PJ_imw_p.c
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#ifndef lint
static const char SCCSID[]="@(#)PJ_imw_p.c 4.1 94/05/22 GIE REL";
#endif
#define PROJ_PARMS__ \
double P, Pp, Q, Qp, R_1, R_2, sphi_1, sphi_2, C2; \
double phi_1, phi_2, lam_1; \
double *en; \
int mode; /* = 0, phi_1 and phi_2 != 0, = 1, phi_1 = 0, = -1 phi_2 = 0 */
#define PJ_LIB__
#include "projects.h"
PROJ_HEAD(imw_p, "International Map of the World Polyconic")
"\n\tMod. Polyconic, Ell\n\tlat_1= and lat_2= [lon_1=]";
#define TOL 1e-10
#define EPS 1e-10
static int
phi12(PJ *P, double *del, double *sig) {
int err = 0;
if (!pj_param(P->params, "tlat_1").i ||
!pj_param(P->params, "tlat_2").i) {
err = -41;
} else {
P->phi_1 = pj_param(P->params, "rlat_1").f;
P->phi_2 = pj_param(P->params, "rlat_2").f;
*del = 0.5 * (P->phi_2 - P->phi_1);
*sig = 0.5 * (P->phi_2 + P->phi_1);
err = (fabs(*del) < EPS || fabs(*sig) < EPS) ? -42 : 0;
}
return err;
}
static XY
loc_for(LP lp, PJ *P, double *yc) {
XY xy;
if (! lp.phi) {
xy.x = lp.lam;
xy.y = 0.;
} else {
double xa, ya, xb, yb, xc, yc, D, B, m, sp, t, R, C;
sp = sin(lp.phi);
m = pj_mlfn(lp.phi, sp, cos(lp.phi), P->en);
xa = P->Pp + P->Qp * m;
ya = P->P + P->Q * m;
R = 1. / (tan(lp.phi) * sqrt(1. - P->es * sp * sp));
C = sqrt(R * R - xa * xa);
if (lp.phi < 0.) C = - C;
C += ya - R;
if (P->mode < 0) {
xb = lp.lam;
yb = P->C2;
} else {
t = lp.lam * P->sphi_2;
xb = P->R_2 * sin(t);
yb = P->C2 + P->R_2 * (1. - cos(t));
}
if (P->mode > 0) {
xc = lp.lam;
yc = 0.;
} else {
t = lp.lam * P->sphi_1;
xc = P->R_1 * sin(t);
yc = P->R_1 * (1. - cos(t));
}
D = (xb - xc)/(yb - yc);
B = xc + D * (C + R - yc);
xy.x = D * sqrt(R * R * (1 + D * D) - B * B);
if (lp.phi > 0)
xy.x = - xy.x;
xy.x = (B + xy.x) / (1. + D * D);
xy.y = sqrt(R * R - xy.x * xy.x);
if (lp.phi > 0)
xy.y = - xy.y;
xy.y += C + R;
}
return (xy);
}
FORWARD(e_forward); /* ellipsoid */
double yc;
xy = loc_for(lp, P, &yc);
return (xy);
}
INVERSE(e_inverse); /* ellipsoid */
XY t;
double yc;
lp.phi = P->phi_2;
lp.lam = xy.x / cos(lp.phi);
do {
t = loc_for(lp, P, &yc);
lp.phi = ((lp.phi - P->phi_1) * (xy.y - yc) / (t.y - yc)) + P->phi_1;
lp.lam = lp.lam * xy.x / t.x;
} while (fabs(t.x - xy.x) > TOL || fabs(t.y - xy.y) > TOL);
return (lp);
}
static void
xy(PJ *P, double phi, double *x, double *y, double *sp, double *R) {
double F;
*sp = sin(phi);
*R = 1./(tan(phi) * sqrt(1. - P->es * *sp * *sp ));
F = P->lam_1 * *sp;
*y = *R * (1 - cos(F));
*x = *R * sin(F);
}
FREEUP; if (P) { if (P->en) pj_dalloc(P->en); pj_dalloc(P); } }
ENTRY1(imw_p, en)
double del, sig, s, t, x1, x2, T2, y1, m1, m2, y2;
int i;
if (!(P->en = pj_enfn(P->es))) E_ERROR_0;
if( (i = phi12(P, &del, &sig)) != 0)
E_ERROR(i);
if (P->phi_2 < P->phi_1) { /* make sure P->phi_1 most southerly */
del = P->phi_1;
P->phi_1 = P->phi_2;
P->phi_2 = del;
}
if (pj_param(P->params, "tlon_1").i)
P->lam_1 = pj_param(P->params, "rlon_1").f;
else { /* use predefined based upon latitude */
sig = fabs(sig * RAD_TO_DEG);
if (sig <= 60) sig = 2.;
else if (sig <= 76) sig = 4.;
else sig = 8.;
P->lam_1 = sig * DEG_TO_RAD;
}
P->mode = 0;
if (P->phi_1) xy(P, P->phi_1, &x1, &y1, &P->sphi_1, &P->R_1);
else {
P->mode = 1;
y1 = 0.;
x1 = P->lam_1;
}
if (P->phi_2) xy(P, P->phi_2, &x2, &T2, &P->sphi_2, &P->R_2);
else {
P->mode = -1;
T2 = 0.;
x2 = P->lam_1;
}
m1 = pj_mlfn(P->phi_1, P->sphi_1, cos(P->phi_1), P->en);
m2 = pj_mlfn(P->phi_2, P->sphi_2, cos(P->phi_2), P->en);
t = m2 - m1;
s = x2 - x1;
y2 = sqrt(t * t - s * s) + y1;
P->C2 = y2 - T2;
t = 1. / t;
P->P = (m2 * y1 - m1 * y2) * t;
P->Q = (y2 - y1) * t;
P->Pp = (m2 * x1 - m1 * x2) * t;
P->Qp = (x2 - x1) * t;
P->fwd = e_forward;
P->inv = e_inverse;
ENDENTRY(P)