/* * cel.c * * Lower level spherical coordinate transformation and projection routines. * *%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% * * This file part of: AstrOmatic WCS library * * Copyright: (C) 2000-2010 IAP/CNRS/UPMC * (C) 1995-1999 Mark Calabretta * * Authors: Emmanuel Bertin (this version) * Mark Calabretta (original version) * * Licenses: GNU General Public License * * AstrOmatic software is free software: you can redistribute it and/or * modify it under the terms of the GNU General Public License as * published by the Free Software Foundation, either version 3 of the * License, or (at your option) any later version. * AstrOmatic software is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * You should have received a copy of the GNU General Public License * along with AstrOmatic software. * If not, see . * * Last modified: 10/10/2010 * *%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%*/ /*============================================================================= * * WCSLIB - an implementation of the FITS WCS proposal. * Copyright (C) 1995-1999, Mark Calabretta * * This library is free software; you can redistribute it and/or modify it * under the terms of the GNU Library General Public License as published * by the Free Software Foundation; either version 2 of the License, or (at * your option) any later version. * * This library is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Library * General Public License for more details. * * You should have received a copy of the GNU Library General Public License * along with this library; if not, write to the Free Software Foundation, * Inc., 675 Mass Ave, Cambridge, MA 02139, USA. * * Correspondence concerning WCSLIB may be directed to: * Internet email: mcalabre@atnf.csiro.au * Postal address: Dr. Mark Calabretta, * Australia Telescope National Facility, * P.O. Box 76, * Epping, NSW, 2121, * AUSTRALIA * *============================================================================= * * C routines which implement the FITS World Coordinate System (WCS) * convention. * * Summary of routines * ------------------- * These routines are provided as drivers for the lower level spherical * coordinate transformation and projection routines. There are separate * driver routines for the forward, celfwd(), and reverse, celrev(), * transformations. * * An initialization routine, celset(), computes intermediate values from * the transformation parameters but need not be called explicitly - see the * explanation of cel.flag below. * * * Initialization routine; celset() * -------------------------------- * Initializes members of a celprm data structure which hold intermediate * values. Note that this routine need not be called directly; it will be * invoked by celfwd() and celrev() if the "flag" structure member is * anything other than a predefined magic value. * * Given: * pcode[4] const char * WCS projection code (see below). * * Given and returned: * cel celprm* Spherical coordinate transformation parameters * (see below). * prj prjprm* Projection parameters (usage is described in the * prologue to "proj.c"). * * Function return value: * int Error status * 0: Success. * 1: Invalid coordinate transformation parameters. * 2: Ill-conditioned coordinate transformation * parameters. * * Forward transformation; celfwd() * -------------------------------- * Compute (x,y) coordinates in the plane of projection from celestial * coordinates (lng,lat). * * Given: * pcode[4] const char * WCS projection code (see below). * lng,lat const double * Celestial longitude and latitude of the projected * point, in degrees. * * Given and returned: * cel celprm* Spherical coordinate transformation parameters * (see below). * * Returned: * phi, double* Longitude and latitude in the native coordinate * theta system of the projection, in degrees. * * Given and returned: * prj prjprm* Projection parameters (usage is described in the * prologue to "proj.c"). * * Returned: * x,y double* Projected coordinates, "degrees". * * Function return value: * int Error status * 0: Success. * 1: Invalid coordinate transformation parameters. * 2: Invalid projection parameters. * 3: Invalid value of (lng,lat). * * Reverse transformation; celrev() * -------------------------------- * Compute the celestial coordinates (lng,lat) of the point with projected * coordinates (x,y). * * Given: * pcode[4] const char * WCS projection code (see below). * x,y const double * Projected coordinates, "degrees". * * Given and returned: * prj prjprm* Projection parameters (usage is described in the * prologue to "proj.c"). * * Returned: * phi, double* Longitude and latitude in the native coordinate * theta system of the projection, in degrees. * * Given and returned: * cel celprm* Spherical coordinate transformation parameters * (see below). * * Returned: * lng,lat double* Celestial longitude and latitude of the projected * point, in degrees. * * Function return value: * int Error status * 0: Success. * 1: Invalid coordinate transformation parameters. * 2: Invalid projection parameters. * 3: Invalid value of (x,y). * * Coordinate transformation parameters * ------------------------------------ * The celprm struct consists of the following: * * int flag * The celprm struct contains pointers to the forward and reverse * projection routines as well as intermediaries computed from the * reference coordinates (see below). Whenever the projection code * (pcode) or any of ref[4] are set or changed then this flag must be * set to zero to signal the initialization routine, celset(), to * redetermine the function pointers and recompute intermediaries. * Once this has been done pcode itself is ignored. * * double ref[4] * The first pair of values should be set to the celestial longitude * and latitude (usually right ascension and declination) of the * reference point of the projection. * * The second pair of values are the native longitude and latitude of * the pole of the celestial coordinate system and correspond to the * FITS keywords LONGPOLE and LATPOLE. * * LONGPOLE defaults to 0 degrees if the celestial latitude of the * reference point of the projection is greater than the native * latitude, otherwise 180 degrees. (This is the condition for the * celestial latitude to increase in the same direction as the native * latitude at the reference point.) ref[2] may be set to 999.0 to * indicate that the correct default should be substituted. * * In some circumstances the latitude of the native pole may be * determined by the first three values only to within a sign and * LATPOLE is used to choose between the two solutions. LATPOLE is * set in ref[3] and the solution closest to this value is used to * reset ref[3]. It is therefore legitimate, for example, to set * ref[3] to 999.0 to choose the more northerly solution - the default * if the LATPOLE card is omitted from the FITS header. For the * special case where the reference point of the projection is at * native latitude zero, its celestial latitude is zero, and * LONGPOLE = +/- 90 then the native latitude of the pole is not * determined by the first three reference values and LATPOLE * specifies it completely. * * The remaining members of the celprm struct are maintained by the * initialization routines and should not be modified. This is done for the * sake of efficiency and to allow an arbitrary number of contexts to be * maintained simultaneously. * * double euler[5] * Euler angles and associated intermediaries derived from the * coordinate reference values. * int (*prjfwd)() * int (*prjrev)() * Pointers to the forward and reverse projection routines. * * * WCS projection codes * -------------------- * Zenithals/azimuthals: * AZP: zenithal/azimuthal perspective * TAN: gnomonic * SIN: synthesis (generalized orthographic) * STG: stereographic * ARC: zenithal/azimuthal equidistant * ZPN: zenithal/azimuthal polynomial * ZEA: zenithal/azimuthal equal area * AIR: Airy * TNX: IRAF's polynomial correction to TAN * * Cylindricals: * CYP: cylindrical perspective * CAR: Cartesian * MER: Mercator * CEA: cylindrical equal area * * Conics: * COP: conic perspective * COD: conic equidistant * COE: conic equal area * COO: conic orthomorphic * * Polyconics: * BON: Bonne * PCO: polyconic * * Pseudo-cylindricals: * GLS: Sanson-Flamsteed (global sinusoidal) * PAR: parabolic * MOL: Mollweide * * Conventional: * AIT: Hammer-Aitoff * * Quad-cubes: * CSC: COBE quadrilateralized spherical cube * QSC: quadrilateralized spherical cube * TSC: tangential spherical cube * * Author: Mark Calabretta, Australia Telescope National Facility * IRAF's TNX added by E.Bertin 2000/03/28 * Filtering of abs(phi)>180 and abs(theta)>90 added by E.Bertin 2000/11/11 * $Id: cel.c,v 1.1.1.1 2002/03/15 16:33:26 bertin Exp $ *===========================================================================*/ #ifdef HAVE_CONFIG_H #include "config.h" #endif #ifdef HAVE_MATHIMF_H #include #else #include #endif #include #include "wcstrig.h" #include "cel.h" #include "sph.h" #include "tnx.h" int npcode = 26; char pcodes[26][4] = {"AZP", "TAN", "SIN", "STG", "ARC", "ZPN", "ZEA", "AIR", "CYP", "CAR", "MER", "CEA", "COP", "COD", "COE", "COO", "BON", "PCO", "GLS", "PAR", "AIT", "MOL", "CSC", "QSC", "TSC", "TNX"}; /* Map error number to error message for each function. */ const char *celset_errmsg[] = { 0, "Invalid coordinate transformation parameters", "Ill-conditioned coordinate transformation parameters"}; const char *celfwd_errmsg[] = { 0, "Invalid coordinate transformation parameters", "Invalid projection parameters", "Invalid value of (lng,lat)"}; const char *celrev_errmsg[] = { 0, "Invalid coordinate transformation parameters", "Invalid projection parameters", "Invalid value of (x,y)"}; int celset(pcode, cel, prj) const char pcode[4]; struct celprm *cel; struct prjprm *prj; { int dophip; const double tol = 1.0e-10; double clat0, cphip, cthe0, theta0, slat0, sphip, sthe0; double latp, latp1, latp2; double u, v, x, y, z; /* Set pointers to the forward and reverse projection routines. */ if (strcmp(pcode, "AZP") == 0) { cel->prjfwd = azpfwd; cel->prjrev = azprev; theta0 = 90.0; } else if (strcmp(pcode, "TAN") == 0) { cel->prjfwd = tanfwd; cel->prjrev = tanrev; theta0 = 90.0; } else if (strcmp(pcode, "SIN") == 0) { cel->prjfwd = sinfwd; cel->prjrev = sinrev; theta0 = 90.0; } else if (strcmp(pcode, "STG") == 0) { cel->prjfwd = stgfwd; cel->prjrev = stgrev; theta0 = 90.0; } else if (strcmp(pcode, "ARC") == 0) { cel->prjfwd = arcfwd; cel->prjrev = arcrev; theta0 = 90.0; } else if (strcmp(pcode, "ZPN") == 0) { cel->prjfwd = zpnfwd; cel->prjrev = zpnrev; theta0 = 90.0; } else if (strcmp(pcode, "ZEA") == 0) { cel->prjfwd = zeafwd; cel->prjrev = zearev; theta0 = 90.0; } else if (strcmp(pcode, "AIR") == 0) { cel->prjfwd = airfwd; cel->prjrev = airrev; theta0 = 90.0; } else if (strcmp(pcode, "CYP") == 0) { cel->prjfwd = cypfwd; cel->prjrev = cyprev; theta0 = 0.0; } else if (strcmp(pcode, "CAR") == 0) { cel->prjfwd = carfwd; cel->prjrev = carrev; theta0 = 0.0; } else if (strcmp(pcode, "MER") == 0) { cel->prjfwd = merfwd; cel->prjrev = merrev; theta0 = 0.0; } else if (strcmp(pcode, "CEA") == 0) { cel->prjfwd = ceafwd; cel->prjrev = cearev; theta0 = 0.0; } else if (strcmp(pcode, "COP") == 0) { cel->prjfwd = copfwd; cel->prjrev = coprev; theta0 = prj->p[1]; } else if (strcmp(pcode, "COD") == 0) { cel->prjfwd = codfwd; cel->prjrev = codrev; theta0 = prj->p[1]; } else if (strcmp(pcode, "COE") == 0) { cel->prjfwd = coefwd; cel->prjrev = coerev; theta0 = prj->p[1]; } else if (strcmp(pcode, "COO") == 0) { cel->prjfwd = coofwd; cel->prjrev = coorev; theta0 = prj->p[1]; } else if (strcmp(pcode, "BON") == 0) { cel->prjfwd = bonfwd; cel->prjrev = bonrev; theta0 = 0.0; } else if (strcmp(pcode, "PCO") == 0) { cel->prjfwd = pcofwd; cel->prjrev = pcorev; theta0 = 0.0; } else if (strcmp(pcode, "GLS") == 0) { cel->prjfwd = glsfwd; cel->prjrev = glsrev; theta0 = 0.0; } else if (strcmp(pcode, "PAR") == 0) { cel->prjfwd = parfwd; cel->prjrev = parrev; theta0 = 0.0; } else if (strcmp(pcode, "AIT") == 0) { cel->prjfwd = aitfwd; cel->prjrev = aitrev; theta0 = 0.0; } else if (strcmp(pcode, "MOL") == 0) { cel->prjfwd = molfwd; cel->prjrev = molrev; theta0 = 0.0; } else if (strcmp(pcode, "CSC") == 0) { cel->prjfwd = cscfwd; cel->prjrev = cscrev; theta0 = 0.0; } else if (strcmp(pcode, "QSC") == 0) { cel->prjfwd = qscfwd; cel->prjrev = qscrev; theta0 = 0.0; } else if (strcmp(pcode, "TSC") == 0) { cel->prjfwd = tscfwd; cel->prjrev = tscrev; theta0 = 0.0; } else if (strcmp(pcode, "TNX") == 0) { cel->prjfwd = tnxfwd; cel->prjrev = tnxrev; theta0 = 90.0; } else { /* Unrecognized projection code. */ return 1; } /* Set default for native longitude of the celestial pole? */ dophip = (cel->ref[2] == 999.0); /* Compute celestial coordinates of the native pole. */ if (theta0 == 90.0) { /* Reference point is at the native pole. */ if (dophip) { /* Set default for longitude of the celestial pole. */ cel->ref[2] = 180.0; } latp = cel->ref[1]; cel->ref[3] = latp; cel->euler[0] = cel->ref[0]; cel->euler[1] = 90.0 - latp; } else { /* Reference point away from the native pole. */ /* Set default for longitude of the celestial pole. */ if (dophip) { cel->ref[2] = (cel->ref[1] < theta0) ? 180.0 : 0.0; } clat0 = wcs_cosd(cel->ref[1]); slat0 = wcs_sind(cel->ref[1]); cphip = wcs_cosd(cel->ref[2]); sphip = wcs_sind(cel->ref[2]); cthe0 = wcs_cosd(theta0); sthe0 = wcs_sind(theta0); x = cthe0*cphip; y = sthe0; z = sqrt(x*x + y*y); if (z == 0.0) { if (slat0 != 0.0) { return 1; } /* latp determined by LATPOLE in this case. */ latp = cel->ref[3]; } else { if (fabs(slat0/z) > 1.0) { return 1; } u = wcs_atan2d(y,x); v = wcs_acosd(slat0/z); latp1 = u + v; if (latp1 > 180.0) { latp1 -= 360.0; } else if (latp1 < -180.0) { latp1 += 360.0; } latp2 = u - v; if (latp2 > 180.0) { latp2 -= 360.0; } else if (latp2 < -180.0) { latp2 += 360.0; } if (fabs(cel->ref[3]-latp1) < fabs(cel->ref[3]-latp2)) { if (fabs(latp1) < 90.0+tol) { latp = latp1; } else { latp = latp2; } } else { if (fabs(latp2) < 90.0+tol) { latp = latp2; } else { latp = latp1; } } cel->ref[3] = latp; } cel->euler[1] = 90.0 - latp; z = wcs_cosd(latp)*clat0; if (fabs(z) < tol) { if (fabs(clat0) < tol) { /* Celestial pole at the reference point. */ cel->euler[0] = cel->ref[0]; cel->euler[1] = 90.0 - theta0; } else if (latp > 0.0) { /* Celestial pole at the native north pole.*/ cel->euler[0] = cel->ref[0] + cel->ref[2] - 180.0; cel->euler[1] = 0.0; } else if (latp < 0.0) { /* Celestial pole at the native south pole. */ cel->euler[0] = cel->ref[0] - cel->ref[2]; cel->euler[1] = 180.0; } } else { x = (sthe0 - wcs_sind(latp)*slat0)/z; y = sphip*cthe0/clat0; if (x == 0.0 && y == 0.0) { return 1; } cel->euler[0] = cel->ref[0] - wcs_atan2d(y,x); } /* Make euler[0] the same sign as ref[0]. */ if (cel->ref[0] >= 0.0) { if (cel->euler[0] < 0.0) cel->euler[0] += 360.0; } else { if (cel->euler[0] > 0.0) cel->euler[0] -= 360.0; } } cel->euler[2] = cel->ref[2]; cel->euler[3] = wcs_cosd(cel->euler[1]); cel->euler[4] = wcs_sind(cel->euler[1]); cel->flag = CELSET; /* Check for ill-conditioned parameters. */ if (fabs(latp) > 90.0+tol) { return 2; } return 0; } /*--------------------------------------------------------------------------*/ int celfwd(pcode, lng, lat, cel, phi, theta, prj, x, y) const char pcode[4]; const double lng, lat; struct celprm *cel; double *phi, *theta; struct prjprm *prj; double *x, *y; { int err; if (cel->flag != CELSET) { if (celset(pcode, cel, prj)) return 1; } /* Compute native coordinates. */ sphfwd(lng, lat, cel->euler, phi, theta); /* Apply forward projection. */ if ((err = cel->prjfwd(*phi, *theta, prj, x, y))) { return err == 1 ? 2 : 3; } return 0; } /*--------------------------------------------------------------------------*/ int celrev(pcode, x, y, prj, phi, theta, cel, lng, lat) const char pcode[4]; const double x, y; struct prjprm *prj; double *phi, *theta; struct celprm *cel; double *lng, *lat; { int err; if (cel->flag != CELSET) { if(celset(pcode, cel, prj)) return 1; } /* Apply reverse projection. */ if ((err = cel->prjrev(x, y, prj, phi, theta))) { return err == 1 ? 2 : 3; } if (fabs(*phi)>180.0 || fabs(*theta)>90.0) return 2; /* Compute native coordinates. */ sphrev(*phi, *theta, cel->euler, lng, lat); return 0; }