Fourth-order Runge–Kutta method(RK4) implementation in Matlab

I'm trying to solve:

``````x' = 60*x - 0.2*x*y;
y' = 0.01*x*y - 100* y;
``````

using the fourth-order Runge-Kutta algorithm.

Starting points: `x(0) = 8000, y(0) = 300` range: `[0,15]`

Here's the complete function:

``````function [xx yy time r] = rk4_m(x,y,step)
A = 0;
B = 15;

h = step;
iteration=0;
t = tic;

xh2 = x;
yh2 = y;

rr = zeros(floor(15/step)-1,1);
xx = zeros(floor(15/step)-1,1);
yy = zeros(floor(15/step)-1,1);
AA = zeros(1, floor(15/step)-1);

while( A < B)

A = A+h;
iteration = iteration + 1;

xx(iteration) = x;
yy(iteration) = y;
AA(iteration) = A;
[x y] = rkstep(x,y,h);

for h2=0:1
[xh2 yh2] = rkstep(xh2,yh2,h/2);
end
r(iteration)=abs(y-yh2);

end
time = toc(t);

xlabel('Range');
ylabel('Value');
hold on
plot(AA,xx,'b');
plot(AA,yy,'g');
plot(AA,r,'r');
fprintf('Solution:\n');
fprintf('x: %f\n', x);
fprintf('y: %f\n', y);
fprintf('A: %f\n', A);
fprintf('Time: %f\n', time);

end

function [xnext, ynext] = rkstep(xcur, ycur, h)
kx1 = f_prim_x(xcur,ycur);
ky1 = f_prim_y(xcur,ycur);

kx2 = f_prim_x(xcur+0.5*h,ycur+0.5*h*kx1);
kx3 = f_prim_x(xcur+0.5*h,ycur+0.5*h*kx2);
kx4 = f_prim_x(xcur+h,ycur+h*kx3);

ky2 = f_prim_y(xcur+0.5*h*ky1,ycur+0.5*h);
ky3 = f_prim_y(xcur+0.5*h*ky2,ycur+0.5*h);
ky4 = f_prim_y(xcur+h*ky2,ycur+h);

xnext = xcur + (1/6)*h*(kx1 + 2*kx2 + 2*kx3 + kx4);
ynext = ycur + (1/6)*h*(ky1 + 2*ky2 + 2*ky3 + ky4);
end

function [fx] = f_prim_x(x,y)
fx = 60*x - 0.2*x*y;
end

function [fy] = f_prim_y(x,y)
fy = 0.01*x*y - 100*y;
end
``````

And I'm running it by executing: `[xx yy time] = rk4_m(8000,300,10)`

The problem is that everything collapses after 2-3 iterations returning useless results. What am I doing wrong? Or is just this method not appropriate for this kind equation?

The semicolons are intentionally omitted.

Looks like I didn't pay attention to actual `h` size. It works now! Thanks!

-

Looks like some form of the Lotka-Volterra equation?

I'm not sure if if your initial condition is `[300;8000]` or `[8000;300]` (you specify it both ways above), but regardless, you have an oscillatory system that you're trying to integrate with a large fixed time step that is (much) greater than the period of oscillation. This is why your error explodes. If you try increasing `n` (say, `1e6`), you'll find that eventually you'll get a stable solution (assuming that your Runge-Kutta implementation is otherwise correct).

Is there a reason why you're not using Matlab's builtin ODE solvers, e.g. `ode45` or `ode15s`?

``````function ode45demo

[t,y]=odeode45(@f,[0 15],[300;8000]);

figure;
plot(t,y);

function ydot=f(t,y)
ydot(1,1) = 60*y(1) - 0.2*y(1)*y(2);
ydot(2,1) = 0.01*y(1)*y(2) - 100*y(2);
``````

You'll find that adaptive step size solvers are much more efficient for these types of oscillatory problems. Because your system has such a high frequency and seems rather stiff, I suggest that you also look at what `ode15s` gives and/or adjust the `'AbsTol'` and `'RelTol'` options with `odeset`.

-
the reason is that I'm interested in learning something and I do not really need the solution ;) I will play with it and try to make it work –  pivovarit May 28 '13 at 3:31
My initial conditions are `[8000,300]` there was a typo in the question –  pivovarit May 28 '13 at 3:51