# Calculating ballistic trajectory with changing conditions during flight

There is a good compilation of trajectory math in wikipedia.

But I need to calculate a trajectory that has non uniform conditions. E.g. the wind speed changes above certain altitude. (Cannot be modeled easily.)

• Should I calculate projectile's velocity vector e.g. every second and then for the next second based on that (having small enough tdelta)

• Or should I try to split the trajectory into pieces - based on the parameters (e.g. wind is vwind 1 between y1 and y2 so I calculate for y<y1, y1≤y<y2 and y2≤y separately).

• Try to build and solve a symbolic equation - run time - with all the parameters modeled. (Is this completely utopistic? Traditional programmin languages aren't too good solving symbols.)

• Something completely different... ?

Are there good languages / frameworks for handling symbolic math?

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Most equations don't account for air resistance, and assume perfectly static conditions. Do it on the fly. –  Blender Mar 9 '11 at 23:11
'on the fly' - I like the pun. –  Joel Mansford Mar 9 '11 at 23:21

I'd suggest an "improved" first approach: solve the differential equations of motion numerically with e.g. the classic Runge-Kutta method.

The nice part is that with these algorithms, once you correctly set up your framework, you just have to write an "evaluate" function for the motion law (which can be almost anything - you don't need to restrict to particular forces), and everything should work fine (as far as the integration step is adequate).

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Can you think of any code I could use as example? –  jkj Mar 10 '11 at 20:27
@jkj: here is an implementation of this stuff that I did as exercise for an exam; the interesting stuff is in esercizio9/Common, in particular in Differential.hpp. The names in code (classes, methods, ...) are written in English, but the comments are in Italian. –  Matteo Italia Mar 11 '11 at 0:38
thanks –  jkj Mar 11 '11 at 9:33
@jkj: you're welcome. Keep in mind that it was written to allow more solution methods, but you can have some gains in performance by removing this modularity and just fixing the Runge-Kutta method (you avoid one virtual dispatch per simulation step). –  Matteo Italia Mar 11 '11 at 15:01