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/*
* cell.c
*
* Unit Cell Calculations
*
* (c) 2006-2010 Thomas White <taw@physics.org>
*
* Part of CrystFEL - crystallography with a FEL
*
*/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include <math.h>
#include <stdlib.h>
#include <stdio.h>
#include <gsl/gsl_matrix.h>
#include <gsl/gsl_blas.h>
#include <gsl/gsl_linalg.h>
#include "cell.h"
#include "utils.h"
#include "image.h"
/* Update the cartesian representation from the crystallographic one */
static void cell_update_cartesian(UnitCell *cell)
{
double tmp, V, cosalphastar, cstar;
if ( !cell ) return;
/* a in terms of x, y and z
* +a (cryst) is defined to lie along +x (cart) */
cell->ax = cell->a;
cell->ay = 0.0;
cell->az = 0.0;
/* b in terms of x, y and z
* b (cryst) is defined to lie in the xy (cart) plane */
cell->bx = cell->b*cos(cell->gamma);
cell->by = cell->b*sin(cell->gamma);
cell->bz = 0.0;
tmp = cos(cell->alpha)*cos(cell->alpha)
- cos(cell->beta)*cos(cell->beta)
- cos(cell->gamma)*cos(cell->gamma)
+ 2.0*cos(cell->alpha)*cos(cell->beta)*cos(cell->gamma);
V = cell->a * cell->b * cell->c * sqrt(1.0 - tmp);
cosalphastar = cos(cell->beta)*cos(cell->gamma) - cos(cell->alpha);
cosalphastar /= sin(cell->beta)*sin(cell->gamma);
cstar = (cell->a * cell->b * sin(cell->gamma))/V;
/* c in terms of x, y and z */
cell->cx = cell->c*cos(cell->beta);
cell->cy = -cell->c*sin(cell->beta)*cosalphastar;
cell->cz = 1.0/cstar;
}
/* Update the crystallographic representation from the cartesian one */
static void cell_update_crystallographic(UnitCell *cell)
{
if ( !cell ) return;
cell->a = modulus(cell->ax, cell->ay, cell->az);
cell->b = modulus(cell->bx, cell->by, cell->bz);
cell->c = modulus(cell->cx, cell->cy, cell->cz);
cell->alpha = angle_between(cell->bx, cell->by, cell->bz,
cell->cx, cell->cy, cell->cz);
cell->beta = angle_between(cell->ax, cell->ay, cell->az,
cell->cx, cell->cy, cell->cz);
cell->gamma = angle_between(cell->ax, cell->ay, cell->az,
cell->bx, cell->by, cell->bz);
}
UnitCell *cell_new()
{
UnitCell *cell;
cell = malloc(sizeof(UnitCell));
if ( !cell ) return NULL;
cell->a = 1.0;
cell->b = 1.0;
cell->c = 1.0;
cell->alpha = M_PI_2;
cell->beta = M_PI_2;
cell->gamma = M_PI_2;
cell_update_cartesian(cell);
return cell;
}
void cell_set_parameters(UnitCell *cell, double a, double b, double c,
double alpha, double beta, double gamma)
{
if ( !cell ) return;
cell->a = a;
cell->b = b;
cell->c = c;
cell->alpha = alpha;
cell->beta = beta;
cell->gamma = gamma;
cell_update_cartesian(cell);
}
void cell_get_parameters(UnitCell *cell, double *a, double *b, double *c,
double *alpha, double *beta, double *gamma)
{
if ( !cell ) return;
*a = cell->a;
*b = cell->b;
*c = cell->c;
*alpha = cell->alpha;
*beta = cell->beta;
*gamma = cell->gamma;
cell_update_cartesian(cell);
}
void cell_set_cartesian(UnitCell *cell,
double ax, double ay, double az,
double bx, double by, double bz,
double cx, double cy, double cz)
{
if ( !cell ) return;
cell->ax = ax; cell->ay = ay; cell->az = az;
cell->bx = bx; cell->by = by; cell->bz = bz;
cell->cx = cx; cell->cy = cy; cell->cz = cz;
cell_update_crystallographic(cell);
}
void cell_set_cartesian_a(UnitCell *cell, double ax, double ay, double az)
{
if ( !cell ) return;
cell->ax = ax; cell->ay = ay; cell->az = az;
cell_update_crystallographic(cell);
}
void cell_set_cartesian_b(UnitCell *cell, double bx, double by, double bz)
{
if ( !cell ) return;
cell->bx = bx; cell->by = by; cell->bz = bz;
cell_update_crystallographic(cell);
}
void cell_set_cartesian_c(UnitCell *cell, double cx, double cy, double cz)
{
if ( !cell ) return;
cell->cx = cx; cell->cy = cy; cell->cz = cz;
cell_update_crystallographic(cell);
}
UnitCell *cell_new_from_parameters(double a, double b, double c,
double alpha, double beta, double gamma)
{
UnitCell *cell;
cell = cell_new();
if ( !cell ) return NULL;
cell_set_parameters(cell, a, b, c, alpha, beta, gamma);
return cell;
}
static UnitCell *cell_new_from_axes(struct rvec as, struct rvec bs,
struct rvec cs)
{
UnitCell *cell;
int s;
gsl_matrix *m;
gsl_matrix *inv;
gsl_permutation *perm;
double lengths[3];
double angles[3];
cell = cell_new();
if ( !cell ) return NULL;
lengths[0] = modulus(as.u, as.v, as.w);
lengths[1] = modulus(bs.u, bs.v, bs.w);
lengths[2] = modulus(cs.u, cs.v, cs.w);
angles[0] = angle_between(bs.u, bs.v, bs.w, cs.u, cs.v, cs.w);
angles[1] = angle_between(as.u, as.v, as.w, cs.u, cs.v, cs.w);
angles[2] = angle_between(as.u, as.v, as.w, bs.u, bs.v, bs.w);
STATUS("as = %9.3e %9.3e %9.3e m^-1\n", as.u, as.v, as.w);
STATUS("bs = %9.3e %9.3e %9.3e m^-1\n", bs.u, bs.v, bs.w);
STATUS("cs = %9.3e %9.3e %9.3e m^-1\n", cs.u, cs.v, cs.w);
STATUS("Creating with %9.3e %9.3e %9.3e m^-1\n", lengths[0],
lengths[1],
lengths[2]);
STATUS("Creating with %5.2f %5.2f %5.2f deg\n", rad2deg(angles[0]),
rad2deg(angles[1]),
rad2deg(angles[2]));
m = gsl_matrix_alloc(3, 3);
gsl_matrix_set(m, 0, 0, as.u);
gsl_matrix_set(m, 0, 1, as.v);
gsl_matrix_set(m, 0, 2, as.w);
gsl_matrix_set(m, 1, 0, bs.u);
gsl_matrix_set(m, 1, 1, bs.v);
gsl_matrix_set(m, 1, 2, bs.w);
gsl_matrix_set(m, 2, 0, cs.u);
gsl_matrix_set(m, 2, 1, cs.v);
gsl_matrix_set(m, 2, 2, cs.w);
/* Invert */
perm = gsl_permutation_alloc(m->size1);
inv = gsl_matrix_alloc(m->size1, m->size2);
gsl_linalg_LU_decomp(m, perm, &s);
gsl_linalg_LU_invert(m, perm, inv);
gsl_permutation_free(perm);
gsl_matrix_free(m);
/* Transpose */
gsl_matrix_transpose(inv);
cell->ax = gsl_matrix_get(inv, 0, 0);
cell->ay = gsl_matrix_get(inv, 0, 1);
cell->az = gsl_matrix_get(inv, 0, 2);
cell->bx = gsl_matrix_get(inv, 1, 0);
cell->by = gsl_matrix_get(inv, 1, 1);
cell->bz = gsl_matrix_get(inv, 1, 2);
cell->cx = gsl_matrix_get(inv, 2, 0);
cell->cy = gsl_matrix_get(inv, 2, 1);
cell->cz = gsl_matrix_get(inv, 2, 2);
cell_update_crystallographic(cell);
return cell;
}
void cell_get_cartesian(UnitCell *cell,
double *ax, double *ay, double *az,
double *bx, double *by, double *bz,
double *cx, double *cy, double *cz)
{
if ( !cell ) return;
*ax = cell->ax; *ay = cell->ay; *az = cell->az;
*bx = cell->bx; *by = cell->by; *bz = cell->bz;
*cx = cell->cx; *cy = cell->cy; *cz = cell->cz;
}
void cell_get_reciprocal(UnitCell *cell,
double *asx, double *asy, double *asz,
double *bsx, double *bsy, double *bsz,
double *csx, double *csy, double *csz)
{
int s;
gsl_matrix *m;
gsl_matrix *inv;
gsl_permutation *perm;
m = gsl_matrix_alloc(3, 3);
gsl_matrix_set(m, 0, 0, cell->ax);
gsl_matrix_set(m, 0, 1, cell->bx);
gsl_matrix_set(m, 0, 2, cell->cx);
gsl_matrix_set(m, 1, 0, cell->ay);
gsl_matrix_set(m, 1, 1, cell->by);
gsl_matrix_set(m, 1, 2, cell->cy);
gsl_matrix_set(m, 2, 0, cell->az);
gsl_matrix_set(m, 2, 1, cell->bz);
gsl_matrix_set(m, 2, 2, cell->cz);
/* Invert */
perm = gsl_permutation_alloc(m->size1);
inv = gsl_matrix_alloc(m->size1, m->size2);
gsl_linalg_LU_decomp(m, perm, &s);
gsl_linalg_LU_invert(m, perm, inv);
gsl_permutation_free(perm);
gsl_matrix_free(m);
/* Transpose */
gsl_matrix_transpose(inv);
*asx = gsl_matrix_get(inv, 0, 0);
*bsx = gsl_matrix_get(inv, 0, 1);
*csx = gsl_matrix_get(inv, 0, 2);
*asy = gsl_matrix_get(inv, 1, 0);
*bsy = gsl_matrix_get(inv, 1, 1);
*csy = gsl_matrix_get(inv, 1, 2);
*asz = gsl_matrix_get(inv, 2, 0);
*bsz = gsl_matrix_get(inv, 2, 1);
*csz = gsl_matrix_get(inv, 2, 2);
}
void cell_print(UnitCell *cell)
{
double asx, asy, asz;
double bsx, bsy, bsz;
double csx, csy, csz;
double angles[3];
STATUS(" a b c alpha beta gamma\n");
STATUS("%5.2f %5.2f %5.2f nm %6.2f %6.2f %6.2f deg\n",
cell->a*1e9, cell->b*1e9, cell->c*1e9,
rad2deg(cell->alpha), rad2deg(cell->beta), rad2deg(cell->gamma));
cell_get_reciprocal(cell, &asx, &asy, &asz,
&bsx, &bsy, &bsz,
&csx, &csy, &csz);
STATUS("a = %10.3e %10.3e %10.3e m\n", cell->ax, cell->ay, cell->az);
STATUS("b = %10.3e %10.3e %10.3e m\n", cell->bx, cell->by, cell->bz);
STATUS("c = %10.3e %10.3e %10.3e m\n", cell->cx, cell->cy, cell->cz);
STATUS("astar = %10.3e %10.3e %10.3e m^-1 (modulus = %10.3e m^-1)\n",
asx, asy, asz, modulus(asx, asy, asz));
STATUS("bstar = %10.3e %10.3e %10.3e m^-1 (modulus = %10.3e m^-1)\n",
bsx, bsy, bsz, modulus(bsx, bsy, bsz));
STATUS("cstar = %10.3e %10.3e %10.3e m^-1 (modulus = %10.3e m^-1)\n",
csx, csy, csz, modulus(csx, csy, csz));
angles[0] = angle_between(bsx, bsy, bsz, csx, csy, csz);
angles[1] = angle_between(asx, asy, asz, csx, csy, csz);
angles[2] = angle_between(asx, asy, asz, bsx, bsy, bsz);
// STATUS("Checking %5.2f %5.2f %5.2f deg\n", rad2deg(angles[0]),
// rad2deg(angles[1]),
// rad2deg(angles[2]));
}
#define MAX_CAND (1024)
static int within_tolerance(double a, double b, double percent)
{
double tol = a * (percent/100.0);
if ( fabs(b-a) < tol ) return 1;
return 0;
}
struct cvec {
struct rvec vec;
float na;
float nb;
float nc;
};
static int same_vector(struct cvec a, struct cvec b)
{
if ( a.na != b.na ) return 0;
if ( a.nb != b.nb ) return 0;
if ( a.nc != b.nc ) return 0;
return 1;
}
/* Attempt to make 'cell' fit into 'template' somehow */
UnitCell *match_cell(UnitCell *cell, UnitCell *template)
{
signed int n1l, n2l, n3l;
double asx, asy, asz;
double bsx, bsy, bsz;
double csx, csy, csz;
int i, j;
double lengths[3];
double angles[3];
struct cvec *cand[3];
int ncand[3] = {0,0,0};
float ltl = 5.0; /* percent */
float angtol = deg2rad(5.0);
UnitCell *new_cell = NULL;
STATUS("Matching with this model cell: ----------------------------\n");
cell_print(template);
STATUS("-----------------------------------------------------------\n");
cell_get_reciprocal(template, &asx, &asy, &asz,
&bsx, &bsy, &bsz,
&csx, &csy, &csz);
lengths[0] = modulus(asx, asy, asz);
lengths[1] = modulus(bsx, bsy, bsz);
lengths[2] = modulus(csx, csy, csz);
angles[0] = angle_between(bsx, bsy, bsz, csx, csy, csz);
angles[1] = angle_between(asx, asy, asz, csx, csy, csz);
angles[2] = angle_between(asx, asy, asz, bsx, bsy, bsz);
STATUS("Looking for %f %f %f\n", rad2deg(angles[0]), rad2deg(angles[1]),
rad2deg(angles[2]));
cand[0] = malloc(MAX_CAND*sizeof(struct cvec));
cand[1] = malloc(MAX_CAND*sizeof(struct cvec));
cand[2] = malloc(MAX_CAND*sizeof(struct cvec));
cell_get_reciprocal(cell, &asx, &asy, &asz,
&bsx, &bsy, &bsz,
&csx, &csy, &csz);
/* Negative values mean 1/n, positive means n, zero means zero */
for ( n1l=-2; n1l<=4; n1l++ ) {
for ( n2l=-2; n2l<=4; n2l++ ) {
for ( n3l=-2; n3l<=4; n3l++ ) {
float n1, n2, n3;
signed int b1, b2, b3;
n1 = (n1l>=0) ? (n1l) : (1.0/n1l);
n2 = (n2l>=0) ? (n2l) : (1.0/n2l);
n3 = (n3l>=0) ? (n3l) : (1.0/n3l);
/* 'bit' values can be +1 or -1 */
for ( b1=-1; b1<=1; b1+=2 ) {
for ( b2=-1; b2<=1; b2+=2 ) {
for ( b3=-1; b3<=1; b3+=2 ) {
double tx, ty, tz;
double tlen;
int i;
n1 *= b1; n2 *= b2; n3 *= b3;
tx = n1*asx + n2*asy + n3*asz;
ty = n1*bsx + n2*bsy + n3*bsz;
tz = n1*csx + n2*csy + n3*csz;
tlen = modulus(tx, ty, tz);
/* Test modulus for agreement with moduli of template */
for ( i=0; i<3; i++ ) {
if ( within_tolerance(lengths[i], tlen, ltl) ) {
cand[i][ncand[i]].vec.u = tx;
cand[i][ncand[i]].vec.v = ty;
cand[i][ncand[i]].vec.w = tz;
cand[i][ncand[i]].na = n1;
cand[i][ncand[i]].nb = n2;
cand[i][ncand[i]].nc = n3;
ncand[i]++;
if ( ncand[i] == MAX_CAND ) {
ERROR("Too many candidates\n");
}
}
}
}
}
}
}
}
}
STATUS("Candidates: %i %i %i\n", ncand[0], ncand[1], ncand[2]);
for ( i=0; i<ncand[0]; i++ ) {
for ( j=0; j<ncand[1]; j++ ) {
double ang;
int k;
if ( same_vector(cand[0][i], cand[1][j]) ) continue;
/* Measure the angle between the ith candidate for axis 0
* and the jth candidate for axis 1 */
ang = angle_between(cand[0][i].vec.u, cand[0][i].vec.v,
cand[0][i].vec.w, cand[1][j].vec.u,
cand[1][j].vec.v, cand[1][j].vec.w);
/* Angle between axes 0 and 1 should be angle 2 */
if ( fabs(ang - angles[2]) > angtol ) continue;
STATUS("Matched %i-%i (0-1 %f deg)\n", i, j, rad2deg(ang));
for ( k=0; k<ncand[2]; k++ ) {
if ( same_vector(cand[1][j], cand[2][k]) ) continue;
/* Measure the angle between the current candidate for
* axis 0 and the kth candidate for axis 2 */
ang = angle_between(cand[0][i].vec.u, cand[0][i].vec.v,
cand[0][i].vec.w, cand[2][k].vec.u,
cand[2][k].vec.v, cand[2][k].vec.w);
/* ... it should be angle 1 ... */
if ( fabs(ang - angles[1]) > angtol ) continue;
STATUS("0-2 %f\n", rad2deg(ang));
/* Finally, the angle between the current candidate for
* axis 1 and the kth candidate for axis 2 */
ang = angle_between(cand[1][j].vec.u, cand[1][j].vec.v,
cand[1][j].vec.w, cand[2][k].vec.u,
cand[2][k].vec.v, cand[2][k].vec.w);
/* ... it should be angle 0 ... */
STATUS("1-2 %f\n", rad2deg(ang));
if ( fabs(ang - angles[0]) > angtol ) continue;
new_cell = cell_new_from_axes(cand[0][i].vec,
cand[1][j].vec,
cand[2][k].vec);
STATUS("Success! --------------- \n");
cell_print(new_cell);
STATUS("The transformation from the original was:\n");
STATUS("%5.2f %5.2f %5.2f\n", cand[0][i].na,
cand[0][i].nb,
cand[0][i].nc);
STATUS("%5.2f %5.2f %5.2f\n", cand[1][j].na,
cand[1][j].nb,
cand[1][j].nc);
STATUS("%5.2f %5.2f %5.2f\n", cand[2][k].na,
cand[2][k].nb,
cand[2][k].nc);
goto done;
}
}
}
done:
free(cand[0]);
free(cand[1]);
free(cand[2]);
return new_cell;
}
double resolution(UnitCell *cell, signed int h, signed int k, signed int l)
{
const double a = cell->a;
const double b = cell->b;
const double c = cell->c;
const double alpha = cell->alpha;
const double beta = cell->beta;
const double gamma = cell->gamma;
const double Vsq = a*a*b*b*c*c*(1 - cos(alpha)*cos(alpha)
- cos(beta)*cos(beta)
- cos(gamma)*cos(gamma)
+ 2*cos(alpha)*cos(beta)*cos(gamma) );
const double S11 = b*b*c*c*sin(alpha)*sin(alpha);
const double S22 = a*a*c*c*sin(beta)*sin(beta);
const double S33 = a*a*b*b*sin(gamma)*sin(gamma);
const double S12 = a*b*c*c*(cos(alpha)*cos(beta) - cos(gamma));
const double S23 = a*a*b*c*(cos(beta)*cos(gamma) - cos(alpha));
const double S13 = a*b*b*c*(cos(gamma)*cos(alpha) - cos(beta));
const double brackets = S11*h*h + S22*k*k + S33*l*l
+ 2*S12*h*k + 2*S23*k*l + 2*S13*h*l;
const double oneoverdsq = brackets / Vsq;
const double oneoverd = sqrt(oneoverdsq);
return oneoverd / 2;
}
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