#define PROJ_PARMS__ \ double alpha, lamc, lam1, phi1, lam2, phi2, Gamma, al, bl, el, \ singam, cosgam, sinrot, cosrot, u_0; \ int ellips, rot; #define PJ_LIB__ #include PROJ_HEAD(omerc, "Oblique Mercator") "\n\tCyl, Sph&Ell\n\t no_rot rot_conv no_uoff and\n\t" "alpha= lonc= or\n\t lon_1= lat_1= lon_2= lat_2="; #define TOL 1.e-7 #define EPS 1.e-10 #define TSFN0(x) tan(.5 * (HALFPI - (x))) FORWARD(e_forward); /* ellipsoid & spheroid */ double con, q, s, ul, us, vl, vs; vl = sin(P->bl * lp.lam); if (fabs(fabs(lp.phi) - HALFPI) <= EPS) { ul = lp.phi < 0. ? -P->singam : P->singam; us = P->al * lp.phi / P->bl; } else { q = P->el / (P->ellips ? pow(pj_tsfn(lp.phi, sin(lp.phi), P->e), P->bl) : TSFN0(lp.phi)); s = .5 * (q - 1. / q); ul = 2. * (s * P->singam - vl * P->cosgam) / (q + 1. / q); con = cos(P->bl * lp.lam); if (fabs(con) >= TOL) { us = P->al * atan((s * P->cosgam + vl * P->singam) / con) / P->bl; if (con < 0.) us += PI * P->al / P->bl; } else us = P->al * P->bl * lp.lam; } if (fabs(fabs(ul) - 1.) <= EPS) F_ERROR; vs = .5 * P->al * log((1. - ul) / (1. + ul)) / P->bl; us -= P->u_0; if (! P->rot) { xy.x = us; xy.y = vs; } else { xy.x = vs * P->cosrot + us * P->sinrot; xy.y = us * P->cosrot - vs * P->sinrot; } return (xy); } INVERSE(e_inverse); /* ellipsoid & spheroid */ double q, s, ul, us, vl, vs; if (! P->rot) { us = xy.x; vs = xy.y; } else { vs = xy.x * P->cosrot - xy.y * P->sinrot; us = xy.y * P->cosrot + xy.x * P->sinrot; } us += P->u_0; q = exp(- P->bl * vs / P->al); s = .5 * (q - 1. / q); vl = sin(P->bl * us / P->al); ul = 2. * (vl * P->cosgam + s * P->singam) / (q + 1. / q); if (fabs(fabs(ul) - 1.) < EPS) { lp.lam = 0.; lp.phi = ul < 0. ? -HALFPI : HALFPI; } else { lp.phi = P->el / sqrt((1. + ul) / (1. - ul)); if (P->ellips) { if ((lp.phi = pj_phi2(pow(lp.phi, 1. / P->bl), P->e)) == HUGE_VAL) I_ERROR; } else lp.phi = HALFPI - 2. * atan(lp.phi); lp.lam = - atan2((s * P->cosgam - vl * P->singam), cos(P->bl * us / P->al)) / P->bl; } return (lp); } FREEUP; if (P) pj_dalloc(P); } ENTRY0(omerc) double con, com, cosph0, d, f, h, l, sinph0, p, j; int azi; P->rot = pj_param(P->params, "bno_rot").i == 0; if( (azi = pj_param(P->params, "talpha").i) != 0.0) { P->lamc = pj_param(P->params, "rlonc").f; P->alpha = pj_param(P->params, "ralpha").f; if ( fabs(P->alpha) <= TOL || fabs(fabs(P->phi0) - HALFPI) <= TOL || fabs(fabs(P->alpha) - HALFPI) <= TOL) E_ERROR(-32); } else { P->lam1 = pj_param(P->params, "rlon_1").f; P->phi1 = pj_param(P->params, "rlat_1").f; P->lam2 = pj_param(P->params, "rlon_2").f; P->phi2 = pj_param(P->params, "rlat_2").f; if (fabs(P->phi1 - P->phi2) <= TOL || (con = fabs(P->phi1)) <= TOL || fabs(con - HALFPI) <= TOL || fabs(fabs(P->phi0) - HALFPI) <= TOL || fabs(fabs(P->phi2) - HALFPI) <= TOL) E_ERROR(-33); } com = (P->ellips = P->es > 0.) ? sqrt(P->one_es) : 1.; if (fabs(P->phi0) > EPS) { sinph0 = sin(P->phi0); cosph0 = cos(P->phi0); if (P->ellips) { con = 1. - P->es * sinph0 * sinph0; P->bl = cosph0 * cosph0; P->bl = sqrt(1. + P->es * P->bl * P->bl / P->one_es); P->al = P->bl * P->k0 * com / con; d = P->bl * com / (cosph0 * sqrt(con)); } else { P->bl = 1.; P->al = P->k0; d = 1. / cosph0; } if ((f = d * d - 1.) <= 0.) f = 0.; else { f = sqrt(f); if (P->phi0 < 0.) f = -f; } P->el = f += d; if (P->ellips) P->el *= pow(pj_tsfn(P->phi0, sinph0, P->e), P->bl); else P->el *= TSFN0(P->phi0); } else { P->bl = 1. / com; P->al = P->k0; P->el = d = f = 1.; } if (azi) { P->Gamma = asin(sin(P->alpha) / d); P->lam0 = P->lamc - asin((.5 * (f - 1. / f)) * tan(P->Gamma)) / P->bl; } else { if (P->ellips) { h = pow(pj_tsfn(P->phi1, sin(P->phi1), P->e), P->bl); l = pow(pj_tsfn(P->phi2, sin(P->phi2), P->e), P->bl); } else { h = TSFN0(P->phi1); l = TSFN0(P->phi2); } f = P->el / h; p = (l - h) / (l + h); j = P->el * P->el; j = (j - l * h) / (j + l * h); if ((con = P->lam1 - P->lam2) < -PI) P->lam2 -= TWOPI; else if (con > PI) P->lam2 += TWOPI; P->lam0 = adjlon(.5 * (P->lam1 + P->lam2) - atan( j * tan(.5 * P->bl * (P->lam1 - P->lam2)) / p) / P->bl); P->Gamma = atan(2. * sin(P->bl * adjlon(P->lam1 - P->lam0)) / (f - 1. / f)); P->alpha = asin(d * sin(P->Gamma)); } P->singam = sin(P->Gamma); P->cosgam = cos(P->Gamma); f = pj_param(P->params, "brot_conv").i ? P->Gamma : P->alpha; P->sinrot = sin(f); P->cosrot = cos(f); P->u_0 = pj_param(P->params, "bno_uoff").i ? 0. : fabs(P->al * atan(sqrt(d * d - 1.) / P->cosrot) / P->bl); if (P->phi0 < 0.) P->u_0 = - P->u_0; P->inv = e_inverse; P->fwd = e_forward; ENDENTRY(P)