velocityModelSpace: Difference between revisions
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Lou Montana (talk | contribs) |
Lou Montana (talk | contribs) m (Text replacement - "<code>([^ ]*)\[\[([a-zA-Z][a-zA-Z0-9_]+)\]\]([^ ]*) ([^ ]*) ([^ ]*)<\/code>" to "<code>$1$2$3 $4 $5</code>") |
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|r1= [[Array]] | |r1= [[Array]] | ||
|x1= <code> | |x1= <code>velocityModelSpace _chopper; | ||
[[comment]] "Returns [X (left(-) right(+)), Y (backward(-) forward(+)), Z (down(-) up(+))]"; | [[comment]] "Returns [X (left(-) right(+)), Y (backward(-) forward(+)), Z (down(-) up(+))]"; | ||
</code> | </code> |
Revision as of 11:43, 12 May 2022
Description
- Description:
- Returns the velocity (speed vector) of the vehicle as an array with format [x, y, z]. Vector is in model space.
- Groups:
- Object Manipulation
Syntax
- Syntax:
- velocityModelSpace vehicle
- Parameters:
- vehicle: Object
- Return Value:
- Array
Examples
- Example 1:
velocityModelSpace _chopper; comment "Returns [X (left(-) right(+)), Y (backward(-) forward(+)), Z (down(-) up(+))]";
Additional Information
Notes
-
Report bugs on the Feedback Tracker and/or discuss them on the Arma Discord or on the Forums.
Only post proven facts here! Add Note
- Posted on December 11, 2014 - 02:55 (UTC)
- Pierre MGI
- This function is useful for helicopters as it returns Z vector like an indicator of thrust/load ratio. More or less climb (+) or descent (-) tendency but: As X,Y,Z vectors are relative to vehicle attitude, this function doesn't return a climb or descend rate (as the attitude of the vehicle can be far from horizontal). You can get negative Z vector, in jets, while climbing fast, peeling off in the sky! More or less, you can use as a Z accelerometer factor but invert the sign: +G acceleration (negative vector below the jet) is -Z here. If not "physically" correct, the behavior is sufficient enough for Arma flight model.
- Posted on June 21, 2015 - 02:36 (UTC)
- K.J.
- Previous note is physically incorrect. Velocity can not be used to give information about Thrust/Load ratio or G-Forces/acceleration. To get acceleration you have to create the derivative of velocity after time dv/dt -> the difference of velocity between 2 timesteps divided by the time that passed between the 2 steps.