Lotus-Suspension-Analysis/Lotus Suspension Analysis 4.03c/RAVEN.HLP/RAVEN.rtf

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\b\fs28 Lotus Suspension Analysis \plain\f0\b\fs28 \'96\f1  RA{\up K}
VEN,  Introduction
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\par \uldb Lotus\plain\fs20  Suspension provides a tool for the design of suspension characteristics using full vehicle handling analysis. Combinations of standard analysis modes are used to review vehicle response for the defined characteristics. The use of a non-multi body model, (only five parts are used, the sprung mass plus four un-sprung corner masses), allow the impact of individual characteristics to be assessed without reference to the constraints of a suspension mechanism.
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\par 3D Graphical Display of Vehicle Model
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\par Vehicle handling is assessed over either individual or combinations of Road Motion, Steering Motion, Acceleration and Braking. Each of these \plain\f0\fs20 \'91\f1 motion\plain\f0\fs20 \'92\f1  sections has a number of individual pre-defined sub-tests, such as 1-wheel bump 2-wheel bump and sine sweep for the Road Motion. Currently the Adams solver is used to run the defined model over the prescribed event.
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\par Definition of the Road Motion Event
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\par Results are displayed simultaneously as 3D animation of the model and x-Y graphs of selected results. Users can display any number of graphs each with their own unique display settings. A cross plot facility allows immediate comparison with previous analysis runs.
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\par Sample X-Y Results Graph Display
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Overview \plain\f0\b\fs28 \'96\f1  Introduction
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\par The Raven module of Lotus Suspension Analysis provides an analysis tool for calculating the overall vehicle handling response under \plain\f0\fs20 \'91\f1 standard\plain\f0\fs20 \'92\f1  road inputs, maneuvers and driver inputs. To do this a reduced degree of freedom model is used using only five parts, (sprung mass + the four un-sprung corner masses), and defining the relationship between them using combinations of splines. Each spline defines a particular characteristic, such as lateral force steer, which allows individual characteristics to be changed and their impact on the total handling response examined.
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\par Overall Appearance of Interface
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\par The reduced mass model enables rapid analysis times, currently the solver uses ADAMS to solve the model. Raven is compatible with all recent versions of the ADAMS solver.
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\par Data input for Raven can come from a number of sources. It can be entered directly by the user from any combination of estimates, measurements or other analysis tool results. It can be automatically produced from a full vehicle compliant SHARK model, (Shark is the Suspension kinematic and compliant module of Lotus Suspension Analysis which is licensed separately). It can come from measurements from an SKCMS rig. The SKCMS rig import is currently specific to Lotus Engineering SKCMS rigs, the import data file format is available for those wishing to convert alternative manufacturers rig results into the right format. The SKCMS file import does not at the current release level provide full a data set, some splines need to be defined after the import.
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\par Reviewing and editing the Spline data
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\par Analysis runs are performed by selected the required solution type and submitting it via a command line option that writes an ADAMS *.adm and *.acf file. ADAMS then runs these files and the results files then loaded back into the interface. All of this is seamless to the user the file writing, solver start-up and results reading being carried out automatically once the job run is selected.
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\par Results are displayed in both 3D graphical form and 2D X-Y graphs. The animation of the 3D viewer is linked to the graphs such that both displays can be used together to review the calculated behavior of the vehicle. Other options include cross plotting of two results for overall comparison between models.
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\par Cross plotting X-Y graphs
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Overview \plain\f0\b\fs28 \'96\f1  Defaults
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\par All user definable settings are saved by the application when it has a normal program exit to its \plain\f0\fs20 \'91\f1 ini\plain\f0\fs20 \'92\f1  file. The location of this ini file depends on the version of Windows currently being used. The file name is \plain\f0\b\fs20 \'91\f1 shark.ini\plain\f0\b\fs20 \'92\plain\fs20  and will be saved to either C:\'5cwindows or C:\'5cwinnt. This file is not directly editable by the user but there are occasions when it is useful to understand where it is and what it stores.
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\par All colours, symbols, visibility, line types and graphics size defaults that can be set by the user are saved to this file. In addition it will retain window sizes, folder settings, and recent open files.
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\par At application start-up this file is searched for in the relevant Windows folder and if found read in to overwrite the internal default settings.
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Overview \plain\f0\b\fs28 \'96\f1  Graphical Interface
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\par The graphical interface consists of a conventional Windows style container window, with a top menu bar and a series of status panels along the bottom.
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\par Optional toolbars are drawn by default to the left of the window, containing short cut icons to some of the main menus. The user can specify the visibility of the toolbars together with their position. Additionally the toolbars can be displayed as \plain\f0\fs20 \'91\f1 floating\plain\f0\fs20 \'92\f1  rather than anchored to one of the edges.
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\par Floating toolbars can be re-docked to the required edge through picking and dragging to the new position, (note the outline shape will change to indicate docking).
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\par The initial positions of the toolbars can be set via the \i SetUp / Start Options / ToolBar Position\plain\fs20  menu item, with \i Top, Bottom, Left \plain\fs20 or \i Right\plain\fs20  options available. This change is saved to the users \plain\f0\fs20 \'91\f1 ini\plain\f0\fs20 \'92\f1  file and will be applied next time the application is re-started.
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\par Confirming the change in toolbar position
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\par The suspension graphics is drawn in the window titled \plain\f0\fs20 \'91\f1 3D Display\plain\f0\fs20 \'92\f1 . This window cannot be closed, but can be repositioned, re-sized and minimized. Only one graphic window can be opened by the application at a time, (i.e. you cannot open different models at the same time using different graphic windows in the way that a multi-document application like Word would).
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\par Example 3D Graphic window
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\par Results graphs are displayed in individual windows. Each new graph added opening a new window. The graph windows can be moved, re-sized, closed and minimized. The title of the graph window reflects the plotted variable.
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\par Example 3D Graph window
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\par By default on start-up only the graphic window and toolbars are drawn, no graphs are displayed until they are added via the \i Graph / New/Open\plain\fs20  menu.
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\par The settings for window positions, sizes and variables can be saved such that when the application is re-started all windows are re-opened in the same positions, see \i SetUp / Save Window Settings\plain\fs20 .
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Overview \plain\f0\b\fs28 \'96\f1  Dynamic Viewing
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\par The main graphical window has dynamic viewing via the mouse, that allows translation, scaling and rotation, of the 3D graphics display.
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\par The \plain\f0\fs20 \'91\f1 dynamic view\plain\f0\fs20 \'92\f1  icon together with the associated menus indicate the status of the dynamic viewing mode, when checked the application is in dynamic view mode and the mouse and its buttons can be used to perform translation, scaling and rotation of the graphics model. Additionally the graphic display has symbols drawn in each corner as a visual indication that the application is in dynamic view mode.
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\par Dynamic Viewing \plain\f0\fs20 \'96\f1  Indicators marked
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\par The dynamic view mode has three options, being Translation, Scaling and Rotation. Each of these options has its own icon and menu item, \i View / Translate View, View / Scale View \plain\fs20  and \i View / Rotate View\plain\fs20 . Selecting any of these options will enable dynamic viewing (if not currently on), or just change dynamic view type, (if already in dynamic view).
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\par Dynamic Viewing \plain\f0\fs20 \'96\f1  View Type Icons
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\par The dynamic view modes use the motion of the mouse between key down and key release to change the view. The translate view mode simply follows the translation of the mouse within the current view plane. The Scale view mode uses the mouse vertical position to scale the current view plane. Moving the mouse up scales the view out, (i.e. model appears further away), whilst moving the mouse down scales the view in.
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\par The rotate dynamic view, has two actions depending on the position of  initial mouse selection point. Selecting towards the middle of the image will rotate the line of sight, whilst selecting towards the edge of the view will rotate the view around the line of sight only.
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\par When in dynamic view mode the right mouse button will cycle through the available dynamic view options.
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Overview \plain\f0\b\fs28 \'96\f1  Graphs
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\par \pard The primary results display method for the application is through the x-y results graphs. Each graph show a single user selected parameters channel plotted against a second parameters channel (normally time). Any number of graphs can be opened and positioned within the display using either the \i Graphs / New/Open\plain\fs20  menu or equivalent icon.
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\par New Graph toolbar Icon
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\par The appearance and settings of each graph can be changed through either the \i Graphs\plain\fs20  pull down menu or the graph\plain\f0\fs20 \'92\f1 s right mouse menu. By selecting a graph with the right mouse button this implies that any changes made from the pop-up menu items is applied to the selected graph only.
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\par Graph right mouse button menu
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\par As each new graph is opened the parameters and channels for x and y are set to the default values. To change the displayed parameters, use the right-mouse menu and select from the available \i Parameter\plain\fs20  list.
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\par Graph Parameter list - right mouse button menu
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\par \b Additional Graph properties that can be defined are;
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\par \i Axis Scales\plain\fs20 : Set the minimum and maximum x and y axis values. The autoscale option can also be used to automatically set the scales.
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\par \i Visibility\plain\fs20 : Set the visibility of individual graph items, Grid Lines, Point Symbols, Data Values.
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\par \i Colours\plain\fs20 : Sets the colour of individual graph items, Grid Lines, Background, Axis Lines + Text, Border Region, Primary Results Line and Secondary Results Line.
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\par \i Line Markers\plain\fs20 : Set the marker for individual graph lines, Primary Results Line and Secondary Results Line.
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\par \i Marker Sizes\plain\fs20 : Sets the size of the markers used for each line type.
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\par \i Text Sizes\plain\fs20 : Sets the size of the text labels for Graph Data Values.
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\par \i Decimal Points Display\plain\fs20 : Defines the number of decimal points used to display numerical values. Individual values are X-Data Listing and Y-Data Listing.
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Overview \plain\f0\b\fs28 \'96\f1  Data Entry
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\par Data entry is through standard Windows style dialogue boxes. These employ standard text and numeric widgets, together with check boxes and selection boxes. Spread sheet style entry where used supports cut and paste from external applications via the clipboard.
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\par Example spread sheet data entry
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\par When using \plain\f0\fs20 \'91\f1 paste\plain\f0\fs20 \'92\f1  into a Raven spread sheet it is only necessary to select the location of the top left hand cell of the paste are that the paste is intended to fill, do not drag and highlight the entire target area.
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Getting Started \plain\f0\b\fs28 \'96\f1  Start-up Steps
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\par Starting the program can be considered to consist of the following steps;
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\par 1) Start the executable, locate either from the \b Start\plain\fs20  menu, (normally \i Start / Programs / Lotus Engineering Software / Lotus Suspension Analysis\plain\fs20 ), or through explorer. Browse to the installed folder (normally c:\'5clesoft), and run the suspension analysis executable \b shark.exe,\plain\fs20  (note that shark.exe contains both the Shark and Raven modules of Lotus Suspension Analysis).
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\par 2) Select the module required, \plain\f0\fs20 \'91\f1 Raven / STD Interface\plain\f0\fs20 \'92\f1 . You should only need to do this if you are licensed for both \plain\f0\fs20 \'91\f1 Shark\plain\f0\fs20 \'92\f1  and \plain\f0\fs20 \'91\f1 Raven\plain\f0\fs20 \'92\f1  modules. If you are licensed for both \plain\f0\fs20 \'91\f1 Shark\plain\f0\fs20 \'92\f1  and \plain\f0\fs20 \'91\f1 Raven\plain\f0\fs20 \'92\f1  then the application will always open in the module that you last used. This setting, along with many others user definable settings, is stored in the \plain\f0\fs20 \'91\f1 ini\plain\f0\fs20 \'92\f1  file.
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\par 3) Enter the required suspension data, either from an existing saved file or through the new file options.
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Getting Started \plain\f0\b\fs28 \'96\f1  Program Start-up
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\par During program start-up a number of system checks are performed. The users ini file is searched for and if found, loaded to overwrite the internal defaults.
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Getting Started \plain\f0\b\fs28 \'96\f1  Start-up Errors
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\par During program start-up the searching for and subsequent loading of the \uldb users \plain\f0\uldb\fs20 \'91\f1 ini\plain\f0\uldb\fs20 \'92\f1  file\plain\fs20  can in exceptional circumstances, results in an error message. This implies a corrupt ini file possibly due to a previous partial save or inappropriate editing, (the ini file should not be edited by hand).
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\par Error message ini file read failure
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\par Selecting okay will continue to start the program, but with only a partial reading of the ini file, (partial up to the point of read error). Partial reading of the ini file may cause problems which may require the program to be closed and restarted. If the problems persists, (as it may, since the invalid settings will be written back into ini file when the program has a normal exit), the only option may be to delete the ini file, see \uldb Defaults\plain\fs20 .
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\par Whilst strictly not a start-up error, the other possible start-up event that may occur is the detection of a previous runs temporary scratch file. This is interpreted as a previous run incorrectly shutting down, as these temporary scratch files used for the undo feature, are deleted on normal program exit.
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\par If a scratch file(s) is identified, the user is given the option of recovering the most recent file and thus avoids potential data loss.
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\par Data Recovery Message
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Getting Started \plain\f0\b\fs28 \'96\f1  Graphics Frame Types
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\par The interfaces main graphics display has two alternative drivers. The default device driver is a Windows GDI, (\i View / Graphics Frame Type / Windows GDI),\plain\fs20  which whilst it works with all Hardware options does so at the expense of both speed and capability. The GDI driver is unable to support depth buffered display and hence the view styles \i View / Fill Style / Hidden Line \plain\fs20 and \i View / Fill Style / Depth Buffered (Flat shaded )\plain\fs20  do not function correctly. The alternative device driver is Open GL, (\i View / Graphics Frame Type / Open GL\plain\fs20 ), which is both faster and supports depth buffering/hidden line display types.
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\par Not all hardware is able to use the Open GL device type, typical failures are inability to refresh and lack of correct hidden line display.
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Getting Started \plain\f0\b\fs28 \'96\f1  Window Descriptions
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\par The application window layout utilizes a Multi Document interface (MDI) style. Where display and graph windows are displayed as children of the main window. The main window has a top menu bar and two toolbars which have optional positions. The graphical display is drawn in a 3D viewing window, whilst individual graphs have separate windows.
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\par Example screen shot \plain\f0\fs20 \'96\f1  Overall appearance of application
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Getting Started \plain\f0\b\fs28 \'96\f1  Module Type
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\par On program start-up by default the application will go into whichever module was last used. If you are licensed for both the \plain\f0\fs20 \'91\f1 Shark\plain\f0\fs20 \'92\f1  and \plain\f0\fs20 \'91\f1 Raven\plain\f0\fs20 \'92\f1  modules you may need to switch modules once the application is open depending on which was used last.
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\par The menu entry \i Module / Raven \plain\fs20 sub menu can be used to select the required module.
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\par Setting the application module \plain\f0\fs20 \'96\f1  pull-down menu options
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Getting Started \plain\f0\b\fs28 \'96\f1  Data Entry
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\par At start-up the main form of data entry to the program is either from a previously saved file, imported from a SKCMS rig results file or as a new file entering data directly through the various data section dialogue boxes. To load an existing data file use the \i File  / Open...\plain\fs20  menu item, (note that the five most recently opened files are appended to the \i File\plain\fs20  menu). To import SKCMS rig data use the \i File / Import SKCMS Rig File\'85\plain\fs20  menu. To create a new model select the \i File / New\plain\fs20  menu item then enter data for the \plain\f0\fs20 \'91\f1 Vehicle\plain\f0\fs20 \'92\f1 , \plain\f0\fs20 \'91\f1 Tyre\plain\f0\fs20 \'92\f1  and \plain\f0\fs20 \'91\f1 Solution\plain\f0\fs20 \'92\f1  data sets.
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\par Importing an SKCMS rig File \plain\f0\fs20 \'96\f1  Selecting symmetry type
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Getting Started \plain\f0\b\fs28 \'96\f1  Exiting the Program
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\par The close the program select the \i File / Exit\plain\fs20  menu item, and then confirm the \plain\f0\fs20 \'91\f1 okay to exit\plain\f0\fs20 \'92\f1  prompt. Alternative methods to close the application include the conventional \plain\f0\fs20 \'91\f1 X\plain\f0\fs20 \'92\f1  from the windows top right corner, Alt+F4 or close from the main windows top left menu. In addition the \plain\f0\fs20 \'91\f1 esc\plain\f0\fs20 \'92\f1  key will close the application, (subject to accepting the prompt).
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\par Okay to exit prompt
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Pull Down Menu Items - File
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\par \cf1 File / New:\plain\fs20  Creates a new model. This initializes the model data and enables the necessary data menus. The user is warned about possible existing data loss, being asked to confirm this action.
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\par \cf1 File / Open:\plain\fs20  Opens the standard Windows file browser to locate the required existing file to load. Note that file open action will lose the current model data.
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\par \cf1 File / Save As:\plain\fs20  Opens the standard Windows  file browser to enable the current model to be saved to disc. Browse to the required folder and enter/select the required file name.
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\par \cf1 File / Write .adm:\plain\fs20  Opens the standard Windows  file browser to define the required file name for the .adm file and folder. This menu option will normally be disabled for external Non-Lotus customers as part of the protection of Lotus intellectual property. Writes a \plain\f0\fs20 \'91\f1 standard\plain\f0\fs20 \'92\f1  Adams \plain\f0\fs20 \'91\f1 adm\plain\f0\fs20 \'92\f1  data file based on the current model definition.
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\par \cf1 File / Write .acf:\plain\fs20  Opens the standard Windows  file browser to define the required file name for the .acf file and folder. This menu option will normally be disabled for external Non-Lotus customers as part of the protection of Lotus intellectual property. Writes a \plain\f0\fs20 \'91\f1 standard\plain\f0\fs20 \'92\f1  Adams \plain\f0\fs20 \'91\f1 acf\plain\f0\fs20 \'92\f1  data file based on the current model definition and solution settings.
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\par \cf1 File / Load External Res\'85 (Primary):\plain\fs20  Opens the standard Windows  file browser to locate and load a previously saved set of Adams results. Users can search for both *.req and *.gra files. Whichever type is located and loaded the other file type of the same name is automatically checked for and loaded if found. These results are then available to be displayed in the 3d graphics viewer (.gra) and the x-y graphs (.req). The label \plain\f0\fs20 \'91\f1 Primary\plain\f0\fs20 \'92\f1  indicates that these are the main results displayed, they can be compared to a second set of results referred to as the \plain\f0\fs20 \'91\f1 Secondary\plain\f0\fs20 \'92\f1  results which are loaded through a similar menu entry, (see below).
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\par \cf1 File / Load External Res\'85 (Secondary):\plain\fs20  Opens the standard Windows  file browser to locate and load a previously saved set of Adams results. Users can search for both *.req and *.gra files. Whichever type is located and loaded the other file type of the same name is automatically checked for and loaded if found. These results are then available to be displayed in the 3d graphics viewer (.gra) and the x-y graphs (.req). The label \plain\f0\fs20 \'91\f1 Secondary\plain\f0\fs20 \'92\f1  indicates that these are the comparison results, only being displayed when the relevant visibility switch is set to \plain\f0\fs20 \'91\f1 on\plain\f0\fs20 \'92\f1  and when primary results have also been loaded.
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\par \cf1 File / Import SKCMS Rig File:\plain\fs20   Opens the standard Windows file browser to locate the required existing file to load. The files required are those that have been produced from the Lotus SKCMS test rig and subsequently processed by the Lotus Controls data processing software. Note that this file import action will lose the current model data. The SKCMS file contains both averaged and individual Left/Right suspension data splines, thus the user is asked to define whether the imported model is required to be symmetrical, (in which case the averaged spline data is used) or asymmetric, (in which case the individual left and right splines are used).
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\par \cf1 File / Exit:\plain\fs20  Closes the application, subject to confirmation of \plain\f0\fs20 \'91\f1 okay to exit\plain\f0\fs20 \'92\f1 .
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\par Appended to the bottom of the \cf1 File\plain\fs20  menu, is a list of the last five (max) opened files.
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Pull Down Menu Items \plain\f0\b\fs28 \'96\f1  Module
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\par \cf1 Module / Shark / 2D Bump:\plain\fs20  Changes to the 2D module in Bump articulation mode. This will only be available if you are licensed for this full vehicle handling module, (licensed separately from Shark).
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\par \cf1 Module / Shark / 2D Roll:\plain\fs20  Changes to the 2D module in Roll articulation mode. This will only be available if you are licensed for this suspension kinematics module, (licensed separately from Raven).
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\par \cf1 Module / Shark / 3D Bump:\plain\fs20  Changes to the 3D module in Bump articulation mode. This will only be available if you are licensed for this suspension kinematics module, (licensed separately from Raven).
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\par \cf1 Module / Shark / 3D Roll:\plain\fs20  Changes to the 3D module in Roll articulation mode. This will only be available if you are licensed for this suspension kinematics module, (licensed separately from Raven).
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\par \cf1 Module / Shark / 3D Steer:\plain\fs20  Changes to the 3D module in Steer articulation mode. This will only be available if you are licensed for this suspension kinematics module, (licensed separately from Raven).
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\par \cf1 Module / Raven / STD Interface:\plain\fs20  Changes to the Raven module. 
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Pull Down Menu Items - Data
\par \pard \plain\fs20 
\par \cf1 Data / Vehicle:\plain\fs20  Displays the Vehicle data dialog box. All vehicle related property values can be displayed and edited through this display. All corner splines are similarly accessed through this via an additional pop-up display.
\par 
\par \cf1 Data / Tyres:\plain\fs20  Displays the Tyre data dialog box. All tyre related properties can be viewed both numerically and graphically through this display. The selection of individual tyre model types and associated property files is similarly controlled/listed via this dialogue box.
\par \pard 
\par \cf1 Data / Solution:\plain\fs20  Displays the Solution control dialog box. The current solution mode is set via this display, with all related solution settings displayed in editable fields. The setting of single mode or multiple mode analysis is controlled by enabling a solution from more than one solution panel. 
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Pull Down Menu Items - View
\par \pard \plain\fs20 
\par \cf1 View / Refresh:\plain\fs20  Updates all graphical displays, both Graphics and Graphs.
\par 
\par \cf1 View / Dynamic Viewing:\plain\fs20  Menu option to switch the  dynamic viewing mode on or off. Either by a toggle action or by specific selection..
\par 
\par \cf1 View / Translate View:\plain\fs20  Sets the dynamic view mode to translate. If dynamic viewing is currently \plain\f0\fs20 \'91\f1 off\plain\f0\fs20 \'92\f1  this will also cause the dynamic view mode to be turned \plain\f0\fs20 \'91\f1 on\plain\f0\fs20 \'92\f1 . Translation by left mouse button hold and move.
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\par \cf1 View / Scale View:\plain\fs20  Sets the dynamic view mode to scale. If dynamic viewing is currently \plain\f0\fs20 \'91\f1 off\plain\f0\fs20 \'92\f1  this will also cause the dynamic view mode to be turned \plain\f0\fs20 \'91\f1 on\plain\f0\fs20 \'92\f1 . Scale by left mouse button hold and drag vertically.
\par 
\par \cf1 View / Rotate View:\plain\fs20  Sets the dynamic view mode to rotate. If dynamic viewing is currently \plain\f0\fs20 \'91\f1 off\plain\f0\fs20 \'92\f1  this will also cause the dynamic view mode to be turned \plain\f0\fs20 \'91\f1 on\plain\f0\fs20 \'92\f1 . Rotation by left mouse button hold and move.
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\par \cf1 View / Zoom:\plain\fs20  Pick the area of the display to zoom to fit current window. The zoom function can accommodate either a two press approach to area selection or a single press, hold and drag selection, a simple time delay trap being used to identify which type is being used. The zoomed view will retain the correct aspect ratio, (i.e. no distortion is allowed), and thus the final displayed region will include additional regions at either the top and bottom or both sides.
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\par \cf1 View / Autoscale (Ctrl+A):\plain\fs20  Resets the graphical view such that all drawn components appear within the display window. Note that this is only applied to the graphics window and not the graphs.
\par 
\par \cf1 View / Fill Style:\plain\fs20  Sets the fill style to be used in the graphics display. Not all the fill style options are supported by every machine. Two \uldb graphics frame\plain\fs20  driver options are used one of which will not correctly support two of the fill styles. The fill styles available are, Wire Frame, Filled, Hidden Line and Depth Buffered (flat shaded). The later two will not work correctly unless the graphics frame type has been set to OpenGL
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\par \cf1 View / Std Views:\plain\fs20  Three orthogonal views are offered to aid simple planar viewing of the 3D model. The std views are y-z (front view), z-x (side view) and x-y (top view). Equivalent view toolbar icons are also available.
\par 
\par \cf1 View / Saved Views / Save\'85:\plain\fs20  Saves the current 3D view settings to a temporary store, given a unique label for possible later retrieval. This temporary store only exists whilst the application is open such that all saved views are lost when the application is closed. Any number of views can be stored.
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\par \cf1 View / Saved Views / Recall Saved:\plain\fs20  Recalls a saved view, replacing the current view with that in the temporary store. Saved views are identified by their labels.
\par 
\par \cf1 View / Saved Views / Delete Saved:\plain\fs20  Deletes a saved view from the temporary store. Only valid use is the simplifying of the displayed options through reduced menu list.
\par 
\par \cf1 View / Saved Views / Delete All:\plain\fs20  Deletes all saved views from the temporary store. Quicker than deleting one at a time if looking to start the storing from scratch.
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\par \cf1 View / Set Background Colour\'85:\plain\fs20  Opens a standard colour selection dialog to pick a new colour for the background colour used in the graphics display. Note that graphs have their ow ncolour settings and are not affected by this change.
\par 
\par \cf1 View / Graphics Frame Type:\plain\fs20  Sets the \uldb graphics frame\plain\fs20  device type as either Windows GDI or Open GL. The default device driver is a Windows GDI, (\i View / Graphics Frame Type / Windows GDI),\plain\fs20  which whilst it works with all Hardware options does so at the expense of both speed and capability. The GDI driver is unable to support depth buffered display and hence the view styles \i View / Fill Style / Hidden Line \plain\fs20 and \i View / Fill Style / Depth Buffered (Flat shaded )\plain\fs20  do not function correctly. The alternative device driver is Open GL, (\i View / Graphics Frame Type / Open GL\plain\fs20 ), which is both faster and supports depth buffering/hidden line display types.
\par \pard 
\par Not all hardware is able to use the Open GL device type, typical failures are inability to refresh and lack of correct hidden line display.
\par 
\par \cf1 View / Animation (Displacements):\plain\fs20  Switches on animation of the suspension(s) over the currently selected articulation type. All standard viewing and editing functions can still be used whilst the animation is on.
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Pull Down Menu Items - Graphics
\par \pard \plain\fs20 
\par \cf1 Graphics / Visibility:\plain\fs20  Toggles the visibility of specific classes of parts on the 3D graphical display. A class may include a number of individual graphical elements that together pictorially describe the \plain\f0\fs20 \'91\f1 part\plain\f0\fs20 \'92\f1 . The individual classes are; \cf1 Front Tyres, Rear Tyres, Body C of G, \plain\f0\fs20\cf1 \'91\f1 H\plain\f0\fs20\cf1 \'92\f1  Point, Front Spring/Damper, Rear Spring Damper, Front Roll Bar, Rear Roll Bar, Jacks, Ground Plane, Time counter\plain\fs20  and \cf1 Axis Symbol\plain\fs20 . All settings are saved to the ini file.
\par \pard 
\par \cf1 Graphics / Visibility General:\plain\fs20  Toggles the visibility of individual graphical elements. Elements are identified by their type and No. Individual graphical element types are; \cf1 Outlines, Circles, Arcs, Cylinders, Forces, Frustrums, Boxes \plain\fs20 and \cf1 Spring/Dampers\plain\fs20 . The visibility settings are displayed in the form of a \plain\f0\fs20 \'91\f1 tree\plain\f0\fs20 \'92\f1  structure. Expand each branch to find individual graphical elements or use the \plain\f0\fs20 \'91\f1 All\plain\f0\fs20 \'92\f1  option to control the visibility of whole graphical type sets. All settings are saved to the ini file.
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\par \cf1 Graphics / Colours:\plain\fs20  Defines the colour of specific classes of parts on the 3D graphical display. The individual classes are; \cf1 Front Tyres, Rear Tyres, Body C of G, \plain\f0\fs20\cf1 \'91\f1 H\plain\f0\fs20\cf1 \'92\f1  Point, Front Spring/Damper, Rear Spring Damper, Front Roll Bar, Rear Roll Bar, Jack Plates, Jack Upper, Jack Lower, Ground Plane \plain\fs20 and \cf1 Time Counter\plain\fs20 . All settings are saved to the ini file. Colour settings are changed by selecting the required new colour from the displayed palette. 
\par \pard 
\par \cf1 Graphics / Colours General:\plain\fs20  Defines the colour of individual graphical elements. As for visibility elements are identified by their type and No. Individual graphical element types are; \cf1 Outlines, Circles, Arcs, Cylinders, Forces, Frustrums, Boxes \plain\fs20 and \cf1 Spring/Dampers\plain\fs20 . The colour settings are displayed in the form of a \plain\f0\fs20 \'91\f1 tree\plain\f0\fs20 \'92\f1  structure. Expand each branch to find individual graphical elements or use the \plain\f0\fs20 \'91\f1 All\plain\f0\fs20 \'92\f1  option to control the colour of whole graphical type sets. All settings are saved to the ini file. The available colours are listed in the form of a menu option, note that fewer colour options are available through this than with the previous menu option.
\par \pard 
\par \cf1 Graphics / Dim. Properties:\plain\fs20  Displays for editing the dimensional properties for graphical element classes. The listed properties control the physical size of the specific class. Each class has its own specific list of properties. Changes made to the graphical properties will have no effect on the currently displayed elements, they will only affect subsequent runs results. The graphical classes that have properties are; \cf1 Front Tyres, Rear Tyres, Body, C of G, \plain\f0\fs20\cf1 \'91\f1 H\plain\f0\fs20\cf1 \'92\f1  Point, Front Spring Damper, Rear Spring Damper, Front Roll Bar, Rear Roll Bar, Jacks \plain\fs20 and \cf1 Ground Plane.\plain\fs20 
\par \pard 
\par \cf1 Graphics / Moving Eye:\plain\fs20  Toggles the \plain\f0\fs20 \'91\f1 moving eye\plain\f0\fs20 \'92\f1  animation option on/off. When \plain\f0\fs20 \'91\f1 on\plain\f0\fs20 \'92\f1  the moving eye modifies the animation view of the 3D graphical results such that the eye point moves with the specified part. The required part to \plain\f0\fs20 \'91\f1 follow\plain\f0\fs20 \'92\f1  is identified through a separate menu. The moving eye can follow the part motion in all three axes or combinations as required, (set by separate toggle switches). A delay in following can also be defined such that there is a lag between the actual motion and the moving eye. This gives a feel for the motion direction but keeps the components within the displayed region.
\par \pard 
\par \cf1 Graphics / Follow Part:\plain\fs20  Opens a selection box listing the currently available parts. The current selection will be highlighted. To change to another part select it and confirm via the \plain\f0\fs20 \'91\f1 ok\plain\f0\fs20 \'92\f1  button.
\par 
\par \cf1 Graphics / Follow X:\plain\fs20  Toggles the setting for the moving eye following the x-axis motion of the selected part.
\par  
\par \cf1 Graphics / Follow Y:\plain\fs20  Toggles the setting for the moving eye following the y-axis motion of the selected part.
\par 
\par \cf1 Graphics / Follow Z:\plain\fs20  Toggles the setting for the moving eye following the z-axis motion of the selected part.
\par \pard 
\par \cf1 Graphics / Follow Delay:\plain\fs20  Toggles the follow delay switch. Controls whether the defined delay is applied to the moving eye view. Only effects the 3D view when in \plain\f0\fs20 \'91\f1 moving eye\plain\f0\fs20 \'92\f1  animation mode.
\par 
\par \cf1 Graphics / Delay Size:\plain\fs20  Defines the magnitude of the delay in terms of calculation steps. It only effects the 3D view if both \plain\f0\fs20 \'91\f1 Moving Eye\plain\f0\fs20 \'92\f1  and \plain\f0\fs20 \'92\f1 Follow Delay\plain\f0\fs20 \'92\f1  are turned on. Note this actual delay value time depends on the solution time step size since this setting is based on the number of calculation steps.
\par \pard 
\par \cf1 Graphics / Secondary Graphics:\plain\fs20  Controls the visibility of the loaded secondary graphics. Controls both 3D graphics and opened graphs. Will only impact the displays if a results file has been loaded into the secondary slot via the external file load menu or via the job submission options.
\par 
\par \cf1 Graphics / Moving  Ground:\plain\fs20  Toggles the moving ground option. When \plain\f0\fs20 \'91\f1 on\plain\f0\fs20 \'92\f1  this visually rotates the wheel graphical elements and shifts the ground plane X lines to give the impression of forward motion.
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\par \cf1 Graphics / Copy to Clipboard:\plain\fs20  Copies the current graphical display to the Windows clipboard such that it can be pasted into other applications.
\par 
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Pull Down Menu Items - Graphs
\par \pard \plain\fs20 
\par \cf1 Graphs / New/Open:\plain\fs20  Opens a new graph window. Each new graph will by default take the use y-variable from the available list. To change the y-variable once opened use the mouse right button menu options.
\par 
\par \cf1 Graphs / Visibility:\plain\fs20  Controls the visibility of the graph items. Options are given to switch individual graph items on and off. For the purpose of this menu the \plain\f0\fs20 \'91\f1 graph\plain\f0\fs20 \'92\f1  items are\cf1 ; Grid Lines, Point Symbols\plain\fs20  and \cf1 Data Values.\plain\fs20 
\par \pard 
\par \cf1 Graphs / Colours:\plain\fs20  Provides control over individual graph element colours. Modified colour settings are stored to the users ini file. The graph elements that can be defined via this menu include; \cf1 Grid Lines, Background, Axis Lines\plain\fs20  and \cf1 Text, Border Region, Primary Results Line\plain\fs20  and \cf1 Secondary Results Line.\plain\fs20 
\par 
\par \cf1 Graphs / Line Marker:\plain\fs20  Provides control over individual graph line markers. Modified marker settings are saved to the users ini file. The graph lines that marker types can be defined for are; \cf1 Primary Results Line\plain\fs20  and \cf1 Secondary Results Line\plain\fs20 . The nine marker types available are \cf1 Filled Diamond, Triangle, Inverted Triangle, Plus, Cross, Square, Diamond, Circle\plain\fs20  and \cf1 Star\plain\fs20 .
\par \pard 
\par \cf1 Graphs / Line Marker / Set to Defaults:\plain\fs20  Single menu selection to set all relevant graph line marker symbols back to the default settings. For relevant elements see previous menu item.
\par 
\par \cf1 Graphs / Autoscale (All):\plain\fs20  Autoscales all open graphs for both x and y-axes. Includes all visible lines. To autoscale individual graphs use the mouse right button menu item.
\par 
\par \cf1 Graphs / Marker/Text Sizes / Edit Sizes:\plain\fs20  Displays the graph marker and text sizes for viewing and editing. Changes are stored to the users ini file. Properties that can be edited include; Data Line Marker Size and Graph Data Values Text Size.
\par \pard 
\par \cf1 Graphs / Marker/Text Sizes / Set to Defaults:\plain\fs20  Single menu selection to set all relevant graph marker and text sizes back to the default settings. For relevant elements see previous menu item.
\par 
\par \cf1 Graphs / Decimal Points Display / Edit Settings:\plain\fs20  Displays the graph decimal points display for viewing and editing. Changes are stored to the users ini file. Properties that can be edited include; X-Data Listing and Y-Data Listing.
\par 
\par \cf1 Graphs / Decimal Points Display / Set to Defaults:\plain\fs20  Single menu selection to set all relevant graph decimal points displays back to the default settings. For relevant elements see previous menu item.
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Pull Down Menu Items - Solve
\par \pard \plain\fs20 
\par \cf1 Solve / Submit:\plain\fs20  Creates a new solution run. Based on the current model settings and solution settings this option writes an *.adm and *.acf file before running the standard ADAMS solver. Options are offered as to whether the results files should be permanently saved to the hard disc and how to load the results files upon job completion. Before this option can be used successfully users must ensure that they have edited the settings for the Batch File and the Command Line Arguments, (see later descriptions for these items).
\par \pard 
\par \cf1 Solve / Tolerances:\plain\fs20  A number of solver tolerances are edited through this menu item. They are included in the written adm and acf files and control the ADAMS solver run. The tolerances listed are; ERROR Tolerance, ALIMIT Tolerance, TLIMIT Tolerance and INTEGRATOR Tolerance. Users should refer to the appropriate ADAMS documentation for descriptions of these variables.
\par 
\par \cf1 Solve / Command Line Arguments:\plain\fs20  Defines the command line arguments used to run the ADAMS solver. The minimum should be \plain\f0\fs20 \'91\f1 ru-user\plain\f0\fs20 \'92\f1 . Normally this would also include the path and name of the varsub.dll file supplied as part of the installation. Without the dll path and name on the command line, no tyre models other than the \plain\f0\fs20 \'91\f1 mal\plain\f0\fs20 \'92\f1  tyre can be used. If the Lotus software has been installed into the default folder the setting for this would normally be \plain\f0\fs20\cf1 \'91\f1 ru-user C:\'5clesoft\'5cvarsub.dll\plain\f0\fs20\cf1 \'92\plain\fs20 .
\par \pard 
\par \cf1 Solve / ADAMS Batch File:\plain\fs20  Defines the path and name of the ADAMS solver \plain\f0\fs20 \'91\f1 mdi.bat\plain\f0\fs20 \'92\f1  file. This would normally be in a sub folder of \plain\f0\fs20 \'91\f1 Program Files\plain\f0\fs20 \'92\f1 , but the exact folder name will vary depending on the actual version of ADAMS installed on the machine. As an example for Adams version 12.0 the setting for this would be \plain\f0\fs20 \'91\f1\cf1 C\'5cProgram Files\'5cADAMS 12.0\'5ccommon\'5cmdi.bat\plain\f0\fs20\cf1 \'92\f1 .
\par \plain\fs20 
\par \cf1 Solve / Solution Data:\plain\fs20  Displays the Solution control dialog box. The current solution mode is set via this display, with all related solution settings displayed in editable fields. The setting of single mode or multiple mode analysis is controlled by enabling a solution from more than one solution panel. 
\par \pard 
\par \cf1 Solve / Road Motion:\plain\fs20  Provides a visual check on the current Road Motion setting, and a quick route to change between Road Motion options.
\par 
\par \cf1 Solve / Steering Motion:\plain\fs20  Provides a visual check on the current Steering Motion setting, and a quick route to change between Steering Motion options.
\par 
\par \cf1 Solve / Braking/Accel.:\plain\fs20  Provides a visual check on the current Braking/Acceleration setting, and a quick route to change between the Braking and Acceleration options.
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Pull Down Menu Items - SetUp
\par \pard \plain\fs20 
\par \cf1 SetUp / Start Options / Toolbar Icons:\plain\fs20  Provides an option for two styles of icons. Select from either \cf1 Standard\plain\fs20  or \cf1 Mouse Sensitive\plain\fs20 . Standard icons have permanently visible boundaries to the icon, whilst mouse sensitive icons \plain\f0\fs20 \'91\f1 raise\plain\f0\fs20 \'92\f1  as the mouse passes over them. This change is stored to the ini file and will only be implemented on next program start-up.
\par 
\par \cf1 SetUp / Start Options / Toolbar Position:\plain\fs20  Sets the default starting position for the toolbars. All visible toolbars will be placed in this position when the application starts up. Once started the user can choose to change the toolbar positions individually as required. The four available positions are Top, Bottom, Left or Right. This change is stored to the ini file and will only be implemented on the next program start-up.
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\par \cf1 SetUp / Start Options / Maximised:\plain\fs20  If checked defines that the application will start up with the main window maximised, (i.e. expanded to fill the current screen size). Note that if the application is maximised during use, then this will also set the \plain\f0\fs20 \'91\f1 maximised\plain\f0\fs20 \'92\f1  setting. This change is stored to the ini file and will be implemented on next program start-up.
\par 
\par \cf1 SetUp / Exception Handler On:\plain\fs20  Provides a software trapping routine to handle application exception failures. Whilst this won\plain\f0\fs20 \'92\f1 t enable the user to recover the current session it will prevent the exception causing a complete system failure. Not normally required this release.
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\par \cf1 SetUp / Save Def. Window Settings:\plain\fs20  When set this options will save to the users ini file the current size, positions and settings of the graphics and graph windows, such that on a subsequent program start-up all windows will be re-created in the same position/size as previously. They are referred to \plain\f0\fs20 \'91\f1 default\plain\f0\fs20 \'92\f1  since users can store different settings to alternative files.
\par 
\par \cf1 SetUp / Save Window Settings to\'85:\plain\fs20  This option allows the user to save the current window and graph settings to a file. These settings can then be retrieved at a later stage or in future runs.
\par \pard 
\par \cf1 SetUp / Load Window Settings from\'85:\plain\fs20  This option allows the user to retrieve from a previously saved file the settings for the main window and graphs. These settings included not only position and size but also displayed variables and axis settings.
\par 
\par \cf1 SetUp / View Toolbar Visibility:\plain\fs20  Sets the visibility option for the \cf1 View\plain\fs20  toolbar. This setting is saved to the ini file and will thus be applied to future runs.
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\par \cf1 SetUp / File + Data Toolbar Visibility:\plain\fs20  Sets the visibility option for the \cf1 File and Data\plain\fs20  toolbar. This setting is saved to the ini file and will thus be applied to future runs.
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Pull Down Menu Items - Window
\par \pard \plain\fs20 
\par \cf1 Window / Tile Horizontal:\plain\fs20  Automatic window positioning option that lays open windows in to a primarily horizontal layout.
\par 
\par \cf1 Window / Tile Vertical:\plain\fs20  Automatic window positioning option that lays open windows in to a primarily vertical layout. 
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\par \cf1 Window / Cascade:\plain\fs20  Automatic window positioning option. All open windows are re-sized to a common size and cascaded down from the top left hand corner in regular steps.
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\par The \cf1 Window\plain\fs20  menu has appended to it an entry for each child window. Child windows include graphic displays all graphs and results displays.
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Pull Down Menu Items - Help
\par \pard \plain\fs20 
\par \cf1 Help / Contents (F1):\plain\fs20  Opens this help file at the contents page.
\par 
\par \cf1 Help / Search for Help On\'85:\plain\fs20  Opens this help file at the \plain\f0\fs20 \'92\f1 index\plain\f0\fs20 \'92\f1  page to allow for searching through the help file by key words.
\par 
\par \cf1 Help / How to Use Help:\plain\fs20  Opens the standard Windows\'ae Help document, describing how to use on-line help files.
\par 
\par \cf1 Help / About Lotus Suspension Analysis\'85:\plain\fs20  Displays the Lotus Suspension Analysis \plain\f0\fs20 \'91\f1 about\plain\f0\fs20 \'92\f1  box listing both the major and minor release levels. Support contact details are also given.
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Mouse Right Button Menu Items \plain\f0\b\fs28 \'96\f1  Graphics
\par \pard \plain\fs20 
\par No specific menus are used on the graphics display for the right mouse button, Instead it is used as a quick cycle through the dynamic viewing modes for the current dynamic viewing status.
\par 
\par In the view zoom mode the right mouse button will cancel the zoom event.
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Mouse Right Button Menu Items \plain\f0\b\fs28 \'96\f1  Graphs
\par \pard \plain\fs20 
\par \cf1 X-Parameter:\plain\fs20  Used to change the displayed x-axis parameter No. for the selected graph. Lists all available options, (some may not be relevant to the current module or model). The current variable is shown checked in the list. A selection is a combination of the parameter and channel No. Each parameter has 6 possible channels.
\par 
\par \cf1 X-Channel:\plain\fs20  Used to change the displayed x-axis channel No. for the selected graph. Lists all available options, (some may not be relevant to the current module or model). The current variable is shown checked in the list. A selection is a combination of the parameter and channel No.
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\par \cf1 Y-Parameter:\plain\fs20  Used to change the displayed y-axis parameter No. for the selected graph. Lists all available options, (some may not be relevant to the current module or model). The current variable is shown checked in the list. A selection is a combination of the parameter and channel No. Each parameter has 6 possible channels.
\par 
\par \cf1 Y-Channel:\plain\fs20  Used to change the displayed y-axis channel No. for the selected graph. Lists all available options, (some may not be relevant to the current module or model). The current variable is shown checked in the list. A selection is a combination of the parameter and channel No.
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\par \cf1 Autoscale:\plain\fs20  Autoscales the selected graph for both x and y-axes. Includes all visible lines on the graph. To autoscale all graphs use the main menu or equivalent toolbar icon.
\par 
\par \cf1 Zoom:\plain\fs20  Pick the area of the selected graph to fit the current window. The zoom function can accommodate either a two press approach to area selection or a single press, hold and drag selection, a simple time delay trap being used to identify which type is being used. The zoomed area will become the plotted region.
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\par \cf1 Axis Scales:\plain\fs20  Displays the selected graphs x and y-axis settings. Axes are defined simply by the minimum and maximum values.
\par 
\par \cf1 List Primary Results Line:\plain\fs20  Lists the selected graphs primary results line for viewing. As these are calculated results they are display only.
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\par \cf1 Copy to Clipboard:\plain\fs20  Copies the selected graph display to the Windows clipboard such that it can be pasted into other applications.
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Icon Description \plain\f0\b\fs28 \'96\f1  General
\par \pard \plain\f0\fs20 
\par \f1 The following icons are used within the application dialogue boxes. A brief description is given for each.
\par 
\par \b \{bmc bm25.bmp\} Generic Editor Icon, normally opens standard data editor display.
\par \plain\fs20 
\par \b \{bmc bm26.bmp\} Opens this Help File at context sensitive page
\par \plain\fs20 
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Icon Description \plain\f0\b\fs28 \'96\f1  View Toolbar
\par \pard \plain\f0\fs20 
\par \f1 The following icons are displayed on the view toolbar. A brief description is given for each.
\par 
\par \b \{bmc bm27.bmp\} Toggle dynamic viewing on/off.
\par \plain\fs20 
\par \b \{bmc bm28.bmp\} Set dynamic view on and mode to translate.
\par \plain\fs20 
\par \b \{bmc bm29.bmp\} Set dynamic view on and mode to scale.
\par \plain\fs20 
\par \b \{bmc bm30.bmp\} Set dynamic view on and mode to rotate.
\par \plain\fs20 
\par \b \{bmc bm31.bmp\} Start zoom event on the graphics display.
\par \plain\fs20 
\par \b \{bmc bm32.bmp\} Autoscale all open graphs.
\par \plain\fs20 
\par \b \{bmc bm33.bmp\} Set graphics view style to Wire Frame.
\par \pard \plain\fs20 
\par \b \{bmc bm34.bmp\} Set graphics view style to Solid Fill.
\par \plain\fs20 
\par \b \{bmc bm35.bmp\} Set graphics view style to Hidden Line.
\par \plain\fs20 
\par \b \{bmc bm36.bmp\} Set graphics view style to Depth Buffered (flat shaded).
\par \plain\fs20 
\par \b \{bmc bm37.bmp\} Set graphics view to Y-Z plane.
\par \plain\fs20 
\par \b \{bmc bm38.bmp\} Set graphics view to X-Z plane.
\par \plain\fs20 
\par \b \{bmc bm39.bmp\} Set graphics view to X-Y plane.
\par \plain\fs20 
\par \b \{bmc bm40.bmp\} Save current graphics view to temporary store.
\par \plain\fs20 
\par \b \{bmc bm41.bmp\} Cycle though the available dynamic view options.
\par \pard \plain\fs20 
\par \page
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Icon Description \plain\f0\b\fs28 \'96\f1  File + Data Toolbar
\par \pard \plain\f0\fs20 
\par \f1 The following icons are displayed on the File toolbar. A brief description is given for each.
\par 
\par \b \{bmc bm42.bmp\} Create a new data file.
\par \plain\fs20 
\par \b \{bmc bm43.bmp\} Open existing data file.
\par \plain\fs20 
\par \b \{bmc bm44.bmp\} Save data to file
\par \plain\fs20 
\par \b \{bmc bm45.bmp\} Edit/View Vehicle data 
\par \plain\fs20 
\par \b \{bmc bm46.bmp\} Edit/View Tyre data
\par \plain\fs20 
\par \b \{bmc bm47.bmp\} Edit/View Solution data
\par \plain\fs20 
\par \b \{bmc bm48.bmp\} Toggle Body visibility
\par \plain\fs20 
\par \b \{bmc bm49.bmp\} Toggle Jacks visibility
\par \plain\fs20 
\par \b \{bmc bm50.bmp\} Toggle ground plane visibility
\par \pard \plain\fs20 
\par \b \{bmc bm51.bmp\} Moving eye point viewing
\par \plain\fs20 
\par \b \{bmc bm52.bmp\} Animate model
\par \plain\fs20 
\par \b \{bmc bm53.bmp\} Copy display to clipboard
\par \plain\fs20 
\par \b \{bmc bm54.bmp\} Open new results graph
\par \plain\fs20 
\par \b \{bmc bm55.bmp\} Autoscale (all) results graphs
\par \plain\fs20 
\par \b \{bmc bm56.bmp\} Submit analysis job
\par \plain\fs20 
\par \page
{\up +}
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{\up #}
{\up >}
\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Data Requirements - Introduction
\par \pard \plain\fs20 
\par This section describes the data requirements for the Raven analysis module. Each data variable is listed, together with its units and any default value.
\par 
\par The listings are broken down into sections as they are displayed in the interface.
\par 
\par \page
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\pard\keepn\sb235\sa55\li715\fi-715 {\up K}
\b\fs28 Data Requirements \plain\f0\b\fs28 \'96\f1  Co-ordinate System
\par \pard \plain\fs20 
\par The \plain\f0\fs20 \'91\f1 RAVEN\plain\f0\fs20 \'92\f1  co-ordinate system is a right handed system with the Y-axis across the car track, the origin of which is assumed to be on the vehicle centre line and the +ve direction being towards the offside suspension (Right hand Corner sitting in car). The X-axis is along the vehicle wheelbase with the +ve direction towards the rear.
\par 
\par \pard\qc \{bmc bm57.bmp\}
\par \plain\f0\fs20 \'91\f1 RAVEN\plain\f0\fs20 \'92\f1  Co-ordinate System
\par \page
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Data Requirements \plain\f0\b\fs28 \'96\f1  Vehicle Data
\par \pard \plain\fs20 
\par The vehicle data display provides access to all vehicle related model data. To open this dialog box select the menu item \i Data / Vehicle...\plain\fs20  or the equivalent icon.
\par 
\par \pard\qc \{bmc bm45.bmp\}
\par Vehicle Data Display Icon
\par \pard 
\par Vehicle data is split into three types:
\par 
\par \pard\li1075\fi-355\tx1075 1)\tab Individual vehicle values
\par 1)\tab Corner Values
\par 1)\tab Corner Splines
\par \pard\tx1075 
\par \pard\tx1075 The individual vehicle values are always displayed on the vehicle graphic in their respective boxes. Corner values are only shown in the corner editable boxes when selected from the \i Corner-Data\plain\fs20  menu list. Corner splines are never listed directly on the main display, access to the splines being through pop-up displays.
\par \pard\tx1075 
\par \pard\qc\tx1075 \{bmc bm58.bmp\}
\par \pard\qc\tx1075 Main Vehicle Data Display
\par \pard\tx1075 
\par \pard\tx1075 Each data type will be listed separately.
\par \pard\tx1075 
\par \pard\tx1075 
\par \pard\tx1075 \b\ul Individual Vehicle Values
\par \pard\tx1075 \plain\fs20 
\par \pard\tx1075 \b Front Track,\plain\fs20   (real),  (units m)
\par \pard\tx1075 The lateral distance between the centres of tyre contact of a pair of front wheels, (SAE J670e)
\par \pard\tx1075 
\par \pard\tx1075 \b No. of Tyres Front Corner,\plain\fs20   (integer)
\par \pard\tx1075 Sets the number of tyres at each front corner. Normally this would be one.
\par \pard\tx1075 
\par \pard\tx1075 \b Front Single Wheel Damper Rate,\plain\fs20   (real),  (units Ns/m)
\par \pard\tx1075 The rate of the viscous damping force of a single front wheel, in vertical displacement, which is proportional and opposite in direction to the wheel vertical velocity. (Note Damping is equivalent to at the wheel).
\par \pard\tx1075 
\par \pard\tx1075 \b Front Tyre Relaxation Angle,\plain\fs20   (real),  (units Rad)
\par \pard\tx1075 The 1st order lag angle. Used to define the rate of lateral force rise as a function of vertical load, at a specified pressure and temperature for the front tyre. Can also be accessed through the Tyre data display.
\par \pard\tx1075 
\par \pard\tx1075 \b Steering Ratio,\plain\fs20   (real)
\par \pard\tx1075 Defines the ratio between hand wheel angle and tyre steer angle.
\par \pard\tx1075 
\par \pard\tx1075 \plain\f0\b\fs20 \'91\f1 H\plain\f0\b\fs20 \'92\f1  Point X, Y and Z,\plain\fs20   (real),  (units m)
\par \pard\tx1075 Defines the position of the \plain\f0\fs20 \'91\f1 H\plain\f0\fs20 \'92\f1  point relative to the C of G position. Locates the point for specific output response results to be calculated for.
\par \pard\tx1075 
\par \pard\tx1075 \b Wheelbase,\plain\fs20   (real),  (units m)
\par \pard\tx1075 The fore/aft distance between the centres of tyre contact of a pair of axles.
\par \pard\tx1075 
\par \pard\tx1075 \b Sprung C of G Height,\plain\fs20   (real),  (units m)
\par \pard\tx1075 Sets the height of the sprung mass\plain\f0\fs20 \'92\f1 s C of G position above the ground plane.
\par \pard\tx1075 
\par \pard\tx1075 \b Sprung Mass,\plain\fs20   (real),  (units kg)
\par \pard\tx1075 All mass which is supported by the suspension, includes portions of the mass of the suspension members, (SAE J670e).
\par \pard\tx1075 
\par \pard\tx1075 \b Total Front Weight Split,\plain\fs20   (real),  (units %)
\par \pard\tx1075 Defines the vehicle total weight split between the front and rear axles, by defining the % weight on the front axle.
\par \pard\tx1075 
\par \pard\tx1075 \b Sprung Inertia, X-X, Y-Y and Z-Z,\plain\fs20   (real),  (units kg.m2)
\par \pard\tx1075 Defines the inertia of the sprung mass about the three global axes. The inertia values should not include the inertial component due to the un-sprung corner weights.
\par \pard\tx1075 
\par \pard\tx1075 \b Rear Track,\plain\fs20   (real),  (units m)
\par \pard\tx1075 The lateral distance between the centres of tyre contact of a pair of rear wheels, (SAE J670e)
\par \pard\tx1075 
\par \pard\tx1075 \b No. of Tyres Rear Corner,\plain\fs20   (integer)
\par \pard\tx1075 Sets the number of tyres at each rear corner. Normally this would be one.
\par \pard\tx1075 
\par \pard\tx1075 \b Rear Single Wheel Damper Rate,\plain\fs20   (real),  (units Ns/m)
\par \pard\tx1075 The rate of the viscous damping force of a single rear wheel, in vertical displacement, which is proportional and opposite in direction to the wheel vertical velocity. (Note Damping is equivalent to at the wheel).
\par \pard\tx1075 
\par \pard\tx1075 \b Rear Relaxation Angle,\plain\fs20   (real),  (units Rad)
\par \pard\tx1075 The 1st order lag angle. Used to define the rate of lateral force rise as a function of vertical load, at a specified pressure and temperature for the rear tyre. Can also be accessed through the Tyre data display.
\par \pard\tx1075 
\par \pard\tx1075 
\par \pard\tx1075 \b\ul Corner Values
\par \pard\tx1075 \plain\fs20 
\par \pard\tx1075 Corner values are only displayed in the editable boxes when that particular variable has been selected from the \i Corner Data / Single Values\plain\fs20  menu list. The listed value\plain\f0\fs20 \'92\f1 s description is shown to the left of the edit box to indicate the displayed variable. If the \plain\f0\fs20 \'91\f1 Edit Data\plain\f0\fs20 \'92\f1  icon is shown rather than an editable field this is because a \i Corner Spline\plain\fs20  has been selected rather than a \i Corner Value.\plain\fs20 
\par \pard\tx1075 
\par \pard\tx1075 As an alternative all \i Corner Values\plain\fs20  can be displayed together using the \i Corner Data / Single Values / Display Full List\plain\fs20  menu option.
\par \pard\tx1075 
\par \pard\qc\tx1075 \{bmc bm59.bmp\}
\par \pard\qc\tx1075 Vehicle Data \plain\f0\fs20 \'91\f1 All Corner Values\plain\f0\fs20 \'92\f1  Display
\par \pard\tx1075 
\par \pard\tx1075 Depending whether the model is defined as symmetrical or asymmetrical will affect if both Left and Right sides are listed/editable. For a symmetrical model only the right hand side is displayed/editable. The Left hand side being assumed the same/mirrored.
\par \pard\tx1075 
\par \pard\tx1075 The list of corner values includes;
\par \pard\tx1075 
\par \pard\tx1075 \b Unsprung Mass,\plain\fs20   (real),  (units kg)
\par \pard\tx1075 Defines the un-sprung mass for one corner of the car. Un-Sprung mass is defined as all mass which is not carried by the suspension system, but is supported directly by the tyre or wheel and is considered to move with it.
\par \pard\tx1075 
\par \pard\tx1075 \b Tyre Vertical Stiffness,\plain\fs20   (real),  (units N/m)
\par \pard\tx1075 Sets the tyre vertical stiffness for each corner at a specified load and inflation pressure. This value can also be edited through the \i Tyre\plain\fs20  data section. The Tyre Vertical Stiffness, Tyre Vertical Damping and Tyre Loss Angle values are linked via the relationship, Damping = Stiffness x Sin(Loss Angle).
\par \pard\tx1075 
\par \pard\tx1075 \b Tyre Vertical Damping,\plain\fs20   (real),  (units N.s/m)
\par \pard\tx1075 Sets the tyre vertical damping for each corner at a specified load and inflation pressure. This value can also be edited through the \i Tyre\plain\fs20  data section. The Tyre Vertical Stiffness, Tyre Vertical Damping and Tyre Loss Angle values are linked via the relationship, Damping = Stiffness x Sin(Loss Angle). If this field is not editable it is because the interface is currently set to define the damping via the loss angle rather than directly with the damping value. The setting of whether to use the loss angle or the damping value is controlled by the Vehicle Data menu item \i Loss Angle / Use Loss Angles\plain\fs20 .
\par \pard\tx1075 
\par \pard\tx1075 \b Non Dimensional Cornering Stiffness,\plain\fs20   (real)
\par \pard\tx1075 Sets one of the tyre characteristics for the simple MAL tyre model. A non-dimensional coefficient that defines the tyre lateral force as a function of the slip angle and vertical load. This value is also editable through the \i Tyre\plain\fs20  data section.
\par \pard\tx1075 
\par \pard\tx1075 \b Non Dimensional Camber Stiffness,\plain\fs20   (real)
\par \pard\tx1075 Sets one of the tyre characteristics for the simple MAL tyre model. A non-dimensional coefficient that defines the tyre camber thrust as a function of the camber angle and vertical load. This value is also editable through the \i Tyre\plain\fs20  data section.
\par \pard\tx1075 
\par \pard\tx1075 \b Bush Lateral Stiffness,\plain\fs20   (real),  (units N/m)
\par \pard\tx1075 Sets the bush lateral stiffness properties for each corner. This is the bush connecting the unsprung corner mass to the sprung mass. The Bush Lateral Stiffness, Bush Lateral Damping and Bush Loss Angle values are linked via the relationship, Damping = Stiffness x Sin(Loss Angle). 
\par \pard\tx1075 
\par \pard\tx1075 \b Bush Lateral Damping,\plain\fs20   (real),  (units N.s/m)
\par \pard\tx1075 Sets the bush lateral damping for each corner. This is the bush connecting the unsprung corner mass to the sprung mass. The Bush Lateral Stiffness, Bush Lateral Damping and Bush Loss Angle values are linked via the relationship, Damping = Stiffness x Sin(Loss Angle). If this field is not editable it is because the interface is currently set to define the damping via the loss angle rather than directly with the damping value. The setting of whether to use the loss angle or the damping value is controlled by the Vehicle Data menu item \i Loss Angle / Use Loss Angles\plain\fs20 .
\par \pard\tx1075 
\par \pard\tx1075 \b Bush Longitudinal Stiffness,\plain\fs20   (real),  (units N/m)
\par \pard\tx1075 Sets the bush longitudinal stiffness properties for each corner. This is the bush connecting the unsprung corner mass to the sprung mass. The Bush Longitudinal Stiffness, Bush Longitudinal Damping and Bush Loss Angle values are linked via the relationship, Damping = Stiffness x Sin(Loss Angle). 
\par \pard\tx1075 
\par \pard\tx1075 \b Bush Longitudinal Damping,\plain\fs20   (real),  (units N.s/m)
\par \pard\tx1075 Sets the bush longitudinal damping for each corner. This is the bush connecting the unsprung corner mass to the sprung mass. The Bush Longitudinal Stiffness, Bush Longitudinal Damping and Bush Loss Angle values are linked via the relationship, Damping = Stiffness x Sin(Loss Angle). If this field is not editable it is because the interface is currently set to define the damping via the loss angle rather than directly with the damping value. The setting of whether to use the loss angle or the damping value is controlled by the Vehicle Data menu item \i Loss Angle / Use Loss Angles\plain\fs20 .
\par \pard\tx1075 
\par \pard\tx1075 \b Static Toe,\plain\fs20   (real),  (units Deg)
\par \pard\tx1075 Sets the static toe angle for each corner. The sign convention is based on the right hand grip rule about the global Z-axis, thus the conventional \plain\f0\fs20 \'91\f1 toe-in\plain\f0\fs20 \'92\f1  would give a different sign for the right (+ve) and left (-ve) suspension sides. Toe angle is defined as the angle between a longitudinal axis of the vehicle and the line of intersection of the wheel plane and the road surface, (SAE J670e).
\par \pard\tx1075 
\par \pard\tx1075 \b Static Camber,\plain\fs20   (real),  (units Deg)
\par \pard\tx1075 Sets the static camber angle for each corner. The sign convention is based on the right hand grip rule about the global X-axis, thus the conventional \plain\f0\fs20 \'91\f1 negative camber\plain\f0\fs20 \'92\f1  would give a different sign for the right (+ve) and left (-ve) suspension sides. Camber angle is defined as the inclination of the wheel plane to the vertical, (SAE J670e).
\par \pard\tx1075 
\par \pard\tx1075 \b Wheel Diameter,\plain\fs20   (real),  (units m)
\par \pard\tx1075 Defines the wheel diameter for each corner.
\par \pard\tx1075 
\par \pard\tx1075 \b Wheel Inertia,\plain\fs20   (real),  (units kg/m2)
\par \pard\tx1075 Defines the wheel inertia for each corner.
\par \pard\tx1075 
\par \pard\tx1075 \b Tyre Loss Angle,\plain\fs20   (real),  (units deg)
\par \pard\tx1075 Sets the Tyre Loss angle for each corner. This value can also be edited through the \i Tyre\plain\fs20  data section. The Tyre Vertical Stiffness, Tyre Vertical Damping and Tyre Loss Angle values are linked via the relationship, Damping = Stiffness x Sin(Loss Angle). If this field is not editable it is because the interface is currently set to define the damping directly with the damping value rather than via the loss angle rather. The setting of whether to use the loss angle or the damping value is controlled by the Vehicle Data menu item \i Loss Angle / Use Loss Angles\plain\fs20 .
\par \pard\tx1075 
\par \pard\tx1075 \b Bush Loss Angle,\plain\fs20   (real),  (units deg)
\par \pard\tx1075 Sets the Bush Loss Angle for each corner. The Bush Stiffness\plain\f0\fs20 \'92\f1 s, Bush Damping and Bush Loss Angle values are linked via the relationship, Damping = Stiffness x Sin(Loss Angle). If this field is not editable it is because the interface is currently set to define the damping via the loss angle rather than directly with the damping value. The setting of whether to use the loss angle or the damping value is controlled by the Vehicle Data menu item \i Loss Angle / Use Loss Angles\plain\fs20 .
\par \pard\tx1075 
\par \pard\tx1075 
\par \pard\tx1075 \b\ul Corner Splines
\par \pard\tx1075 \plain\fs20 
\par \pard\tx1075 Corner splines are only displayed by selecting either the individual \i Edit Data\plain\fs20  button when that particular variable has been selected from the \i Corner Data / Splines\plain\fs20  menu list or a from the combined displaye using the \i Corner Data / Splines / Display Full List\plain\fs20  menu option.
\par \pard\tx1075 
\par \pard\qc\tx1075 \{bmc bm60.bmp\}
\par \pard\qc\tx1075 Vehicle Data \plain\f0\fs20 \'91\f1 Display Full List\plain\f0\fs20 \'92\f1  Display
\par \pard\tx1075 
\par \pard\tx1075 Depending whether the model is defined as symmetrical or asymmetrical will affect if both Left and Right sides are listed/editable. For a symmetrical model only the right hand side is displayed/editable. The Left hand side being assumed the same/mirrored.
\par \pard\tx1075 
\par \pard\tx1075 The list of corner splines includes;
\par \pard\tx1075 
\par \pard\tx1075 \b Toe Change Bump,\plain\fs20   (real),  (units m,deg)
\par \pard\tx1075 List the change in Toe angle for each wheel with bump/rebound motion.
\par \pard\tx1075 
\par \pard\tx1075 \b Camber Change Bump,\plain\fs20   (real),  (units m,deg)
\par \pard\tx1075 List the change in Camber angle for each wheel with bump/rebound motion.
\par \pard\tx1075 
\par \pard\tx1075 \b Toe Change Roll,\plain\fs20   (real),  (units m,deg)
\par \pard\tx1075 List the change in Toe angle for each wheel with roll motion. Currently this is not used by the adm so can be left undefined unless the user has set the \i Spline-Type \plain\fs20 setting to \i Roll.\plain\fs20 
\par \pard\tx1075 
\par \pard\tx1075 \b Camber Change Roll,\plain\fs20   (real),  (units m,deg)
\par \pard\tx1075 List the change in Camber angle for each wheel with roll motion. Currently this is not used by the adm so can be left undefined unless the user has set the \i Spline-Type \plain\fs20 setting to \i Roll.\plain\fs20 
\par \pard\tx1075 
\par \pard\tx1075 \b Opposed Lateral Force Steer,\plain\fs20   (real),  (units N,deg)
\par \pard\tx1075 List the change in Toe angle of each wheel for opposed lateral forces applied to each upright at the tyre contact point.
\par \pard\tx1075 
\par \pard\tx1075 \b Parallel Lateral Force Steer,\plain\fs20   (real),  (units N,deg)
\par \pard\tx1075 List the change in Toe angle of each wheel for parallel lateral forces applied to each upright at the tyre contact point.
\par \pard\tx1075 
\par \pard\tx1075 \b Opposed Trailed Lateral Force Steer,\plain\fs20   (real),  (units N,deg)
\par \pard\tx1075 List the change in Toe angle of each wheel for opposed trailed lateral forces applied to each upright at 30 mm behind the tyre contact point.
\par \pard\tx1075 
\par \pard\tx1075 \b Parallel Trailed Lateral Force Steer,\plain\fs20   (real),  (units N,deg)
\par \pard\tx1075 List the change in Toe angle of each wheel for parallel trailed lateral forces applied to each upright at 30 mm behind the tyre contact point.
\par \pard\tx1075 
\par \pard\tx1075 \b Opposed Wheel Vertical Force,\plain\fs20   (real),  (units m,N)
\par \pard\tx1075 List the change in tyre vertical force for opposed vertical displacement of the tyre contact point.
\par \pard\tx1075 
\par \pard\tx1075 \b Parallel Wheel Vertical Force,\plain\fs20   (real),  (units m,N)
\par \pard\tx1075 List the variation in tyre vertical force for parallel vertical displacement of the tyre contact point.
\par \pard\tx1075 
\par \pard\tx1075 \b Single Wheel Brake Steer,\plain\fs20   (real),  (units N,deg)
\par \pard\tx1075 List the change in Toe angle of each wheel for a single longitudinal force applied to the upright at the tyre contact point.
\par \pard\tx1075 
\par \pard\tx1075 \b Parallel Wheel Brake Steer,\plain\fs20   (real),  (units N,deg)
\par \pard\tx1075 List the change in Toe angle of each wheel for parallel longitudinal forces applied to each upright at the tyre contact point.
\par \pard\tx1075 
\par \pard\tx1075 \b Track Change Gradient,\plain\fs20   (real),  (units m, mm/mm)
\par \pard\tx1075 List the variation in the rate of change of track for each wheel over bump/rebound motion.
\par \pard\tx1075 
\par \pard\tx1075 \b Lateral Force Camber Compliance,\plain\fs20   (real),  (units N, deg)
\par \pard\tx1075 List the change in the camber angle of each wheel for lateral forces applied to each upright at the tyre contact point.
\par \pard\tx1075 
\par \pard\tx1075 \b Wbase TCP Gradient,\plain\fs20   (real),  (units m, mm/mm)
\par \pard\tx1075 List the variation in the rate of change of the wheelbase for each wheel over bump/rebound motion for the Tyre contact point.
\par \pard\tx1075 
\par \pard\tx1075 \b Wbase Hub Gradient,\plain\fs20   (real),  (units m, mm/mm)
\par \pard\tx1075 List the variation in the rate of change of the wheelbase for each wheel over bump/rebound motion for the Hub point.
\par \pard\tx1075 
\par \pard\tx1075 \b Ackermann,\plain\fs20   (real),  (units deg, deg)
\par \pard\tx1075 Not strictly the variation in Ackermann % but the relationship of the wheel toe angles with change in steering hand wheel angle. Is only applicable for the front corners.
\par \pard\tx1075 
\par \pard\tx1075 \b Steer Jacking,\plain\fs20   (real),  (units deg, N)
\par \pard\tx1075 List the change in tyre vertical force due to steering. Vertical force is listed against toe angle for each wheel at the normal ride height. Is only applicable for the front corners.
\par \pard\tx1075 
\par \page
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\pard\keepn\sb235\sa55\li715\fi-715 \b\fs28 Data Requirements \plain\f0\b\fs28 \'96\f1  Tyre Data
\par \pard \plain\fs20 
\par 
\par The tyre data display provides access to all tyre related model data. To open this dialog box select the menu item \i Data / Tyre...\plain\fs20  or the equivalent icon.
\par 
\par \pard\qc \{bmc bm46.bmp\}
\par Tyre Data Display Icon
\par \pard 
\par The primary function of the tyre display window is to select the required tyre model and graphically display the defined tyre properties. The tyre properties displayed graphically are Lateral Force, Aligning Torque and Longitudinal Force. The Longitudinal Force option is only relevant for the \plain\f0\fs20 \'91\f1 Modified Delft\plain\f0\fs20 \'92\f1  model option.
\par 
\par \pard\qc \{bmc bm61.bmp\}
\par Tyre Data Display \plain\f0\fs20 \'96\f1  Showing Lateral Force Plot
\par \pard 
\par Each tyre model has its own unique data requirements, usually in the form of a series of coefficients, or a complete data file.
\par 
\par The secondary function of the tyre display window is to list for editing/display the other tyre related model properties. Some of these can also be edited through the vehicle data display.
\par 
\par \pard\qc \{bmc bm62.bmp\}
\par Tyre General Data Display
\par \pard 
\par 
\par \b\ul Tyre General Data
\par \plain\fs20 
\par \b Unloaded Radius,\plain\fs20   (real),  (units m)
\par Defines the rolling radius for the tyre.
\par 
\par \b Vertical Stiffness,\plain\fs20   (real),  (units N/m)
\par Defines the tyres vertical stiffness. The Tyre Vertical Stiffness, Tyre Vertical Damping and Tyre Loss Angle values are linked via the relationship, Damping = Stiffness x Sin(Loss Angle).
\par 
\par \b Vertical Damping,\plain\fs20   (real),  (units Ns/m)
\par Sets the tyre vertical damping. The Tyre Vertical Stiffness, Tyre Vertical Damping and Tyre Loss Angle values are linked via the relationship, Damping = Stiffness x Sin(Loss Angle). The setting of whether to use the loss angle or the damping value is controlled by the Vehicle Data menu item \i Loss Angle / Use Loss Angles\plain\fs20 .
\par \pard 
\par \b Lateral Stiffness,\plain\fs20   (real),  (units N/m)
\par Defines the tyre lateral stiffness value. Only used with the Adams carpet plot type tyre model.
\par 
\par \plain\f0\b\fs20 \'91\f1 Mu\plain\f0\b\fs20 \'92\f1  Dynamic,\plain\fs20   (real)
\par Defines the Dynamic coefficient of friction. Only used with the Adams carpet plot type tyre model.
\par 
\par \plain\f0\b\fs20 \'91\f1 Mu\plain\f0\b\fs20 \'92\f1  Static,\plain\fs20   (real)
\par Defines the Static coefficient of friction. Only used with the Adams carpet plot type tyre model.
\par 
\par \b Dynamic Velocity,\plain\fs20   (real),  (units m/s)
\par \pard Defines the Dynamic velocity value for the tyre model. Only used with the Adams carpet plot type tyre model.
\par 
\par \b Static Velocity,\plain\fs20   (real),  (units m/s)
\par Defines the Static velocity value for the tyre model. Only used with the Adams carpet plot type tyre model.
\par 
\par \b Rolling Resistance Coefficient,\plain\fs20   (real)
\par Defines the Rolling resistance coefficient value for the tyre model. Only used with the Adams carpet plot type tyre model.
\par 
\par \b Equivalent Plane Angle,\plain\fs20   (real)
\par \pard Defines the Equivalent plane angle value for the tyre model. Only used with the Adams carpet plot type tyre model.
\par 
\par \b Equivalent Plane Increment,\plain\fs20   (real)
\par Defines the Equivalent plane increment value for the tyre model. Only used with the Adams carpet plot type tyre model.
\par 
\par \b Tyre Relaxation Angle,\plain\fs20   (real),  (units rad)
\par The 1st order lag angle. Used to define the rate of lateral force rise as a function of vertical load, at a specified pressure and temperature for the tyre. Can also be accessed through the Vehicle data display.
\par \pard 
\par 
\par \b\ul MAL - Tyre Model Data
\par \plain\fs20 
\par \b Non Dimensional Cornering Stiffness,\plain\fs20   (real)
\par A non-dimensional coefficient that defines the tyre lateral force as a function of the slip angle and vertical load. This value is also editable through the \i Tyre\plain\fs20  data section.
\par 
\par \b Non Dimensional Camber Stiffness,\plain\fs20   (real)
\par A non-dimensional coefficient that defines the tyre camber thrust as a function of the camber angle and vertical load. This value is also editable through the \i Tyre\plain\fs20  data section.
\par \pard 
\par \b Tyre \plain\f0\b\fs20 \'91\f1 mu\plain\f0\b\fs20 \'92\f1 ,\plain\fs20   (real)
\par Defines the limiting lateral mu for the tyre.
\par 
\par \b Saturation Force,\plain\fs20   (real),  (units N)
\par Defines the vertical force saturation value fro the tyre.
\par 
\par \b Tyre Width,\plain\fs20   (real),  (units m)
\par Defines the overall tyre width.
\par 
\par \b Vertical Force Coefficient,\plain\fs20   (real)
\par A non-dimensional coefficient that defines the tyre vertical force behaviour.
\par 
\par 
\par \b\ul Pacejka - Tyre Model Data
\par \plain\fs20 
\par \b Lateral Force Coefficients,\plain\fs20   (real)
\par \pard Pacejka uses 15 \plain\f0\fs20 \'91\f1 A\plain\f0\fs20 \'92\f1  coefficients to describe the variation of tyre lateral force with variation in Vertical force, slip angle and camber angle.
\par 
\par A0, A1, A2, A3, A4, A5, A6, A7, A8, A9, A10, A111, A112, A12 and A13
\par 
\par \b Aligning Torque Coefficients,\plain\fs20   (real)
\par Pacejka uses 18 \plain\f0\fs20 \'91\f1 C\plain\f0\fs20 \'92\f1  coefficients to describe the variation of tyre aligning torque with variation in Vertical force, slip angle and camber angle.
\par 
\par C0, C1, C2, C3, C4, C5, C6, C7, C8, C9, C10, C11, C12, C13, C14, C15, C16 and C17
\par \pard 
\par 
\par \b\ul Delft - Tyre Model Data
\par \plain\fs20 
\par \b Lateral Force Coefficients,\plain\fs20   (real)
\par Delft uses 19 \plain\f0\fs20 \'91\f1 A\plain\f0\fs20 \'92\f1  coefficients to describe the variation of tyre lateral force with variation in Vertical force, slip angle and camber angle.
\par 
\par A0, A1, A2, A3, A4, A5, A6, A7, A8, A9, A10, A111, A12, A13, A14, A15, A16, A17 and FZ0
\par 
\par \b Aligning Torque Coefficients,\plain\fs20   (real)
\par Delft uses 25 \plain\f0\fs20 \'91\f1 C\plain\f0\fs20 \'92\f1  coefficients to describe the variation of tyre aligning torque with variation in Vertical force, slip angle and camber angle.
\par \pard 
\par C0, C1, C2, C3, C4, C5, C6, C7, C8, C9, C10, C11, C12, C13, C14, C15, C16, C17, C18, C19, C20, C21, C22, C23 and R0
\par 
\par 
\par \b\ul Modified Delft - Tyre Model Data
\par \plain\fs20 
\par \b Lateral Force Coefficients,\plain\fs20   (real)
\par Modified Delft uses 30 \plain\f0\fs20 \'91\f1 A\plain\f0\fs20 \'92\f1  coefficients to describe the variation of tyre lateral force with variation in Vertical force, slip angle and camber angle.
\par 
\par A0, A1, A2, A3, A4, A5, A6, A7, A8, A9, A10, A111, A12, A13, A14, A15, A16, A17, A18, A19, A20, A21, A22, A23, A24, A25, A26, A27, A28 and FZ0
\par \pard 
\par \b Aligning Torque Coefficients,\plain\fs20   (real)
\par Modified Delft uses 29 \plain\f0\fs20 \'91\f1 C\plain\f0\fs20 \'92\f1  coefficients to describe the variation of tyre aligning torque with variation in Vertical force, slip angle and camber angle.
\par 
\par C0, C1, C2, C3, C4, C5, C6, C7, C8, C9, C10, C11, C12, C13, C14, C15, C16, C17, C18, C19, C20, C21, C22, C23, C24, C25, C26, C27 and R0
\par 
\par \b Longitudinal Force Coefficients,\plain\fs20   (real)
\par Modified Delft uses 18 \plain\f0\fs20 \'91\f1 L\plain\f0\fs20 \'92\f1  coefficients to describe the variation of tyre longitudinal force with variation in Vertical force, slip angle and camber angle.
\par \pard 
\par L0, L1, L2, L3, L4, L5, L6, L7, L8, L9, L10, L11, L12, L13, L14, L15, L16, L17 and L18
\par 
\par 
\par \b\ul Adams Carpet/Tyre - Tyre Model Data
\par \plain\fs20 
\par \b Lateral Force,\plain\fs20   (real),  (N)
\par Listed in a data file as a fully populated 3D array of lateral force variation with vertical force, slip angle and camber angle.
\par 
\par \b Aligning Torque,\plain\fs20   (real),  (Nm)
\par Listed in a data file as a fully populated 3D array of aligning torque variation with vertical force, slip angle and camber angle.
\par \pard 
\par \page
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\pard\keepn\sb235\sa55\li715\fi-715 {\up K}
\b\fs28 Data Requirements \plain\f0\b\fs28 \'96\f1  Solution Data
\par \pard \plain\fs20 
\par 
\par The Solution data display provides access to all solution related settings. To open this dialog box select the menu item \i Data / Solution...\plain\fs20  or the equivalent icon.
\par 
\par \pard\qc \{bmc bm47.bmp\}
\par Solution Data Display Icon
\par \pard 
\par The solution data is subdivided into three solution classes; Road motion, Steering Motion and Acceleration/Braking. Additional general solution data/settings can also be edited through this display, (see pull down menus).
\par 
\par 
\par \b\ul Solution Control
\par \plain\fs20 
\par The following values are listed independent of the solution class, (for further information on solution control variables refer to the relevant ADAMS documentation).
\par 
\par \b End Time,\plain\fs20   (real),  (s)
\par Sets the end of solution time value. Solution will run till this value provided no errors occur.
\par \pard 
\par \b No. of Solution Steps,\plain\fs20   (integer)
\par Defines the number of solution time steps used over the defined run time.
\par 
\par 
\par \b\ul Road Motion
\par \plain\fs20 
\par \pard\qc \{bmc bm63.bmp\}
\par Solution Data  - Road Motion
\par \pard 
\par \b Road Motion Types,\plain\fs20   (choice)
\par Three road motion types are available; 1-Wheel Bump, 2-Wheel Bump and Sine Sweep.
\par 
\par \b Velocity,\plain\fs20   (real),  (m/s)
\par Defines the vehicle forward speed for the analysis event.
\par 
\par \b Start Time,\plain\fs20   (real),  (s)
\par Defines the point in the analysis event when the start of the bump is reached by the front axle.
\par 
\par \b Bump Height,\plain\fs20   (real),  (m)
\par Sets the maximum height of the bump above the ground plane.
\par 
\par \b Length Up,\plain\fs20   (real),  (m)
\par \pard Defines the length of the \plain\f0\fs20 \'91\f1 up-ramp\plain\f0\fs20 \'92\f1  of the bump, distance taken to reach the maximum bump height from ground plane.
\par 
\par \b Dwell Length,\plain\fs20   (real),  (m)
\par Defines the length of the bump at the maximum bump height..
\par 
\par \b Length Down,\plain\fs20   (real),  (m)
\par Defines the length of the \plain\f0\fs20 \'91\f1 down-ramp\plain\f0\fs20 \'92\f1  of the bump, distance taken to reach the ground plane from the maximum bump height.
\par 
\par \b Steer Input,\plain\fs20   (real),  (deg)
\par Defines the magnitude of the steering input of the input sine wave.
\par \pard 
\par \b Phase,\plain\fs20   (real),  (rad)
\par Defines the initial phase of the input sine wave.
\par 
\par \b Time Offset,\plain\fs20   (real),  (s)
\par Defines the time delay to the start of the sine wave steering input.
\par 
\par 
\par \b\ul Steering Motion
\par \plain\fs20 
\par \pard\qc \{bmc bm64.bmp\}
\par Solution Data  - Steering Motion
\par \pard 
\par \b Steering Motion Types,\plain\fs20   (choice)
\par Five steering motion types are available; Step Change, Ramp Up, Lane Change, Sine Sweep and Steering Pad.
\par 
\par \b Velocity,\plain\fs20   (real),  (m/s)
\par Defines the vehicle forward speed for the analysis event.
\par 
\par \b Start Time,\plain\fs20   (real),  (s)
\par Defines the point in the analysis event when the steering event starts.
\par 
\par \b Steer Input,\plain\fs20   (real),  (deg)
\par Defines the magnitude of the hand-wheel step steer input.
\par 
\par \b Duration,\plain\fs20   (real),  (deg)
\par \pard Defines the time duration of the step steer input.
\par 
\par \b Rate,\plain\fs20   (real),  (deg/s)
\par Defines the rate of change of the steering hand-wheel angle for ramp steer input.
\par 
\par \b Change Size,\plain\fs20   (real),  (deg/s)
\par For a lane change manoeuvre defines the hand-wheel angle magnitude for each of the three steering inputs.
\par 
\par \b Lock On Time,\plain\fs20   (real),  (s)
\par Sets the event time for the lock on, (first), part of the lane change manoeuvre.
\par 
\par \b Lock Off Time,\plain\fs20   (real),  (s)
\par \pard Sets the event time for the lock off, (second), part of the lane change manoeuvre.
\par 
\par \b Straighten Time,\plain\fs20   (real),  (s)
\par Sets the event time for the straighten, (third), part of the lane change manoeuvre.
\par 
\par \b Steer Input,\plain\fs20   (real),  (deg)
\par Defines the magnitude of the steering input of the input sine wave.
\par 
\par \b Phase,\plain\fs20   (real),  (rad)
\par Defines the initial phase of the input sine wave.
\par 
\par \b Time Offset,\plain\fs20   (real),  (s)
\par Defines the time delay to the start of the sine wave steering input.
\par \pard 
\par \b Corner Radius,\plain\fs20   (real),  (m)
\par Defines the radius of the steering pad.
\par 
\par \b Velocity Rate,\plain\fs20   (real),  (m/s/s)
\par Sets the rate at which the vehicle speed is increased from the initial velocity.
\par 
\par \b Gain,\plain\fs20   (real)
\par Defines the gain value for the steering feedback controller, used to retain the prescribed path.
\par 
\par \b Integral Feedback,\plain\fs20   (real)
\par Defines the Integral value for the steering feedback controller, used to retain the prescribed path.
\par 
\par \b Differential Feedback,\plain\fs20   (real)
\par \pard Defines the Differential value for the steering feedback controller, used to retain the prescribed path.
\par 
\par 
\par \b\ul Acceleration/Braking Events
\par \plain\fs20 
\par \pard\qc \{bmc bm65.bmp\}
\par Solution Data  - Acceleration and Braking Events
\par \pard 
\par \b Acceleration and Braking Event Types,\plain\fs20   (choice)
\par Two acceleration/braking event types are available; Braking \plain\f0\fs20 \'91\f1 G\plain\f0\fs20 \'92\f1  and Acceleration \plain\f0\fs20 \'91\f1 G\plain\f0\fs20 \'92\f1 .
\par 
\par \b Velocity,\plain\fs20   (real),  (m/s)
\par Defines the vehicle forward speed for the analysis event.
\par 
\par \b Start Time,\plain\fs20   (real),  (s)
\par Defines the point in the analysis event when the accel/braking event starts.
\par 
\par \b Lift Off Time,\plain\fs20   (real),  (s)
\par Defines the point in the analysis event when the accel/braking event ends.
\par \pard 
\par \b Lift Duration,\plain\fs20   (real),  (s)
\par Defines the duration of the lift for the acceleration or braking event.
\par 
\par \b G Level,\plain\fs20   (real),  (g)
\par Defines accel. or Deccel. level applied to the model.
\par 
\par \b Split Mu Factor Right,\plain\fs20   (real)
\par Defines the surface mu for the right hand wheels.
\par 
\par \b Split Mu Factor Left,\plain\fs20   (real)
\par Defines the surface mu for the left hand wheels.
\par 
\par \b Brake Split Front,\plain\fs20   (real) ,  (0-1)
\par Defines the overall vehicle brake split by definition of the amount on the front axle.
\par \pard 
\par \b Drive Split Front,\plain\fs20   (real) ,  (0-1)
\par Defines the overall vehicle drive split by definition of the amount of drive through the front axle.
\par 
\par \page
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\pard\keepn\sb235\sa55\li715\fi-715 {\up K}
\b\fs28 LOTUS ENGINEERING\plain\fs28 
\par \pard\qc \b\fs20 
\par \{bmc bm66.bmp\}
\par \{bmc bm67.bmp\}
\par \{bmc bm68.bmp\}
\par \pard 
\par \page
\pard\keepn\sb235\sa55\li715\fi-715 \fs28 
\par \page
}