PJ_laea.c
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#define PROJ_PARMS__ \
double sinb1; \
double cosb1; \
double xmf; \
double ymf; \
double mmf; \
double qp; \
double dd; \
double rq; \
double *apa; \
int mode;
#define PJ_LIB__
#include <projects.h>
PROJ_HEAD(laea, "Lambert Azimuthal Equal Area") "\n\tAzi, Sph&Ell";
#define sinph0 P->sinb1
#define cosph0 P->cosb1
#define EPS10 1.e-10
#define NITER 20
#define CONV 1.e-10
#define N_POLE 0
#define S_POLE 1
#define EQUIT 2
#define OBLIQ 3
FORWARD(e_forward); /* ellipsoid */
double coslam, sinlam, sinphi, q, sinb=0.0, cosb=0.0, b=0.0;
coslam = cos(lp.lam);
sinlam = sin(lp.lam);
sinphi = sin(lp.phi);
q = pj_qsfn(sinphi, P->e, P->one_es);
if (P->mode == OBLIQ || P->mode == EQUIT) {
sinb = q / P->qp;
cosb = sqrt(1. - sinb * sinb);
}
switch (P->mode) {
case OBLIQ:
b = 1. + P->sinb1 * sinb + P->cosb1 * cosb * coslam;
break;
case EQUIT:
b = 1. + cosb * coslam;
break;
case N_POLE:
b = HALFPI + lp.phi;
q = P->qp - q;
break;
case S_POLE:
b = lp.phi - HALFPI;
q = P->qp + q;
break;
}
if (fabs(b) < EPS10) F_ERROR;
switch (P->mode) {
case OBLIQ:
xy.y = P->ymf * ( b = sqrt(2. / b) )
* (P->cosb1 * sinb - P->sinb1 * cosb * coslam);
goto eqcon;
break;
case EQUIT:
xy.y = (b = sqrt(2. / (1. + cosb * coslam))) * sinb * P->ymf;
eqcon:
xy.x = P->xmf * b * cosb * sinlam;
break;
case N_POLE:
case S_POLE:
if (q >= 0.) {
xy.x = (b = sqrt(q)) * sinlam;
xy.y = coslam * (P->mode == S_POLE ? b : -b);
} else
xy.x = xy.y = 0.;
break;
}
return (xy);
}
FORWARD(s_forward); /* spheroid */
double coslam, cosphi, sinphi;
sinphi = sin(lp.phi);
cosphi = cos(lp.phi);
coslam = cos(lp.lam);
switch (P->mode) {
case EQUIT:
xy.y = 1. + cosphi * coslam;
goto oblcon;
case OBLIQ:
xy.y = 1. + sinph0 * sinphi + cosph0 * cosphi * coslam;
oblcon:
if (xy.y <= EPS10) F_ERROR;
xy.x = (xy.y = sqrt(2. / xy.y)) * cosphi * sin(lp.lam);
xy.y *= P->mode == EQUIT ? sinphi :
cosph0 * sinphi - sinph0 * cosphi * coslam;
break;
case N_POLE:
coslam = -coslam;
case S_POLE:
if (fabs(lp.phi + P->phi0) < EPS10) F_ERROR;
xy.y = FORTPI - lp.phi * .5;
xy.y = 2. * (P->mode == S_POLE ? cos(xy.y) : sin(xy.y));
xy.x = xy.y * sin(lp.lam);
xy.y *= coslam;
break;
}
return (xy);
}
INVERSE(e_inverse); /* ellipsoid */
double cCe, sCe, q, rho, ab=0.0;
switch (P->mode) {
case EQUIT:
case OBLIQ:
if ((rho = hypot(xy.x /= P->dd, xy.y *= P->dd)) < EPS10) {
lp.lam = 0.;
lp.phi = P->phi0;
return (lp);
}
cCe = cos(sCe = 2. * asin(.5 * rho / P->rq));
xy.x *= (sCe = sin(sCe));
if (P->mode == OBLIQ) {
q = P->qp * (ab = cCe * P->sinb1 + xy.y * sCe * P->cosb1 / rho);
xy.y = rho * P->cosb1 * cCe - xy.y * P->sinb1 * sCe;
} else {
q = P->qp * (ab = xy.y * sCe / rho);
xy.y = rho * cCe;
}
break;
case N_POLE:
xy.y = -xy.y;
case S_POLE:
if (!(q = (xy.x * xy.x + xy.y * xy.y)) ) {
lp.lam = 0.;
lp.phi = P->phi0;
return (lp);
}
/*
q = P->qp - q;
*/
ab = 1. - q / P->qp;
if (P->mode == S_POLE)
ab = - ab;
break;
}
lp.lam = atan2(xy.x, xy.y);
lp.phi = pj_authlat(asin(ab), P->apa);
return (lp);
}
INVERSE(s_inverse); /* spheroid */
double cosz=0.0, rh, sinz=0.0;
rh = hypot(xy.x, xy.y);
if ((lp.phi = rh * .5 ) > 1.) I_ERROR;
lp.phi = 2. * asin(lp.phi);
if (P->mode == OBLIQ || P->mode == EQUIT) {
sinz = sin(lp.phi);
cosz = cos(lp.phi);
}
switch (P->mode) {
case EQUIT:
lp.phi = fabs(rh) <= EPS10 ? 0. : asin(xy.y * sinz / rh);
xy.x *= sinz;
xy.y = cosz * rh;
break;
case OBLIQ:
lp.phi = fabs(rh) <= EPS10 ? P->phi0 :
asin(cosz * sinph0 + xy.y * sinz * cosph0 / rh);
xy.x *= sinz * cosph0;
xy.y = (cosz - sin(lp.phi) * sinph0) * rh;
break;
case N_POLE:
xy.y = -xy.y;
lp.phi = HALFPI - lp.phi;
break;
case S_POLE:
lp.phi -= HALFPI;
break;
}
lp.lam = (xy.y == 0. && (P->mode == EQUIT || P->mode == OBLIQ)) ?
0. : atan2(xy.x, xy.y);
return (lp);
}
FREEUP;
if (P) {
if (P->apa)
pj_dalloc(P->apa);
pj_dalloc(P);
}
}
ENTRY1(laea,apa)
double t;
if (fabs((t = fabs(P->phi0)) - HALFPI) < EPS10)
P->mode = P->phi0 < 0. ? S_POLE : N_POLE;
else if (fabs(t) < EPS10)
P->mode = EQUIT;
else
P->mode = OBLIQ;
if (P->es) {
double sinphi;
P->e = sqrt(P->es);
P->qp = pj_qsfn(1., P->e, P->one_es);
P->mmf = .5 / (1. - P->es);
P->apa = pj_authset(P->es);
switch (P->mode) {
case N_POLE:
case S_POLE:
P->dd = 1.;
break;
case EQUIT:
P->dd = 1. / (P->rq = sqrt(.5 * P->qp));
P->xmf = 1.;
P->ymf = .5 * P->qp;
break;
case OBLIQ:
P->rq = sqrt(.5 * P->qp);
sinphi = sin(P->phi0);
P->sinb1 = pj_qsfn(sinphi, P->e, P->one_es) / P->qp;
P->cosb1 = sqrt(1. - P->sinb1 * P->sinb1);
P->dd = cos(P->phi0) / (sqrt(1. - P->es * sinphi * sinphi) *
P->rq * P->cosb1);
P->ymf = (P->xmf = P->rq) / P->dd;
P->xmf *= P->dd;
break;
}
P->inv = e_inverse;
P->fwd = e_forward;
} else {
if (P->mode == OBLIQ) {
sinph0 = sin(P->phi0);
cosph0 = cos(P->phi0);
}
P->inv = s_inverse;
P->fwd = s_forward;
}
ENDENTRY(P)