Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I have all the data and an ODE system of three equations which has 9 unknown coefficients (a1, a2,..., a9).

dS/dt = a1*S+a2*D+a3*F
dD/dt = a4*S+a5*D+a6*F
dF/dt = a7*S+a8*D+a9*F

t = [1 2 3 4 5]
S = [17710 18445 20298 22369 24221]
D = [1357.33 1431.92 1448.94 1388.33 1468.95]
F = [104188 104792 112097 123492 140051]

How to find these coefficients (a1,..., a9) of an ODE using Matlab?

share|improve this question
you problalby mean dS/dt,...? – Ander Biguri May 15 '13 at 9:52
This is a simple linear system, so you can solve it analytically. You may then fit the solution to the data, although you probably need more observations to constrain your parameters! – David Zwicker May 15 '13 at 11:24
Ander, exactly. I fixed it. How to solve in Matlab, any examples? – Karolis Valiulis May 15 '13 at 11:50
Better fits – Dr_Sam May 15 '13 at 13:54
@DavidZwicker: you're saying 15 equations aren't enough to solve for 9 unknowns? :) – Rody Oldenhuis May 16 '13 at 5:15

I can't spend too much time on this, but basically you need to use math to reduce the equation to something more meaningful:

your equation is of the order

dx/dt = A*x

ergo the solution is

x(t-t0) = exp(A*(t-t0)) * x(t0)


exp(A*(t-t0)) = x(t-t0) * Pseudo(x(t0))

Pseudo is the Moore-Penrose Pseudo-Inverse.

EDIT: Had a second look at my solution, and I didn't calculate the pseudo-inverse properly.

Basically, Pseudo(x(t0)) = x(t0)'*inv(x(t0)*x(t0)'), as x(t0) * Pseudo(x(t0)) equals the identity matrix

Now what you need to do is assume each time step (1 to 2, 2 to 3, 3 to 4) is an experiment (therefore t-t0=1), so the solution would be to:

1- Build your pseudo inverse:

xt = [S;D;F];
xt0 = xt(:,1:4);

xInv = xt0'*inv(xt0*xt0');

2- Get exponential result

xt1 = xt(:,2:5);
expA =  xt1 * xInv;

3- Get the logarithm of the matrix:

A = logm(expA);

And since t-t0= 1, A is our solution.

And a simple proof to check

[t, y] = ode45(@(t,x) A*x,[1 5], xt(1:3,1));
plot (t,y,1:5, xt,'x')

enter image description here

share|improve this answer
Didn't calculate the pseudo-inverse properly... Corrected – Rasman May 15 '13 at 18:57
@RodyOldenhuis Basically you're applying the same weight to all three variables despite one being several orders of magnitude greater then the others. If you looked at relative values (sum((1-y(:)./xt(:)).^2), my solution is 4.4922e-04 vs 0.0143. In other words, while you punish F from deviating, you're a lot more lenient on D. – Rasman May 15 '13 at 20:40
I'm still a bit fuzzy on the details of your method...How would you have solved the problem when the increment in t was non-uniform? – Rody Oldenhuis May 16 '13 at 4:49
Also, when I take your solution as an initial estimate and run it through an optimizer, I can pretty easily reduce the sum of relative squared errors down to 3.86846e-004 (same for absolute errors). This means your solution is not optimal in a least-squares sense...Perhaps we can take the discussion here. – Rody Oldenhuis May 16 '13 at 5:12
@RodyOldenhuis This is a LS solution to the exponential of A. That's what Moore-Penrose provides (cf. wikipedia). While I'm not using all the data points I could to further refine the solution, the approximation error is judged to be small and relatively trivial by engineering standards and would be considered sufficient. Parameter estimation is a very ugly subject, and one should take any solution that does the job. – Rasman May 16 '13 at 18:37

You have a linear, coupled system of ordinary differential equations,

y' = Ay    with    y = [S(t);  D(t);  F(t)]

and you're trying to solve the inverse problem,

A = unknown


First line of attack

For given A, it is possible to solve such systems analytically (read the wiki for example).

The general solution for 3x3 design matrices A take the form

[S(t) D(t) T(t)].' = c1*V1*exp(r1*t) + c2*V2*exp(r2*t) + c3*V3*exp(r3*t)

with V and r the eigenvectors and eigenvalues of A, respectively, and c scalars that are usually determined by the problem's initial values.

Therefore, there would seem to be two steps to solve this problem:

  1. Find vectors c*V and scalars r that best-fit your data
  2. reconstruct A from the eigenvalues and eigenvectors.

However, going down this road is treaturous. You'd have to solve the non-linear least-squares problem for the sum-of-exponentials equation you have (using lsqcurvefit, for example). That would give you vectors c*V and scalars r. You'd then have to unravel the constants c somehow, and reconstruct the matrix A with V and r.

So, you'd have to solve for c (3 values), V (9 values), and r (3 values) to build the 3x3 matrix A (9 values) -- that seems too complicated to me.

Simpler method

There is a simpler way; use brute-force:

function test

    % find  
    [A, fval] = fminsearch(@objFcn, 10*randn(3))


function objVal = objFcn(A)

    % time span to be integrated over
    tspan = [1 2 3 4 5];

    % your desired data
    S = [17710    18445    20298    22369    24221   ];
    D = [1357.33  1431.92  1448.94  1388.33  1468.95 ];
    F = [104188   104792   112097   123492   140051  ];

    y_desired = [S; D; F].';

    % solve the ODE
    y0 =  y_desired(1,:);
    [~,y_real] = ode45(@(~,y) A*y, tspan, y0);

    % objective function value: sum of squared quotients
    objVal = sum((1 - y_real(:)./y_desired(:)).^2);


So far so good.

However, I tried both the complicated way and the brute-force approach above, but I found it very difficult to get the squared error anywhere near satisfyingly small.

The best solution I could find, after numerous attempts:

A =
    1.216731997197118e+000    2.298119167536851e-001   -2.050312097914556e-001
   -1.357306715497143e-001   -1.395572220988427e-001    2.607184719979916e-002
    5.837808840775175e+000   -2.885686207763313e+001   -6.048741083713445e-001

fval =

Which isn't bad at all :) But I would've liked a solution that was less difficult to find...

share|improve this answer
As a simple note, this is a plain example of the butterfly effect, whereas if I simply plug your A matrix into the solution, I get a very incorrect result at t=5. More sig figs are needed. – Rasman May 15 '13 at 20:42
@Rasman: Fixed. Also using relative errors now – Rody Oldenhuis May 16 '13 at 4:52
Thanks a lot @RodyOldenhuis When I run this function first time it calculates the results in a seconds, but when I try to run second time, it is running eternally and doesn't stop. I am using Matlab 7.11.0 Does it happen for you? How do you chose the best solution after numerous attempts? With lowest difference between given points? – Karolis Valiulis May 20 '13 at 13:25

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.