# Writing Runge-Kutta ODE solver using gsl

It's been some time since I did any C/c++, but I wanted to write an ODE solver using the gsl library to solve the following ODE set

``````\$\$ u'(r)=up(r)\$\$
\$\$ up'(r)=-(2*(r-1)/(r*(r-2)))*up(r)-((r*r/((r-2)*(r-2)))-(2/r*(r-2)))*u(r) \$\$
``````

so in the gsl notation my y[0]=u, y[1]==up, and the RHS of the above defines f[0] and f[1]. From these definitions one can then compute the Jacobian and dfdr (usually their 'time' variable is called 't' not 'r'). The reason for doing this is because I am having speed issues with Mathematica. I took the gsl example code at the end of their documentation on the ODE solver, and tried to adapt it to my problem as follows:

`````` #include <stdio.h>
#include <gsl/gsl_errno.h>
#include <gsl/gsl_matrix.h>
#include <gsl/gsl_odeiv2.h>
#include <complex.h>

int
func (double r, const double y[], double f[],
void *params)
{
double mu = *(double *)params;
f[0] = y[1];
f[1] = -(2*(r-1)/(r*(r-2)))*y[1]-((r*r/((r-2)*(r-2)))-(2/r*(r-2)))*y[0];
return GSL_SUCCESS;
}

/* void tester (double r) {  double outer=-((r*r/((r-2)*(r-2)))-(2/(r*(r-2))));  printf ("%.5e \n", outer); } */

int
jac (double r, const double y[], double *dfdy,
double dfdt[], void *params)
{
double mu = *(double *)params;
gsl_matrix_view dfdy_mat
= gsl_matrix_view_array (dfdy, 2, 2);
gsl_matrix * m = &dfdy_mat.matrix;
gsl_matrix_set (m, 0, 0, 0.0);
gsl_matrix_set (m, 0, 1, 1.0);
gsl_matrix_set (m, 1, 0,-((r*r/((r-2)*(r-2)))-(2/(r*(r-2)))));
gsl_matrix_set (m, 1, 1, -(2*(r-1)/(r*(r-2))));
dfdt[0] = 0.0;
dfdt[1] =((1/(r*r))+(1/((r-2)*(r-2))))*y[1]-((4*(1-r)/(r*r*(r-2)*(r-2)))+(4*r/((r-2)*(r-2)*(r-2))))*y[0];
return GSL_SUCCESS;
}

int
main (void)
{
/* tester(5);*/
double om = 2;
gsl_odeiv2_system sys = {func, jac, 2, &om};

gsl_odeiv2_driver * d =
gsl_odeiv2_driver_alloc_y_new (&sys, gsl_odeiv2_step_rk8pd,
1e-6, 1e-6, 0.0);
int i;
double r = 10, r1 = 100;
double y[2] = { 0.0000341936, -0.0000572397 };

for (i = 1; i <= 90; i++)
{
double ri = 10 + i;
int status = gsl_odeiv2_driver_apply (d, &r, ri, y);

if (status != GSL_SUCCESS)
{
printf ("error, return value=%d\n", status);
break;
}

printf ("%.5e %.5e %.5e\n", r, y[0], y[1]);
}

gsl_odeiv2_driver_free (d);
return 0;
}
``````

This is giving numbers but they are not the same numbers as Mathematica NDSolve gives, even when I have a low WorkingPrecision and PrecisionGoal. Is there an error in what I've done?

-

Methinks you're just lacking a parenthesis around `r*(r-2)` in
``````((r*r/((r-2)*(r-2)))-(2/r*(r-2)))*y[0];
(also in `up'(r)=-(2*(r-1)/(r*(r-2)))*up(r)-((r*r/((r-2)*(r-2)))-(2/r*(r-2)))*u(r)`), you have the corresponding parentheses in `jac`.
I have to admit that I have zero knowledge of gsl. I don't know if there is a better way to do it, or whether you can get anything better than `double` precision with gsl. Sorry that I can't help you more. –  Daniel Fischer Oct 24 '12 at 19:18