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Help with Powell's method using GSL

Hi All,

I am struggling to implement Powell's method for structure determination of a model using the GNU Scientific Library.

I have the following function elsewhere in the code with #include "search.h":

double eval_func(const gsl_vector *x);  /* where vector x contains the structural parameters for the model */

I am then trying to find the best set of model parameters using Powell's method, where my code currently looks like this:

#include <math.h>
#include <stdio.h>
#include <gsl/gsl_vector.h>
#include <gsl/gsl_matrix.h>
#include <gsl/gsl_multiroots.h>

#include "search.h"

#ifndef MAX_ITER_POWELL      
#define MAX_ITER_POWELL 200

int powell (const gsl_vector *x, void *params, gsl_vector *f)
   /*!TODO: this is where the code needs to evaluate the current set 
            of parameters... PLEASE HELP! */

   return GSL_SUCCESS;

int sr_powell_gsl(gsl_vector *x, gsl_matrix *M, double epsilon, 
                  size_t *iter, double *fret)
 Find minimum by using Powell's method (GSL methodology)


  gsl_vector *x - (input, output) initial starting point p[0..n-1]. After 
            completion, p returns the coordinates of the minimum.

  gsl_matrix *M - (input, output) matrix [0..n-1][0..n-1] whose columns contain 
            the initial set of directions (usually the n unit vectors).
            After completion, xi returns the then-current direction set.

  double epsilon - (input) convergence criterion the absolute tolerance in the
            function value such that failure to decrease by more than 
            this amount on one iteration signals completion.

  int *iter - (output) number of iterations.

  double *fret - (output) minimum function value found in the search.


  - relative convergence criterion has been replaced by absolute value.




 status - GSL code for solver.

    double x_root;

    int status = GSL_CONTINUE;
    size_t n = x->size;

    *fret = eval_funct(x);

    const gsl_multiroot_fsolver_type *T = gsl_multiroot_fsolver_hybrid;
    gsl_multiroot_fsolver *solver = gsl_multiroot_fsolver_alloc(T, n);
    gsl_multiroot_function F;

    /* setup solver */
    F.f = &powell;
    F.params = (void *) NULL;
    F.n = n;

    gsl_multiroot_fsolver_set(solver, &F, x);    

    /* iterate solver to find solution */
    for (*iter = 0; *iter < MAX_ITER_POWELL && 
                    status == GSL_CONTINUE; *iter += 1) 
        /* Iterate one step of the solver */
        status = gsl_multiroot_fsolver_iterate(solver);

        /* Get the new approximate solution */
        x_root = gsl_multiroot_fsolver_root(solver);

        /* evaluate current parameter set - also need help on... */
        *fret = eval_func(fgsl_multiroot_fsolver_f(solver)); 
        fprintf(stdout, "(sr_powell_gsl): ITERATION NO: %d, FRET = %f\n", 
                *iter, *fret);

        /* Check to see if the solution is within epsilon */
        status = gsl_multiroot_test_residual(solver->f, (double) epsilon);


    /* Free the solver */

    if (status == GSL_CONTINUE) {
        fprintf(stderr, "***error (sr_powell_gsl): too many iterations\n");
    } else if (status != GSL_SUCCESS) {
        fprintf(stderr, "***error (sr_powell_gsl): %s\n", 

    return status;
} /* end of function sr_powell_gsl */


Any help on how to implement the powell() function and how to then use this with the eval_func() would be most appreciated!

Thanks in advance!!

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