# Solving a matrix differential equation with Mathematica

I need to solve this equation in Mathematica:

d/dx v(x) = A . v(x)

here v is the column vector `{v1(x),v2(x),v3(x),v4(x)}` and A is a 4 x 4 matrix. I want to solve for the functions `v1, v2, v3, v4` with any initial conditions. The range of x is from 0 to 1000.

How do I write Mathematica code for this type of differential equation using `NDSolve`?

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It might be worth asking this question here: mathematica.stackexchange.com –  Tom Chantler Jan 25 '12 at 8:10
Thank you Dommer! –  Mush Jan 25 '12 at 8:28

So, if you have some horrible matrix

``````A =  RandomReal[0.1, {4, 4}]; (* A horrible matrix *)
``````

which we make anti-symmetric (so the solution is oscillatory)

``````A = A - Transpose@A;
``````

Define the vector of functions and their initial conditions

``````v[x_] := {v1[x], v2[x], v3[x], v4[x]};

init = v[0] == RandomReal[1, 4]
``````

Then the `NDSolve` command looks like

``````sol = NDSolve[LogicalExpand[v'[x] == A.v[x] && init],
{v1, v2, v3, v4}, {x, 0, 1000}]
``````

And the solutions can be plotted with

``````Plot[Evaluate[v[x] /. sol], {x, 0, 1000}]
``````

Note that that the above differential equation is a linear, first order equation with constant coefficients, so is simply solved using a matrix exponential. However, if the matrix `A` was a function of `x`, then analytic solutions become hard, but the numerical code stays the same.

For example, try:

``````A = RandomReal[1/10, {4, 4}] - Exp[-RandomReal[1/100, {4, 4}] x^2];
A = A - Transpose@A;
``````

Which can produce solutions like

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wow! Thaaaaanks a Lot ! great job :) My Horrible matrix is a function of x. Thank god you said that the numerical code remains the same ! :P One more suggestion needed. Can you refer me a good book book for mathematica? –  Mush Jan 25 '12 at 12:37
@Mush: A solid and recent book is Mathematica In Action. But the Mathematica documentation is also really good, there's lots of hidden gems in there. Finally, there's this site - some good Mathematica programmers around here (including a few WRI employees). See the big list posted at stackoverflow.com/q/8672115/421225 –  Simon Jan 25 '12 at 13:08
@Mush: btw, if my post answered your question, don't forget to press the checkmark button to accept it. –  Simon Jan 25 '12 at 13:09
Thanks again. & pressed :) –  Mush Jan 25 '12 at 13:17
@PlatoManiac: You probably shouldn't link to illegal copies of books. Link to Sal's homepage instead, or to Amazon, since stackexchange automatically affiliates those links. –  Simon Jan 25 '12 at 13:25

I wanted to do the same with a matrix instead of a vector v. As long as equation for it can be read correctly without knowing that this symbol represents a vector or a matrix, NDSolve deduced its character from initial condition, however in case when dimensionality of variable is explicit:

``````M'[t]==a[t]*IdentityMatrix[2]+M[t]
``````

it fails. An "ordinary" solution is to define matrix explicitly and flatten it when giving as a list of variables.

However I omitted this issue (and many relatex syntax problems) just introducing a reduntant variable which only role is to be the identity matrix but without introducing a list (matrix is 2d list, so Mathematica acts as while adding lists to each other, generating the error):

``````eqn = {w'[t] == a[t]*identity[t] + w[t], a'[t] == 2, identity'[t] == {{0, 0}, {0, 0}}}
init={ w[0] == {{1, 2}, {2, 1}}, a[0] == 1, identity[0] == {{1, 0}, {0, 1}}}

sol = NDSolve[eqn&&init, {w, a, identity}, {t, 0, 1}]
``````

Some evidence of work:

``````Plot[{Evaluate[w[t] /. sol][[1, 1, 1]], Evaluate[w[t] /. sol][[1, 1, 2]]}, {t, 0, 1}]
``````
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Try something like this (I do not have Mathematica on my home notebook :))

``````NDSolve[Transpose[{v1[x],v2[x],v3[x],v4[x]}']=={{a11,a12,a13,a14},{a21,a22,a23,a24},{a31,a32,a33,a34},{a41,a42,a43,a44}}.Transpose[{v1[x],v2[x],v3[x],v4[x]}], {v1,v2,v3,v4},{x,0,1000}]
``````

ps: you can rewrite it in a different way, replacing your record as a set of equations {v1'[x]==a11*v1[x]+a12*v2[x]+a13*v3[x]+a14*v4[x],v2'[x]==a21*v1[x]+a22*v2[x]+a23*v3[x]+a24*v4[x], and so on..} if you want )

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Thanks Cherry. But my matrix A horrible. i cant put its elements a11,a22... by hand :(. After some operation i get a matrix. So i need to use that result directly. will it work well if just write A instead of elements? :-s –  Mush Jan 25 '12 at 8:50
@Mush Try it as in my first example - I will be near Mathematica only tomorrow :) And if you have A matrix, you do not need to rewrite its elements - you can access them directly, like A[[1]][[2]] will give you a12 –  Cheery Jan 25 '12 at 8:52
oh! Thanks a lot ! I'll try that :) –  Mush Jan 25 '12 at 9:13
@Cheery: In your first code block, you accidentally used `*` instead of `.`. –  Simon Jan 25 '12 at 9:48
@Simon It doesn't matter here. {{a, b}, {c, d}}.{x, y} or {{a, b}, {c, d}}*{x, y} records are the same. –  Cheery Jan 25 '12 at 9:53