diff options
author | Thomas White <taw@physics.org> | 2010-10-29 16:44:05 +0200 |
---|---|---|
committer | Thomas White <taw@physics.org> | 2012-02-22 15:27:04 +0100 |
commit | 82284b116dab90f697970f1a2b1e798f352d7bde (patch) | |
tree | 3bd9a244fcdc2af1c739d80130af53e9696724bf /src/geometry.c | |
parent | cc23b6eb31f8c4f59be3acf9f1bc8c51daf25e55 (diff) |
Satisfactory peak location
Diffstat (limited to 'src/geometry.c')
-rw-r--r-- | src/geometry.c | 59 |
1 files changed, 33 insertions, 26 deletions
diff --git a/src/geometry.c b/src/geometry.c index 1f21c96f..11020909 100644 --- a/src/geometry.c +++ b/src/geometry.c @@ -28,12 +28,12 @@ #define MAX_CPEAKS (256 * 256) -static signed int locate_peak(double x, double y, double z, double lambda, +static signed int locate_peak(double x, double y, double z, double k, struct detector *det, double *xdap, double *ydap) { int p; signed int found = -1; - const double den = 1.0/lambda + z; + const double den = k + z; for ( p=0; p<det->n_panels; p++ ) { @@ -76,17 +76,15 @@ static signed int locate_peak(double x, double y, double z, double lambda, static double excitation_error(double xl, double yl, double zl, - double ds, double lambda) + double ds, double k) { double tt, al; double r; - tt = angle_between(0.0, 0.0, 1.0, xl, yl, zl+1.0/lambda); + tt = angle_between(0.0, 0.0, 1.0, xl, yl, zl+k); al = M_PI_2 - asin(-zl/ds); - r = ds * sin(al) / sin(tt); - - r -= 1.0/lambda; + r = ( ds * sin(al) / sin(tt) ) - k; return r; } @@ -107,7 +105,7 @@ struct cpeak *find_intersections(struct image *image, UnitCell *cell, double divergence = image->div; double lambda = image->lambda; const double profile_cutoff = 0.005e9; /* 0.1 nm^-1 */ - double llow, lhigh; /* Wavelength */ + double klow, kcen, khigh; /* Wavenumber */ cpeaks = malloc(sizeof(struct cpeak)*MAX_CPEAKS); if ( cpeaks == NULL ) { @@ -119,9 +117,6 @@ struct cpeak *find_intersections(struct image *image, UnitCell *cell, &bsx, &bsy, &bsz, &csx, &csy, &csz); - /* FIXME: Account for left-handed indexing */ - asz = -asz; bsz = -bsz; csz = -csz; - mres = 1.0 / 8.0e-10; /* 8 Angstroms */ hmax = mres / modulus(asx, asy, asz); kmax = mres / modulus(bsx, bsy, bsz); @@ -129,8 +124,9 @@ struct cpeak *find_intersections(struct image *image, UnitCell *cell, /* "low" gives the largest Ewald sphere, * "high" gives the smallest Ewald sphere. */ - llow = lambda - lambda*bandwidth/2.0; - lhigh = lambda + lambda*bandwidth/2.0; + klow = 1.0/(lambda - lambda*bandwidth/2.0); + kcen = 1.0/lambda; + khigh = 1.0/(lambda + lambda*bandwidth/2.0); for ( h=-hmax; h<hmax; h++ ) { for ( k=-kmax; k<kmax; k++ ) { @@ -138,18 +134,18 @@ struct cpeak *find_intersections(struct image *image, UnitCell *cell, double xl, yl, zl; double ds, ds_sq; - double rlow, rhigh; /* "Excitation error" */ - signed int p; - double lcen; - double xda, yda; - int close, straddled; + double rlow, rhigh; /* "Excitation error" */ + signed int p; /* Panel number */ + double xda, yda; /* Position on detector */ + int close, inside; /* Ignore central beam */ if ( (h==0) && (k==0) && (l==0) ) continue; /* Get the coordinates of the reciprocal lattice point */ zl = h*asz + k*bsz + l*csz; - if ( zl > 0.0 ) continue; /* Throw out if it's "in front" */ + /* Throw out if it's "in front" */ + if ( zl > profile_cutoff ) continue; xl = h*asx + k*bsx + l*csx; yl = h*asy + k*bsy + l*csy; @@ -159,8 +155,8 @@ struct cpeak *find_intersections(struct image *image, UnitCell *cell, if ( ds > mres ) continue; /* Outside resolution range */ /* Calculate excitation errors */ - rlow = excitation_error(xl, yl, zl, ds, llow); - rhigh = excitation_error(xl, yl, zl, ds, lhigh); + rlow = excitation_error(xl, yl, zl, ds, klow); + rhigh = excitation_error(xl, yl, zl, ds, khigh); /* Is the reciprocal lattice point close to either extreme of * the sphere, maybe just outside the "Ewald volume"? */ @@ -169,15 +165,26 @@ struct cpeak *find_intersections(struct image *image, UnitCell *cell, /* Is the reciprocal lattice point somewhere between the * extremes of the sphere, i.e. inside the "Ewald volume"? */ - straddled = signbit(rlow) ^ signbit(rhigh); + inside = signbit(rlow) ^ signbit(rhigh); + + /* Can't be both inside and close */ + if ( inside ) close = 0; /* Neither? Skip it. */ - if ( !(close || straddled) ) continue; + if ( !(close || inside) ) continue; + + /* If the "lower" Ewald sphere is a long way away, use the + * position at which the Ewald sphere would just touch the + * reflection. */ + if ( rlow > profile_cutoff ) rlow = profile_cutoff; + if ( rlow < -profile_cutoff ) rlow = -profile_cutoff; - lcen = -2.0*zl / ds_sq; + /* As above, other side. */ + if ( rhigh > profile_cutoff ) rhigh = profile_cutoff; + if ( rhigh < -profile_cutoff ) rhigh = -profile_cutoff; - /* Locate peak on detector, and check it doesn't span panels */ - p = locate_peak(xl, yl, zl, lcen, image->det, &xda, &yda); + /* Locate peak on detector. */ + p = locate_peak(xl, yl, zl, kcen, image->det, &xda, &yda); if ( p == -1 ) continue; cpeaks[np].h = h; |