void iauAticqn(double ri, double di, iauASTROM *astrom, int n, iauLDBODY b[], double *rc, double *dc) /* ** - - - - - - - - - ** i a u A t i c q n ** - - - - - - - - - ** ** Quick CIRS to ICRS astrometric place transformation, given the star- ** independent astrometry parameters plus a list of light-deflecting ** bodies. ** ** Use of this function is appropriate when efficiency is important and ** where many star positions are all to be transformed for one date. ** The star-independent astrometry parameters can be obtained by ** calling one of the functions iauApci[13], iauApcg[13], iauApco[13] ** or iauApcs[13]. * * If the only light-deflecting body to be taken into account is the * Sun, the iauAticq function can be used instead. ** ** This function is part of the International Astronomical Union's ** SOFA (Standards of Fundamental Astronomy) software collection. ** ** Status: support function. ** ** Given: ** ri,di double CIRS RA,Dec (radians) ** astrom iauASTROM* star-independent astrometry parameters: ** pmt double PM time interval (SSB, Julian years) ** eb double[3] SSB to observer (vector, au) ** eh double[3] Sun to observer (unit vector) ** em double distance from Sun to observer (au) ** v double[3] barycentric observer velocity (vector, c) ** bm1 double sqrt(1-|v|^2): reciprocal of Lorenz factor ** bpn double[3][3] bias-precession-nutation matrix ** along double longitude + s' (radians) ** xpl double polar motion xp wrt local meridian (radians) ** ypl double polar motion yp wrt local meridian (radians) ** sphi double sine of geodetic latitude ** cphi double cosine of geodetic latitude ** diurab double magnitude of diurnal aberration vector ** eral double "local" Earth rotation angle (radians) ** refa double refraction constant A (radians) ** refb double refraction constant B (radians) ** n int number of bodies (Note 3) ** b iauLDBODY[n] data for each of the n bodies (Notes 3,4): ** bm double mass of the body (solar masses, Note 5) ** dl double deflection limiter (Note 6) ** pv [2][3] barycentric PV of the body (au, au/day) ** ** Returned: ** rc,dc double ICRS astrometric RA,Dec (radians) ** ** Notes: ** ** 1) Iterative techniques are used for the aberration and light ** deflection corrections so that the functions iauAticqn and ** iauAtciqn are accurate inverses; even at the edge of the Sun's ** disk the discrepancy is only about 1 nanoarcsecond. ** ** 2) If the only light-deflecting body to be taken into account is the ** Sun, the iauAticq function can be used instead. ** ** 3) The struct b contains n entries, one for each body to be ** considered. If n = 0, no gravitational light deflection will be ** applied, not even for the Sun. ** ** 4) The struct b should include an entry for the Sun as well as for ** any planet or other body to be taken into account. The entries ** should be in the order in which the light passes the body. ** ** 5) In the entry in the b struct for body i, the mass parameter ** b[i].bm can, as required, be adjusted in order to allow for such ** effects as quadrupole field. ** ** 6) The deflection limiter parameter b[i].dl is phi^2/2, where phi is ** the angular separation (in radians) between star and body at ** which limiting is applied. As phi shrinks below the chosen ** threshold, the deflection is artificially reduced, reaching zero ** for phi = 0. Example values suitable for a terrestrial ** observer, together with masses, are as follows: ** ** body i b[i].bm b[i].dl ** ** Sun 1.0 6e-6 ** Jupiter 0.00095435 3e-9 ** Saturn 0.00028574 3e-10 ** ** 7) For efficiency, validation of the contents of the b array is ** omitted. The supplied masses must be greater than zero, the ** position and velocity vectors must be right, and the deflection ** limiter greater than zero. ** ** Called: ** iauS2c spherical coordinates to unit vector ** iauTrxp product of transpose of r-matrix and p-vector ** iauZp zero p-vector ** iauAb stellar aberration ** iauLdn light deflection by n bodies ** iauC2s p-vector to spherical ** iauAnp normalize angle into range +/- pi ** ** This revision: 2013 October 9 ** ** SOFA release 2015-02-09 ** ** Copyright (C) 2015 IAU SOFA Board. See notes at end. */ { int j, i; double pi[3], ppr[3], pnat[3], pco[3], w, d[3], before[3], r2, r, after[3]; /* CIRS RA,Dec to Cartesian. */ iauS2c(ri, di, pi); /* Bias-precession-nutation, giving GCRS proper direction. */ iauTrxp(astrom->bpn, pi, ppr); /* Aberration, giving GCRS natural direction. */ iauZp(d); for (j = 0; j < 2; j++) { r2 = 0.0; for (i = 0; i < 3; i++) { w = ppr[i] - d[i]; before[i] = w; r2 += w*w; } r = sqrt(r2); for (i = 0; i < 3; i++) { before[i] /= r; } iauAb(before, astrom->v, astrom->em, astrom->bm1, after); r2 = 0.0; for (i = 0; i < 3; i++) { d[i] = after[i] - before[i]; w = ppr[i] - d[i]; pnat[i] = w; r2 += w*w; } r = sqrt(r2); for (i = 0; i < 3; i++) { pnat[i] /= r; } } /* Light deflection, giving BCRS coordinate direction. */ iauZp(d); for (j = 0; j < 5; j++) { r2 = 0.0; for (i = 0; i < 3; i++) { w = pnat[i] - d[i]; before[i] = w; r2 += w*w; } r = sqrt(r2); for (i = 0; i < 3; i++) { before[i] /= r; } iauLdn(n, b, astrom->eb, before, after); r2 = 0.0; for (i = 0; i < 3; i++) { d[i] = after[i] - before[i]; w = pnat[i] - d[i]; pco[i] = w; r2 += w*w; } r = sqrt(r2); for (i = 0; i < 3; i++) { pco[i] /= r; } } /* ICRS astrometric RA,Dec. */ iauC2s(pco, &w, dc); *rc = iauAnp(w); /* Finished. */ /*---------------------------------------------------------------------- ** ** Copyright (C) 2015 ** Standards Of Fundamental Astronomy Board ** of the International Astronomical Union. ** ** ===================== ** SOFA Software License ** ===================== ** ** NOTICE TO USER: ** ** BY USING THIS SOFTWARE YOU ACCEPT THE FOLLOWING SIX TERMS AND ** CONDITIONS WHICH APPLY TO ITS USE. ** ** 1. The Software is owned by the IAU SOFA Board ("SOFA"). ** ** 2. Permission is granted to anyone to use the SOFA software for any ** purpose, including commercial applications, free of charge and ** without payment of royalties, subject to the conditions and ** restrictions listed below. ** ** 3. You (the user) may copy and distribute SOFA source code to others, ** and use and adapt its code and algorithms in your own software, ** on a world-wide, royalty-free basis. That portion of your ** distribution that does not consist of intact and unchanged copies ** of SOFA source code files is a "derived work" that must comply ** with the following requirements: ** ** a) Your work shall be marked or carry a statement that it ** (i) uses routines and computations derived by you from ** software provided by SOFA under license to you; and ** (ii) does not itself constitute software provided by and/or ** endorsed by SOFA. ** ** b) The source code of your derived work must contain descriptions ** of how the derived work is based upon, contains and/or differs ** from the original SOFA software. ** ** c) The names of all routines in your derived work shall not ** include the prefix "iau" or "sofa" or trivial modifications ** thereof such as changes of case. ** ** d) The origin of the SOFA components of your derived work must ** not be misrepresented; you must not claim that you wrote the ** original software, nor file a patent application for SOFA ** software or algorithms embedded in the SOFA software. ** ** e) These requirements must be reproduced intact in any source ** distribution and shall apply to anyone to whom you have ** granted a further right to modify the source code of your ** derived work. ** ** Note that, as originally distributed, the SOFA software is ** intended to be a definitive implementation of the IAU standards, ** and consequently third-party modifications are discouraged. All ** variations, no matter how minor, must be explicitly marked as ** such, as explained above. ** ** 4. You shall not cause the SOFA software to be brought into ** disrepute, either by misuse, or use for inappropriate tasks, or ** by inappropriate modification. ** ** 5. The SOFA software is provided "as is" and SOFA makes no warranty ** as to its use or performance. SOFA does not and cannot warrant ** the performance or results which the user may obtain by using the ** SOFA software. SOFA makes no warranties, express or implied, as ** to non-infringement of third party rights, merchantability, or ** fitness for any particular purpose. In no event will SOFA be ** liable to the user for any consequential, incidental, or special ** damages, including any lost profits or lost savings, even if a ** SOFA representative has been advised of such damages, or for any ** claim by any third party. ** ** 6. The provision of any version of the SOFA software under the terms ** and conditions specified herein does not imply that future ** versions will also be made available under the same terms and ** conditions. * ** In any published work or commercial product which uses the SOFA ** software directly, acknowledgement (see www.iausofa.org) is ** appreciated. ** ** Correspondence concerning SOFA software should be addressed as ** follows: ** ** By email: [email protected] ** By post: IAU SOFA Center ** HM Nautical Almanac Office ** UK Hydrographic Office ** Admiralty Way, Taunton ** Somerset, TA1 2DN ** United Kingdom ** **--------------------------------------------------------------------*/ }
void mexFunction(int nlhs, mxArray *plhs[], int nrhs, const mxArray *prhs[]) { size_t numSource, numBodies, baseIdx,curBody,curSource; double *vObsSource,posObs[3], *MSolar, *xBody, *deflecLimit; iauLDBODY *bodyParam; mxArray *vDeflMATLAB; double *vDefl; if(nrhs<4||nrhs>5) { mexErrMsgTxt("Incorrect number of inputs."); return; } if(nlhs>1) { mexErrMsgTxt("Wrong number of outputs."); return; } //Check the inputs checkRealDoubleArray(prhs[0]); checkRealDoubleArray(prhs[1]); checkRealDoubleArray(prhs[2]); //Check the inputs numSource=mxGetN(prhs[0]); if(mxGetM(prhs[0])!=3||numSource==0) { mexErrMsgTxt("The input vObsSource has the wrong dimensionality."); } if(mxGetM(prhs[1])!=3||mxGetN(prhs[1])!=1) { mexErrMsgTxt("The input posObs has the wrong dimensionality."); } numBodies=mxGetM(prhs[2]); if(numBodies==0||mxGetN(prhs[2])!=1) { mexErrMsgTxt("The input MSolar has the wrong dimensionality."); } if(mxGetM(prhs[3])!=6||mxGetN(prhs[2])!=numBodies) { mexErrMsgTxt("The input xBody has the wrong dimensionality."); } if(nrhs>3) { checkRealDoubleArray(prhs[4]); if(mxGetM(prhs[4])!=numBodies||mxGetN(prhs[4])!=1) { mexErrMsgTxt("The input deflecLimit has the wrong dimensionality."); } } else { deflecLimit=NULL; } vObsSource=(double*)mxGetData(prhs[0]); //Get the observer position and convert from meters to AU. { double *temp=(double*)mxGetData(prhs[1]); posObs[0]=temp[0]/DAU; posObs[1]=temp[1]/DAU; posObs[2]=temp[2]/DAU; } MSolar=(double*)mxGetData(prhs[2]); //The units have to be converted to AU and AU/Day xBody=(double*)mxGetData(prhs[3]); //Allocate space to hold the parameters of the astronomical bodies in a //manner suitable for the iauLdn function. bodyParam=(iauLDBODY*)mxMalloc(sizeof(iauLDBODY)*numBodies); baseIdx=0; for(curBody=0;curBody<numBodies;curBody++) { int i; bodyParam[curBody].bm=MSolar[curBody]; if(deflecLimit!=NULL) { bodyParam[curBody].dl=deflecLimit[curBody]; } else { //A value suitably small for Saturn. bodyParam[curBody].dl=3e-10; } //Position for(i=0;i<3;i++) { //The division converts from meters to AU. bodyParam[curBody].pv[0][i]=xBody[baseIdx+i]/DAU; } //Velocity for(i=0;i<3;i++) { //Convert from meters per second BCRS to AU/ day. bodyParam[curBody].pv[1][i]=xBody[3+baseIdx+i]*(1/DAU)*(1/DAYSEC); } baseIdx+=6; } //Allocate space for the return values. vDeflMATLAB=mxCreateDoubleMatrix(3,numSource,mxREAL); vDefl=(double*)mxGetData(vDeflMATLAB); baseIdx=0; for(curSource=0;curSource<numSource;curSource++) { double vecMag, sc[3];//Unit vector to the source //Get a unit direction vector and magnitude to the current source. iauPn(vObsSource+baseIdx, &vecMag, sc); iauLdn(numBodies, bodyParam, posObs, sc,vDefl+baseIdx); //Deal with possibly non-unit magnitudes on the input. vDefl[baseIdx]*=vecMag; vDefl[baseIdx+1]*=vecMag; vDefl[baseIdx+2]*=vecMag; baseIdx+=3; } //Free temporary memory; set the return value. mxFree(bodyParam); plhs[0]=vDeflMATLAB; }