source: Sophya/trunk/Cosmo/RadioBeam/srcat2cube.cc@ 3826

Last change on this file since 3826 was 3825, checked in by ansari, 15 years ago

modifs et ajout de programme pour traitement cartes GSM (Global Sky Model), Reza 02/08/2010
File size: 6.4 KB
RevLine 
[3785]1/* ------------------------ Projet BAORadio --------------------
2 Programme de fabrication d'un cube 3D (angles,fre)
3 a partir du catalogue de source radio (NVSS)
4 R. Ansari , C. Magneville - Juin 2010
5
6 Usage: srccat2cube CatalogFitsName Out3DPPFName [Out2DMapName]
7--------------------------------------------------------------- */
8
9#include "sopnamsp.h"
10#include "machdefs.h"
11#include <math.h>
12#include <iostream>
13#include <typeinfo>
14
15#include "array.h"
16#include "histats.h"
17
18#include "swfitsdtable.h"
19#include "fitshdtable.h"
20
21#include "randr48.h"
22
23#include "xastropack.h" // Pour faire les conversions de coordonnees celestes
24
25#include "radutil.h"
26
27// Pour l'initialisation des modules
28#include "tarrinit.h"
29#include "histinit.h"
30#include "fiosinit.h"
31
32#include "timing.h"
33#include "ctimer.h"
34
35#include "cubedef.h"
36
37//----------------------------------------------------------------------------
38//----------------------------------------------------------------------------
39int main(int narg, char* arg[])
40{
41 // Sophya modules initialization
42 TArrayInitiator _inia;
43 HiStatsInitiator _inih;
44 FitsIOServerInitiator _inif;
45 //------- AU LIEU DE ------> SophyaInit();
46
47 InitTim(); // Initializing the CPU timer
48 Timer tm("srcat2cube");
49
50 if (narg < 3) {
51 cout << "Usage: srccat2cube NVSS_CatalogFitsName Out3DPPFName [Out2DMapName]\n" << endl;
52 return 1;
53 }
54
55
56 // decodage arguments
57 string outname = arg[2];
58 string inname = arg[1];
59 int rc = 91;
60
61 cout << " ====== srccat2cube : Input NVSS catalog name= " << inname << " OutName=" << outname;
62 bool fginmap=true;
63 try {
64 DataTable nvss;
65 cout << "srccat2cube[1]: reading NVSS catalog from " << inname << endl;
66 {
67 FitsInOutFile fis(inname, FitsInOutFile::Fits_RO);
68 fis >> nvss;
69 }
70 cout << nvss;
71 sa_size_t idxa = nvss.IndexNom("C_RAJ2000");
72 sa_size_t idxd = nvss.IndexNom("C_DEJ2000");
73 sa_size_t idxf = nvss.IndexNom("S1_4");
[3825]74 sa_size_t idxmajax = nvss.IndexNom("MajAxis");
75 sa_size_t idxminax = nvss.IndexNom("MinAxis");
[3785]76
[3825]77 cout << " ... Index Alpha: " << idxa << " Delta: " << idxd << " Flux: " << idxf
78 << " MajAxis: " << idxmajax << " MajAxis: " << idxminax << endl;
79
[3785]80 TArray<r_4> omap(NPhi,NTheta);
81 double tet0 = Theta0Degre;
82 double phi0 = Phi0Degre;
83 double tetmax = tet0+ThetaSizeDegre;
84 double phimax = phi0+PhiSizeDegre;
85
86 cout << "srccat2cube[2]: projecting sources to map ..." << endl;
87
88 sa_size_t srccnt=0;
[3825]89 sa_size_t extendedsrccnt=0;
90
[3785]91 double meanflx=0.;
92 double flxmin=9.e99;
93 double flxmax=-9.e99;
94
95 double dtet = ThetaSizeDegre/(double)NTheta;
96 double dphi = PhiSizeDegre/(double)NPhi;
[3825]97 double mpixsizarcmin = 0.5*(dtet+dphi)*60.;
98
[3785]99 for (sa_size_t n=0; n<nvss.NRows(); n++) {
100 r_8* pline=nvss.GetLineD(n);
101 double alpha=pline[idxa]; // alpha en degre
102 double delta=pline[idxd]; // delta en degre
103 double flx=pline[idxf]*1.e-3; // flux en Jy
[3825]104 double srcszarcmin=0.5*(pline[idxmajax]+pline[idxminax])/60.; // taille (extension de la source en arcmin
105 if (srcszarcmin<1.) srcszarcmin=1.;
[3785]106 double tet = 90.-delta;
107 double phi = alpha;
108 sa_size_t i = (phi-phi0)/dphi;
109 sa_size_t j = (tet-tet0)/dtet;
110 if ((i<0)||(i>=omap.SizeX())) continue;
111 if ((j<0)||(j>=omap.SizeY())) continue;
[3825]112 double srat = (4.*srcszarcmin*srcszarcmin)/(mpixsizarcmin*mpixsizarcmin);
113 if (srcszarcmin<(0.5*mpixsizarcmin)) { // Toute l'energie dans un seul pixel
114 omap(i,j) += flx*srat;
115 }
116 else { // on repartit l'energie de la source dans plusieurs pixels
117 extendedsrccnt++;
118 for(int bi=-1;bi<=1;bi++) {
119 for(sa_size_t bj=-1; bj<=1; bj++) {
120 sa_size_t ii = (phi-phi0+bi*srcszarcmin/60.)/dphi;
121 sa_size_t jj = (tet-tet0+bj*srcszarcmin/60.)/dtet;
122 if ((ii<0)||(ii>=omap.SizeX())) continue;
123 if ((jj<0)||(jj>=omap.SizeY())) continue;
124 if ((bi==0)&&(bj==0)) omap(ii,jj) += flx*srat*0.3;
125 else omap(ii,jj) += flx*srat*0.7/8.;
126 }
127 }
128 }
[3785]129 srccnt++; meanflx+=flx;
130 if (flx<flxmin) flxmin=flx;
131 if (flx>flxmax) flxmax=flx;
132 }
133
134 cout << "srccat2cube[3]: Output rectangular map computed " << endl;
135 meanflx /= (double)srccnt;
[3825]136 cout << " SrcCount in map: " << srccnt << " extended=" << extendedsrccnt
137 << " -> meanFlx=" << meanflx << " min=" << flxmin
[3785]138 << " max=" << flxmax << " Jy" << endl;
139
140 double mean, sigma;
[3825]141 r_4 mintemp, maxtemp;
142 omap.MinMax(mintemp, maxtemp);
[3785]143 MeanSigma(omap, mean, sigma);
144 cout << " Src Map : Mean=" << mean << " Sigma=" << sigma << " Jy - Sizes:" << endl;
145 omap.Show();
146
147 H21Conversions conv;
148 conv.setRedshift(0.);
149 conv.setOmegaPixDeg2(dphi*dtet);
150 cout << "srccat2cube[4] H21Conversions, OmegaPix=" << conv.getOmegaPix() << " srad"
151 << " toKelvin(1 Jy)= " << conv.toKelvin(1.) << endl;
152 omap *= (r_4)conv.toKelvin(1.);
153 MeanSigma(omap, mean, sigma);
154 cout << " After conversion : Mean=" << mean << " Sigma=" << sigma << " Kelvin " << endl;
155
156 if (narg > 3) {
157 string ppfname = arg[3];
158 cout << " srccat2cube[4]: Saving inmap/outmap tp PPF file-> " << ppfname << endl;
159 POutPersist po(ppfname);
160 po << PPFNameTag("omap") << omap;
161 }
162
163 TArray<r_4> ocube(NPhi,NTheta,NFreq);
164
165 double infreq = 1420.; // frequence de reference du flux des sources
166 double freq0 = Freq0MHz; // Freq0 du cube de sortie
167 double dfreq = FreqSizeMHz/(double)NFreq;
168
169 ThSDR48RandGen rg;
170 for (sa_size_t j=0; j<ocube.SizeY(); j++) {
171 for (sa_size_t i=0; i<ocube.SizeX(); i++) {
172 double freqexpo = rg.Gaussian(sigPLidxSrc,PLidxSrc);
173 for (sa_size_t k=0; k<ocube.SizeZ(); k++) {
174 double rapfreq = pow((freq0+k*dfreq)/infreq, freqexpo);
175 ocube(i,j,k) = AmpPL1*omap(i,j)*rapfreq;
176 }
177 }
178 }
179
180 // On sauve le cube de sortie
181 {
182 cout << " srccat2cube[5]: Saving output cube to -> " << outname << endl;
183 POutPersist poc(outname);
184 poc << ocube;
185 }
186
187 rc = 0;
188 }
189 catch (PThrowable& exc) {
190 cerr << " srccat2cube.cc catched Exception " << exc.Msg() << endl;
191 rc = 77;
192 }
193 catch (std::exception& sex) {
194 cerr << "\n srccat2cube.cc std::exception :"
195 << (string)typeid(sex).name() << "\n msg= "
196 << sex.what() << endl;
197 }
198 catch (...) {
199 cerr << " srccat2cube.cc catched unknown (...) exception " << endl;
200 rc = 78;
201 }
202
203 cout << ">>>> srccat2cube[9] ------- FIN ----------- Rc=" << rc << endl;
204 return rc;
205}
206
207
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