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I have a stiff system of coupled ODEs that I am feeding MATLAB's ode15s solver. It works well, but now I'm trying to optimize the speed of integration. I am modeling 5 different variables on N different spatial sites, giving 5N coupled equations. For the moment, N=20 and integration time is about 25s, but I would like to go to larger values of N.

I used the profiler to see that the vast majority of the time is spent evaluating myODEfun. I did my best to optimize the code, but that doesn't change the fact that there is quite a bit going on in the function and that it is being evaluated ~50,000 times. I read that using the 'Vectorized' property for the ODEfunction can reduce the number of evaluations needed.

But I don't quite understand what exactly it is that I need to change about my ODEfun to make it conform to what Matlab wants a 'vectorized' ODEfun to look like.

From the documentation I see that you can change the example Van der Pol system from its normal form:

function dydt = vdp1000(t,y)
dydt = [y(2); 1000*(1-y(1)^2)*y(2)-y(1)];

to the vectorized form:

function dydt = vdp1000(t,y)
dydt = [y(2,:); 1000*(1-y(1,:).^2).*y(2,:)-y(1,:)];

I don't understand exactly what this new matrix of y is supposed to represent, and how the size of the second dimension is even defined. I could almost live with just adding ",:" and not thinking about it, but I am running into problems because I am already doing some vector operations in my code.

Here is a simplified example of my current functions, not yet vectorized. It models 2 variables, making 2*N equations. Please don't try to make sense of the ODEs that are generated here: they don't. I am talking about the operations that are happening.

function dydt = exampleODEfun(t,y,N)

dydt = zeros(2*N,1);
dTdt = zeros(N,1);
dXdt = zeros(N,1);

T = y(1:N);
X = y(N+1:2*N);

a = [T(2:N).^2 T(2:N) ones(N-1,1)];
b = [3 5 -2];

dTdt(1:N) = 0;
dXdt(1) = 0;
dXdt(2:N) = a*b';

dydt(1:N) = dTdt;
dydt(N+1:2*N) = dXdt;


Obviously in the real function a lot more is going on, both for T and X. As you can see, dXdt(1) is a boundary condition and needs its own calculations.

Blindly passing odeset 'Vectorized','on' and just adding ",:" to all the indexes does not work. For example, what size do I need to initialize dTdt and dXdt to now? What do I do to the ones(N-1,1)? And what do I need to do to make (a*b') still make sense?

I am using Matlab R2006a.

share|improve this question
R2006a, wow....that takes me back :p –  Rody Oldenhuis Sep 6 '13 at 12:15

1 Answer 1

up vote 0 down vote accepted

From help odeset:

Vectorized - Vectorized ODE function [ on | {off} ]

Set this property 'on' if the ODE function F is coded so that 
F(t,[y1 y2 ...]) returns [F(t,y1) F(t,y2) ...].

For the van der Pol example:

without vectorization:

function dydt = vdp1000(t,y)             %// 'y' is passed as [y1 
                                         %//                   y2]

    dydt = [y(2);                        %// 'dydt' is computed as [y1´
            1000*(1-y(1)^2)*y(2)-y(1)]   %//                        y2´]
                                         %// where the ´ indicates d/dt

with vectorization:

function dydt = vdp1000(t,y)            %// 'y' is passed as [y11 y21 y31 ...
                                        %//                   y12 y22 y32 ...] 

    dydt = [y(2,:);                             %// 'dydt' is computed as 
            1000*(1-y(1,:).^2).*y(2,:)-y(1,:)]; %//   [y11´ y21´ y31´ ...
                                                %//    y12´ y22´ y32´ ...]

where the y1, y2, y3, etc. refer to different vectors y at the same time t that ode15s will use to compute the next step.

For your example, you have to take into account that the y you get passed is no longer a vector, but a matrix in which every column represents a different vector you need to compute the derivative of:

function dydt = exampleODEfun(t,y,N)

    %// Adjust sizes to meet size of y
    dydt = zeros(2*N, size(y,2));
    dTdt = zeros(N, size(y,2));
    dXdt = zeros(N, size(y,2));

    %// Adjust indices to extract proper vales of ALL vectors
    T = y(1:N,:);
    X = y(N+1:2*N,:);

    %// This sort of section is usually where all the "thought" goes into:
    %// you can't use a*b' anymore, so I sum over the third dimension of the 
    % 3D array I built from your original vector
    b  = [3 5 -2];
    ab = sum(cat(3, b(1)*T(2:N,:).^2, b(2)*T(2:N,:), b(3)*ones(N-1, size(y,2))), 3);

    %// and finish it off
    dTdt(1:N,:) = 0;
    dXdt(1,:) = 0;
    dXdt(2:N,:) = ab;

    dydt(1:N,:) = dTdt;
    dydt(N+1:2*N,:) = dXdt;

share|improve this answer
Thanks, the key insight I was missing is that the matrix is composed of different vectors for y at the same t. But that doesn't explain why there are different solutions fed through the ODEfun for the same time. Surely in the end there is only one solution for every t. My guess would be that the solver computes multiple possible solutions for y and the process of deciding which one to use somehow requires execution of the ODEfun? –  Piet de Bakker Sep 6 '13 at 12:41
@PietdeBakker: ode15s uses the Jacobian (df/dy) to compute steps. If you can't compute or otherwise do not have explicit values for the Jacobian, ode15s will estimate the Jacobian through finite differences. This process involves evaluating f(t,y) for many y at the same t. –  Rody Oldenhuis Sep 6 '13 at 12:50
@PietdeBakker: In other words: another way to speed up your problem is by deriving and implementing the problem's Jacobian. See help odeset for more information. –  Rody Oldenhuis Sep 6 '13 at 12:50
Thanks for the tip. The basic step of suppling the solver with a JPattern for the problem has cut the computation time spent in my function by 80%. And that is without vectorizing. –  Piet de Bakker Sep 6 '13 at 14:28
@PietdeBakker: wow...well, glad to help :) –  Rody Oldenhuis Sep 6 '13 at 15:32

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