. <br>
NS = NUMBER(CH) <br>
IS = INTEGR(CH) <br>
IB = I <br>
ENDIF <br>
ENDIF <br>
ENDIF <br>
ENDIF <br>
C <br>
IF ( END ) RETURN <br>
C *** IF THE END RETURN <br>
IL = I <br>
C *** &lt;IL&gt; IS THE LAST CHARACTER PROCESSED <br>
GO TO 20 <br>
C *** GO AND DEAL WITH NEXT CHARACTER <br>
C *** END <br>
END <br>
C <br>
C ********* END OF ROUTINE *********************** <br>
C <br>
FUNCTION LENSTR(STR) <br>
C <br>
C This Function finds the Characters to the <br>
C The end of a character string <br>
C <br>
CHARACTER*(*)STR <br>
LENS=LEN(STR) <br>
C <br>
DO 50 I=LENS,1,-1 <br>
IF (STR(I:I).NE.' ')GO TO 60 <br>
50 CONTINUE <br>
C <br>
LENSTR=0 <br>
RETURN <br>
C <br>
60 CONTINUE <br>
C <br>
LENSTR=I <br>
RETURN <br>
C <br>
END <br>
C <br>
C ********* END OF ROUTINE *********************** <br>
C<font size="2"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><b><font size="4">Data Checking Wizard <br>
</font></b><font size="2">Overview<br>
</font><font face="Times New Roman"><br>
<font face="Arial">The data checking wizard provides a tool that allows the user to check the validity the current data. A large number of checks are performed and a list is given for each data section, of the number of <i>Errors, Warnings </i></font></font>and<i> Comments </i>found in the current data. A message is given for each item in the list that identifies the particular data variable at <font face="Times New Roman"><font face="Arial">fault</font></font><font face="Times New Roman"><font face="Arial">.<br>
<br>
The data checking wizard is run in one of two modes, either directly as a interactive window, or indirectly as a summary message dialogue.<br>
</font></font><br>
The data checking wizard is run directly through the menu item <u>Tools</u> / <u>Data-check Wizard</u>. This displays a window that shows the list of messages in a scrollable text region adjacent to the appropriate data section icon.<br>
<br>
The data checking wizard is run indirectly every time a calculation is performed, the data values are checked and if any discrepancies identified a simple summary of the number of errors, warnings and comments is displayed.<br>
<br>
{button ,AL(`list4',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Data Checking Fail Types<br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">Three fail types are used within the data checker, being <i>Error, Warning</i></font></font></font> and <i>Comment</i>. Due to the complexity of the data requirements and the inter dependency it is not always clear cut as to the appropriateness of a particular value or flag setting. Some solution types will use different data values and thus adds further vagaries to their validity. <br>
<br>
The first category of <i>Error</i> is used when a data value(s) or type is felt to be in error in all possible scenarios. Typical examples of this are failure to enter a value for a compulsory variable, or incorrectly entered, negative or out of range numbers.<br>
<br>
The second category of <i>Warning</i> is used when a data value(s) or type is considered incorrect or not set, but that in some solution cases is not used and could therefore be acceptable. Typical examples of this are when a data value is not entered and therefore contains a zero value. <br>
<br>
The third category of <i>C</i>omment is used when a data value(s) is outside of the normal range. Where appropriate a data value will have a minimum and maximum value that set this normal range. Currently only the default set of ranges is available, but it is envisaged that later releases will also employ a user definable set of ranges.<br>
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{button ,AL(`list4',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Opening the Data Checking Wizard <br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To open the data checking wizard select the menu <u>Tools</u></font></font></font> / <u>Data-check Wizard</u> from the main window menubar. Alternatively the <u>Data Checking Icon</u> can be selected.Whilst the wizard is open the icon remains indented and the pull down menu item is <font face="Times New Roman"><font face="Arial">ticked</font></font><font face="Times New Roman"><font face="Arial">.<br>
<br>
When the wizard is initially opened, it checks the current data for discrepancies. Any that are found are identified by either the <u>question mark</u></font></font> or <u>cross</u> icons being displayed next to the scrollable text region for that data section. Data sections being identified by their appropriate icon. If no discrepancies have been identified in a data section the <u>tick</u> icon is displayed.<br>
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{button ,AL(`list4',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Closing the Data Checking Wizard <br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To close the data checking wizard select either the </font></font></font><font face="Times New Roman"><font face="Arial">close</font></font><font face="Times New Roman"><font face="Arial"> icon at the top right corner of the wizard window, the wizard window menu at the top left, the menu item <u>Functions</u></font></font> / <u>Close</u> from the wizard menubar, or alternatively the <u>Data Checking Icon</u> can be un-selected.<b><br>
</b><br>
{button ,AL(`list4',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Jumping to the Data Windows <br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">The <u>data icons</u></font></font></font> down the side of the data checking wizard can be used to open the data window for that data section, by simply selecting the required icon.<br>
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{button ,AL(`list4',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Updating the Data Checking Wizard Display<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">If the data checking wizard window has been left open whilst changes have been made to data, its display will potentially no longer reflect the true No. of errors, warnings and comments. To update the display select <u>Functions</u></font></font></font> / <u>Update</u> from the wizard menubar. The current data will then be checked and the wizard display updated. <br>
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{button ,AL(`list4',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">The Default Data Checking Wizard Ranges<br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">The following lists the default ranges for data values, used in the data checking wizard. Values outside of these ranges result in a <i>Comment</i></font></font></font> entry.<br>
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<table border="2">
<tr><td>Vehicle Data</td>
</tr>
<tr><td><div align="right">
Test Weight</td>
</div>
</div>
<td><center>kg</td>
</center>
<td><center>500</td>
</center>
<td><center>25000</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Wheelbase</td>
</div>
</div>
<td><center>m</td>
</center>
<td><center>0.5</td>
</center>
<td><center>25</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Front track</td>
</div>
</div>
<td><center>m</td>
</center>
<td><center>0.5</td>
</center>
<td><center>25</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Rear Track</td>
</div>
</div>
<td><center>m</td>
</center>
<td><center>0.5</td>
</center>
<td><center>25</td>
</tr>
</center>
</center>
<tr><td><div align="right">
C of G Distance</td>
</div>
</div>
<td><center>m</td>
</center>
<td><center>-25</td>
</center>
<td><center>25</td>
</tr>
</center>
</center>
<tr><td><div align="right">
C of G Height</td>
</div>
</div>
<td><center>m</td>
</center>
<td><center>-25</td>
</center>
<td><center>25</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Frontal Area</td>
</div>
</div>
<td><center>m2</td>
</center>
<td><center>0.25</td>
</center>
<td><center>250</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Drag Coeff</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0</td>
</center>
<td><center>10</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Plan Area</td>
</div>
</div>
<td><center>m2</td>
</center>
<td><center>0</td>
</center>
<td><center>250</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Front Lift Coeff</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>-10</td>
</center>
<td><center>10</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Rear Lift Coeff</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>-10</td>
</center>
<td><center>10</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Air Density</td>
</div>
</div>
<td><center>kg/m3</td>
</center>
<td><center>1.0</td>
</center>
<td><center>1.5</td>
</tr>
</center>
<br>
<tr><td>Dynamometer Data</td>
</tr>
<tr><td><div align="right">
Inertia Class</td>
</div>
</div>
<td><center>kg</td>
</center>
<td><center>0</td>
</center>
<td><center>6000</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Constant</td>
</div>
</div>
<td><center>N</td>
</center>
<td><center>0</td>
</center>
<td><center>1000</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Velocity Term</td>
</div>
</div>
<td><center>N/m/s</td>
</center>
<td><center>-100</td>
</center>
<td><center>100</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Velocity2 Term</td>
</div>
</div>
<td><center>N/m2/s2</td>
</center>
<td><center>-10</td>
</center>
<td><center>10</td>
</tr>
</center>
<br>
<tr><td>Tyre Data</td>
</tr>
<tr><td><div align="right">
Rolling Radius</td>
</div>
</div>
<td><center>m</td>
</center>
<td><center>0.1</td>
</center>
<td><center>5</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Drive Efficiency</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0.5</td>
</center>
<td><center>1</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Coeff of Slip</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0.1</td>
</center>
<td><center>1.5</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Constant</td>
</div>
</div>
<td></td>
</center>
<td><center>0</td>
</center>
<td><center>1000</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Velocity Term</td>
</div>
</div>
<td></td>
</center>
<td><center>-10</td>
</center>
<td><center>10</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Velocity2 Term</td>
</div>
</div>
<td></td>
</center>
<td><center>-1</td>
</center>
<td><center>1</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Velocity3 Term</td>
</div>
</div>
<td></td>
</center>
<td><center>-0.1</td>
</center>
<td><center>0.1</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Velocity4 Term</td>
</div>
</div>
<td></td>
</center>
<td><center>-0.01</td>
</center>
<td><center>0.01</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Velocity5 Term</td>
</div>
</div>
<td></td>
</center>
<td><center>-0.001</td>
</center>
<td><center>0.001</td>
</tr>
</center>
<br>
<tr><td>Driveline Data - Clutch or Torque Converter</td>
</tr>
<tr><td><div align="right">
Declutch Speed</td>
</div>
</div>
<td><center>km/h</td>
</center>
<td><center>0</td>
</center>
<td><center>50</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Speed ratio</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0</td>
</center>
<td><center>1</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Torque Ratio</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0</td>
</center>
<td><center>5</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Input Capacity</td>
</div>
</div>
<td><center>rad/s/Nm</td>
</center>
<td><center>0</td>
</center>
<td><center>200</td>
</tr>
</center>
<br>
<tr><td>Driveline Data - Torque Converter Idle Speed</td>
</tr>
<tr><td><div align="right">
Speed Ratio</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0</td>
</center>
<td><center>2</td>
</tr>
</center>
<br>
<tr><td>Driveline Data - Final Drive</td>
</tr>
<tr><td><div align="right">
Front Wheel Inertia</td>
</div>
</div>
<td><center>kg.m2</td>
</center>
<td><center>0</td>
</center>
<td><center>2</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Rear Wheel Inertia</td>
</div>
</div>
<td><center>kg.m2</td>
</center>
<td><center>0</td>
</center>
<td><center>2</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Drive Shaft Inertia</td>
</div>
</div>
<td><center>kg.m2</td>
</center>
<td><center>0</td>
</center>
<td><center>2</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Propshaft Inertia</td>
</div>
</div>
<td><center>kg.m2</td>
</center>
<td><center>0</td>
</center>
<td><center>2</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Final Drive Ratio</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>1</td>
</center>
<td><center>5</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Final Drive Eff.</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0.5</td>
</center>
<td><center>1</td>
</tr>
</center>
<br>
<tr><td>Gearbox Data - Gearbox Specification</td>
</tr>
<tr><td><div align="right">
Max. Input Torque</td>
</div>
</div>
<td><center>Nm</td>
</center>
<td><center>0</td>
</center>
<td><center>500</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Max. Input Speed</td>
</div>
</div>
<td><center>rpm</td>
</center>
<td><center>0</td>
</center>
<td><center>12000</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Gear Ratio</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0</td>
</center>
<td><center>6</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Gear Efficiency</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0.5</td>
</center>
<td><center>1</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Gear Inertia</td>
</div>
</div>
<td><center>kg.m2</td>
</center>
<td><center>0.00005</td>
</center>
<td><center>1</td>
</tr>
</center>
<br>
<tr><td>Gearbox Data - Gear Losses</td>
</tr>
<tr><td><div align="right">
Speed</td>
</div>
</div>
<td><center>rpm</td>
</center>
<td><center>500</td>
</center>
<td><center>12000</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Load Fraction</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0</td>
</center>
<td><center>1</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Torque Loss</td>
</div>
</div>
<td><center>Nm</td>
</center>
<td><center>0.002</td>
</center>
<td><center>50</td>
</tr>
</center>
<br>
<tr><td>Engine Data - Engine</td>
</tr>
<tr><td><div align="right">
Bore</td>
</div>
</div>
<td><center>mm</td>
</center>
<td><center>20</td>
</center>
<td><center>200</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Stroke</td>
</div>
</div>
<td><center>mm</td>
</center>
<td><center>20</td>
</center>
<td><center>200</td>
</tr>
</center>
</center>
<tr><td><div align="right">
No. of Cylinders </td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>1</td>
</center>
<td><center>20</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Idle Speed</td>
</div>
</div>
<td><center>rpm</td>
</center>
<td><center>300</td>
</center>
<td><center>4000</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Maximum Speed</td>
</div>
</div>
<td><center>rpm</td>
</center>
<td><center>1000</td>
</center>
<td><center>12000</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Engine Inertia</td>
</div>
</div>
<td><center>kg.m2</td>
</center>
<td><center>0.001</td>
</center>
<td><center>1</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Engine Speed</td>
</div>
</div>
<td><center>rpm</td>
</center>
<td><center>500</td>
</center>
<td><center>12000</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Engine Torque</td>
</div>
</div>
<td><center>Nm</td>
</center>
<td><center>10</td>
</center>
<td><center>1000</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Compression Ratio</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>4</td>
</center>
<td><center>25</td>
</tr>
</center>
<br>
<tr><td>Engine Data - Catalyst</td>
</tr>
<tr><td><div align="right">
HC Maximum Eff.</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0</td>
</center>
<td><center>1</td>
</tr>
</center>
</center>
<tr><td><div align="right">
NOx Maximum Eff.</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0</td>
</center>
<td><center>1</td>
</tr>
</center>
</center>
<tr><td><div align="right">
CO Maximum eff</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0</td>
</center>
<td><center>1</td>
</tr>
</center>
</center>
<tr><td><div align="right">
HC Time to Max Eff</td>
</div>
</div>
<td><center>s</td>
</center>
<td><center>0</td>
</center>
<td><center>100</td>
</tr>
</center>
</center>
<tr><td><div align="right">
NOx Time to Max Eff</td>
</div>
</div>
<td><center>s</td>
</center>
<td><center>0</td>
</center>
<td><center>100</td>
</tr>
</center>
</center>
<tr><td><div align="right">
CO Time to Max Eff</td>
</div>
</div>
<td><center>s</td>
</center>
<td><center>0</td>
</center>
<td><center>100</td>
</tr>
</center>
</center>
<tr><td><div align="right">
HC Warming Time</td>
</div>
</div>
<td><center>s</td>
</center>
<td><center>0</td>
</center>
<td><center>200</td>
</tr>
</center>
</center>
<tr><td><div align="right">
NOx Warming Time</td>
</div>
</div>
<td><center>s</td>
</center>
<td><center>0</td>
</center>
<td><center>200</td>
</tr>
</center>
</center>
<tr><td><div align="right">
CO Warming Time</td>
</div>
</div>
<td><center>s</td>
</center>
<td><center>0</td>
</center>
<td><center>200</td>
</tr>
</center>
<br>
<tr><td>Engine Data - Warm-Up</td>
</tr>
<tr><td><div align="right">
HC Warm-up Factor</td>
</div>
</div>
<td></td>
</center>
<td><center>0</td>
</center>
<td><center>200</td>
</tr>
</center>
</center>
<tr><td><div align="right">
NOx Warm-up Factor</td>
</div>
</div>
<td></td>
</center>
<td><center>0</td>
</center>
<td><center>200</td>
</tr>
</center>
</center>
<tr><td><div align="right">
CO Warm-up Factor</td>
</div>
</div>
<td></td>
</center>
<td><center>0</td>
</center>
<td><center>200</td>
</tr>
</center>
</center>
<tr><td><div align="right">
HC Factor Time</td>
</div>
</div>
<td><center>s</td>
</center>
<td><center>0</td>
</center>
<td><center>100</td>
</tr>
</center>
</center>
<tr><td><div align="right">
NOx Factor Time</td>
</div>
</div>
<td><center>s</td>
</center>
<td><center>0</td>
</center>
<td><center>100</td>
</tr>
</center>
</center>
<tr><td><div align="right">
CO Factor Time</td>
</div>
</div>
<td><center>s</td>
</center>
<td><center>0</td>
</center>
<td><center>100</td>
</tr>
</center>
</center>
<tr><td><div align="right">
HC Accel Factor</td>
</div>
</div>
<td></td>
</center>
<td><center>0</td>
</center>
<td><center>200</td>
</tr>
</center>
</center>
<tr><td><div align="right">
NOx Accel Factor</td>
</div>
</div>
<td></td>
</center>
<td><center>0</td>
</center>
<td><center>200</td>
</tr>
</center>
</center>
<tr><td><div align="right">
CO Accel Factor</td>
</div>
</div>
<td></td>
</center>
<td><center>0</td>
</center>
<td><center>200</td>
</tr>
</center>
<br>
<tr><td>Engine Data - Auxiliaries</td>
</tr>
<tr><td><div align="right">
Drive Ratio</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0</td>
</center>
<td><center>200</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Rotational Inertia</td>
</div>
</div>
<td><center>kg/m2</td>
</center>
<td><center>0</td>
</center>
<td><center>200</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Speed</td>
</div>
</div>
<td><center>rpm</td>
</center>
<td><center>0</td>
</center>
<td><center>12000</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Torque</td>
</div>
</div>
<td><center>Nm</td>
</center>
<td><center>0</td>
</center>
<td><center>200</td>
</tr>
</center>
<br>
<tr><td>Engine Data - Grid Analysis</td>
</tr>
<tr><td><div align="right">
Speed</td>
</div>
</div>
<td><center>rpm</td>
</center>
<td><center>0</td>
</center>
<td><center>12000</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Torque</td>
</div>
</div>
<td><center>Nm</td>
</center>
<td><center>0</td>
</center>
<td><center>1000</td>
</tr>
</center>
<br>
<tr><td>Engine Data - Primary Drive</td>
</tr>
<tr><td><div align="right">
Drive Ratio</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0</td>
</center>
<td><center>20</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Drive Efficiency</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0.5</td>
</center>
<td><center>1</td>
</tr>
</center>
<br>
<tr><td>Hybrid Data</td>
</tr>
<tr><td><div align="right">
Max. Capacity</td>
</div>
</div>
<td><center>kW.h</td>
</center>
<td><center>10</td>
</center>
<td><center>1000</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Min. capacity</td>
</div>
</div>
<td><center>kW.h</td>
</center>
<td><center>0</td>
</center>
<td><center>1000</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Max. Out. Torque</td>
</div>
</div>
<td><center>Nm</td>
</center>
<td><center>0</td>
</center>
<td><center>1000</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Max In Torque</td>
</div>
</div>
<td><center>Nm</td>
</center>
<td><center>0</td>
</center>
<td><center>1000</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Output Efficiency</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0.1</td>
</center>
<td><center>1</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Input efficiency</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0.1</td>
</center>
<td><center>1</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Capacity at Start</td>
</div>
</div>
<td><center>kW.h</td>
</center>
<td><center>0</td>
</center>
<td><center>1000</td>
</tr>
</center>
<br>
<tr><td>Driver Data</td>
</tr>
<tr><td><div align="right">
Cornering Eff.</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0.5</td>
</center>
<td><center>1</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Braking Eff</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0.5</td>
</center>
<td><center>1</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Braking Balance</td>
</div>
</div>
<td><center>-</td>
</center>
<td><center>0.5</td>
</center>
<td><center>1</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Gear Shift Time</td>
</div>
</div>
<td><center>s</td>
</center>
<td><center>0.1</td>
</center>
<td><center>5</td>
</tr>
</center>
</center>
<tr><td><div align="right">
Min Shift Interval</td>
</div>
</div>
<td><center>s</td>
</center>
<td><center>0.1</td>
</center>
<td><center>5</td>
</tr>
</center>
<br>
<br>
{<tr><td>button ,AL(`list4',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Column Write Wizard<br>
</font></b></font><font size="2">Overview<br>
</font><font face="Times New Roman"><br>
<font face="Arial">The column write wizard allows the user to generate an ASCII column file from the Lotus Vehicle Simulation results that are currently displayed on the graphs. This then provides a route for processing and plotting of the results in external applications such as Excel.<br>
<br>
The format of the columns can be controlled to be set as real or integer and in the case of real numbers in either <i>E</i></font></font> or <i>F</i> format with the number of decimal points defined.<br>
<br>
Simple scaling and shifting can also be applied to individual columns.<br>
<br>
The column delimitation can be set to either <i>space</i>, <i>tab</i> or <i>comma</i>.<br>
<br>
Only data currently loaded and displayed on a results graph can be saved through the column wizard, since the selection of the columns is based on picking from the graph<font face="Times New Roman"><font face="Arial">s X or Y axes.<br>
<br>
{button ,AL(`list5',0,&quot;&quot;,`main')} <u>Related Topics</u></font></font><br>
<font face="Times New Roman"><br>
<p><hr><p>
</font></td>
</tr>
</table>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><font face="Arial"><b><font size="4">Opening the Column Write Wizard<br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To display the column write wizard select the menu item <u>Tools</u></font></font></font> / <u>Column Write Wizard</u>. (Note; that this window will ignore selection of menu items outside of its own window, and thus must be closed before any other Lotus Vehicle Simulation window can be accessed)<b> .</b><br>
<br>
{button ,AL(`list5',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Closing the Column Write Wizard<br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To close the column write wizard and return to Lotus Vehicle Simulation select either the </font></font></font><font face="Times New Roman"><font face="Arial">close</font></font><font face="Times New Roman"><font face="Arial"> icon at the top right corner of the write wizard window, or </font></font><font face="Times New Roman"><font face="Arial">close</font></font><font face="Times New Roman"><font face="Arial"> from the write wizard window menu at the top left corner. Closing the column write wizard will lose all current settings.<b><br>
</b></font></font><br>
{button ,AL(`list5',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Defining the Column Data<br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To define the column data the user must first load and display the required data on a results graph, since column selection is based on picking from the graph</font></font></font><font face="Times New Roman"><font face="Arial">s X or Y axes.<br>
<br>
Set the number of columns required in the appropriate value box then step through each column using the arrow icons and entering the required settings.<br>
<br>
Default values are pre-set for scale, shift, format width, number of decimal points and format specifier at each column, these can modified as required. The user must select the required axis from x-axis, y-axis 1, y-axis 2, y-axis 3 and y-axis 4, and the required position from 1 to 5. <br>
</font></font><br>
{button ,AL(`list5',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Data Manipulation<br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">Individual columns can be scaled and/or shifted before being written out. <br>
<br>
To scale a column, display its settings using the arrow icons then enter the required scale value in the <i>scale factor</i></font></font></font> box.<br>
<br>
To shift a column, display its settings using the arrow icons then enter the required shift value in the <i>shift</i> box.<br>
<br>
If both scale and shift are applied to a column the values are scaled first then shifted.<br>
<br>
The default values apply a scale factor of 1 and a shift of 0.<br>
<br>
{button ,AL(`list5',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Controlling the Column Format<br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">The output format of an individual column</font></font></font><font face="Times New Roman"><font face="Arial">s values written to a file can be controlled via the format setting values.<br>
<br>
All graph values are handled as real numbers but can be written as either integers or reals.<br>
<br>
If writing out as Integers they can be in either integer form or nearest integer form, (i.e. Fortran syntax INT and NINT). To set a column to integer or nearest integer select from the <i>Format Specifier</i></font></font> the <i>I Format</i> option and set the <i>Format Width</i> to be wide enough for the largest number. Selecting the <i>I format</i> option will automatically set the number of decimal places to zero,if the nearest integer value is required this should be set to -1. (note that setting to integer or nearest integer can be done directly by simply editing the <i>No. of Decimal points</i> to 0 or -1 as required rather than using the <i>Format Specifier</i> pull down menu. Integer values are output padded with leading blanks.<br>
<br>
If writing out as reals they can be in either floating point of exponent format. To set a column to real select from <i>Format Specifier</i> the <i>F Format</i> option for floating point or the <i>E F</i>ormat for the exponent format, then set the <i>Format Width</i> to be wide enough for the largest number and the required number of decimal places. Real numbers are rounded to the last decimal place and padded with leading blanks.<br>
<br>
If the values exceed the defined format width specified they will be output as <font face="Times New Roman"><font face="Arial">*******</font></font><font face="Times New Roman"><font face="Arial">, and users should thus be wary of defining too small a column width. This mimics the standard Fortran output behaviour.<br>
</font></font><br>
By default the column values are written in <i>F Format </i>with a <i>format width</i> of 12 and <i>number of decimal points</i> as 4.<br>
<br>
{button ,AL(`list5',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Setting the Columns as Graph &<br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To set the settings of the column data wizard to be such that they produce a listing of a currently displayed particular graph, the user could set the number of columns and then toggle through the settings for each column picking the axis as x-axis then the appropriate y-axis. for each position until they had all been selected in turn. <br>
<br>
Alternatively select <u>Options</u></font></font></font> / <u>Set as graph</u> and chose the required graph. This will then define the no of valid columns and their settings. It will only <font face="Times New Roman"><font face="Arial">add in</font></font><font face="Times New Roman"><font face="Arial"> axis that are both switched on and have data values loaded. Thus if no results are currently loaded, no columns will be set to </font></font><font face="Times New Roman"><font face="Arial">on</font></font><font face="Times New Roman"><font face="Arial">. The format settings for columns added in this way, will be set to the default settings. Thus this option defines the settings to produce a column file for all lines currently displayed on the selected graph.<br>
</font></font><br>
The number of columns that will be loaded is given by,<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
the number of active positions x ( X-axis + Y-axes {if active} )<br>
<br>
(note, Individual results files are stored in a position from 1 to 5 to provide a method of cross plotting results from different runs.)<br>
<br>
(note, The x-axis values from each position file may not be the same and thus the x-axis values for each position file are included in the listing.)<br>
<br>
{button ,AL(`list5',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Setting the Columns as Position &<br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To define the settings such that it will produce a column file for all lines currently displayed from a given position, select <u>Options</u></font></font></font> / <u>Set as Position</u> and chose the required position. This will then define the no of valid columns and their settings. It will only <font face="Times New Roman"><font face="Arial">add in</font></font><font face="Times New Roman"><font face="Arial"> axis that are both switched on and have data values loaded. Thus if no results are currently loaded, no columns will be set to </font></font><font face="Times New Roman"><font face="Arial">on</font></font><font face="Times New Roman"><font face="Arial">. The format settings for columns added in this way, will be set to the default settings. <br>
</font></font><br>
The number of columns that will be loaded is given by,<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
X-axis + number of active Y-axes (for the selected position)<br>
<br>
(note, Individual results files are stored in a position from 1 to 5 to provide a method of cross plotting results from different runs.)<br>
<br>
(note, The x-axis values from each position file may not be the same.)<br>
<br>
{button ,AL(`list5',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Setting the Column Delimiter<br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">Columns files created by this wizard can be separated by either spaces, tabs or commas. <br>
<br>
The default setting is to use a space between each column.<br>
<br>
To change the delimiter, select <u>Delimiter</u></font></font></font> and the required item from the wizard menubar.<br>
<br>
{button ,AL(`list5',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Saving the Column Data to File<br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To save the defined column data to a file enter the required name into the<i> Filename</i></font></font></font> box and select the <i>Write</i> button. The file browser icon can also be used to locate the required destination filename. The user is warned if this action will overwrite an existing file.<br>
<br>
The default file extension types are <font face="Times New Roman"><font face="Arial">*.prn</font></font><font face="Times New Roman"><font face="Arial"> for space delimited files, </font></font><font face="Times New Roman"><font face="Arial">*.txt</font></font><font face="Times New Roman"><font face="Arial"> for tab delimited files and </font></font><font face="Times New Roman"><font face="Arial">*.csv</font></font><font face="Times New Roman"><font face="Arial"> for comma separated files. (These are in-line with Excel file extensions).<br>
</font></font><br>
{button ,AL(`list5',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Track Builder / Viewer Tool <br>
</font></b></font><font size="2">Overview</font><font face="Times New Roman"><br>
<br>
<font face="Arial">The track builder and viewer tool allows the user to either create a new track model or view and modify an existing track model. The </font></font><font face="Times New Roman"><font face="Arial">standard</font></font><font face="Times New Roman"><font face="Arial"> track models can also be loaded directly into the viewer. The track is defined as a series of </font></font><font face="Times New Roman"><font face="Arial">straights</font></font><font face="Times New Roman"><font face="Arial"> and </font></font><font face="Times New Roman"><font face="Arial">curves</font></font><font face="Times New Roman"><font face="Arial"> with appropriate properties being defined for these sections.<br>
<br>
The current maximum number of track sections that can be defined is 250.<br>
<br>
{button ,AL(`list2',0,&quot;&quot;,`main')} <u>Related Topics</u></font></font><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></font><font face="Arial"><b><font size="4">Opening the Track Builder / Viewer Tool<br>
</font></b></font><font size="2"><br>
</font>To display the track builder window select the menu item <u>Tools</u> / <u>Track Builder/Viewer</u>. (Note; that this window will ignore selection of menu items outside of its own window, and thus must be closed before any other Lotus Vehicle Simulation window can be accessed)<b> .</b> <br>
<br>
{button ,AL(`list2',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<b><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></b><font size="4">Closing the Track Builder / Viewer Tool<br>
</font><font size="2"><br>
To close the track builder window and return to Lotus Vehicle Simulation select either the </font><font face="Times New Roman"><font face="Arial">close</font></font><font face="Times New Roman"><font face="Arial"> icon at the top right corner of the track window, the track window menu at the top left or alternatively select the menu item <u>File</u></font></font> / <u>Close</u> from the track builder menubar. Closing the track window will lose all unsaved data.<b><br>
</b><br>
{button ,AL(`list2',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<b><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></b><font size="4">Track Data Variables<br>
</font><font size="2"><br>
</font>There are two basic track types, straights and curves, with up to seven variables being used to define each track section, (not all being valid for each type). The values are displayed in the window spread sheet under the following headings.<br>
<br>
<b>1) Feature:</b> (integer) Identifies the track section as being either a straight (1) or a curve (2). Acceptable integer values are 1 or 2.<br>
<b>2) Gradient: </b>(real) (deg) Sets the gradient of track on this feature in degrees relative to the horizontal.<br>
<b>3) Camber:</b> (real) (deg) Sets the camber of track on this feature in degrees to the horizontal. A positive No. is such that the track to the right hand side of the driver is raised.<br>
<b>4) Dimension:</b> (real) (M) Defines the feature dimension. For straights this set the length of the straight, for curves it set the radius of the curve.<br>
<b>5) Angle:</b> (real) (deg) Not used for straights, for curves it defines the angle of the curve segment. <br>
<b>6) Width:</b> (real) (M) Defines the width of the track.(this variable is not used at present)<br>
<b>7)Vmax:</b> (real) (Km/h) Defines the maximum velocity permited on this track section. If Vmax = 9999.0 then the maximum achievable velocity is permitted.<br>
<br>
<br>
The number of track sections controls the spread sheet such that only the defined number of sections are editable.<br>
<br>
The Maximum time step defines the maximum time step (s) to be used by the solver.<br>
<br>
{button ,AL(`list2',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<b><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></b><font size="4">Loading and Saving Track Files<br>
</font><font size="2"><br>
To load an existing track file select <u>File</u></font> / <u>Open</u> from the track builder menubar. The file browser is displayed with the default file extension being *.ord. Browse and select the required file, the file is then read and the track data loaded into the window. Note that existing track data will be overwriten and if required should be saved before opening another file, (the user is reminded of this via a message box).<br>
<br>
Selecting <u>File</u> / <u>New</u> from the track builder menubar will delete the current track data, and if required should be saved before creating a new track.<br>
<br>
To save the current track select either <u>File</u> / <u>Save</u> or <u>File</u> / <u>Save_As</u> from the track builder menubar. The <i>Save</i> option will, if appropriate, save the track data to the current filename. The current filename being displayed at the top of the track builder window. The <i>Save_as</i> option will display the file browser to allow the required filename to be entered.<br>
<br>
<br>
{button ,AL(`list2',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<b><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></b><font size="4">Loading Standard Track Files<br>
</font><font size="2"><br>
The </font><font face="Times New Roman"><font face="Arial">standard</font></font><font face="Times New Roman"><font face="Arial"> track files can be loaded into the track builder by selecting <u>File</u></font></font> / <u>Load Standard</u> from the track builder menubar and chosing the required track from the presented alternatives. This data can then be edited and saved to a user specified file just like any other user defined track file. The <font face="Times New Roman"><font face="Arial">standard</font></font><font face="Times New Roman"><font face="Arial"> track files are those that are given within the calculation setup window, namely<br>
</font></font>1) Oval<br>
2) Lotus Test Track<b><br>
</b>3) Snetterton Race Circuit - Norfolk<b><br>
</b><br>
{button ,AL(`list2',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><b><font size="4">Inserting and Deleting Track Sections<br>
</font></b><font size="2"><br>
To add further sections to the end of a partially defined currently displayed track, edit the value for the No. of track sections to reflect the new required total number of track sections. Editing the No. of track sections value alters the scrollable spread sheet display such that the additional sections can be entered into the display.<br>
<br>
To insert a new track section into the middle of an existing displayed track, select <u>Edit</u></font> / <u>Insert Section</u> from the track builder menubar. You are then prompted for the position in the list at which to insert the new section. The new section is inserted immediately before the entered section No. The number of track sections is increased by one, the existing sections being shuffled and renumbered. The values for this new section should then be entered into the spread sheet.<br>
<br>
To delete a track section from an existing displayed track, select <u>Edit</u> / <u>Delete Section</u> from the track builder menubar. You are then prompted for the section No. in the list that you wish to delete. This track section is then removed from the list, the number of track sections automatically reduced by one and the remaining track sections being shuffled and renumbered. <br>
<br>
{button ,AL(`list2',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<b><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></b><font size="4">Setting the Track View<br>
</font><font size="2"><br>
</font>The displayed track<font face="Times New Roman"><font face="Arial">s view can be manipulated via the </font></font><font face="Times New Roman"><font face="Arial">zoom</font></font><font face="Times New Roman"><font face="Arial"> and </font></font><font face="Times New Roman"><font face="Arial">autoscale</font></font><font face="Times New Roman"><font face="Arial"> functions, to enable a portion or all of the track to be viewed. <br>
<br>
To zoom in on the display select <u>View</u></font></font> / <u>Zoom</u> from the track builder menubar, then with the mouse select one corner of the required area with the left mouse button, then drag the rubber band box and select the other corner, again with the left mouse button. The display is then redrawn showing the selected area. Using the right mouse button for either of the selections cancels the zoom action. The zoom function will not distort the true aspect ratio, the correct relationship between x and y dimensions being maintained.<br>
<br>
To display the entire track select <u>View</u> / <u>Autoscale</u> from the track builder menubar. The display will be redrawn to display the complete track, again the correct aspect ratio is maintained.<br>
<br>
To reflect changes made to data in the spread sheet on the graphical display, the graphics needs to be <i>refreshed.</i> Select <u>View</u> / <u>Refresh</u> from the track builder menubar, the display will be redrawn using the current view settings and data values.<br>
<br>
To assist in identifying track sections the section number as used in the spread sheet can be displayed on the graphical display. To toggle the visibility select <u>View</u> / <u>Section No.</u> from the track builder menubar, a tick indicates that the visibility is <i>on</i>.<b><br>
</b><br>
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<b><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></b><font size="4">Track File Format<br>
</font><font size="2"><br>
User defined track files are stored as ASCII data with the following format.<br>
<br>
Record 1: <b>NSECT, TSTEP</b></font><br>
<br>
where &nbsp;&nbsp;
<b>NSECT</b> &nbsp;&nbsp;
(integer) (max 50). Number of track sections.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>TSTEP</b> &nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(real). (s) Maximum solver time step.<br>
<br>
Record 2: <b>IFEAT, GRAD, CAMB, DIM, ANG, WIDTH, VMAX</b><br>
<br>
where&nbsp;&nbsp;&nbsp;
<b>IFEAT</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(integer).Identifies the track section as being either a straight (1) or a curve (2). Acceptable integer values are 1 or 2.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>GRAD</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(real) (deg) Sets the gradient of track on this feature in degrees relative to the horizontal.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>CAMB</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(real) (deg) Sets the camber of track on this feature in degrees to the horizontal. A positive No. is such that the track to the right hand side of the driver is raised.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>DIM</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(real) (M) Defines the feature dimension. For straights this set the length of the straight, for curves it set the radius of the curve.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>ANG</b>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(real) (deg) Not used for straights, for curves it defines the angle of the curve segment.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>WIDTH</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(real) (M) Defines the width of the track.(this variable is not used at present)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>VMAX</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(real) (Km/h) Defines the maximum velocity permited on this track section. If Vmax = 9999.0 then the maximum achievable velocity is permitted.<br>
<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Record 2 is repeated for each track section<br>
<br>
The following lines show the user track file for the Lotus test Track<br>
<br>
<font size="1"> 13 0.100000<br>
1.00000 0.000000E+00 0.000000E+00 426.500 0.0000 10.0000 9999.00<br>
2.00000 0.000000E+00 0.000000E+00 187.000 -70.0000 10.0000 9999.00<br>
1.00000 0.000000E+00 0.000000E+00 875.000 0.0000 10.0000 9999.00<br>
</font> 2.00000 0.000000E+00 0.000000E+00 53.0000 -180.500 10.0000 9999.00<br>
1.00000 0.000000E+00 0.000000E+00 617.500 0.0000 10.0000 9999.00<br>
2.00000 0.000000E+00 0.000000E+00 314.000 42.5000 10.0000 9999.00<br>
1.00000 0.000000E+00 0.000000E+00 195.000 0.0000 10.0000 9999.00<br>
2.00000 0.000000E+00 0.000000E+00 283.000 31.0000 10.0000 9999.00<br>
1.00000 0.000000E+00 0.000000E+00 184.000 0.0000 10.0000 9999.00<br>
2.00000 0.000000E+00 0.000000E+00 131.000 -39.0000 10.0000 9999.00<br>
1.00000 0.000000E+00 0.000000E+00 32.0000 0.0000 10.0000 9999.00<br>
2.00000 0.000000E+00 0.000000E+00 37.7428 -144.000 10.0000 9999.00<br>
1.00000 0.000000E+00 0.000000E+00 144.129 0.0000 10.0000 9999.00<br>
<font size="2"><br>
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<b><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></b><font size="4">Copying the Track Display to the Clipboard <br>
</font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To copy the displayed picture from the track builder to the clipboard select the <u>View / Copy to Clipboard</u></font></font></font> menu option from the track builder menubar. The image can then be pasted from the clipboard into a number of proprietary windows applications, e.g. Powerpoint.<br>
<br>
{button ,AL(`list2',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Cycle Builder / Viewer Tool <br>
</font></b></font><font size="2">Overview</font><font face="Times New Roman"><br>
<br>
<font face="Arial">The cycle builder and viewer tool allows the user to either create a new emissions cycle or view and modify an existing emissions cycle. The </font></font><font face="Times New Roman"><font face="Arial">standard</font></font><font face="Times New Roman"><font face="Arial"> emissions cycles can also be loaded directly into the viewer. The cycle is defined by a series of time points, the points being set at an equal time increment. For each time step the velocity and gear is defined.<br>
<br>
The current maximum number of time steps that can be defined is 2000.<br>
<br>
</font></font>The velocity time history uses color to identify the defined gear. The default colors for neutral and the first 5 gears are as follows;<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
neutral = red, 1st = orange, 2nd = yellow, 3rd = green, 4th = cyan, 5th = blue<br>
<br>
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<font face="Times New Roman"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></font><font face="Arial"><b><font size="4">Opening the Cycle Builder / Viewer Tool<br>
</font></b></font><font size="2"><br>
</font>To display the cycle builder window select the menu item <u>Tools</u> / <u>Cycle Builder/Viewer</u>. (Note; that this window will ignore selection of menu items outside of its own window, and thus must be closed before any other Lotus Vehicle Simulation window can be accessed)<b> .</b><br>
<br>
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<b><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></b><font size="4">Closing the Cycle Builder / Viewer Tool<br>
</font><font size="2"><br>
To close the cycle builder window and return to Lotus Vehicle Simulation select either the </font><font face="Times New Roman"><font face="Arial">close</font></font><font face="Times New Roman"><font face="Arial"> icon at the top right corner of the cycle window, the cycle window menu at the top left or alternatively select the menu item <u>File</u></font></font> / <u>Close</u> from the cycle builder menubar. Closing the cycle window will lose all unsaved data.<b><br>
</b><br>
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<b><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></b><font size="4">Cycle Data Variables<br>
</font><font size="2"><br>
</font>The cycle data consists of a series of points at constant time step increments starting from zero seconds. At each time point the vehicle velocity and gear No. is defined. The values are displayed in the window spread sheet under the following headings.<br>
<br>
<b>1) Time:</b> (real) (s) Shows the time value for this point. It is not editable directly, being defined by the point number and the current input time step.<br>
<b>2) Speed: </b>(real) (km/h) Sets the required velocity for this time point.<br>
<b>3) Gear:</b> (integer) Sets the required gear for this time point.<br>
<br>
<br>
The <i>number of steps</i> controls the spread sheet such that only the defined number of time steps are editable.<br>
<br>
The <i>input time step</i> sets the time increment between succesive data points.<br>
<br>
The <i>solve time step</i> defines the maximum time step (s) to be used by the solver.<br>
<br>
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<b><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></b><font size="4">Loading and Saving Cycle Files<br>
</font><font size="2"><br>
To load an existing cycle file select <u>File</u></font> / <u>Open</u> from the cycle builder menubar. The file browser is displayed with the default file extension being *.cyc. Browse and select the required file, the file is then read and the cycle data loaded into the window. Note that existing cycle data will be overwriten and if required should be saved before opening another file, (the user is reminded of this via a message box).<br>
<br>
Selecting <u>File</u> / <u>New</u> from the cycle builder menubar will delete the current cycle data, and if required should be saved before creating a new cycle.<br>
<br>
To save the current cycle select either <u>File</u> / <u>Save</u> or <u>File</u> / <u>Save_As</u> from the cycle builder menubar. The <i>Save</i> option will, if appropriate, save the cycle data to the current filename. The current filename being displayed at the top of the cycle builder window. The <i>Save_as</i> option will display the file browser to allow the required filename to be entered.<br>
<br>
<br>
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<b><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></b><font size="4">Loading Standard Cycle Files<br>
</font><font size="2"><br>
The </font><font face="Times New Roman"><font face="Arial">standard</font></font><font face="Times New Roman"><font face="Arial"> cycle files can be loaded into the cycle builder by selecting <u>File</u></font></font> / <u>Load Standard</u> from the cycle builder menubar and chosing the required cycle from the presented alternatives. This data can then be edited and saved to a user specified file just like any other user defined cycle file. The <font face="Times New Roman"><font face="Arial">standard</font></font><font face="Times New Roman"><font face="Arial"> cycle files are those that are given within the calculation setup window, namely<br>
</font></font>1) USA &nbsp;
Federal FTP75<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Federal Highway<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Federal FTP06<br>
2) EURO&nbsp;
EURO<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
EUDC<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
EURO + EUDC<b><br>
</b>3) EURO (under powered)<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
EURO<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
EUDC<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
EURO + EUDC<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
4) JAPAN&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Japanese 15 mode<b><br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><b><font size="4">Inserting and Deleting Cycle Steps<br>
</font></b><font size="2"><br>
To add further time steps to the end of a partially defined currently displayed cycle, edit the value for the No. of time steps to reflect the new required total number of time steps. Editing the No. of time steps value alters the scrollable spread sheet display such that the additional steps can be entered into the display.<br>
<br>
To insert a new time step into the middle of an existing displayed cycle, select <u>Edit</u></font> / <u>Insert Step</u> from the cycle builder menubar. You are then prompted for the position in the list at which to insert the new time step. The new time step is inserted immediately before the entered step No. The number of time steps is increased by one, the existing steps being shuffled and renumbered. The values for this new time step should then be entered into the spread sheet.<br>
<br>
To delete a time step from an existing displayed cycle, select <u>Edit</u> / <u>Delete Step</u> from the cycle builder menubar. You are then prompted for the step No. in the list that you wish to delete. This time step is then removed from the list, the number of time steps automatically reduced by one and the remaining time steps being shuffled and renumbered. <br>
<br>
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<b><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></b><font size="4">Setting the Cycle View<br>
</font><font size="2"><br>
</font>The displayed cycle<font face="Times New Roman"><font face="Arial">s view can be manipulated via the </font></font><font face="Times New Roman"><font face="Arial">zoom</font></font><font face="Times New Roman"><font face="Arial"> and </font></font><font face="Times New Roman"><font face="Arial">autoscale</font></font><font face="Times New Roman"><font face="Arial"> functions, to enable a portion or all of the cycle to be viewed. <br>
<br>
To zoom in on the display select <u>View</u></font></font> / <u>Zoom</u> from the cycle builder menubar, then with the mouse select one corner of the required area with the left mouse button, then drag the rubber band box and select the other corner, again with the left mouse button. The display is then redrawn showing the selected area. Using the right mouse button for either of the selections cancels the zoom action.<br>
<br>
To display the entire cycle select <u>View</u> / <u>Autoscale</u> from the cycle builder menubar. The display will be redrawn to display the complete cycle.<br>
<br>
To reflect changes made to data in the spread sheet on the graphical display, the graphics needs to be <i>refreshed.</i> Select <u>View</u> / <u>Refresh</u> from the cycle builder menubar, the display will be redrawn using the current view settings and data values.<br>
<br>
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<b><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup></b><font size="4">Cycle File Format<br>
</font><font size="2"><br>
User defined cycle files are stored as ASCII data with the following format.<br>
<br>
Record 1: <b>NSTEP, TINC, TSTEP</b></font><br>
<br>
where &nbsp;&nbsp;
<b>NSECT</b> &nbsp;&nbsp;
(integer) (max 50). Number of track sections.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>TINC</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(real) (s) Time step increment<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>TSTEP</b> &nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(real).(s) Maximum solver time step.<br>
<br>
Record 2: <b>VELO, IGEAR</b><br>
<br>
where&nbsp;&nbsp;&nbsp;
<b>VELO</b>&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(real).(km/h) Sets the required velocity for this time point.<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<b>IGEAR</b>&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
(int) Sets the required gear for this time point.<br>
<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Record 2 is repeated for each time step<br>
<br>
The following lines shows an extract from the top of the Euro EUDC cycle<br>
<br>
<font face="Times New Roman"> 406 1.00000 0.500000<br>
0.000000E+00 1<br>
0.000000E+00 1<br>
0.000000E+00 1<br>
0.000000E+00 1<br>
0.000000E+00 1<br>
0.000000E+00 0<br>
0.000000E+00 0<br>
0.000000E+00 0<br>
0.000000E+00 0<br>
0.000000E+00 0<br>
0.000000E+00 0<br>
</font> 0.000000E+00 0<br>
0.000000E+00 0<br>
&&.<br>
&&.<br>
<font face="Arial"><br>
<br>
{button ,AL(`list3',0,&quot;&quot;,`main')} <u>Related Topics</u></font><br>
<b><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></b><font size="4">Copying the Cycle Display to the Clipboard <br>
</font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To copy the displayed picture from the cycle builder to the clipboard select the <u>View / Copy to Clipboard</u></font></font></font> menu option from the cycle builder menubar. The image can then be pasted from the clipboard into a number of proprietary windows applications, e.g. Powerpoint.<br>
<br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">DataBase Wizard <br>
</font></b><font size="2">Overview</font><font face="Times New Roman"><br>
<br>
<font face="Arial">The DataBase wizard provides a tool that allows data to be stored and retrieved at a component level, i.e. vehicle, engine, gearbox etc. rather than as a complete Lotus Vehicle Simulation file. The user can create these database files with specific read/write protection levels on them such that access to the data or the ability to overwrite/modify the data requires a password to be given. As further protection of the database files they are 'scrambled' to prevent direct reading of them, but users should be aware that these files could still be corrupted or deleted and regular backups should be performed to maintain data.<br>
</font></font><br>
The database wizard breaks the Lotus Vehicle Simulation data down into three sections, Compulsory, Optional and Controllers, each of these sections has a number of components related to them. The <i><b>compulsory</b></i> section consists of those components that are compulsory within a Lotus Vehicle Simulation data file, they have the colour <font color="#ff0000">'red'<font color="#000000"> associated with them. The second section, <i><b>optional,</b></i></font></font><font color="#000000"> consists of the components that are optional within a Lotus Vehicle Simulation data file and have <font color="#008000">'green'<font color="#000000"> as their associated colour. The third section, <i><b>controllers</b></i></font></font></font><font color="#000000">, contains data elements related to the control of the vehicle and use the <font color="#0000ff">'blue'<font color="#000000"> colour.</font></font></font><br>
<br>
The components related to each section and their relevant icons are; <br>
<br>
<b>Compulsory</b><br>
<u><img data="bm59.bmp" title="bm59.bmp"></u> &nbsp;&nbsp;&nbsp;
Vehicle<br>
<u><img data="bm60.bmp" title="bm60.bmp"></u> &nbsp;&nbsp;&nbsp;
Wheel and Tyre<br>
<u><img data="bm61.bmp" title="bm61.bmp"></u> &nbsp;&nbsp;&nbsp;
Final Drive<br>
<u><img data="bm62.bmp" title="bm62.bmp"></u> &nbsp;&nbsp;&nbsp;
Gearbox<br>
<u><img data="bm63.bmp" title="bm63.bmp"></u> &nbsp;&nbsp;&nbsp;
Engine<br>
<u><img data="bm64.bmp" title="bm64.bmp"></u> &nbsp;&nbsp;&nbsp;
Clutch<br>
<br>
<b>Optional</b><br>
<u><img data="bm65.bmp" title="bm65.bmp"></u> &nbsp;&nbsp;&nbsp;
Torque Converter<br>
<u><img data="bm66.bmp" title="bm66.bmp"></u> &nbsp;&nbsp;&nbsp;
Catalyst<br>
<u><img data="bm67.bmp" title="bm67.bmp"></u> &nbsp;&nbsp;&nbsp;
Dynamometer<br>
<u><img data="bm68.bmp" title="bm68.bmp"></u> &nbsp;&nbsp;&nbsp;
Primary Drive<br>
<u><img data="bm69.bmp" title="bm69.bmp"></u> &nbsp;&nbsp;&nbsp;
Auxiliaries<br>
<u><img data="bm70.bmp" title="bm70.bmp"></u> &nbsp;&nbsp;&nbsp;
Hybrid (simple)<br>
<u><img data="bm71.bmp" title="bm71.bmp"></u> &nbsp;&nbsp;&nbsp;
Hybrid Battery<br>
<u><img data="bm72.bmp" title="bm72.bmp"></u> &nbsp;&nbsp;&nbsp;
Hybrid Motor<br>
<u><img data="bm73.bmp" title="bm73.bmp"></u> &nbsp;&nbsp;&nbsp;
Hybrid Generator<br>
<u><img data="bm74.bmp" title="bm74.bmp"></u> &nbsp;&nbsp;&nbsp;
Hybrid Drive Regenerator<br>
<br>
<b>Controllers</b><br>
<u><img data="bm75.bmp" title="bm75.bmp"></u> &nbsp;&nbsp;&nbsp;
Shift Maps<br>
<u><img data="bm76.bmp" title="bm76.bmp"></u> &nbsp;&nbsp;&nbsp;
Driver<br>
<u><img data="bm77.bmp" title="bm77.bmp"></u> &nbsp;&nbsp;&nbsp;
Hybrid Control<br>
<br>
The 'component' approach employed in the database wizard means that any data that is used to define a component will, if entered, be saved/read when the component is saved or loaded. An example of this is the engine component that also includes 'Maps', 'Warm-up' and 'Grid' data sections. A full list of this connectivity is given below in terms of their data file keywords;<br>
<br>
<b>Vehicle</b>&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
'<i>Vehicle', 'Suspensions', 'Aerodynamics'<br>
</i><b>Wheel/Tyre&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b><i>'Tyre', 'Xtyre', 'Drive'</i><br>
<b>Gearbox</b>&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<i>'Gearbox', 'Gloss'</i><br>
<b>Engine</b><i>&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
'Engine', 'Maps', 'Optimum', 'Eng_scale', 'Warm_up', 'Grid'<br>
</i><b>Hybrid Battery&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b><i>'Hybpower', 'Hybloss', 'Hybbattery'<br>
</i><b>Hybrid Motor&nbsp;&nbsp;&nbsp;&nbsp;
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b><i>'Hybpower', 'Hybloss'<br>
</i><b>Hybrid Generator&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b><i>'Hybpower', 'Hybloss''<br>
</i><b>Hybrid Drive Regen&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
</b><i>'Hybpower', 'Hybloss''<br>
</i><br>
note also that some Lotus Vehicle Simulation data sections are common between a number of components. This has been necessary because of the original Lotus Vehicle Simulation data structure. A particular example of this is with the 'Wheel/tyre' component. The inertia values for the wheels are contained in the 'drive' data section these values are saved with the wheel component rather than the final drive component.<br>
<br>
The database wizard allows for multiple database files to be <u>opened</u>, the <u>details</u> of which can be displayed. The <u>details</u> and <u>properties</u> of individual components within a database can be viewed, <u>edited</u> or the component <u>removed</u> from the database. In addition any current 'Lotus Vehicle Simulation' data can be <u>added</u> to a database file.<br>
<br>
The database wizard can be used to put together a complete Lotus Vehicle Simulation data file all in one go, or alternatively can be used to just select single components to <u>add/replace</u> that in your current Lotus Vehicle Simulation data.<br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Opening the DataBase Wizard<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To open the DataBase wizard, select the menu item <u>Tools</u></font></font></font> / <u>Database Wizard</u> from the main menubar. When the wizard is open the pull down menu option is 'ticked' and all events in other windows ignored.<br>
<br>
On initially opening the wizard no database files are open. Previously opened database files names are saved to the bottom of the <u>DataBase</u> menu on the wizards menubar.<br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><sup>A</sup><b><font size="4">Closing the DataBase Wizard<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To close the DataBase wizard, select either the menu item <u>File</u></font></font></font> / <u>Close</u> from the wizards menubar, or close from the wizards top left window menu or the close symbol at the top right of the wizards window.<br>
<br>
On closing the window all data settings within the wizard is lost and all opened database files are closed. Thus all settings are lost on close and will need to be re-set or files re-opened if required when the wizard is subsequently opened.<br>
<br>
Depending on the method of closing the window and the state of the selected data, a message prompt may be displayed on closing. This prompt is informing the user that they have selected a component from a database file and that if this component data is to be transferred into the current Lotus Vehicle Simulation data, the 'make current' option should be used. This warning is only given if the menu item <u>File</u> / <u>Close</u> from the wizards menubar is used.<br>
<br>
On closing the database wizard any open data windows are 'refreshed' to reflect any changes made to the Lotus Vehicle Simulation data.<br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Creating a New DataBase File<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To create a new database file, with the database wizard open select the menu item <u>DataBase</u></font></font></font> / <u>Create</u> from the wizard menubar. The file browser is opened to allow the user to enter the required file name. The default extension for Lotus Vehicle Simulation database files is *.dbs. Note that you cannot select a file name of an existing file.<br>
<br>
The create dialog box is then displayed through which the user selects whether to apply any protection to the file, give the file an entry name and use three lines of text to describe the contents or function of this particular database file, only the entry name is compulsory.<br>
<br>
File protection can be one of 'none', 'write' or 'read and write'. If either of the last two options are selected, a password must be entered. Note that the password string is case sensitive.<br>
<br>
Write protection implies that when ever a user tries to <u>add a component</u> to an opened database file they will be prompted for the required password. 'Read + Write' protection is similar to write protection in that a password is required to add a component to the database file but also that the password is required to initially <u>open the database</u> file.<br>
<br>
Suggestions for what the entry name and text descriptions should be used for are, to provide easy identification of the database files contents, who created it and when, and whether it is a project specific file or not.<br>
<br>
Selecting 'Ok' will then create the file and leave it opened. The database file name being added to the 'details' and 'close' pop-up menus.<br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u><font face="Times New Roman"><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Opening and Closing a DataBase File<br>
</font></b></font><font face="Times New Roman"><font size="2"><br>
<font face="Arial">An existing database file can be opened in one of two modes, as either 'exclusive' or 'add'. Exclusive as it implies will open the selected file closing all other open database files. The 'add' mode will open the selected file in addition to any already opened.<br>
<br>
To open a existing database file, with the database wizard open select the menu item <u>DataBase</u></font></font></font> / <u>Open (exclusive)</u> or <u>DataBase</u> / <u>Open (add)</u> as required from the wizard menubar. The file browser is opened to allow the user to select the required file. The default extension for Lotus Vehicle Simulation database files is *.dbs.<br>
<br>
The 5 most recently opened database files names are added to the bottom of the <u>DataBase</u> menu and these can be opened in 'add' mode by simply selecting the required file from the list.<br>
<br>
If a database file has 'read' protection, the user is then prompted for the necessary password before the file will be loaded. Note that the password is case sensitive.<br>
<br>
When a database file is opened in the 'exclusive' mode the database files that as a result are being closed are checked to see if any component has been 'added' from them. The user is then warned that closing this file will lose the 'added' component details. <br>
<br>
As database files are opened the file names are added to the <u>Database</u> / <u>Close</u> and <u>Database</u> / <u>Details</u> pull down menu lists.<br>
<br>
To close a database file select the required file name from the <u>Database</u> / <u>Close</u> list. The user will be warned if this database file currently has a component 'added' from it, and that this selection will be lost.<br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u> <br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Viewing a DataBase File<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">The details of an existing database file can be viewed by selecting the menu item <u>DataBase</u></font></font></font> / <u>View</u> from the wizard menubar. The file browser is opened to allow the user to select the required file. The default extension for Lotus Vehicle Simulation database files is *.dbs.<br>
<br>
If a database file has 'read' protection, the user is then prompted for the necessary password before the file can be viewed. Note that the password is case sensitive.<br>
<br>
The details of the particular selected database file are then displayed, giving filename, protection status, entry name and the descriptive strings.<br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Listing DataBase File Details<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">The details of an opened database file can be viewed by selecting the required filename from the list of opened files under the menu item <u>DataBase</u></font></font></font> / <u>Details</u> from the wizard menubar.<br>
<br>
The details of the particular selected database file are then displayed, giving filename, protection status, file number, entry name and the descriptive strings.<br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Listing Details of a Component<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">Within the database wizard the available components are listed for the current selected component type. The component type is set by selecting the required component from the component icons arranged under the three categories of 'Compulsory', 'Optional' and 'Controllers'. Selecting the required component will change the list title and update the list entries. To identify what component an icon represents select it with the right mouse button.<br>
<br>
To display the details of a particular component, with the required component highlighted in the list select the 'details' button below the list. Alternatively again with the required component highlighted in the list use the right mouse button and select 'details' from the pop-up menu.<br>
</font></font></font><br>
The details of the particular selected component are then displayed, giving the component type, its database filename, itas entry no. in the file, entry name and the descriptive strings.<br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Listing Properties of a Component<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">Within the database wizard the available components are listed for the current selected component type. The component type is set by selecting the required component from the component icons arranged under the three categories of 'Compulsory', 'Optional' and 'Controllers'. Selecting the required component will change the list title and update the list entries. To identify what component an icon represents select it with the right mouse button.<br>
<br>
To display the properties of a particular component, with the required component highlighted in the list select the 'properties' button below the list. Alternatively again with the required component highlighted in the list use the right mouse button and select 'properties' from the pop-up menu.<br>
</font></font></font><br>
The properties of the particular selected component are then displayed, giving the entry name, descriptive strings and the associated data. The data is displayed in a scrollable text region, (non-editable), in the standard 'Lotus Vehicle Simulation' data file format.<br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Editing Properties of a Component<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">Within the database wizard the available components are listed for the current selected component type. The component type is set by selecting the required component from the component icons arranged under the three categories of 'Compulsory', 'Optional' and 'Controllers'. Selecting the required component will change the list title and update the list entries. To identify what component an icon represents select it with the right mouse button.<br>
<br>
To edit the properties of a particular component, with the required component highlighted in the list select the menu item <u>Component</u></font></font></font> / <u>Edit</u> from the wizard menubar,. Alternatively again with the required component highlighted in the list use the right mouse button and select 'edit' from the pop-up menu.<br>
<br>
The properties of the particular selected component are then displayed, giving the entry name, descriptive strings and the associated data. The data is displayed in a scrollable editable text region, in the standard <u>'Lotus Vehicle Simulation' data file format</u>.<br>
<br>
The data, (and text strings), can be edited and the changes saved by selecting 'ok', the user is warned that this will permanently change the stored data, and if it is a component that has currently been 'added' to the database wizard model, that this will change the data selection. Selecting 'cancel will ignore any changes made. <br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u> <br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Removing a Component from a DataBase File<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">Within the database wizard the available components are listed for the current selected component type. The component type is set by selecting the required component from the component icons arranged under the three categories of 'Compulsory', 'Optional' and 'Controllers'. Selecting the required component will change the list title and update the list entries. To identify what component an icon represents select it with the right mouse button.<br>
<br>
To remove a particular component from an existing database file, with the required component highlighted in the list select the menu item <u>Component</u></font></font></font> / <u>Remove</u> from the wizard menubar,. Alternatively again with the required component highlighted in the list use the right mouse button and select 'remove' from the pop-up menu.<br>
<br>
The user is warned that this will permanently removed the selected component from the database file, and if it is a component that has currently been 'added' to the database wizard model, that this will lose this data selection.<br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Adding a Component to a DataBase File<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">Within the database wizard the available components are listed for the current selected component type. The component type is set by selecting the required component from the component icons arranged under the three categories of 'Compulsory', 'Optional' and 'Controllers'. Selecting the required component will change the list title and update the list entries. To identify what component an icon represents select it with the right mouse button.<br>
<br>
To add a particular component to an existing database file the required database file must be open and be the only database file opened. The component data required to save should have been loaded into Lotus Vehicle Simulation as part of a conventional Lotus Vehicle Simulation data file.<br>
</font></font></font><br>
From the wizard menubar select <u>Component</u> / <u>Check-in</u> and then the required component, if the required component is 'greyed' out then the data for that component has not been loaded into Lotus Vehicle Simulation.<br>
<br>
The properties of the particular component to be added are then displayed, giving the entry name, descriptive strings and the associated data. The data is displayed in a scrollable editable text region, in the standard <u>'Lotus Vehicle Simulation' data file format</u>. This data and text can be edited prior to adding to the database file. An entry name must be given.<br>
<br>
Users should take every care to ensure that the data saved to a database file is both valid and clearly identified such that it can be safely recovered and used. Ideally data should have at least been checked with the data-checking wizard.<br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Selecting a Component from the DataBase<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">Within the database wizard the available components are listed for the current selected component type. The component type is set by selecting the required component from the component icons arranged under the three categories of 'Compulsory', 'Optional' and 'Controllers'. Selecting the required component will change the list title and update the list entries. To identify what component an icon represents select it with the right mouse button.<br>
<br>
To add a particular component into your database wizard model, with the required component highlighted in the list select the 'add' button below the list. Alternatively again with the required component highlighted in the list use the right mouse button and select 'add' from the pop-up menu.<br>
</font></font></font><br>
If this component type has already been 'added' you will be asked to confirm that you wish to replace your previous section with this selection.<br>
<br>
To indicate that this component has been added to the wizard model the particular icon on the graphical display will change from white text on a coloured background to coloured text on a grey background. In this way you can clearly see which components have been selected.<br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Cancelling a Component Selection<br>
</font></b><font size="2"><br>
To cancel the selection of a particular component in your database wizard model, select the required component by ensuring that the component icon on the graphical display portion of the wizard is 'indented', ( use left mouse button to select) . With the required component selected use the right mouse button and select 'remove' from the pop-up menu.<br>
<br>
You will be asked to confirm that you wish to cancel your previous section, and the component will then be displayed as 'unselected'.<br>
</font><br>
To indicate that this component has been 'unselcted' from the wizard model the particular icon on the graphical display will change from coloured text on a grey background to white text on a coloured background. In this way you can clearly see which components are still selected.<br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><sup>A</sup><b><font size="4">Listing Details of a Selected Component<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To display the details of a selected component, select with the left mouse button from the graphical display on the wizard, the icon for the required component such that it is indented, (do not confuse the component icons at the top left of the wizard window with those on the graphical display. The icons on the top left are for setting the current component type when adding components to the wizard model, whilst those on the graphical display indicate which components have been added and allow specific functions to be applied to them). Use the right mouse button and select 'details' from the pop-up menu.<br>
</font></font></font><br>
The details of the current selection for that component are then displayed, giving the component type, its database filename, itas entry no. in the file, entry name and the descriptive strings.<br>
<br>
If no current selection exists for that component, the user is informed via a reduced pop-up menu.<br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><sup>A</sup><b><font size="4">Listing Properties of a Selected Component<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To display the properties of a selected component, select with the left mouse button from the graphical display on the wizard, the icon for the required component such that it is indented, (do not confuse the component icons at the top left of the wizard window with those on the graphical display. The icons on the top left are for setting the current component type when adding components to the wizard model, whilst those on the graphical display indicate which components have been added and allow specific functions to be applied to them). Use the right mouse button and select 'properties' from the pop-up menu.<br>
</font></font></font><br>
The properties of the current selection for that component are then displayed, giving the entry name, descriptive strings and the associated data. The data is displayed in a scrollable text region, (non-editable), in the standard <u>'Lotus Vehicle Simulation' data file format</u>.<br>
<br>
If no current selection exists for that component, the user is informed via a reduced pop-up menu.<br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Making the Selected Data Current<br>
</font></b><font face="Times New Roman"><font size="2"><br>
<font face="Arial">To move the selected component data from the database wizard and copy it into your Lotus Vehicle Simulation data you must use the <u>File</u></font></font></font> / <u>Make Current</u> menu item from the database wizard menubar. This will extract the data values from the database files for the selected components and load them into the current Lotus Vehicle Simulation data. This will overwrite any current Lotus Vehicle Simulation data for the components selected. Note that the Lotus Vehicle Simulation data values for components not selected within the wizard are left unchanged, thus individual components can be extracted from database files and added to or replace existing components in your Lotus Vehicle Simulation data.<br>
<br>
{button ,AL(`list16',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
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<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Users Guide - File Formats</font></b><font size="3"><br>
</font><b><br>
</b><font size="2">LOTUS VEHICLE SIMULATION uses several file types for the storage of data and results. These are:<br>
<br>
</font><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">*.car : Contains the model data eg. Chassis, engine and transmission specifications<b><font size="3"><br>
</font></b></font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">*_n.crs : Text results file detailing modelled specification and simulation results<b><font size="3"><br>
</font></b></font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">*_n.grs : Graphical results file containing complete simulation results<b><font size="3"><br>
</font></b></font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">*_n.grd : Text results file containing grid simulation results<b><font size="3"><br>
</font></b></font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">*.cyc : User drive-cycle datafile - created using cycle builder<b><font size="3"><br>
</font></b></font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">*.ord : User track datafile - created using track builder<b><font size="3"><br>
</font></b></font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">*.prn : Space delimited column format results file<b><font size="3"><br>
</font></b></font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">*.txt : Tab delimited column format results file<b><font size="3"><br>
</font></b></font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">*.csv : Comma delimited column format results file<b><font size="3"><br>
</font></b></font></font></span><span style="font-size:9pt">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<font face="Arial"><font size="2">*.stg : STAGS graph files - for the Lotus graph plotting software program </font></font></span><font face="Times New Roman"><font face="Arial">STAGS</font></font><font face="Times New Roman"><font face="Arial"><b><font size="3"><br>
</font></b></font></font><br>
<font size="2">For the </font><font face="Times New Roman"><font face="Arial">crs</font></font><font face="Times New Roman"><font face="Arial">, </font></font><font face="Times New Roman"><font face="Arial">grs</font></font><font face="Times New Roman"><font face="Arial"> and </font></font><font face="Times New Roman"><font face="Arial">grd</font></font><font face="Times New Roman"><font face="Arial"> files n is the <i>Plot File Counter</i></font></font> number which is incremented for each calculation, and the <font face="Times New Roman"><font face="Arial">*</font></font><font face="Times New Roman"><font face="Arial"> is the <i>Test No.</i></font></font> string supplied by the user, both are displayed in the vehicle data window.<br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Brief Explanations - Introduction</font></b><font size="3"><br>
</font><b><br>
</b><font size="2">The three basic steps necessary to create and run a LOTUS VEHICLE SIMULATION vehicle simulation are;<b><font size="3"><br>
</font></b></font><font size="2"><br>
</font>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Step 1 Generate the model data through either editing the data values into the appropriate data windows, or load them from an existing data file.<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Step 2 Select the required solution type, defining any user specific track or cycle file and solve.<br>
<br>
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
Step 3 Load the simulation results as either textual or graphical displays to review the calculated values.<br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Brief Explanations - Generating a Model</font></b><font size="3"><br>
</font><font size="2"><br>
Generating a model is the process by which the user identifies the modelling options required and sets the relevant data values. The data is for convenience broken down into eight major sub-sections, three of which are further sub-divided.<br>
<br>
Each sub-section has its own window that can be opened through either the main pull down menus or the <u>tool bar icons</u></font>.<br>
<br>
Some of the data sections are <font face="Times New Roman"><font face="Arial">optional</font></font><font face="Times New Roman"><font face="Arial">, where this is the case the sub section</font></font><font face="Times New Roman"><font face="Arial">s window will contain a combi-box to toggle the option </font></font><font face="Times New Roman"><font face="Arial">on</font></font><font face="Times New Roman"><font face="Arial"> and </font></font><font face="Times New Roman"><font face="Arial">off</font></font><font face="Times New Roman"><font face="Arial">. Optional data values will be </font></font><font face="Times New Roman"><font face="Arial">greyed</font></font><font face="Times New Roman"><font face="Arial"> out until their option is set </font></font><font face="Times New Roman"><font face="Arial">on</font></font><font face="Times New Roman"><font face="Arial">.<br>
</font></font><br>
Where the data values are of a graphical nature the <u>graph icon</u> can be used to open the graphical display of the data for viewing, listing, printing etc.<br>
<br>
Each required sub sections window should be opened in-turn and the required data values entered. Once entered, data values are retained even when that sub-section<font face="Times New Roman"><font face="Arial">s window is closed, data is only overwritten if a data file is </font></font><font face="Times New Roman"><font face="Arial">loaded</font></font><font face="Times New Roman"><font face="Arial"> or the </font></font><font face="Times New Roman"><font face="Arial">new</font></font><font face="Times New Roman"><font face="Arial"> file option is selected. The </font></font><font face="Times New Roman"><font face="Arial">new</font></font><font face="Times New Roman"><font face="Arial"> file option returns all modelling option settings to the defaults and zero</font></font><font face="Times New Roman"><font face="Arial">s all data values.<br>
</font></font><br>
A number of the data variables are selected from a combi-box, this presents a fixed list of the available choices and helps to minimise data entry errors. The validity of the current defined data can be checked using the <u><i>Data Checking Wizard</i></u><i></i> which identifies by section, any data irregularities.<br>
<br>
Spread sheet type forms are used for the entry of the 2d curves and 3d maps. The spread sheets support <font face="Times New Roman"><font face="Arial">cut and paste</font></font><font face="Times New Roman"><font face="Arial"> type functionality via the right mouse button, which can be used to speed up repetitive data entry. If the individual cells of a spread sheet are </font></font><font face="Times New Roman"><font face="Arial">greyed out</font></font><font face="Times New Roman"><font face="Arial"> this implies that either the relevant option is </font></font><font face="Times New Roman"><font face="Arial">off</font></font><font face="Times New Roman"><font face="Arial"> or that the necessary spread sheet dimension(s) variable has not been set. Where multiple curves or maps are employed </font></font><font face="Times New Roman"><font face="Arial">arrow</font></font><font face="Times New Roman"><font face="Arial"> icons are used to step through the defined data sets.<br>
</font></font><br>
Existing data files can be loaded using either the <u>file open icon</u>, or by using the pull down menu options. Since the <font face="Times New Roman"><font face="Arial">*.car</font></font><font face="Times New Roman"><font face="Arial"> data files are ASCII text files and can thus be edited direct, two tools are provided within Lotus Vehicle Simulation to allow the user to either view the file or view and edit the data file. A direct link exists between these tools and the Lotus Vehicle Simulation data windows to allow data to be transferred between them without having to write and load data files.<br>
</font></font><br>
{button ,AL(`list10',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup><b><font size="4">Brief Explanations - Solving a Model</font></b><font size="3"><br>
</font><font size="2"><br>
The solve module controls which particular calculation run is performed from the available options. The user can specify a steady speed test, an acceleration test, an emissions test and a track test, with sub-options available with each. Sub solution options included setting the required shift map, identifying the particular emissions cycle or selecting the target acceleration.<br>
<br>
To solve a model <u>open</u></font> the <i>Calculation Set-up</i> window and <u>set</u> the required solution run, setting any relevant sub options and solution run values.<br>
<br>
Once the run has been defined selecting the <u>run icon</u> will perform the calculations, displaying either a simple progress bar or the animated results on the <u>telemetry screen</u>.<br>
<br>
<br>
{button ,AL(`list9',0,&quot;&quot;,`main')} <u>Related Topics</u><br>
<font face="Times New Roman"><br>
<font face="Arial"><br>
<p><hr><p>
<sup>+</sup><sup>$</sup><sup>#</sup><sup>&gt;</sup></font></font><b><font size="4">Brief Explanations - Viewing Results</font></b><font size="3"><br>
</font><font size="2"><br>
The <i>Result File Viewer</i></font> is a scrollable resizable text window that allows the user to load, read and print the Lotus Vehicle Simulation text results files. These text results files contain a summary of the input data, the solution type and the major results pertinent to the solution run.<br>
<br>
{button ,AL(`list7',0,&quot;&quot;,`main')} <u>Related Text Results Topics</u><br>
<br>
The <i>Result Graph Viewer</i> is a resizable graphics window that allows the user to load, plot and print the Lotus Vehicle Simulation graphical results files that contain up to 77 calculated variables. Within the window a maximum of four graphs can be plotted, either as individual plots or overlayed on a single graph. All graphs are plotted against a single common x-axis variable. Cross plotting of up to five graphical results can be employed to enable rapid presentation of trends and differences to be performed.<br>
<br>
{button ,AL(`list8',0,&quot;&quot;,`main')} <u>Related Graph Results Topics</u><br>
<font face="Times New Roman"><br>
<font face="Arial">Once the calculation is complete the results either textual or graphical can be loaded into the appropriate window. <br>
<br>
For text results <u>open</u></font></font> the text results file viewer and <u>load</u> the required text results file, selecting <u>load current</u> will load the last runs text results.<br>
<br>
For graph results <u>open</u> the graph viewer and <u>load</u> the required graphical results file, selecting <u>load current</u> will load the last runs graphical results.<font face="Times New Roman"><br>
</font><br>
<font face="Arial">If the variables displayed need to be changed, open the <u><i>specify graph axes</i></u></font><i></i> window and set the required axes. The <u><i>Autoscale</i></u><i></i>. <u><i>Zoom</i></u><i> </i>and <u><i>Axis Scales</i></u><i></i> functions can be used to manipulated the actual displayed area.<br>
<br>
Additional functionality can be used to <u>cross plot</u> the results against a previous run, <u>list point values</u> and <u>generate hard copies</u> of the graphs.<br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Naturally Aspirated / Turbocharged Simulation Input File<br>
</font></b></font><font size="2"><br>
NATURALLY ASPIRATED SIMULATION INPUT FILE<br>
</font><br>
ELAN 1.6 NA<br>
SIMULATION<br>
elana 301<br>
VEHICLE<br>
1175.<br>
1.920 0.3300 0.0000E+00 0.0000E+00 0.0000E+00<br>
1.205<br>
2.250 1.000 1.000 0.7425 0.4200<br>
TYRE<br>
0.2830<br>
2 1.000 0.9500<br>
10.00 -0.6418E-01 0.4274E-02 0.0000E+00 0.0000E+00 0.0000E+00<br>
DRIVE<br>
1<br>
0.3692 0.3713<br>
0.1000E-04 0.0000E+00<br>
4.117 0.9700 2<br>
GEARBOX<br>
5 200.0 0.0000E+00 2<br>
3.333 0.9600 0.3600E-03<br>
1.916 0.9600 0.1700E-03<br>
1.333 0.9600 0.1400E-03<br>
1.027 0.9500 0.1100E-03<br>
0.8290 0.9500 0.9000E-04<br>
GSHIFT<br>
0<br>
CLUTCH<br>
1 5.000<br>
PDRIVE<br>
1.000 1.000 2<br>
ENGINE<br>
1<br>
80.00 79.00 10.00 4 4 0.8200E-01<br>
1000. 7600.<br>
19<br>
1000. 7.980<br>
1400. 8.440<br>
1800. 8.900<br>
2200. 9.130<br>
2600. 9.440<br>
3000. 9.670<br>
3400. 9.900<br>
3800. 10.21<br>
4200. 10.55<br>
4600. 10.75<br>
5000. 10.59<br>
5400. 10.55<br>
5800. 10.44<br>
6200. 10.17<br>
6600. 10.00<br>
7000. 9.750<br>
7200. 9.670<br>
7400. 9.290<br>
7600. 8.910<br>
<br>
<b>TURBOCHARGED SIMULATION INPUT FILE</b><br>
<br>
ELAN 1.6 TURBO<br>
SIMULATION<br>
elant 301<br>
VEHICLE<br>
1191.<br>
1.920 0.3300 0.0000E+00 0.0000E+00 0.0000E+00<br>
1.205<br>
2.250 0.0000E+00 0.0000E+00 0.7425 0.4200<br>
TYRE<br>
0.2830<br>
2 1.000 0.9500<br>
10.00 -0.6418E-01 0.4274E-02 0.0000E+00 0.0000E+00 0.0000E+00<br>
DRIVE<br>
1<br>
0.3692 0.3713<br>
0.1000E-04 0.0000E+00<br>
3.833 0.9700 2<br>
GEARBOX<br>
5 200.0 0.0000E+00 2<br>
3.333 0.9600 0.3600E-03<br>
1.916 0.9600 0.1700E-03<br>
1.333 0.9600 0.1400E-03<br>
1.027 0.9500 0.1100E-03<br>
0.8290 0.9500 0.9000E-04<br>
GSHIFT<br>
0<br>
CLUTCH<br>
1 5.000<br>
PDRIVE<br>
1.000 1.000 2<br>
ENGINE<br>
1<br>
80.00 79.00 10.00 4 4 0.8200E-01<br>
1000. 7000.<br>
13<br>
1000. 7.320<br>
1500. 10.52<br>
2000. 12.96<br>
2500. 14.42<br>
3000. 15.21<br>
3500. 15.61<br>
4000. 15.77<br>
4500. 15.77<br>
5000. 15.77<br>
5500. 15.57<br>
6000. 15.02<br>
6500. 14.30<br>
7000. 12.88<br>
<br>
<p><hr><p>
<sup>#</sup><sup>&gt;</sup><b><font size="4">Naturally Aspirated / Turbocharged Simulation Results Files<br>
</font></b><font face="Times New Roman"><font size="2"><br>
</font></font><font face="Arial"><b><font size="3"><center>NATURALLY ASPIRATED SIMULATION RESULTS FILE</font></b></font><font face="Courier"><font size="2"><br>
</font></font></center>
<font face="Courier New">===================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p2<br>
Test No. elana Counter No. 1<br>
run at 10:37:45 on 26/ 5/98<br>
====================================================================<br>
<br>
ELAN 1.6 NA<br>
SIMULATION<br>
RESULTS<br>
~~~~~~~<br>
Vehicle Acceleration From Rest (Slip start)<br>
</font> <br>
Total Cycle Time . . . 80.0 s<br>
<br>
Dist Travelled (nom) . 3570.0 m<br>
Dist Travelled (nom) . 3.570 km<br>
Dist Travelled (nom) . 2.218 miles<br>
Mean Power Developed . 84.70 kw<br>
<br>
Default Gear Shift Map<br>
No. of Gear Changes 4<br>
<br>
Time to Speed<br>
MPH Time (s) Ratio:1 RPM KMH Time (s) Ratio:1 RPM<br>
0 - 10 = 0.891 3.333 4595. 0 - 10 = 0.551 3.333 4596.<br>
0 - 20 = 1.802 3.333 4593. 0 - 20 = 1.111 3.333 4595.<br>
0 - 30 = 2.877 3.333 6377. 0 - 30 = 1.678 3.333 4593.<br>
0 - 40 = 4.434 1.916 4840. 0 - 40 = 2.303 3.333 5291.<br>
0 - 50 = 6.300 1.916 6045. 0 - 50 = 3.001 3.333 6601.<br>
0 - 60 = 8.363 1.916 7245. 0 - 60 = 3.947 1.916 4512.<br>
0 - 70 = 11.320 1.333 5860. 0 - 70 = 5.073 1.916 5262.<br>
0 - 80 = 14.773 1.333 6693. 0 - 80 = 6.244 1.916 6011.<br>
0 - 90 = 18.931 1.333 7522. 0 - 90 = 7.492 1.916 6757.<br>
0 - 100 = 25.981 1.027 6430. 0 - 100 = 8.850 1.916 7497.<br>
0 - 110 = 36.120 1.027 7070. 0 - 110 = 10.798 1.333 5722.<br>
0 - 120 = 12.833 1.333 6240.<br>
0 - 130 = 15.064 1.333 6758.<br>
0 - 140 = 17.553 1.333 7274.<br>
0 - 150 = 21.001 1.027 5994.<br>
0 - 160 = 25.513 1.027 6392.<br>
0 - 170 = 31.099 1.027 6791.<br>
0 - 180 = 38.645 1.027 7189.<br>
0 - 190 = 53.345 1.027 7583.<br>
<br>
Time to Distance<br>
Time (s) Ratio:1 RPM MPH KMH<br>
400 M = 16.5003 1.3330 7063.7 84.5 135.9<br>
1/4 Mile = 16.5621 1.3330 7076.4 84.6 136.2<br>
Kilometre = 30.4462 1.0270 6749.1 105.0 169.0<br>
Mile = 42.8175 1.0270 7347.3 114.3 184.0<br>
<br>
Distance in Time<br>
Distance in 3.0 seconds = 22.225 m<br>
Distance in 5.0 seconds = 55.933 m<br>
<br>
Gear Change Points<br>
Distance (m) Time (s) Ratio:1 RPM MPH KMH<br>
30.1 3.5250 3.3330 7497.6 35.4 56.9<br>
152.2 9.0250 1.9160 7582.8 62.9 101.2<br>
514.9 19.4250 1.3330 7596.4 91.0 146.4<br>
2251.5 55.1244 1.0270 7599.9 118.4 190.5<br>
<br>
=====================================================================<br>
<br>
<font face="Arial"><b><font size="3"><center>TURBOCHARGED SIMULATION RESULTS FILE</font></b></font><font face="Courier New"><font size="2"><br>
</font></font></center>
<br>
=====================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p2<br>
Test No. elant Counter No. 2<br>
run at 10:38:59 on 26/ 5/98<br>
===================================================================<br>
<br>
ELAN 1.6 TURBO<br>
SIMULATION<br>
RESULTS<br>
~~~~~~~<br>
Vehicle Acceleration From Rest (Slip start)<br>
<br>
Total Cycle Time . . . 80.0 s<br>
<br>
Dist Travelled (nom) . 4071.0 m<br>
Dist Travelled (nom) . 4.071 km<br>
Dist Travelled (nom) . 2.530 miles<br>
Mean Power Developed . 117.41 kw<br>
<br>
Default Gear Shift Map<br>
No. of Gear Changes 4<br>
<br>
Time to Speed<br>
MPH Time (s) Ratio:1 RPM KMH Time (s) Ratio:1 RPM<br>
0 - 10 = 0.866 3.333 1994. 0 - 10 = 0.536 3.333 1825.<br>
0 - 20 = 1.736 3.333 3997. 0 - 20 = 1.081 3.333 2484.<br>
0 - 30 = 2.605 3.333 5995. 0 - 30 = 1.618 3.333 3725.<br>
0 - 40 = 3.787 1.916 4539. 0 - 40 = 2.157 3.333 4967.<br>
0 - 50 = 5.089 1.916 5669. 0 - 50 = 2.698 3.333 6209.<br>
0 - 60 = 6.535 1.916 6780. 0 - 60 = 3.440 1.916 4231.<br>
0 - 70 = 8.604 1.333 5482. 0 - 70 = 4.236 1.916 4935.<br>
0 - 80 = 10.841 1.333 6258. 0 - 80 = 5.050 1.916 5637.<br>
0 - 90 = 13.664 1.027 5408. 0 - 90 = 5.916 1.916 6331.<br>
0 - 100 = 17.399 1.027 6006. 0 - 100 = 6.919 1.365 6891.<br>
0 - 110 = 22.119 1.027 6601. 0 - 110 = 8.260 1.333 5353.<br>
0 - 120 = 29.885 0.829 5805. 0 - 120 = 9.589 1.333 5837.<br>
0 - 130 = 44.911 0.829 6286. 0 - 130 = 11.030 1.333 6318.<br>
0 - 140 = 12.651 1.333 6796.<br>
0 - 150 = 14.788 1.027 5600.<br>
0 - 160 = 17.162 1.027 5972.<br>
0 - 170 = 19.890 1.027 6342.<br>
0 - 180 = 23.194 1.027 6710.<br>
0 - 190 = 27.986 0.829 5712.<br>
0 - 200 = 34.876 0.829 6011.<br>
0 - 210 = 46.111 0.829 6310.<br>
<br>
Time to Distance<br>
Time (s) Ratio:1 RPM MPH KMH<br>
400 M = 15.0697 1.0270 5646.9 94.0 151.3<br>
1/4 Mile = 15.1253 1.0270 5656.0 94.1 151.5<br>
Kilometre = 27.5386 0.8290 5688.5 117.6 189.2<br>
Mile = 38.6500 0.8290 6133.4 126.8 204.1<br>
<br>
Distance in Time<br>
Distance in 3.0 seconds = 23.566 m<br>
Distance in 5.0 seconds = 61.012 m<br>
<br>
Gear Change Points<br>
Distance (m) Time (s) Ratio:1 RPM MPH KMH<br>
24.0 3.0250 3.3330 6924.4 34.7 55.9<br>
106.7 6.8250 1.9160 6972.7 61.8 99.4<br>
332.5 13.4250 1.3330 6993.7 89.6 144.2<br>
952.2 26.6249 1.0270 6998.2 116.7 187.9<br>
<br>
============================================================================<br>
<br>
<p><hr><p>
<sup>#</sup><sup>&gt;</sup><font face="Arial"><b><font size="4">Engine Inertia Data<br>
</font></b></font><font size="3"><br>
<font size="2">The following curve provides a relatively general correlation for the relationship between engine inertia and the engine swept volume. This is a first approximation and can not be expected to provide close agreement for all types.<br>
<br>
<u><img data="bm78.bmp" title="bm78.bmp"></u></font></font><br>
<br>
<p><hr><p>
<sup>#</sup><sup>&gt;</sup><b><font size="4">Automatic Economy Simulation Input File<font face="Courier New"><br>
</font></font></b><font size="2">1.5L AUTOMATIC<br>
ECONOMY STUDY<br>
autotrans 301<br>
VEHICLE<br>
1205.<br>
1.950 0.3800 0.0000E+00 0.0000E+00 0.0000E+00<br>
1.205<br>
2.450 1.000 1.000 0.8860 0.6000<br>
DYNO<br>
1250. 345.0 0.0000E+00 0.8000E-01<br>
TYRE<br>
0.2810<br>
1 1.000 0.9500<br>
DRIVE<br>
2<br>
0.6770 0.6770<br>
0.0000E+00 0.0000E+00<br>
3.742 0.9600 2<br>
GEARBOX<br>
4 0.0000E+00 0.0000E+00 2<br>
3.027 0.9800 0.4330E-01<br>
</font> 1.619 0.9800 0.4470E-01<br>
1.000 0.9800 0.7520E-01<br>
0.6940 0.9800 0.7870E-01<br>
GSHIFT<br>
1<br>
Econ-Map<br>
10 1 3<br>
0.0000E+00<br>
0.0000E+00 12.00<br>
9.000 26.00<br>
9.000 35.00<br>
40.00 170.0<br>
0.4000<br>
0.0000E+00 12.00<br>
9.000 26.00<br>
14.00 35.00<br>
40.00 170.0<br>
0.7000<br>
0.0000E+00 12.00<br>
9.000 26.00<br>
19.00 35.00<br>
40.00 170.0<br>
0.7800<br>
0.0000E+00 12.00<br>
9.000 26.00<br>
20.00 65.00<br>
40.00 170.0<br>
0.8000<br>
0.0000E+00 12.00<br>
9.000 54.00<br>
20.00 86.00<br>
40.00 170.0<br>
0.8600<br>
0.0000E+00 12.00<br>
9.000 71.00<br>
30.00 110.0<br>
40.00 170.0<br>
0.9000<br>
0.0000E+00 12.00<br>
9.000 86.00<br>
48.00 130.0<br>
87.00 170.0<br>
0.9400<br>
0.0000E+00 12.00<br>
9.000 100.0<br>
66.00 154.0<br>
104.0 170.0<br>
0.9800<br>
0.0000E+00 12.00<br>
44.00 103.0<br>
75.00 170.0<br>
142.0 170.0<br>
1.000<br>
0.0000E+00 58.00<br>
44.00 103.0<br>
75.00 170.0<br>
142.0 170.0<br>
2 0<br>
TORQUE CONVERTER<br>
11<br>
0.0000000E+00 0.1000000 0.2000000 0.3000000 0.4000000<br>
0.5000000 0.6000000 0.7000000 0.8000000 0.9000000<br>
1.000000<br>
2.280000 2.120000 1.960000 1.800000 1.640000<br>
1.480000 1.320000 1.160000 1.000000 1.000000<br>
1.000000<br>
23.30000 23.40000 23.60000 23.80000 24.10000<br>
24.80000 25.80000 27.10000 29.30000 37.40000<br>
1000.000<br>
1 1 1<br>
1.000 6000. 6000. 3200. 3200.<br>
2050. 2050. 1400. 1400.<br>
0<br>
PDRIVE<br>
1.000 1.000 1<br>
ENGINE<br>
1<br>
77.00 79.00 10.00 4 4 0.1261<br>
850.0 6500.<br>
16<br>
850.0 7.370<br>
1000. 7.620<br>
1400. 8.210<br>
1800. 8.800<br>
2200. 9.130<br>
2600. 9.880<br>
3000. 10.05<br>
3400. 9.800<br>
3800. 9.800<br>
4200. 10.14<br>
4600. 10.22<br>
5000. 9.800<br>
5400. 9.630<br>
5800. 9.130<br>
6200. 8.290<br>
6500. 7.120<br>
MAPS<br>
16<br>
850.0 1000. 1400. 1800. 2200.<br>
2600. 3000. 3400. 3800. 4200.<br>
4600. 5000. 5400. 5800. 6200.<br>
6500.<br>
12<br>
0.1000E-01 0.8380 1.676 2.514 3.352<br>
4.190 5.028 5.866 6.704 7.542<br>
8.380 9.218<br>
1<br>
1 2 0.7500 0.4200E+05 1.00 FUEL g/kW.h<br>
0.6973E+05 1008. 572.9 504.1 406.7<br>
368.3 351.8 368.3 376.6 408.3<br>
440.2 471.7<br>
0.5930E+05 816.3 462.1 381.0 340.1<br>
313.1 299.1 313.1 320.1 347.1<br>
374.2 401.0<br>
0.4781E+05 748.0 461.9 374.0 313.0<br>
299.0 292.0 286.0 286.0 298.9<br>
326.1 353.1<br>
0.3865E+05 680.0 449.0 367.0 313.0<br>
299.0 279.0 270.0 264.9 270.1<br>
299.0 311.9<br>
0.3651E+05 653.1 435.1 353.0 299.0<br>
292.0 278.9 270.0 264.9 270.0<br>
286.0 300.0<br>
0.3701E+05 748.0 476.0 367.0 306.0<br>
292.1 286.1 278.9 264.9 265.0<br>
279.1 299.0<br>
0.3798E+05 748.0 476.0 353.0 313.0<br>
299.0 285.9 278.9 271.9 265.0<br>
286.0 313.0<br>
0.3874E+05 680.1 449.0 367.2 318.9<br>
313.0 291.9 278.9 279.0 286.0<br>
313.0 313.0<br>
0.3871E+05 653.0 449.0 381.1 340.0<br>
326.0 326.1 340.1 326.0 326.0<br>
313.0 313.0<br>
0.3872E+05 748.0 517.2 407.9 393.9<br>
374.0 347.0 353.0 340.0 326.0<br>
319.0 313.0<br>
0.5478E+05 789.0 639.0 544.0 476.0<br>
435.0 394.0 367.0 360.0 353.0<br>
340.0 333.0<br>
0.6829E+05 952.2 789.0 585.1 489.1<br>
476.0 428.0 421.0 401.0 381.0<br>
367.0 381.0<br>
0.7976E+05 1292. 816.1 639.0 530.0<br>
516.9 476.0 462.0 449.0 408.0<br>
394.0 408.0<br>
0.9116E+05 1400. 856.2 666.0 612.0<br>
544.0 502.9 476.0 469.0 442.0<br>
428.0 442.0<br>
0.9120E+05 1496. 952.1 692.9 666.1<br>
598.1 544.0 530.0 476.0 476.0<br>
476.0 496.0<br>
0.9950E+05 1577. 982.8 710.9 672.6<br>
600.3 543.8 526.9 472.7 470.7<br>
469.0 486.7<br>
2<br>
0.1220 0.1220 0.1220 0.1220 0.1220<br>
0.1200 0.1220 0.1220 0.1220 0.1220<br>
0.1220 0.1220 0.1220 0.1220 0.1220<br>
0.1220<br>
AUXILIARIES<br>
1<br>
AIR-CON<br>
1 2 1.000 0.1000E-02<br>
1000. 15.13<br>
6000. 15.13<br>
DRIVER<br>
0.5000 1.000 0.5000 0.3000 0.3000 0<br>
<br>
<p><hr><p>
<sup>#</sup><sup>&gt;</sup><font face="Arial"><b><font size="4">Economy Simulation Results<br>
</font></b></font><font face="Courier New"><font size="2"> <br>
====================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p1<br>
Test No. at3 Counter No. 5<br>
run at 7:53: 6 on 27/ 5/98<br>
=====================================================================<br>
<br>
1.5L AUTOMATIC<br>
ECONOMY STUDY<br>
INPUT DATA<br>
~~~~~~~~~~<br>
</font></font> VEHICLE<br>
~~~~~~~<br>
Weight . . . . . . . . 1205.0 kg<br>
Frontal Area . . . . . 1.950 m2 Plan Area. . . . . . . 0.000 m2<br>
Air Density. . . . . . 1.205 kg/m3 Drag Coefficient . . . 0.380<br>
Front Lift Coeff . . . 0.000 Rear Lift Coeff. . . . 0.000<br>
Wheel Base . . . . . . 2.45 m Track. . . . . . . . . 1.00 m<br>
CoG to front axle. . . 0.89 m CoG to ground. . . . . 0.60 m<br>
DYNAMOMETER<br>
~~~~~~~~~~~<br>
Dyno Inertia Weight. . 1250.0 kg Load A constant. . . . 345.000<br>
Load B*v constant. . . 0.000 Load C*v2 constant . . 0.080<br>
TYRE<br>
~~~~<br>
Rolling Radius . . . . 0.2810 m Coeff.of Friction. . . 1.000<br>
Default Rolling Resistance Coefficients<br>
DRIVELINE<br>
~~~~~~~~~<br>
Rear wheel drive<br>
Total Inertia Fr Wheels 1.354 kg.m2 Total Inertia Rr Wheels 1.354 kg.m2<br>
Driven Axle Inertia . . 0.000 kg.m2 Prop Shaft Inertia. . . 0.000 kg.m2<br>
Final Drive Ratio . . . 3.742 Final Drive Efficiency. 0.960<br>
GEARBOX<br>
~~~~~~~<br>
Automatic<br>
Number of ratios. . . . 4<br>
Gear change Time. . . . 0.3 s Min Time Between Shifts 0.3 s<br>
Default Max Gearbox Torque. Default Max Gearbox Speed<br>
Gear. . 1 Ratio . 3.0270 Effy. . 0.980 Box Inertia. 0.0433 kg.m2<br>
Overall Ratio . 11.3270 O.Effy. 0.941 MPH/1000 RPM 5.81<br>
Gear. . 2 Ratio . 1.6190 Effy. . 0.980 Box Inertia. 0.0447 kg.m2<br>
Overall Ratio . 6.0583 O.Effy. 0.941 MPH/1000 RPM 10.87<br>
Gear. . 3 Ratio . 1.0000 Effy. . 0.980 Box Inertia. 0.0752 kg.m2<br>
Overall Ratio . 3.7420 O.Effy. 0.941 MPH/1000 RPM 17.59<br>
Gear. . 4 Ratio . 0.6940 Effy. . 0.980 Box Inertia. 0.0787 kg.m2<br>
Overall Ratio . 2.5969 O.Effy. 0.941 MPH/1000 RPM 25.35<br>
T.Converter Stall Speed 2331.4 rpm<br>
ENGINE<br>
~~~~~~~<br>
Internal combustion engine<br>
Number of Cylinders . 4 Cycle Type . . . . . . 4<br>
Bore . . . . . . . . . 77.00 mm Stroke . . . . . . . . 79.00 mm<br>
Swept Volume . . . . . 1.4715 l Rotating Inertia . . . 0.1261 kg.m2<br>
Idle Speed . . . . . . 850.0 rpm Max Engine Speed . . . 6500.0 rpm<br>
Max Power. . . . . . . 64.9 kw Max Power Speed .. . . 5800.0 rpm<br>
Max Torque . . . . . . 119.7 nm Max Torque Speed . . . 4600.0 rpm<br>
Primary Drive Ratio. . 1.000 Primary Drive Effy . . 1.000<br>
Power/Weight Ratio . . 53.9 kw/tonne<br>
<br>
=====================================================================<br>
<br>
=====================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p2<br>
Test No. at3 Counter No. 5<br>
run at 7:53: 6 on 27/ 5/98<br>
=====================================================================<br>
<br>
1.5L AUTOMATIC<br>
ECONOMY STUDY<br>
RESULTS - Air Con off<br>
~~~~~~~<br>
Road Speed .. . . 40.0 kmh<br>
<br>
Total Cycle Time . . . 300.0 s<br>
<br>
Dist Travelled (nom) . 3222.2 m<br>
Dist Travelled (nom) . 3.222 km<br>
Dist Travelled (nom) . 2.002 miles<br>
Mean Power Developed . 6.29 kw<br>
<br>
User Specified Shift Map Econ-Map<br>
No. of Gear Changes 0<br>
<br>
Fuel Consumption from Map . . 1<br>
Litres per 100 km. . . 6.786 Km per Litre . . . . . 14.737 km/l<br>
Miles per Imp.Gallon . 41.63 mpg Miles per US Gallon. . 34.66 mpgUS<br>
Grams per Test . . . . 163.984 g<br>
Grams per KM . . . . . 50.892 g/km Grams per Mile . . . . 81.902 g/mil<br>
Mean Consumption . . . 1967.81 g/h Mean Spec.Consumption. 312.61 g/kw.h<br>
Overall Cycle Efficiency 27.419 %<br>
<br>
=====================================================================<br>
<br>
<br>
=====================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p2<br>
Test No. at3 Counter No. 6<br>
run at 7:53:28 on 27/ 5/98<br>
=====================================================================<br>
<br>
1.5L AUTOMATIC<br>
ECONOMY STUDY<br>
RESULTS - Air Con off <br>
~~~~~~~<br>
Road Speed .. . . 60.0 kmh<br>
<br>
Total Cycle Time . . . 300.0 s<br>
<br>
Dist Travelled (nom) . 4833.3 m<br>
Dist Travelled (nom) . 4.833 km<br>
Dist Travelled (nom) . 3.003 miles<br>
Mean Power Developed . 7.95 kw<br>
<br>
User Specified Shift Map Econ-Map<br>
No. of Gear Changes 0<br>
<br>
Fuel Consumption from Map . . 1<br>
Litres per 100 km. . . 5.379 Km per Litre . . . . . 18.591 km/l<br>
Miles per Imp.Gallon . 52.52 mpg Miles per US Gallon. . 43.73 mpgUS<br>
Grams per Test . . . . 194.982 g<br>
Grams per KM . . . . . 40.341 g/km Grams per Mile . . . . 64.923 g/mil<br>
Mean Consumption . . . 2339.79 g/h Mean Spec.Consumption. 294.33 g/kw.h<br>
Overall Cycle Efficiency 29.122 %<br>
<br>
=====================================================================<br>
<br>
<br>
=====================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p2<br>
Test No. at3 Counter No. 7<br>
run at 7:53:42 on 27/ 5/98<br>
=====================================================================<br>
<br>
1.5L AUTOMATIC<br>
ECONOMY STUDY<br>
RESULTS - Air Con off<br>
~~~~~~~<br>
Road Speed .. . . 80.0 kmh<br>
<br>
Total Cycle Time . . . 300.0 s<br>
<br>
Dist Travelled (nom) . 6444.4 m<br>
Dist Travelled (nom) . 6.444 km<br>
Dist Travelled (nom) . 4.004 miles<br>
Mean Power Developed . 11.25 kw<br>
<br>
User Specified Shift Map Econ-Map<br>
No. of Gear Changes 0<br>
<br>
Fuel Consumption from Map . . 1<br>
Litres per 100 km. . . 5.480 Km per Litre . . . . . 18.247 km/l<br>
Miles per Imp.Gallon . 51.55 mpg Miles per US Gallon. . 42.92 mpgUS<br>
Grams per Test . . . . 264.878 g<br>
Grams per KM . . . . . 41.102 g/km Grams per Mile . . . . 66.147 g/mil<br>
Mean Consumption . . . 3178.53 g/h Mean Spec.Consumption. 282.56 g/kw.h<br>
Overall Cycle Efficiency 30.335 %<br>
<br>
=====================================================================<br>
<br>
<br>
=====================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p2<br>
Test No. at3 Counter No. 8<br>
run at 7:53:47 on 27/ 5/98<br>
=====================================================================<br>
<br>
1.5L AUTOMATIC<br>
ECONOMY STUDY<br>
RESULTS - Air Con off<br>
~~~~~~~<br>
Road Speed .. . . 100.0 kmh<br>
<br>
Total Cycle Time . . . 300.0 s<br>
<br>
Dist Travelled (nom) . 8055.6 m<br>
Dist Travelled (nom) . 8.056 km<br>
Dist Travelled (nom) . 5.005 miles<br>
Mean Power Developed . 15.04 kw<br>
<br>
User Specified Shift Map Econ-Map<br>
No. of Gear Changes 0<br>
<br>
Fuel Consumption from Map . . 1<br>
Litres per 100 km. . . 5.862 Km per Litre . . . . . 17.060 km/l<br>
Miles per Imp.Gallon . 48.19 mpg Miles per US Gallon. . 40.13 mpgUS<br>
Grams per Test . . . . 354.145 g<br>
Grams per KM . . . . . 43.963 g/km Grams per Mile . . . . 70.751 g/mil<br>
Mean Consumption . . . 4249.74 g/h Mean Spec.Consumption. 282.54 g/kw.h<br>
Overall Cycle Efficiency 30.337 %<br>
<br>
=====================================================================<br>
<br>
=========================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p2<br>
Test No. at3 Counter No. 23<br>
run at 9:29:59 on 27/ 5/98<br>
=====================================================================<br>
<br>
1.5L AUTOMATIC<br>
ECONOMY STUDY<br>
RESULTS - Air Con off<br>
~~~~~~~<br>
User Defined Test Cycle Simulation - Japanese 10 mode<br>
<br>
Total Cycle Time . . . 545.5 s<br>
<br>
Dist Travelled (nom) . 2655.1 m Dist Travelled (act) . 2655.1 m<br>
Dist Travelled (nom) . 2.655 km Dist Travelled (act) . 2.655 km<br>
Dist Travelled (nom) . 1.650 miles Dist Travelled (act) . 1.650 miles<br>
Mean Power Developed . 4.31 kw<br>
<br>
User Specified Shift Map Econ-Map<br>
No. of Gear Changes 40<br>
<br>
Fuel Consumption from Map . . 1<br>
Litres per 100 km. . . 12.246 Km per Litre . . . . . 8.166 km/l<br>
Miles per Imp.Gallon . 23.07 mpg Miles per US Gallon. . 19.21 mpgUS<br>
Grams per Test . . . . 243.846 g<br>
Grams per KM . . . . . 91.842 g/km Grams per Mile . . . . 147.806 g/mil<br>
Mean Consumption . . . 1609.25 g/h Mean Spec.Consumption. 373.32 g/kw.h<br>
Overall Cycle Efficiency 22.960 %<br>
<br>
=====================================================================<br>
<font face="Times New Roman"><br>
<font face="Courier New"> =====================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p2<br>
Test No. at3 Counter No. 1<br>
</font></font> run at 7:50: 4 on 27/ 5/98<br>
=====================================================================<br>
<br>
1.5L AUTOMATIC<br>
ECONOMY STUDY<br>
RESULTS - Air Con on<br>
~~~~~~~<br>
Road Speed .. . . 40.0 kmh<br>
<br>
Total Cycle Time . . . 300.0 s<br>
<br>
Dist Travelled (nom) . 3222.2 m<br>
Dist Travelled (nom) . 3.222 km<br>
Dist Travelled (nom) . 2.002 miles<br>
Mean Power Developed . 8.71 kw<br>
<br>
User Specified Shift Map Econ-Map<br>
No. of Gear Changes 0<br>
<br>
Fuel Consumption from Map . . 1<br>
Litres per 100 km. . . 8.731 Km per Litre . . . . . 11.454 km/l<br>
Miles per Imp.Gallon . 32.35 mpg Miles per US Gallon. . 26.94 mpgUS<br>
Grams per Test . . . . 210.998 g<br>
Grams per KM . . . . . 65.482 g/km Grams per Mile . . . . 105.383 g/mil<br>
Mean Consumption . . . 2531.97 g/h Mean Spec.Consumption. 290.78 g/kw.h<br>
Overall Cycle Efficiency 29.478 %<br>
<br>
=====================================================================<br>
<br>
=====================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p2<br>
Test No. at3 Counter No. 2<br>
run at 7:51:29 on 27/ 5/98<br>
=====================================================================<br>
<br>
1.5L AUTOMATIC<br>
ECONOMY STUDY<br>
RESULTS - Air Con on<br>
~~~~~~~<br>
Road Speed .. . . 60.0 kmh<br>
<br>
Total Cycle Time . . . 300.0 s<br>
<br>
Dist Travelled (nom) . 4833.3 m<br>
Dist Travelled (nom) . 4.833 km<br>
Dist Travelled (nom) . 3.003 miles<br>
Mean Power Developed . 10.21 kw<br>
<br>
User Specified Shift Map Econ-Map<br>
No. of Gear Changes 0<br>
<br>
Fuel Consumption from Map . . 1<br>
Litres per 100 km. . . 6.631 Km per Litre . . . . . 15.081 km/l<br>
Miles per Imp.Gallon . 42.60 mpg Miles per US Gallon. . 35.47 mpgUS<br>
Grams per Test . . . . 240.370 g<br>
Grams per KM . . . . . 49.732 g/km Grams per Mile . . . . 80.035 g/mil<br>
Mean Consumption . . . 2884.43 g/h Mean Spec.Consumption. 282.49 g/kw.h<br>
Overall Cycle Efficiency 30.342 %<br>
<br>
=====================================================================<br>
<br>
=====================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p2<br>
Test No. at3 Counter No. 3<br>
run at 7:52: 1 on 27/ 5/98<br>
=====================================================================<br>
<br>
1.5L AUTOMATIC<br>
ECONOMY STUDY<br>
RESULTS - Air Con on<br>
~~~~~~~<br>
Road Speed .. . . 80.0 kmh<br>
<br>
Total Cycle Time . . . 300.0 s<br>
<br>
Dist Travelled (nom) . 6444.4 m<br>
Dist Travelled (nom) . 6.444 km<br>
Dist Travelled (nom) . 4.004 miles<br>
Mean Power Developed . 14.26 kw<br>
<br>
User Specified Shift Map Econ-Map<br>
No. of Gear Changes 0<br>
<br>
Fuel Consumption from Map . . 1<br>
Litres per 100 km. . . 6.600 Km per Litre . . . . . 15.152 km/l<br>
Miles per Imp.Gallon . 42.80 mpg Miles per US Gallon. . 35.64 mpgUS<br>
Grams per Test . . . . 318.992 g<br>
Grams per KM . . . . . 49.499 g/km Grams per Mile . . . . 79.661 g/mil<br>
Mean Consumption . . . 3827.91 g/h Mean Spec.Consumption. 268.36 g/kw.h<br>
Overall Cycle Efficiency 31.941 %<br>
<br>
=====================================================================<br>
<br>
<br>
=====================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p2<br>
Test No. at3 Counter No. 4<br>
run at 7:52:21 on 27/ 5/98<br>
=====================================================================<br>
<br>
1.5L AUTOMATIC<br>
ECONOMY STUDY<br>
RESULTS - Air Con on<br>
~~~~~~~<br>
Road Speed .. . . 100.0 kmh<br>
<br>
Total Cycle Time . . . 300.0 s<br>
<br>
Dist Travelled (nom) . 8055.6 m<br>
Dist Travelled (nom) . 8.056 km<br>
Dist Travelled (nom) . 5.005 miles<br>
Mean Power Developed . 18.81 kw<br>
<br>
User Specified Shift Map Econ-Map<br>
No. of Gear Changes 0<br>
<br>
Fuel Consumption from Map . . 1<br>
Litres per 100 km. . . 6.955 Km per Litre . . . . . 14.379 km/l<br>
Miles per Imp.Gallon . 40.62 mpg Miles per US Gallon. . 33.82 mpgUS<br>
Grams per Test . . . . 420.175 g<br>
Grams per KM . . . . . 52.160 g/km Grams per Mile . . . . 83.943 g/mil<br>
Mean Consumption . . . 5042.10 g/h Mean Spec.Consumption. 268.04 g/kw.h<br>
Overall Cycle Efficiency 31.979 %<br>
<br>
=====================================================================<br>
<font face="Times New Roman"> <br>
<font face="Courier New"> <br>
=====================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p2<br>
Test No. at3 Counter No. 24<br>
run at 9:30:41 on 27/ 5/98<br>
=====================================================================<br>
<br>
1.5L AUTOMATIC<br>
ECONOMY STUDY<br>
RESULTS - Air Con on<br>
~~~~~~~<br>
</font></font> User Defined Test Cycle Simulation - Japanese 10 Mode<br>
<br>
Total Cycle Time . . . 545.5 s<br>
<br>
Dist Travelled (nom) . 2655.2 m Dist Travelled (act) . 2655.2 m<br>
Dist Travelled (nom) . 2.655 km Dist Travelled (act) . 2.655 km<br>
Dist Travelled (nom) . 1.650 miles Dist Travelled (act) . 1.650 miles<br>
Mean Power Developed . 6.21 kw<br>
<br>
User Specified Shift Map Econ-Map<br>
No. of Gear Changes 24<br>
<br>
Fuel Consumption from Map . . 1<br>
Litres per 100 km. . . 15.977 Km per Litre . . . . . 6.259 km/l<br>
Miles per Imp.Gallon . 17.68 mpg Miles per US Gallon. . 14.72 mpgUS<br>
Grams per Test . . . . 318.164 g<br>
Grams per KM . . . . . 119.825 g/km Grams per Mile . . . . 192.840 g/mil<br>
Mean Consumption . . . 2099.71 g/h Mean Spec.Consumption. 338.23 g/kw.h<br>
Overall Cycle Efficiency 25.342 %<br>
<br>
=====================================================================<font face="Times New Roman"><br>
</font><br>
<p><hr><p>
<sup>#</sup><sup>&gt;</sup><font face="Arial"><b><font size="4">Emissions Simulation Input File<br>
</font></b></font><font face="Courier New"><font size="2">EMISSIONS SIMULATION<br>
LOTUS LEV RESEARCH<br>
lowemissionsvehicle 301<br>
VEHICLE<br>
1183.<br>
2.080 0.3300 0.0000E+00 0.0000E+00 0.0000E+00<br>
1.205<br>
2.520 1.000 1.000 0.9580 0.5800<br>
TYRE<br>
0.2896<br>
1 0.9800 0.9500<br>
DRIVE<br>
1<br>
0.7385 0.7385<br>
0.1000E-03 0.1000E-03<br>
3.550 0.9800 2<br>
GEARBOX<br>
5 -1.000 0.0000E+00 2<br>
3.550 0.9700 0.1000E-02<br>
2.160 0.9700 0.1000E-02<br>
</font></font> 1.480 0.9700 0.1000E-02<br>
1.120 0.9700 0.1000E-02<br>
0.8900 0.9700 0.1000E-02<br>
GSHIFT<br>
3<br>
EURO_shift<br>
1 10 3<br>
1.000<br>
0.0000E+00 15.00<br>
5.000 35.00<br>
5.000 50.10<br>
50.00 70.00<br>
69.00 150.0<br>
2 0<br>
FTP_shift<br>
1 10 4<br>
1.000<br>
0.0000E+00 15.00<br>
10.00 25.00<br>
20.00 40.00<br>
35.00 45.00<br>
40.00 150.0<br>
2 0<br>
ACC_shift<br>
1 10 1<br>
1.000<br>
1000. 6500.<br>
1000. 6500.<br>
1000. 6500.<br>
1000. 6500.<br>
1000. 6500.<br>
2 0<br>
CLUTCH<br>
1 5.000<br>
PDRIVE<br>
1.000 1.000 2<br>
ENGINE<br>
1<br>
79.00 81.50 10.00 4 4 0.0000E+00<br>
1000. 6200.<br>
14<br>
1000. 8.900<br>
1400. 9.700<br>
1800. 10.20<br>
2200. 10.80<br>
2600. 10.70<br>
3000. 11.10<br>
3400. 11.10<br>
3800. 11.80<br>
4200. 11.60<br>
4600. 11.80<br>
5000. 11.50<br>
5400. 10.60<br>
5800. 10.20<br>
6200. 9.700<br>
MAPS<br>
14<br>
1000. 1400. 1800. 2200. 2600.<br>
3000. 3400. 3800. 4200. 4600.<br>
5000. 5400. 5800. 6200.<br>
12<br>
1.000 2.000 3.000 4.000 5.000<br>
6.000 7.000 8.000 9.000 10.00<br>
11.00 12.00<br>
10<br>
1 2 0.7500 0.4200E+05 1.00 FUEL g/kW.h<br>
594.0 389.8 338.0 301.0 285.0<br>
273.0 280.0 257.0 275.0 274.9<br>
275.0 275.1<br>
574.9 397.1 338.0 293.0 271.0<br>
264.0 252.0 252.0 245.0 257.0<br>
257.0 257.0<br>
588.9 381.9 326.0 294.0 272.0<br>
259.1 248.0 250.1 244.0 269.0<br>
269.0 269.0<br>
591.1 385.9 325.0 291.0 272.1<br>
259.9 248.1 244.1 241.9 237.0<br>
251.0 248.0<br>
584.0 392.1 328.0 288.0 269.9<br>
252.0 244.1 236.9 235.0 235.0<br>
246.0 246.0<br>
612.0 402.1 331.0 291.1 277.0<br>
263.0 251.0 246.0 238.0 236.0<br>
273.0 272.0<br>
635.1 416.3 349.9 304.9 288.0<br>
269.0 259.0 249.0 245.0 240.0<br>
235.0 293.0<br>
635.0 409.1 333.9 300.9 277.0<br>
263.0 253.0 248.0 243.0 241.0<br>
240.0 307.0<br>
661.1 427.1 345.0 302.0 285.9<br>
264.0 258.0 249.0 245.0 240.0<br>
240.0 267.0<br>
655.9 438.1 351.1 310.0 283.0<br>
270.0 263.0 254.0 252.0 246.0<br>
246.0 266.0<br>
656.9 437.2 348.9 317.9 285.1<br>
272.1 262.0 258.0 258.0 258.0<br>
285.0 283.0<br>
681.9 430.8 353.0 316.0 291.0<br>
274.0 266.0 266.0 266.0 294.0<br>
304.0 304.0<br>
681.9 423.0 355.0 323.0 293.0<br>
279.0 269.0 269.0 269.0 311.0<br>
315.0 315.0<br>
752.2 465.9 376.9 336.0 301.0<br>
292.0 275.0 269.0 311.0 299.0<br>
315.0 320.0<br>
2<br>
0.1030 0.1554 0.1841 0.2258 0.2636<br>
0.3186 0.3747 0.4188 0.4818 0.5277<br>
0.5703 0.6392 0.6865 0.8099<br>
3 2 1.000 HC g/kW.h<br>
11.33 6.290 5.400 4.511 3.960<br>
3.550 3.150 3.609 4.139 4.139<br>
4.139 4.141<br>
9.310 6.160 5.321 4.118 3.730<br>
3.270 3.109 2.870 2.699 3.329<br>
3.330 3.329<br>
8.888 5.591 4.640 4.149 3.893<br>
3.530 3.349 3.030 2.940 3.931<br>
3.931 3.931<br>
9.119 5.821 4.670 4.279 3.871<br>
3.510 3.390 2.960 2.699 2.499<br>
3.211 3.080<br>
8.309 5.760 4.620 3.910 3.600<br>
3.281 3.009 2.830 2.580 2.650<br>
3.200 3.200<br>
7.711 5.438 4.470 3.972 3.540<br>
3.370 3.100 2.991 2.800 2.750<br>
4.219 4.252<br>
7.639 4.449 3.599 3.320 3.300<br>
2.919 2.660 2.390 2.450 2.280<br>
2.320 4.298<br>
5.749 3.988 3.351 3.120 2.940<br>
2.930 2.610 2.420 2.310 2.320<br>
2.220 4.522<br>
4.961 3.717 3.480 3.360 2.970<br>
2.430 2.560 2.400 2.250 2.130<br>
3.150 2.820<br>
3.330 2.790 3.031 3.121 3.180<br>
3.220 2.980 2.770 2.370 2.030<br>
3.490 2.860<br>
6.002 4.372 3.668 3.300 3.110<br>
2.840 2.600 2.440 2.600 4.071<br>
3.791 3.640<br>
6.789 4.471 3.751 4.021 4.079<br>
3.050 2.940 2.980 3.170 4.629<br>
4.770 4.769<br>
9.928 5.400 3.650 3.160 3.040<br>
3.140 2.810 3.150 2.750 4.871<br>
4.848 4.848<br>
8.062 4.432 4.118 4.118 3.801<br>
3.820 3.859 3.410 5.591 5.280<br>
5.280 5.280<br>
2<br>
0.4255E-02 0.4894E-02 0.6008E-02 0.7510E-02 0.8073E-02<br>
0.8699E-02 0.9700E-02 0.8198E-02 0.7823E-02 0.7823E-02<br>
0.7823E-02 0.8486E-02 0.1333E-01 0.1157E-01<br>
4 2 1.000 NOX g/kW.h<br>
2.250 4.900 6.271 8.131 10.91<br>
12.26 15.05 14.33 6.149 6.148<br>
6.149 6.148<br>
3.121 7.319 10.52 13.01 15.06<br>
16.05 16.35 15.61 15.60 7.189<br>
7.189 7.190<br>
7.139 12.42 15.75 17.28 17.16<br>
17.27 16.59 16.21 16.07 5.512<br>
5.512 5.512<br>
9.119 13.91 15.86 16.83 17.19<br>
17.24 16.94 15.99 16.17 15.91<br>
7.492 8.481<br>
9.208 8.817 15.54 15.77 16.87<br>
16.95 16.67 16.66 17.15 17.35<br>
7.262 7.261<br>
14.71 16.73 18.48 18.18 17.37<br>
17.30 17.80 17.76 16.75 16.44<br>
3.080 3.030<br>
14.59 14.12 15.50 14.84 16.54<br>
16.63 15.77 14.84 15.32 14.72<br>
14.93 2.310<br>
17.62 16.94 17.56 18.75 19.10<br>
19.51 18.69 18.20 18.04 18.18<br>
17.45 1.620<br>
16.48 17.54 19.18 19.79 20.59<br>
20.30 19.83 19.24 19.10 18.43<br>
4.349 6.040<br>
21.18 23.55 24.72 24.90 23.99<br>
24.18 24.29 22.51 20.31 18.22<br>
4.731 7.988<br>
22.34 24.49 24.33 25.36 24.07<br>
23.78 23.16 21.34 20.10 4.169<br>
4.770 4.988<br>
20.26 22.43 23.70 24.56 23.95<br>
22.24 21.43 19.77 17.89 5.517<br>
4.478 4.477<br>
28.73 27.52 27.55 28.14 26.64<br>
22.86 21.89 19.63 17.14 4.540<br>
3.290 3.290<br>
37.29 31.22 28.62 26.21 24.57<br>
24.85 24.43 23.12 5.591 6.942<br>
6.941 6.940<br>
2<br>
0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00<br>
0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00<br>
0.0000E+00 0.0000E+00 0.0000E+00 0.0000E+00<br>
5 2 1.000 CO g/kW.h<br>
50.01 33.29 32.50 28.10 31.80<br>
29.20 23.30 29.00 114.6 114.6<br>
114.6 114.6<br>
47.41 37.19 33.90 25.80 19.10<br>
18.80 19.70 19.00 19.20 100.4<br>
100.4 100.4<br>
67.00 42.30 38.41 32.80 30.49<br>
28.41 26.39 27.00 28.20 149.9<br>
149.9 149.9<br>
56.42 34.80 31.20 27.20 23.40<br>
26.20 23.70 28.00 26.00 23.80<br>
107.9 92.81<br>
52.49 35.10 29.40 25.80 25.00<br>
24.11 24.09 22.30 20.10 21.10<br>
112.1 112.1<br>
72.69 43.09 39.71 31.99 34.50<br>
33.00 31.21 31.10 28.00 25.80<br>
220.6 219.7<br>
114.4 67.39 56.00 54.11 53.50<br>
45.51 44.21 63.28 40.72 40.72<br>
37.51 279.9<br>
64.69 39.09 35.50 32.50 28.60<br>
26.80 25.80 26.31 25.10 25.60<br>
26.90 322.2<br>
58.29 42.29 35.70 32.51 28.59<br>
22.70 26.20 28.70 25.00 25.50<br>
209.7 159.5<br>
49.10 35.91 30.60 27.61 27.69<br>
31.50 30.80 31.00 32.70 33.40<br>
227.7 146.4<br>
69.97 46.12 33.31 29.31 27.00<br>
25.30 24.80 24.40 20.30 248.8<br>
214.5 201.2<br>
69.19 43.61 31.41 30.10 26.39<br>
24.50 21.80 27.00 28.30 220.9<br>
237.9 237.9<br>
96.02 53.79 37.51 26.50 24.10<br>
37.80 26.90 32.00 25.00 248.9<br>
283.7 283.7<br>
70.99 41.51 34.69 33.10 30.60<br>
28.10 25.80 26.50 255.6 209.4<br>
209.4 209.4<br>
2<br>
0.9387E-02 0.0000E+00 0.0000E+00 0.9387E-02 0.9387E-02<br>
0.9387E-02 0.9387E-02 0.9387E-02 0.9387E-02 0.9387E-02<br>
0.9387E-02 0.9387E-02 0.9387E-02 0.9387E-02<br>
6 2 1.000 CO2 g/kW.h<br>
2010. 1330. 1140. 1020. 960.3<br>
920.1 940.0 860.0 789.7 790.0<br>
789.9 789.9<br>
1950. 1340. 1140. 990.1 920.3<br>
899.9 860.1 860.0 830.1 749.8<br>
750.0 749.9<br>
1971. 1280. 1090. 980.0 910.2<br>
870.1 830.1 849.9 830.2 720.0<br>
720.0 720.0<br>
1990. 1300. 1100. 980.0 920.2<br>
879.9 850.0 820.1 820.1 799.9<br>
730.0 740.2<br>
1980. 1330. 1110. 980.0 920.2<br>
850.0 830.2 799.9 800.0 799.9<br>
699.9 699.9<br>
2050. 1350. 1110. 969.9 920.1<br>
879.8 839.9 830.2 799.9 800.0<br>
630.0 630.0<br>
2070. 1360. 1140. 989.9 929.8<br>
879.8 839.9 799.9 799.9 780.1<br>
769.8 609.9<br>
2150. 1380. 1130. 1010. 929.9<br>
889.9 850.0 839.9 819.7 810.3<br>
809.7 600.0<br>
2250. 1440. 1160. 1020. 969.9<br>
900.0 870.1 840.0 830.4 130.0<br>
670.0 709.7<br>
2260. 1510. 1200. 1060. 960.1<br>
910.1 879.9 850.0 839.8 819.9<br>
690.3 719.9<br>
2210. 1470. 1170. 1080. 969.8<br>
920.1 889.8 900.3 889.7 689.9<br>
679.8 699.7<br>
2300. 1440. 1200. 1060. 980.0<br>
920.3 909.7 869.9 860.0 699.9<br>
710.0 710.1<br>
2260. 1410. 1190. 1100. 1000.<br>
940.0 929.6 869.9 870.1 720.1<br>
680.1 680.1<br>
2540. 1580. 1270. 1130. 1010.<br>
979.6 920.1 899.9 699.6 729.9<br>
730.2 730.0<br>
2<br>
0.3066 0.0000E+00 0.0000E+00 0.1877 0.6258<br>
1.252 1.502 1.752 2.003 2.190<br>
2.378 2.628 2.816 3.442<br>
7 2 1.000 O2 g/kW.h<br>
37.90 26.60 23.80 21.30 18.30<br>
16.70 25.80 13.00 2.900 2.901<br>
2.900 2.899<br>
41.19 28.80 22.20 15.50 12.70<br>
11.80 12.40 11.00 9.400 3.401<br>
3.400 3.400<br>
34.80 22.00 19.50 22.40 16.50<br>
14.70 12.50 12.40 12.00 2.600<br>
2.600 2.600<br>
34.30 21.00 19.00 14.10 12.90<br>
12.40 11.90 10.10 9.601 9.399<br>
2.900 3.500<br>
25.30 17.20 14.60 13.00 11.90<br>
11.40 11.80 10.00 11.30 9.000<br>
8.291 3.500<br>
32.20 21.70 17.90 16.60 13.00<br>
12.40 14.30 14.40 12.60 11.90<br>
2.800 3.100<br>
43.49 34.70 28.70 22.50 20.01<br>
21.20 18.80 16.30 15.60 14.20<br>
13.50 3.300<br>
31.50 18.00 16.80 15.50 14.50<br>
14.10 12.00 12.40 11.50 11.70<br>
11.20 1.900<br>
25.90 21.10 19.70 14.20 13.90<br>
14.60 12.70 13.10 13.50 12.00<br>
3.100 2.500<br>
24.90 19.20 17.00 16.21 15.40<br>
13.70 12.80 12.10 11.30 10.40<br>
2.800 3.999<br>
35.70 22.50 20.49 20.60 15.70<br>
14.10 13.10 11.80 12.90 2.500<br>
3.000 2.700<br>
52.82 30.69 22.60 23.69 22.50<br>
22.70 19.10 20.00 14.10 3.300<br>
3.100 3.100<br>
36.51 29.60 34.20 35.40 31.10<br>
27.00 26.10 19.00 17.50 3.899<br>
4.000 4.001<br>
46.53 32.20 26.40 23.30 20.49<br>
19.80 19.00 18.40 6.802 5.198<br>
5.197 5.200<br>
2<br>
0.6590E-02 0.7159E-02 0.6050E-02 0.5963E-02 0.4398E-02<br>
0.5597E-02 0.7560E-02 0.5476E-02 0.4502E-02 0.4329E-02<br>
0.6206E-02 0.9181E-02 0.6346E-02 0.8085E-02<br>
10 0 1.000 SPARK<br>
22.00 20.00 15.00 11.00 9.000<br>
6.000 4.500 3.400 1.000 1.000<br>
1.000 1.000<br>
22.00 20.00 17.00 15.00 14.00<br>
13.00 12.00 7.000 6.000 6.000<br>
6.000 6.000<br>
22.00 20.00 20.00 19.00 18.00<br>
17.50 14.00 10.00 9.000 9.000<br>
9.000 9.000<br>
21.00 20.00 18.00 17.00 16.00<br>
15.00 14.00 12.00 10.00 9.000<br>
9.000 9.000<br>
22.00 20.00 18.00 17.00 16.00<br>
16.00 15.00 14.00 13.00 12.00<br>
12.00 12.00<br>
25.00 23.00 21.00 20.00 17.00<br>
16.00 16.00 15.00 14.50 13.00<br>
12.50 12.00<br>
25.00 21.00 19.00 18.00 18.00<br>
18.00 15.00 13.00 13.00 12.00<br>
12.00 10.00<br>
25.00 23.00 21.00 20.00 19.00<br>
19.00 17.00 15.00 15.00 14.00<br>
12.00 8.000<br>
25.00 24.00 23.00 22.00 21.00<br>
21.00 19.00 18.00 17.00 15.00<br>
12.00 10.00<br>
26.00 25.00 25.00 24.00 23.00<br>
23.00 21.00 21.00 14.00 11.00<br>
10.50 10.50<br>
28.00 28.00 28.00 27.00 26.00<br>
25.00 23.00 22.00 18.00 16.00<br>
16.00 11.00<br>
30.00 30.00 30.00 30.00 29.00<br>
27.00 24.00 23.00 20.00 18.00<br>
16.00 16.00<br>
34.00 34.00 33.00 31.00 30.00<br>
28.00 26.00 24.00 20.00 19.00<br>
19.00 19.00<br>
37.00 37.00 34.00 32.00 31.00<br>
30.00 30.00 27.00 28.00 25.00<br>
25.00 25.00<br>
2<br>
22.00 22.00 22.00 21.00 22.00<br>
25.00 25.00 25.00 25.00 26.00<br>
28.00 30.00 34.00 37.00<br>
11 0 1.000 THROTTLE<br>
1.000 4.000 7.000 11.00 10.00<br>
15.00 21.00 28.00 100.0 100.0<br>
100.0 100.0<br>
4.000 8.000 12.00 14.00 18.00<br>
21.00 25.00 28.00 32.00 100.0<br>
100.0 100.0<br>
5.000 9.000 14.00 16.00 20.00<br>
23.00 25.00 29.00 33.00 100.0<br>
100.0 100.0<br>
10.00 11.00 16.00 20.00 23.00<br>
26.00 28.00 30.00 34.00 41.00<br>
84.00 100.0<br>
7.000 14.00 18.00 22.00 25.00<br>
26.00 28.00 30.00 44.00 41.00<br>
100.0 100.0<br>
14.00 19.00 22.00 25.00 27.00<br>
29.00 31.00 33.00 36.00 42.00<br>
70.00 100.0<br>
18.00 23.00 27.00 29.00 31.00<br>
32.00 34.00 36.00 39.00 44.00<br>
60.00 100.0<br>
16.00 22.00 27.00 27.00 31.00<br>
32.00 34.00 36.00 39.00 43.00<br>
53.00 100.0<br>
23.00 27.00 29.00 31.00 33.00<br>
34.00 36.00 38.00 41.00 45.00<br>
54.00 100.0<br>
22.00 25.00 27.00 29.00 30.00<br>
32.00 34.00 36.00 39.00 45.00<br>
52.00 100.0<br>
27.00 30.00 32.00 33.00 35.00<br>
36.00 38.00 41.00 45.00 48.00<br>
55.00 100.0<br>
28.00 30.00 32.00 34.00 36.00<br>
38.00 40.00 43.00 48.00 56.00<br>
100.0 100.0<br>
15.00 18.00 20.00 22.00 24.00<br>
27.00 29.00 34.00 45.00 70.00<br>
100.0 100.0<br>
18.00 20.00 22.00 24.00 25.00<br>
29.00 32.00 39.00 52.00 100.0<br>
100.0 100.0<br>
2<br>
1.000 4.000 5.000 10.00 7.000<br>
14.00 18.00 16.00 23.00 22.00<br>
27.00 28.00 15.00 18.00<br>
13 0 1.000 AFR<br>
14.49 14.56 14.55 14.57 14.49<br>
14.49 14.83 14.38 13.19 13.19<br>
13.19 13.19<br>
14.60 14.58 14.51 14.47 14.47<br>
14.47 14.49 14.47 14.42 13.31<br>
13.31 13.31<br>
14.43 14.43 14.43 14.58 14.45<br>
14.44 14.40 14.41 14.39 12.78<br>
12.78 12.78<br>
14.47 14.46 14.48 14.41 14.43<br>
14.40 14.41 14.33 14.35 14.38<br>
13.20 13.39<br>
14.39 14.38 14.40 14.41 14.40<br>
14.40 14.43 14.40 14.48 14.39<br>
13.13 13.13<br>
14.40 14.43 14.40 14.44 14.34<br>
14.34 14.42 14.43 14.42 14.42<br>
12.01 12.03<br>
14.36 14.54 14.54 14.42 14.35<br>
14.48 14.44 14.17 14.39 14.35<br>
14.36 11.56<br>
14.48 14.44 14.45 14.45 14.47<br>
14.48 14.44 14.45 14.45 14.45<br>
14.42 11.23<br>
14.45 14.48 14.51 14.41 14.45<br>
14.56 14.46 14.45 14.51 14.47<br>
12.25 12.72<br>
14.52 14.52 14.51 14.52 14.49<br>
14.40 14.39 14.37 14.35 14.33<br>
12.15 12.89<br>
14.50 14.46 14.54 14.60 14.51<br>
14.50 14.49 14.46 14.53 11.97<br>
12.21 12.34<br>
14.68 14.62 14.60 14.64 14.65<br>
14.74 14.67 14.65 14.45 12.19<br>
12.08 12.08<br>
14.32 14.51 14.81 14.98 14.95<br>
14.71 14.82 14.55 14.61 12.04<br>
11.73 11.73<br>
14.57 14.65 14.63 14.59 14.57<br>
14.57 14.58 14.58 12.01 12.35<br>
12.35 12.35<br>
2<br>
14.49 14.60 14.43 14.47 14.39<br>
14.40 14.36 14.48 14.45 14.52<br>
14.50 14.68 14.32 14.57<br>
14 0 1.000 EXH TEMP<br>
480.3 486.8 527.0 562.5 515.8<br>
534.5 532.8 524.0 514.8 514.8<br>
514.8 514.8<br>
547.0 546.5 559.8 557.8 560.0<br>
560.3 561.0 572.8 576.0 557.3<br>
557.3 557.3<br>
568.0 563.5 574.3 571.3 579.8<br>
579.8 587.5 599.3 601.5 573.3<br>
573.3 573.3<br>
607.3 600.8 606.5 610.8 614.0<br>
620.0 627.5 631.0 643.0 647.5<br>
631.3 635.5<br>
632.0 625.8 636.3 634.3 635.5<br>
636.5 640.5 648.0 654.5 662.5<br>
639.3 639.3<br>
646.5 646.3 648.8 649.8 657.5<br>
659.3 660.5 664.5 668.3 676.3<br>
625.8 625.0<br>
663.3 675.8 677.3 700.5 691.0<br>
683.0 687.0 692.5 694.8 700.5<br>
705.8 647.5<br>
698.5 702.8 659.8 698.0 699.8<br>
706.5 714.5 722.8 726.5 729.5<br>
742.0 677.3<br>
725.8 724.0 716.8 717.0 717.3<br>
718.5 723.3 726.8 733.3 738.8<br>
700.8 723.5<br>
710.3 755.5 747.3 743.8 742.8<br>
740.0 742.0 739.5 766.3 781.5<br>
731.5 751.8<br>
744.3 764.5 766.0 762.3 764.8<br>
767.5 767.5 788.3 806.0 737.0<br>
740.3 760.5<br>
770.8 777.3 776.5 775.0 773.5<br>
781.3 794.0 801.8 817.5 767.5<br>
767.8 767.8<br>
775.3 780.5 779.8 786.0 787.5<br>
791.0 799.5 811.3 833.3 763.8<br>
750.0 750.0<br>
794.8 816.3 792.8 801.5 804.8<br>
806.3 808.0 815.0 731.8 767.8<br>
767.8 767.8<br>
2<br>
480.3 547.0 568.0 607.3 632.0<br>
646.5 663.3 698.5 725.8 710.3<br>
744.3 770.8 775.3 794.8<br>
OPTIMUM<br>
2<br>
1<br>
CATALYST<br>
0.9500 100.0 20.00<br>
0.9800 80.00 20.00<br>
0.9600 120.0 20.00<br>
WARM-UP<br>
4.000 80.00 0.8000E-01<br>
0.0000E+00 0.0000E+00 0.0000E+00<br>
1.000 80.00 0.0000E+00<br>
DRIVER<br>
1.000 1.000 0.5000 0.4000 0.4000 0<br>
<font face="Times New Roman"><br>
<p><hr><p>
<sup>#</sup><sup>&gt;</sup></font><font face="Arial"><b><font size="4">Emissions Simulation Results<font face="Courier New"> <br>
</font></font></b></font><font face="Times New Roman"><font size="2"> <br>
<font face="Courier New"> ============================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p1<br>
Test No. lev Counter No. 7<br>
run at 17:15:35 on 26/ 5/98<br>
============================================================================<br>
<br>
EMISSIONS SIMULATION<br>
LOTUS LEV RESEARCH<br>
INPUT DATA<br>
~~~~~~~~~~<br>
</font></font></font> VEHICLE<br>
~~~~~~~<br>
Weight . . . . . . . . 1183.0 kg<br>
Frontal Area . . . . . 2.080 m2 Plan Area. . . . . . . 0.000 m2<br>
Air Density. . . . . . 1.205 kg/m3 Drag Coefficient . . . 0.330<br>
Front Lift Coeff . . . 0.000 Rear Lift Coeff. . . . 0.000<br>
Wheel Base . . . . . . 2.52 m Track. . . . . . . . . 1.00 m<br>
CoG to front axle. . . 0.96 m CoG to ground. . . . . 0.58 m<br>
TYRE<br>
~~~~<br>
Rolling Radius . . . . 0.2896 m Coeff.of Friction. . . 0.980<br>
Default Rolling Resistance Coefficients<br>
DRIVELINE<br>
~~~~~~~~~<br>
Front wheel drive<br>
Total Inertia Fr Wheels 1.477 kg.m2 Total Inertia Rr Wheels 1.477 kg.m2<br>
Driven Axle Inertia . . 0.000 kg.m2 Prop Shaft Inertia. . . 0.000 kg.m2<br>
Final Drive Ratio . . . 3.550 Final Drive Efficiency. 0.980<br>
GEARBOX<br>
~~~~~~~<br>
Manual<br>
Number of ratios. . . . 5<br>
Gear change Time. . . . 0.4 s Min Time Between Shifts 0.4 s<br>
Default Max Gearbox Torque. Default Max Gearbox Speed<br>
Gear. . 1 Ratio . 3.5500 Effy. . 0.970 Box Inertia. 0.0010 kg.m2<br>
Overall Ratio . 12.6025 O.Effy. 0.951 MPH/1000 RPM 5.38<br>
Gear. . 2 Ratio . 2.1600 Effy. . 0.970 Box Inertia. 0.0010 kg.m2<br>
Overall Ratio . 7.6680 O.Effy. 0.951 MPH/1000 RPM 8.85<br>
Gear. . 3 Ratio . 1.4800 Effy. . 0.970 Box Inertia. 0.0010 kg.m2<br>
Overall Ratio . 5.2540 O.Effy. 0.951 MPH/1000 RPM 12.91<br>
Gear. . 4 Ratio . 1.1200 Effy. . 0.970 Box Inertia. 0.0010 kg.m2<br>
Overall Ratio . 3.9760 O.Effy. 0.951 MPH/1000 RPM 17.06<br>
Gear. . 5 Ratio . 0.8900 Effy. . 0.970 Box Inertia. 0.0010 kg.m2<br>
Overall Ratio . 3.1595 O.Effy. 0.951 MPH/1000 RPM 21.47<br>
Vehicle declutch speed 5.0 kmh<br>
ENGINE<br>
~~~~~~~<br>
Internal combustion engine<br>
Number of Cylinders . 4 Cycle Type . . . . . . 4<br>
Bore . . . . . . . . . 79.00 mm Stroke . . . . . . . . 81.50 mm<br>
Swept Volume . . . . . 1.5979 l Rotating Inertia . . . 0.0000 kg.m2<br>
Idle Speed . . . . . . 1000.0 rpm Max Engine Speed . . . 6200.0 rpm<br>
Max Power. . . . . . . 80.1 kw Max Power Speed .. . . 6200.0 rpm<br>
Max Torque . . . . . . 150.0 nm Max Torque Speed . . . 4600.0 rpm<br>
Primary Drive Ratio. . 1.000 Primary Drive Effy . . 1.000<br>
Power/Weight Ratio . . 67.7 kw/tonne<br>
<br>
====================================================================<br>
<br>
===================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p2<br>
Test No. lev Counter No. 7<br>
run at 17:15:35 on 26/ 5/98<br>
====================================================================<br>
<br>
EMISSIONS SIMULATION<br>
LOTUS LEV RESEARCH<br>
RESULTS<br>
~~~~~~~<br>
FTP75 Urban Cycle Simulation<br>
<br>
Total Cycle Time . . . 1876.5 s<br>
<br>
Dist Travelled (nom) . 17722.1 m Dist Travelled (act) . 17767.5 m<br>
Dist Travelled (nom) . 17.722 km Dist Travelled (act) . 17.767 km<br>
Dist Travelled (nom) . 11.012 miles Dist Travelled (act) . 11.040 miles<br>
Mean Power Developed . 4.10 kw<br>
<br>
Default Gear Shift Map<br>
No. of Gear Changes 69<br>
<br>
Fuel Consumption from Map . . 1<br>
Litres per 100 km. . . 7.133 Km per Litre . . . . . 14.019 km/l<br>
Miles per Imp.Gallon . 39.60 mpg Miles per US Gallon. . 32.97 mpgUS<br>
Grams per Test . . . . 948.086 g<br>
Grams per KM . . . . . 53.497 g/km Grams per Mile . . . . 86.096 g/mil<br>
Mean Consumption . . . 1818.87 g/h Mean Spec.Consumption. 443.37 g/kw.h<br>
Overall Cycle Efficiency 19.332 %<br>
Weighted Results . . . .<br>
Grams per KM . . . . . 54.074 g/km Grams per Mile . . . . 87.024 g/mil<br>
<br>
Hydrocarbon Emissions from Map 2<br>
Grams per Test . . . . 33.274 g<br>
Grams per KM . . . . . 1.878 g/km Grams per Mile . . . . 3.022 g/mil<br>
Mean Consumption . . . 63.83 g/h Mean Spec.Consumption. 15.56 g/kw.h<br>
Weighted Results . . . .<br>
Grams per KM . . . . . 1.947 g/km Grams per Mile . . . . 3.134 g/mil<br>
Post Catalyst . . . .<br>
Grams per Test . . . . 4.366 g<br>
Grams per KM . . . . . 0.246 g/km Grams per Mile . . . . 0.396 g/mil<br>
Mean Consumption . . . 8.38 g/h Mean Spec.Consumption. 2.04 g/kw.h<br>
Post Catalyst Weighted Results.<br>
Grams per KM . . . . . 0.281 g/km Grams per Mile . . . . 0.453 g/mil<br>
<br>
NOx Emissions from Map . . . 3<br>
Grams per Test . . . . 30.612 g<br>
Grams per KM . . . . . 1.727 g/km Grams per Mile . . . . 2.780 g/mil<br>
Mean Consumption . . . 58.73 g/h Mean Spec.Consumption. 14.32 g/kw.h<br>
Weighted Results . . . .<br>
Grams per KM . . . . . 1.688 g/km Grams per Mile . . . . 2.717 g/mil<br>
Post Catalyst . . . .<br>
Grams per Test . . . . 1.459 g<br>
Grams per KM . . . . . 0.082 g/km Grams per Mile . . . . 0.132 g/mil<br>
Mean Consumption . . . 2.80 g/h Mean Spec.Consumption. 0.68 g/kw.h<br>
Post Catalyst Weighted Results.<br>
Grams per KM . . . . . 0.091 g/km Grams per Mile . . . . 0.147 g/mil<br>
<br>
CO Emissions from Map . . . . 4<br>
Grams per Test . . . . 85.205 g<br>
Grams per KM . . . . . 4.808 g/km Grams per Mile . . . . 7.737 g/mil<br>
Mean Consumption . . . 163.46 g/h Mean Spec.Consumption. 39.85 g/kw.h<br>
Weighted Results . . . .<br>
Grams per KM . . . . . 4.856 g/km Grams per Mile . . . . 7.815 g/mil<br>
Post Catalyst . . . .<br>
Grams per Test . . . . 9.068 g<br>
Grams per KM . . . . . 0.512 g/km Grams per Mile . . . . 0.823 g/mil<br>
Mean Consumption . . . 17.40 g/h Mean Spec.Consumption. 4.24 g/kw.h<br>
Post Catalyst Weighted Results.<br>
Grams per KM . . . . . 0.580 g/km Grams per Mile . . . . 0.933 g/mil<br>
<br>
CO2 Emissions from Map . . . 5<br>
Grams per Test . . . . 2832.365 g<br>
Grams per KM . . . . . 159.821 g/km Grams per Mile . . . . 257.208 g/mil<br>
Mean Consumption . . . 5433.79 g/h Mean Spec.Consumption. 1324.55 g/kw.h<br>
Weighted Results . . . .<br>
Grams per KM . . . . . 160.580 g/km Grams per Mile . . . . 258.429 g/mil<br>
<br>
O2 Emissions from Map . . . . 6<br>
Grams per Test . . . . 45.847 g<br>
Grams per KM . . . . . 2.587 g/km Grams per Mile . . . . 4.163 g/mil<br>
Mean Consumption . . . 87.96 g/h Mean Spec.Consumption. 21.44 g/kw.h<br>
<br>
Spark Timing from Map . . . . 7<br>
<br>
Throttle Position from Map. . 8<br>
<br>
Air Fuel Ratio from Map . . . 9<br>
<br>
Exhaust Temp from Map . . . . 10<br>
<br>
=====================================================================<br>
<br>
<br>
<p><hr><p>
<sup>#</sup><sup>&gt;</sup><font face="Arial"><b><font size="4">Track Simulation Input File<font face="Courier New"><br>
</font></font></b></font><font size="2"><br>
esprit cardat file<br>
92 spec<br>
esprt 301<br>
VEHICLE<br>
1509.<br>
1.770 0.3400 1.900 -0.2530 -0.3030<br>
1.205<br>
2.438 1.524 1.554 1.414 0.4800<br>
TYRE<br>
0.3146<br>
2 1.090 0.9500<br>
10.00 0.0000E+00 0.1500E-02 0.0000E+00 0.0000E+00 0.0000E+00<br>
DRIVE<br>
2<br>
0.7385 0.7385<br>
0.1000E-02 0.1000E-02<br>
3.889 0.9700 2<br>
GEARBOX<br>
5 0.2000 0.0000E+00 2<br>
</font> 3.363 0.9800 0.1000E-02<br>
2.059 0.9700 0.1000E-02<br>
1.387 0.9700 0.1000E-02<br>
1.037 0.9700 0.1000E-02<br>
0.8205 0.9700 0.1000E-02<br>
GSHIFT<br>
1<br>
acc<br>
1 0 1<br>
1.000<br>
0.0000E+00 7400.<br>
0.0000E+00 7400.<br>
0.0000E+00 7400.<br>
0.0000E+00 7400.<br>
0.0000E+00 7400.<br>
2 0<br>
CLUTCH<br>
1 1.000<br>
PDRIVE<br>
1.000 1.000 2<br>
ENGINE<br>
1<br>
95.30 76.20 10.00 4 4 0.1476<br>
1000. 7500.<br>
10<br>
1000. 7.000<br>
2000. 12.40<br>
2500. 18.20<br>
3000. 18.90<br>
3900. 20.50<br>
5000. 18.80<br>
6000. 17.80<br>
6500. 16.78<br>
7000. 15.10<br>
7500. 13.20<br>
DRIVER<br>
0.9000 0.8000 0.6000 0.1000 0.1000 0<br>
<p><hr><p>
<sup>#</sup><sup>&gt;</sup><font face="Arial"><b><font size="4">TRACK SIMULATION RESULTS FILE<br>
</font></b></font><font face="Courier New"><font size="2"> =========================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p1<br>
Test No. esprt Counter No. 1<br>
run at 10:26: 4 on 26/ 5/98<br>
=========================================================================<br>
<br>
esprit cardat file<br>
92 spec<br>
INPUT DATA<br>
~~~~~~~~~~<br>
</font></font> VEHICLE<br>
~~~~~~~<br>
Weight . . . . . . . . 1509.0 kg<br>
Frontal Area . . . . . 1.770 m2 Plan Area. . . . . . . 1.900 m2<br>
Air Density. . . . . . 1.205 kg/m3 Drag Coefficient . . . 0.340<br>
Front Lift Coeff . . . -0.253 Rear Lift Coeff. . . . -0.303<br>
Wheel Base . . . . . . 2.44 m Track. . . . . . . . . 1.54 m<br>
CoG to front axle. . . 1.41 m CoG to ground. . . . . 0.48 m<br>
TYRE<br>
~~~~<br>
Rolling Radius . . . . 0.3146 m Coeff.of Friction. . . 1.090<br>
User Rolling Resistance Coefficients<br>
DRIVELINE<br>
~~~~~~~~~<br>
Rear wheel drive<br>
Total Inertia Fr Wheels 1.477 kg.m2 Total Inertia Rr Wheels 1.477 kg.m2<br>
Driven Axle Inertia . . 0.001 kg.m2 Prop Shaft Inertia. . . 0.001 kg.m2<br>
Final Drive Ratio . . . 3.889 Final Drive Efficiency. 0.970<br>
GEARBOX<br>
~~~~~~~<br>
Manual<br>
Number of ratios. . . . 5<br>
Gear change Time. . . . 0.1 s Min Time Between Shifts 0.1 s<br>
Max Gearbox Torque. . . 0.2 nm Default Max Gearbox Speed<br>
Gear. . 1 Ratio . 3.3630 Effy. . 0.980 Box Inertia. 0.0010 kg.m2<br>
Overall Ratio . 13.0787 O.Effy. 0.951 MPH/1000 RPM 5.63<br>
Gear. . 2 Ratio . 2.0590 Effy. . 0.970 Box Inertia. 0.0010 kg.m2<br>
Overall Ratio . 8.0075 O.Effy. 0.941 MPH/1000 RPM 9.20<br>
Gear. . 3 Ratio . 1.3870 Effy. . 0.970 Box Inertia. 0.0010 kg.m2<br>
Overall Ratio . 5.3940 O.Effy. 0.941 MPH/1000 RPM 13.66<br>
Gear. . 4 Ratio . 1.0370 Effy. . 0.970 Box Inertia. 0.0010 kg.m2<br>
Overall Ratio . 4.0329 O.Effy. 0.941 MPH/1000 RPM 18.27<br>
Gear. . 5 Ratio . 0.8205 Effy. . 0.970 Box Inertia. 0.0010 kg.m2<br>
Overall Ratio . 3.1909 O.Effy. 0.941 MPH/1000 RPM 23.10<br>
Vehicle declutch speed 1.0 kmh<br>
ENGINE<br>
~~~~~~~<br>
Internal combustion engine<br>
Number of Cylinders . 4 Cycle Type . . . . . . 4<br>
Bore . . . . . . . . . 95.30 mm Stroke . . . . . . . . 76.20 mm<br>
Swept Volume . . . . . 2.1742 l Rotating Inertia . . . 0.1476 kg.m2<br>
Idle Speed . . . . . . 1000.0 rpm Max Engine Speed . . . 7500.0 rpm<br>
Max Power. . . . . . . 197.6 kw Max Power Speed .. . . 6500.0 rpm<br>
Max Torque . . . . . . 354.7 nm Max Torque Speed . . . 3900.0 rpm<br>
Primary Drive Ratio. . 1.000 Primary Drive Effy . . 1.000<br>
Power/Weight Ratio . . 131.0 kw/tonne<br>
<br>
========================================================================<br>
<br>
=========================================================================<br>
VEHICLE PERFORMANCE SIMULATION PROGRAM - p2<br>
Test No. esprt Counter No. 1<br>
run at 10:26: 4 on 26/ 5/98<br>
=========================================================================<br>
<br>
esprit cardat file<br>
92 spec<br>
RESULTS<br>
~~~~~~~<br>
Lotus Track Simulation<br>
<br>
Total Cycle Time . . . 173.6 s<br>
<br>
Dist Travelled (nom) . 6882.8 m<br>
Dist Travelled (nom) . 6.883 km<br>
Dist Travelled (nom) . 4.277 miles<br>
Mean Power Developed . 108.60 kw<br>
<br>
Default Gear Shift Map<br>
No. of Gear Changes 26<br>
<br>
========================================================================<br>
<font face="Times New Roman"><br>
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