Second Order Differential Equations

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Leila
Leila le 11 Juil 2014
Commenté : Torsten le 20 Fév 2015
I have seen all of the documentation of converting second order diffeq's to first order, but what if your equations are coupled...for instance:
y''[t] = 3x''[t] -4y[t];
x''[t] = 2y''[t] + 6x[t];

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Brian B
Brian B le 11 Juil 2014
Modifié(e) : Brian B le 11 Juil 2014
You can rewrite that system with a constant mass matrix M. That is, the system above is equivalent to
M * d/dt[x1; x2; x3; x4] = [x2; x4; -4 x3; 6 x1]
where
M = [1 0 0 0; 0 0 1 0; 0 -3 0 1; 0 1 0 -2].
Use odeset to specify the mass matrix.
  2 commentaires
Helge
Helge le 20 Fév 2015
Modifié(e) : Helge le 20 Fév 2015
Hi Community,
isn't it possible to rewrite the above differential equations, so they aren't coupled anymore in terms of the second derivative? I would do it as follows:
  1. Insert the 2nd eqn into the first, which gives: y''[t] = 3*(2y''[t] + 6x[t]) - 4y[t] and solve this for y''[t]:: y''[t] = -18/5 * x[t] + 4/5 y[t]
  2. Re-Insert this in the 2nd eqn from "Leila" above, which gives x''[t] = 2(-18/5 * x[t] + 4/5 * y[t]) + 6 * x[t] and solve for x''[t]:: x''[t] = 8/5 * y[t] - 6/5 * x[t]
  3. Now these two equations can be brought to State Space Representation and solved with ode45()
I tried to solve my problem this way and now I am unsure if that is even possible or do I have two use the mass matrix M in any case?
Best wishes, Helge
Torsten
Torsten le 20 Fév 2015
Everything is all right with your way of solving the above system.
Best wishes
Torsten.

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