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path: root/src/ProjectionTangentialLSQ.cxx
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//
// Copyright 2006 Johannes Hofmann <Johannes.Hofmann@gmx.de>
//
// This software may be used and distributed according to the terms
// of the GNU General Public License, incorporated herein by reference.

#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>

#include <gsl/gsl_rng.h>
#include <gsl/gsl_randist.h>
#include <gsl/gsl_vector.h>
#include <gsl/gsl_blas.h>
#include <gsl/gsl_multifit_nlin.h>

#include "ProjectionTangentialLSQ.H"


static double sec(double a) {
	return 1.0 / cos(a);
}

static double pi_d = asin(1.0) * 2.0, deg2rad = pi_d / 180.0;

#include "lsq_funcs.c"

static double
comp_tilt(double tan_nick_view, double tan_dir_view, double n_scale,
	double tan_nick_m, double tan_dir_m,
	double x, double y, double pi_d);

int
ProjectionTangentialLSQ::comp_params(const Hills *h, ViewParams *parms) {
	const Hill *tmp, *m1, *m2;
	double a_center_tmp, scale_tmp, a_nick_tmp;

	if (h->get_num() < 2) {
		fprintf(stderr, "Please position at least 2 hills\n");
		return 1;
	} else if (h->get_num() > 3) {
		fprintf(stderr, "Performing calibration\n");
		parms->k0 = 0.0;
		parms->k1 = 0.0;
	}

	m1 = h->get(0);
	m2 = h->get(1);

	scale_tmp = comp_scale(m1->alph, m2->alph, m1->x, m2->x);
	if (isnan(scale_tmp) || scale_tmp < 100.0) {
		// try again with mountains swapped
		tmp = m1;
		m1 = m2;
		m2 = tmp;
		scale_tmp = comp_scale(m1->alph, m2->alph, m1->x, m2->x);
	}


	if (isnan(scale_tmp) || scale_tmp < 100.0) {
		return 1;
	} else {

		parms->a_center = m1->alph;
		parms->scale    = scale_tmp;
		parms->a_nick   = 0.0;
		parms->a_tilt   = 0.0;

		lsq(h, parms);

		return 0;
	}
}

double 
ProjectionTangentialLSQ::angle_dist(double a1, double a2) {
	double ret;

	a1 = fmod(a1, 2.0 * pi_d); 
	if (a1 < 0.0) {
		a1 = a1 + 2.0 * pi_d;
	}
	a2 = fmod(a2, 2.0 * pi_d); 
	if (a2 < 0.0) {
		a2 = a2 + 2.0 * pi_d;
	}

	ret = fabs(a1 - a2);
	if (ret > pi_d) {
		ret = 2.0 * pi_d - ret;
	} 

	return ret;
}

struct data {
	const Hills *h;
	const ViewParams *old_params;
};

#define CALL(A) A(c_view, c_nick, c_tilt, scale, k0, k1, m->alph, m->a_nick) 

static int
lsq_f (const gsl_vector * x, void *data, gsl_vector * f) {
	struct data *dat = (struct data *) data;
	double c_view, c_nick, c_tilt, scale, k0, k1, u0, v0;

	c_view = gsl_vector_get (x, 0);
	c_nick = gsl_vector_get (x, 1);
	c_tilt = gsl_vector_get (x, 2);
	scale = gsl_vector_get (x, 3);
	if (x->size >= 6) {
		k0  = gsl_vector_get (x, 4);
		k1 = gsl_vector_get (x, 5);
	} else {
		k0 = dat->old_params->k0;
		k1 = dat->old_params->k1;
	}

	for (int i=0; i<dat->h->get_num(); i++) {
		Hill *m = dat->h->get(i);

		double mx = CALL(mac_x);
		double my = CALL(mac_y);

		gsl_vector_set (f, i*2, mx - m->x);
		gsl_vector_set (f, i*2+1, my - m->y);
	}

	return GSL_SUCCESS;
}

 
static int
lsq_df (const gsl_vector * x, void *data, gsl_matrix * J) {
	struct data *dat = (struct data *) data;
    double c_view, c_nick, c_tilt, scale, k0, k1, u0, v0;

    c_view = gsl_vector_get (x, 0);
    c_nick = gsl_vector_get (x, 1);
    c_tilt = gsl_vector_get (x, 2);
    scale = gsl_vector_get (x, 3);
    if (x->size >= 6) {
        k0  = gsl_vector_get (x, 4);
        k1 = gsl_vector_get (x, 5);
    } else {
        k0 = dat->old_params->k0;
        k1 = dat->old_params->k1;
    }            

	for (int i=0; i<dat->h->get_num(); i++) {
		Hill *m = dat->h->get(i);

		gsl_matrix_set (J, 2*i, 0, CALL(mac_x_dc_view));
		gsl_matrix_set (J, 2*i, 1, CALL(mac_x_dc_nick));
		gsl_matrix_set (J, 2*i, 2, CALL(mac_x_dc_tilt));
		gsl_matrix_set (J, 2*i, 3, CALL(mac_x_dscale));
		if (x->size >= 6) {
			gsl_matrix_set (J, 2*i, 4, CALL(mac_x_dk0));
			gsl_matrix_set (J, 2*i, 5, CALL(mac_x_dk1));
		}

		gsl_matrix_set (J, 2*i+1, 0, CALL(mac_y_dc_view));
		gsl_matrix_set (J, 2*i+1, 1, CALL(mac_y_dc_nick));
		gsl_matrix_set (J, 2*i+1, 2, CALL(mac_y_dc_tilt));
		gsl_matrix_set (J, 2*i+1, 3, CALL(mac_y_dscale));
		if (x->size >= 6) {
			gsl_matrix_set (J, 2*i+1, 4, CALL(mac_y_dk0));
			gsl_matrix_set (J, 2*i+1, 5, CALL(mac_y_dk1));
		}
	}

	return GSL_SUCCESS;
}

static int
lsq_fdf (const gsl_vector * x, void *data, gsl_vector * f, gsl_matrix * J) {
	lsq_f (x, data, f);
	lsq_df (x, data, J);
     
	return GSL_SUCCESS;
}

int
ProjectionTangentialLSQ::lsq(const Hills *h, ViewParams *parms) {
	const gsl_multifit_fdfsolver_type *T;
	gsl_multifit_fdfsolver *s;
	gsl_multifit_function_fdf f;
	struct data dat;
	double x_init[8];
	gsl_vector_view x;
	int status;
	int num_params = h->get_num()>3?6:4;

	fprintf(stderr, "x %f, y %f\n",
		h->get(0)->x,
		h->get(0)->y);


	dat.h = h;
	dat.old_params = parms;

	x_init[0] = parms->a_center;
	x_init[1] = parms->a_nick;
	x_init[2] = parms->a_tilt;
	x_init[3] = parms->scale;
	x_init[4] = parms->k0;
	x_init[5] = parms->k1;

	x = gsl_vector_view_array (x_init, num_params);

   f.f = &lsq_f;
   f.df = &lsq_df;
   f.fdf = &lsq_fdf;
   f.n = h->get_num() * 2;
   f.p = num_params;
   f.params = &dat;

	T = gsl_multifit_fdfsolver_lmsder;
	s = gsl_multifit_fdfsolver_alloc (T, h->get_num() * 2, num_params);
	gsl_multifit_fdfsolver_set (s, &f, &x.vector);

    for (int i=0; i<100; i++) {

		status = gsl_multifit_fdfsolver_iterate (s);
		if (status) {
			fprintf(stderr, "gsl_multifit_fdfsolver_iterate: %d\n", status);
			break;
		}

		fprintf(stderr, "%d, |f(x)| = %g\n", i, gsl_blas_dnrm2 (s->f));
	} 

	parms->a_center = gsl_vector_get(s->x, 0);
	parms->a_nick = gsl_vector_get(s->x, 1);
	parms->a_tilt = gsl_vector_get(s->x, 2);
	parms->scale = gsl_vector_get(s->x, 3);

	if (num_params == 6) {
		parms->k0 = gsl_vector_get(s->x, 4);
		parms->k1 = gsl_vector_get(s->x, 5);
	}

	gsl_multifit_fdfsolver_free (s);

	fprintf(stderr, "k0 %f, k1 %f\n", parms->k0, parms->k1);

	return 0;
}

void 
ProjectionTangentialLSQ::get_coordinates(double alph, double a_nick,
	const ViewParams *parms, double *x, double *y) {

	*x = mac_x(parms->a_center, parms->a_nick, parms->a_tilt, parms->scale,
		parms->k0, parms->k1, alph, a_nick); 
	*y = mac_y(parms->a_center, parms->a_nick, parms->a_tilt, parms->scale,
		parms->k0, parms->k1, alph, a_nick); 
}

double
ProjectionTangentialLSQ::comp_center_angle(double a1, double a2, double d1, double d2) {
	double sign1 = 1.0;
	double tan_acenter, tan_a1, tan_a2, a_center;

	tan_a1 = tan(a1);
	tan_a2 = tan(a2);

	tan_acenter = (((pow(((pow((1.0 + (tan_a1 * tan_a2)), 2.0) * ((d1 * d1) + (d2 * d2))) + (2.0 * d1 * d2 * ((2.0 * ((tan_a2 * tan_a1) - (tan_a2 * tan_a2))) - ((tan_a1 * tan_a1) * (2.0 + (tan_a2 * tan_a2))) - 1.0))), (1.0 / 2.0)) * sign1) + ((1.0 - (tan_a1 * tan_a2)) * (d1 - d2))) / (2.0 * ((d2 * tan_a2) - (d1 * tan_a1))));

	a_center = atan(tan_acenter);

	if (a_center > 2.0 * pi_d) {
		a_center = a_center - 2.0 * pi_d;
	} else if (a_center < 0.0) {
		a_center = a_center + 2.0 * pi_d;
	}

	// atan(tan_dir_view) is not the only possible solution.
	// Choose the one which is close to m1->alph.
	if (fabs(a_center - a1) > pi_d/2.0) {
		a_center = a_center + pi_d;
	}

	return a_center; 
}

double
ProjectionTangentialLSQ::comp_scale(double a1, double a2, double d1, double d2) {
	double sign1 = 1.0;
	double sc, tan_a1, tan_a2;

	tan_a1 = tan(a1);
	tan_a2 = tan(a2);

	sc = ((((1.0 + (tan_a1 * tan_a2)) * (d1 - d2)) - (sign1 * pow((((1.0 + pow((tan_a1 * tan_a2), 2.0)) * ((d1 * d1) + (d2 * d2))) + (2.0 * ((tan_a1 * tan_a2 * pow((d1 + d2), 2.0)) - (d1 * d2 * (((tan_a1 * tan_a1) * (2.0 + (tan_a2 * tan_a2))) + 1.0 + (2.0 * (tan_a2 * tan_a2))))))), (1.0 / 2.0)))) / (2.0 * (tan_a1 - tan_a2)));

	return sc;
}

static double
comp_tilt(double tan_nick_view, double tan_dir_view, double n_scale,
	double tan_nick_m, double tan_dir_m,
	double x, double y, double pi_d) {
	double y_tmp, x_tmp, sin_a_tilt1, sin_a_tilt2, sin_a_tilt, res;

	y_tmp = - (((tan_nick_view - tan_nick_m) * n_scale) / 
		(tan_nick_m * tan_nick_view + 1));
	x_tmp = - (((tan_dir_view - tan_dir_m) * n_scale) / 
		(tan_dir_m * tan_dir_view + 1));


	sin_a_tilt1 = - (y * - pow(x*x + y*y - y_tmp*y_tmp, 0.5) - x * y_tmp) /
		(x*x + y*y);

	sin_a_tilt2 = - (y * pow(x*x + y*y - y_tmp*y_tmp, 0.5) - x * y_tmp) / 
		(x*x + y*y);

	sin_a_tilt = fabs(sin_a_tilt1) < fabs(sin_a_tilt2)?sin_a_tilt1:sin_a_tilt2;

	res = asin(sin_a_tilt);

	if (res > pi_d / 4.0) {
		res = res - pi_d / 2.0;
	} else if (res < -pi_d / 4.0) {
		res = res + pi_d / 2.0;
	}

	return res;
}