# GSL solving ODE for a pendulum movement

I'm trying to solve a differential equation for a pendulum movement, given the pendulum initial angle (x), gravity acceleration (g), line length (l), and a time step (h). I've tried this one using Euler method and everything's alright. But now i am to use Runge-Kutta method implemented in GSL. I've tried to implement it learning from the gsl manual, but I'm stuck at one problem. The pendulum doesn't want to stop. Let's say that I start it with initial angle 1 rad, it always has it's peak tilt at 1 rad, no matter how many swings it already did. Here's the equation and the function i use to give it to GSL:

``````x''(t) + g/l*sin(x(t)) = 0
``````

transforming it:

``````x''(t) = -g/l*sin(x(t))
``````

and decomposing:

``````y(t) = x'(t)
y'(t) = -g/l*sin(x(t))
``````

Here's the code snippet, if that's not enough i can post the whole program (it's not too long), but maybe here's the problem somewhere:

``````    int func (double t, const double x[], double dxdt[], void *params){
double l = *(double*) params;
double g = *(double*) (params+sizeof(double));
dxdt[0] = x[1];
dxdt[1] = -g/l*sin(x[0]);
return GSL_SUCCESS;
}
``````

The parameters `g` and `l` are passed correctly to the function, I've already checked that.

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In the absence of friction, this is exactly what you should expect. –  Barton Chittenden Apr 25 '12 at 20:27
Hmm, haven't thought about it this way, but you're probably right. Why the other way of solving it (with Euler method) causes it to stop finally then? Maybe I've made a mistake somewhere, but yes, you're perfectly right i think. It seems like the other program is bugged, not this one. I'm so silly... If I did this program first and then the other one, maybe I wouldn't be influenced by the eventual stop of the pendulum and think it over before writing here. Thank you! –  Wojtek Apr 25 '12 at 20:36
Great question. Although the premise was incorrect, I learned a lot from it! Thanks! –  gns-ank Jul 14 '12 at 19:56