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TestSources.cc@ 1153

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Last change on this file since 1153 was 1148, checked in by ansari, 25 years ago
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[1148]	1	// Dominique YVON, CEA/DAPNIA/SPP 02/2000
	2
	3	#include <stdio.h>
	4	#include <stdlib.h>
	5	#include <math.h>
	6	#include <iostream>
	7	#include <fstream>
	8	//#include <SIOUX.h>
	9
	10	#ifdef __MWERKS__
	11	#include "unixmac.h"
	12	#include "macenvvariables.h"
	13	#endif
	14
	15	#include "squarefilt.h"
	16
	17	#include "alllobe.h"
	18	#include "alllightsources.h"
	19	#include "sigcalctools.h"
	20
	21	#define NLatTestMap (256)
	22
	23	int CompareMapResults();
	24	int TestSommeMapsInBand(char file1[], long nlat);
	25
	26	int CompareMapResults()
	27	{
	28	cout<< "Test du fonctionnement par la comparaison systematique";
	29	cout<< " Avec les resultats de supertango"<<endl;
	30
	31
	32
	33	#ifndef __MWERKS__
	34	char* PATHResults=getenv("PATHResults");
	35	char* PATHDataLScr=getenv("PATHDataLScr");
	36	char* PATHCarteLobe=getenv("PATHCarteLobe");
	37	char* PATHSTangoRes=getenv("PATHSTangoRes");
	38	#endif
	39
	40	// double Min, Max, Moy, sigma;
	41	char filename [150];
	42
	43	sprintf(filename,"CarteCieltot_res0256.fits");
	44
	45	TestSommeMapsInBand(filename,NLatTestMap);
	46
	47	return 0;
	48	}
	49
	50	int TestSommeMapsInBand(char fileTotPower[], long nlat) // Pas fini Ne pas utiliser!
	51	{
	52	double Min, Max, Moy, sigma;
	53	char filename[150];
	54	// On lit les donnees brutes
	55	SphereHEALPix<r_4> PowerMap(nlat); // Pour se mettre a l'unite nW/m2/St
	56
	57	// Definition channel C
	58	LobeGaussien LobeGaussChanC(28.2/60.,30.e9,50.e09);
	59	// LobeConique ConeLobe(1.,10.e9,3000.e9); // pour des test simples
	60	SquareFilter FlatFilter(36.e9,44.e9); // Hz
	61
	62	// Test lobes
	63	// On somme les trois contributions intgres sur la bande passante
	64	/*
	65	// OK pour le synchrotron
	66	{ LightSynchro Synchro(nlat);
	67	SigCalcTool ChanCTool(&Synchro,&LobeGaussChanC,&FlatFilter);
	68	addInInBandPowerMap(PowerMap,ChanCTool); // OK pour le synchrotron
	69	}
	70
	71	// On ajoute la poussiere diffuse
	72	{ LightDiffDust DiffDust(nlat);
	73	SigCalcTool ChanCTool(&DiffDust,&LobeGaussChanC,&FlatFilter);
	74	addInInBandPowerMap(PowerMap,ChanCTool);
	75	}
	76
	77	// On ajoute le CMB
	78	{ LightCMBPrim CMB(nlat);
	79	SigCalcTool ChanCTool(&CMB,&LobeGaussChanC,&FlatFilter);
	80	addInInBandPowerMap(PowerMap,ChanCTool);
	81	}
	82
	83
	84	// On ajoute du bruit
	85	{ SphereHEALPix<r_4> NoiseChanCMap(nlat);
	86	sprintf(filename, "%schannelC_noise_res%04i.fits",PATHSTangoRes,nlat);
	87	FitsServer.load(NoiseChanCMap,filename);
	88	scaleMap(1.e-9,NoiseChanCMap); // Pour se mettre W/m2/St
	89	addMap(PowerMap,NoiseChanCMap);
	90	}
	91
	92	// Bilan carte sommee
	93	cout<<"Carte Totale"<<endl;
	94	MinMaxSigMap(PowerMap,Min,Max,Moy,sigma);
	95	cout <<"PowerMap: "<<"Min="<<Min<<" Max="<<Max;
	96	cout<<" Moy="<<Moy<<" sigma="<<sigma<<endl<<endl;
	97
	98	FitsServer.save(PowerMap,file1);
	99	*/
	100	/*
	101	// Test-Validation Ptotale si ca se passe bien
	102	{
	103	SphereHEALPix<r_4> ObsTotSTango(256);
	104	sprintf(filename, "%schannelC_obs_res0256.fits",PATHSTangoRes);
	105	FitsServer.load(ObsTotSTango,filename);
	106	scaleMap(1.e-9,ObsTotSTango); // Pour se mettre W/m2/St
	107
	108	MinMaxSigMap(ObsTotSTango,Min,Max,Moy,sigma);
	109	cout <<"ObsTotSTango W/m2/sr: "<<"Min="<<Min<<" Max="<<Max;
	110	cout<<" Moy="<<Moy<<" sigma="<<sigma<<endl<<endl;
	111
	112	divMap1WithMap2(PowerMap,ObsTotSTango);
	113	MinMaxSigMap(PowerMap,Min,Max,Moy,sigma);
	114	cout <<"Test: "<<"Min="<<Min<<" Max="<<Max;
	115	cout<<" Moy="<<Moy<<" sigma="<<sigma<<endl<<endl;
	116
	117	// On sauve la carte sur disque
	118	sprintf(filename,"SinusDivCieltot_res0256.fits");
	119	FitsServer.sinus_picture_projection(PowerMap,filename);
	120
	121	// On regarde la carte obtenue
	122	sprintf(filename,"SinusCieltot_res%04i.fits",nlat);
	123	FitsServer.sinus_picture_projection(PowerMap,filename);
	124	}
	125	*/
	126
	127	/*
	128	// On veut convoluer avec un lobe gaussien
	129	{
	130
	131	LightSrcMapPowerInband LightMapInCBand(fileTotPower,256,36.e9,44.e9);
	132	// On utilise une carte deja integree sur la reponse spectrale
	133	// Dont les bornes en frequence sont specifiees dans le constructeur
	134	// Pour la forme en coherence avec ChannelC
	135	// On utilse un lobe (large bande)
	136
	137
	138	// Voila l'outil
	139	SigCalcTool ChannelCtool(&LightMapInCBand,&LobeGaussChanC,&FlatFilter);
	140
	141	// La carte
	142	SphereHEALPix<r_4> ChannelCConvolue(nlat);
	143
	144	// On convolue
	145	addToSkyMap(ChannelCConvolue, ChannelCtool);
	146
	147	// On sauvegarde
	148	sprintf(filename,"ChannelConvolue%04i.fits",nlat);
	149	FitsServer.save(ChannelCConvolue, filename);
	150
	151	MinMaxSigMap(ChannelCConvolue,Min,Max,Moy,sigma);
	152	cout <<"ChannelCConvolue: "<<"Min="<<Min<<" Max="<<Max;
	153	cout<<" Moy="<<Moy<<" sigma="<<sigma<<endl<<endl;
	154
	155	// On regarde la carte obtenue
	156	sprintf(filename,"SinusCielCconvol%04i.fits",nlat);
	157	FitsServer.sinus_picture_projection(ChannelCConvolue,filename);
	158	}
	159	*/
	160
	161	/*
	162	{ // On Compare
	163	#ifndef __MWERKS__
	164	char* PATHSTangoRes=getenv("PATHSTangoRes");
	165	#endif
	166	SphereHEALPix<r_4> ObsConvolSTango(nlat);
	167	sprintf(filename, "%schannelC_convolved.fits",PATHSTangoRes);
	168	FitsServer.load(ObsConvolSTango,filename);
	169	// Unite nW/m2/St
	170
	171	// On met a la meme echelle
	172	LightSrcMapPowerInband LightMapInCBand(fileTotPower,256,36.e9,44.e9);
	173	SigCalcTool ChannelCtool(&LightMapInCBand,&LobeGaussChanC,&FlatFilter);
	174	double lobeSize=ChannelCtool.CalcLobeSize(); //Steradian
	175	double scaleFactor= 1.e-9 * lobeSize; // Pour se mettre W/m2
	176	scaleMap(scaleFactor,ObsConvolSTango);
	177
	178	MinMaxSigMap(ObsConvolSTango,Min,Max,Moy,sigma);
	179	cout <<"ObsConvolSTango W/m2/sr: "<<"Min="<<Min<<" Max="<<Max;
	180	cout<<" Moy="<<Moy<<" sigma="<<sigma<<endl<<endl;
	181
	182	SphereHEALPix<r_4> ChannelCConvolue(nlat);
	183	sprintf(filename,"ChannelConvolue%04i.fits",nlat);
	184	FitsServer.load(ChannelCConvolue,filename);
	185
	186	MinMaxSigMap(ChannelCConvolue,Min,Max,Moy,sigma);
	187	cout <<"ChannelCConvolue W/m2/sr: "<<"Min="<<Min<<" Max="<<Max;
	188	cout<<" Moy="<<Moy<<" sigma="<<sigma<<endl<<endl;
	189
	190	// On divise
	191	divMap1WithMap2(ChannelCConvolue,ObsConvolSTango);
	192	MinMaxSigMap(ChannelCConvolue,Min,Max,Moy,sigma);
	193	cout <<"Test: "<<"Min="<<Min<<" Max="<<Max;
	194	cout<<" Moy="<<Moy<<" sigma="<<sigma<<endl<<endl;
	195
	196	// On sauvegarde la carte
	197	sprintf(filename,"SinusConvolDiv%04i.fits",nlat);
	198	FitsServer.sinus_picture_projection(ChannelCConvolue,filename);
	199	}
	200	*/
	201	return 0;
	202	}
	203
	204
	205
	206	/*
	207	// On lit les templates pour voir
	208	sprintf(filename, "%sdust_res0256.fits",PATHDataLScr);
	209	FitsServer.load(DiffDustMap,filename);
	210	MinMaxSigMap(DiffDustMap,Min,Max,Moy,sigma);
	211	flog<<"DiffDustMap: "<<"Min="<<Min<<" Max="<<Max;
	212	flog<<" Moy="<<Moy<<" sigma="<<sigma<<endl<<endl;
	213
	214	*/
	215	/*
	216	sprintf(filename, "%ssync_res0256.fits",PATHDataLScr);
	217	FitsServer.load(SynchroMap,filename);
	218	MinMaxSigMap(SynchroMap,Min,Max,Moy,sigma);
	219	flog<<"SynchroMap: "<<"Min="<<Min<<" Max="<<Max;
	220	flog<<" Moy="<<Moy<<" sigma="<<sigma<<endl<<endl;
	221	*/
	222
	223	/*
	224	sprintf(filename, "%scmb_res0256.fits",PATHDataLScr);
	225	FitsServer.load(CMBPrimMap,filename);
	226	MinMaxSigMap(CMBPrimMap,Min,Max,Moy,sigma);
	227	flog<<"CMBPrimMap: "<<"Min="<<Min<<" Max="<<Max;
	228	flog<<" Moy="<<Moy<<" sigma="<<sigma<<endl<<endl;
	229	*/
	230
	231	/*
	232	// Test Module synchrotron
	233	SphereHEALPix<r_4> ChanCSynchro(256);
	234	SphereHEALPix<r_4> MYCSynchro(256);
	235
	236
	237	// Sans lobes d'abord
	238	// Lecture resultats de supertango
	239	sprintf(filename, "%schannelC_sync_res0256.fits",PATHSTangoRes);
	240	FitsServer.load(ChanCSynchro,filename);
	241	MinMaxSigMap(ChanCSynchro,Min,Max,Moy,sigma);
	242	flog<<"ChanCSynchro: "<<"Min="<<Min<<" Max="<<Max;
	243	flog<<" Moy="<<Moy<<" sigma="<<sigma<<endl;
	244
	245	// Calcul SigPred
	246	LightSynchro Synchro(256);
	247	SigCalcTool ChanCTool(&Synchro,&ConeLobe,&FlatFilter);
	248	//ChanCTool.SetLightScr(&Synchro);
	249
	250	addInBandPower(MYCSynchro,ChanCTool);
	251	scaleMap(1.e9,MYCSynchro); // Pour se mettre a l'unite nW/m2/St
	252	MinMaxSigMap(MYCSynchro,Min,Max,Moy,sigma);
	253	flog<<"MYCSynchro: "<<"Min="<<Min<<" Max="<<Max;
	254	flog<<" Moy="<<Moy<<" sigma="<<sigma<<endl;
	255	*/
	256	// Validation
	257	/* //substractMap(MYCSynchro,ChanCSynchro);
	258	divMap1WithMap2(MYCSynchro,ChanCSynchro);
	259	MinMaxSigMap(MYCSynchro,Min,Max,Moy,sigma);
	260	flog<<"Division des cartes: "<<"Min="<<Min<<" Max="<<Max;
	261	flog<<" Moy="<<Moy<<" sigma="<<sigma<<endl;
	262	*/
	263	/* // test
	264	divMap1WithMap2(MYCSynchro,SynchroMap);
	265	MinMaxSigMap(MYCSynchro,Min,Max,Moy,sigma);
	266	flog<<"MycoeffIntegrale MYCSynchro: "<<"Min="<<Min<<" Max="<<Max;
	267	flog<<" Moy="<<Moy<<" sigma="<<sigma<<endl;
	268
	269	divMap1WithMap2(ChanCSynchro,SynchroMap);
	270	MinMaxSigMap(ChanCSynchro,Min,Max,Moy,sigma);
	271	flog<<"STangoCoeffIntegrale ChanCSynchro: "<<"Min="<<Min<<" Max="<<Max;
	272	flog<<" Moy="<<Moy<<" sigma="<<sigma<<endl;
	273
	274	*/
	275
	276	/*
	277	// Test Module CMB
	278	SphereHEALPix<r_4> ChanCCMB(256);
	279	SphereHEALPix<r_4> MYCCMB(256);
	280
	281	// Sans lobes d'abord: Integrale sur les dependances spectrales
	282	//degrs, freqmin, Freqmax
	283	LightCMBPrim CMB(256);
	284	SigCalcTool ChanCTool(&CMB,&ConeLobe,&FlatFilter);
	285
	286	// Lecture resultats de supertango
	287	sprintf(filename,"%schannelC_cmb_res0256.fits",PATHSTangoRes);
	288	FitsServer.load(ChanCCMB,filename);
	289	MinMaxSigMap(ChanCCMB,Min,Max,Moy,sigma);
	290	flog<<"ChanCCMB: "<<"Min="<<Min<<" Max="<<Max;
	291	flog<<" Moy="<<Moy<<" sigma="<<sigma<<endl;
	292	*/
	293	/* // Calcul SigPred
	294	addInBandPower(MYCCMB,ChanCTool);
	295	scaleMap(1.e9,MYCCMB); // Pour se mettre a l'unite nW/m2/St
	296	MinMaxSigMap(MYCCMB,Min,Max,Moy,sigma);
	297	flog<<"MYCCMB: "<<"Min="<<Min<<" Max="<<Max;
	298	flog<<" Moy="<<Moy<<" sigma="<<sigma<<endl;
	299	*/
	300	// Validation
	301
	302	/* // test
	303	divMap1WithMap2(MYCCMB,CMBPrimMap);
	304	MinMaxSigMap(MYCCMB,Min,Max,Moy,sigma);
	305	flog<<" MycoeffIntegrale MYCCMB: "<<"Min="<<Min<<" Max="<<Max;
	306	flog<<" Moy="<<Moy<<" sigma="<<sigma<<endl;
	307
	308	divMap1WithMap2(ChanCCMB,CMBPrimMap);
	309	MinMaxSigMap(ChanCCMB,Min,Max,Moy,sigma);
	310	flog<<"STangoCoeffIntegrale ChanCCMB: "<<"Min="<<Min<<" Max="<<Max;
	311	flog<<" Moy="<<Moy<<" sigma="<<sigma<<endl<<endl;
	312	*/
	313
	314	/*
	315	// Sans lobes d'abord: Integrale sur les dependances spectrales
	316	//degrs, freqmin, Freqmax
	317	LightDiffDust DiffDust(256);
	318	SigCalcTool ChanCTool(&DiffDust,&ConeLobe,&FlatFilter);
	319
	320	// Test Module poussire diffuse
	321	SphereHEALPix<r_4> ChanCDiffDust(256);
	322	SphereHEALPix<r_4> MYCDiffDust(256);
	323
	324
	325	// Lecture resultats de supertango
	326	sprintf(filename,"%schannelC_dust_res0256.fits",PATHSTangoRes);
	327	FitsServer.load(ChanCDiffDust,filename);
	328	MinMaxSigMap(ChanCDiffDust,Min,Max,Moy,sigma);
	329	flog<<"ChanCDiffDust: "<<"Min="<<Min<<" Max="<<Max;
	330	flog<<" Moy="<<Moy<<" sigma="<<sigma<<endl;
	331	*/
	332
	333	/* // Calcul SigPred
	334	addInBandPower(MYCDiffDust,ChanCTool);
	335	scaleMap(1.e9,MYCDiffDust); // Pour se mettre a l'unite nW/m2/St
	336	MinMaxSigMap(MYCDiffDust,Min,Max,Moy,sigma);
	337	flog<<"MYCDiffDust: "<<"Min="<<Min<<" Max="<<Max;
	338	flog<<" Moy="<<Moy<<" sigma="<<sigma<<endl;
	339	*/
	340	// Validation
	341
	342	/* // test
	343	divMap1WithMap2(MYCDiffDust,DiffDustMap);
	344	MinMaxSigMap(MYCDiffDust,Min,Max,Moy,sigma);
	345	flog<<"MycoeffIntegrale MYCDiffDust: "<<"Min="<<Min<<" Max="<<Max;
	346	flog<<" Moy="<<Moy<<" sigma="<<sigma<<endl;
	347
	348	divMap1WithMap2(ChanCDiffDust,DiffDustMap);
	349	MinMaxSigMap(ChanCDiffDust,Min,Max,Moy,sigma);
	350	flog<<"STangoCoeffIntegrale ChanCDiffDust: "<<"Min="<<Min<<" Max="<<Max;
	351	flog<<" Moy="<<Moy<<" sigma="<<sigma<<endl<<endl;
	352	*/
	353
	354
	355	int Basictests()
	356	{
	357	// MakeTrap99Timeline();
	358	// cerr.setf(ios::scientific);
	359	cerr<< "C'est parti"<<endl;
	360
	361
	362
	363	SphereHEALPix<r_4>* pTestMap;
	364	pTestMap= new SphereHEALPix<r_4>(64);
	365	SphereHEALPix<r_4>& TestMap=(*pTestMap);
	366
	367	#ifndef __MWERKS__
	368	char* PATHResults=getenv("PATHResults");
	369	char* PATHDataLScr=getenv("PATHDataLScr");
	370	char* PATHCarteLobe=getenv("PATHCarteLobe");
	371	#endif
	372
	373	//_________________ Test implementation des lobes ___________________
	374	LobeGaussien GaussLobe(0.3,75.e9,125.e9); //degrs, freqmin, Freqmax
	375	LobeConique ConeLobe(1.,75.e9,125.e9);
	376	Lobe4PiGaussien Lobe4Pi1(1.,75.e9,125.e9);
	377
	378	// Test de la classe Cartelobe
	379	char lobeFileNameRoot[150];
	380	sprintf(lobeFileNameRoot, "%sdetector100_1_cf",PATHCarteLobe);
	381	char LobeFitsFile[150];
	382	sprintf(LobeFitsFile, "%sCarteLobe100GHz_1_cf.fits",PATHResults);
	383
	384
	385	// Test LobeCartoMoyen ___________________________________________
	386	// CarteLobe CarteLobe100GHzCF(lobeFileNameRoot,100.e9); // Hz
	387	// LobeCartoMoyen LobeCartoTest(&CarteLobe100GHzCF,75.e9,125.e9);
	388
	389	// Un filtre bete........
	390	SquareFilter FlatFilter(85.e9, 115.e9); // Hz
	391
	392	cout<<"param specifiques a BoloFilterFlat"<<endl;
	393	cout<<"mean: "<< FlatFilter.meanFreq()<<"/tPeakTransmission: "<<
	394	FlatFilter.transmission(FlatFilter.meanFreq())<<flush;
	395	cout<<"Width: "<<FlatFilter.maxFreq()-FlatFilter.minFreq()<<endl;
	396	/*
	397	cout<<" Lobe conique:"<<endl;
	398	cout<<" Nlat gorsky: "<<LobeCartoTest.gorskyNlatFromRes();
	399	cout<<" Resolution du lobe: "<<LobeCartoTest.lobeResol();
	400	cout<<" Radian" <<endl;
	401	*/
	402	char FileSinus[150];
	403
	404	// Du plus simple au plus compliqu
	405	/*
	406	// Dipole
	407	LightDipole Dipole;
	408	SigCalcTool DipoleTool(&Dipole,&ConeLobe,&FlatFilter);
	409	// SigCalcTool DipoleTool(&Dipole,&GaussLobe,&FlatFilter);
	410	compSkyMap(TestMap,DipoleTool);
	411	sprintf(FileSinus,"%sMapSinus_Dipole.fits",PATHResults);
	412	FitsServer.sinus_picture_projection(TestMap,FileSinus);
	413
	414	double MaxDipole=0;
	415	for (long i=0; i<TestMap.NbPixels(); i++)
	416	if(TestMap(i)>MaxDipole) MaxDipole=TestMap(i);
	417	cout<<"Maximum du dipole: "<<MaxDipole<<endl;
	418	*/
	419	/*
	420	// Quadrupole
	421	LightQuadrupole Quadrupole;
	422	SigCalcTool QuadTool(&Quadrupole,&ConeLobe,&FlatFilter);
	423	compSkyMap(TestMap,QuadTool);
	424	sprintf(FileSinus,"%sMapSinus_quadrupole.fits",PATHResults);
	425	FitsServer.sinus_picture_projection(TestMap,FileSinus);
	426
	427	// Total des contributions du dipole
	428	addToSkyMap(TestMap,DipoleTool);
	429	sprintf(FileSinus, "%sMapSinus_Dip_Quad.fits",PATHResults);
	430	FitsServer.sinus_picture_projection(TestMap,FileSinus);
	431	*/
	432
	433	/* // Effet du soleil
	434	double SunAngsize = 4.833e-3; // Radian;
	435	// double SunAngsize = 4.833e-2; // Debug
	436	QuasiPtSources Sun(5800.,SunAngsize,M_PI/2.,M_PI);
	437	SigCalcTool SunTool(&Sun,&GaussLobe,&FlatFilter);
	438	//SigCalcTool SunTool(&Sun,&ConeLobe,&FlatFilter);
	439	compSkyMap(TestMap,SunTool);
	440
	441	// sprintf(FileSinus,"%sSphereGorsky_Soleil.fits",PATHResults);
	442	// FitsServer.save(TestMap, FileSinus);
	443
	444	sprintf(FileSinus,"%sMapSinus_Soleil.fits",PATHResults);
	445	FitsServer.sinus_picture_projection(TestMap,FileSinus);
	446
	447	double MaxSun=0.;
	448	for (long i=0; i<TestMap.NbPixels(); i++)
	449	if(TestMap(i)>MaxSun) MaxSun=TestMap(i);
	450	cout<<"Maximum du soleil: "<<MaxSun<<endl;
	451	*/
	452
	453	/*
	454	// Fluctuation primordiales
	455	LightCMBPrim CMBFlucLight(256,1.e-5);
	456	SigCalcTool CMBGraalTool(&CMBFlucLight,&ConeLobe,&FlatFilter);
	457	compSkyMap(TestMap,CMBGraalTool);
	458	sprintf(FileSinus,"%sMapSinus_CMBPrimordial.fits",PATHResults);
	459	FitsServer.sinus_picture_projection(TestMap,FileSinus);
	460	*/
	461
	462	/*
	463	// Carte synchrotron
	464	LightSynchro Synchro(256);
	465	SigCalcTool SynchroTool(&Synchro,&ConeLobe,&FlatFilter);
	466	compSkyMap(TestMap,SynchroTool);
	467
	468	sprintf(FileSinus,"%sMapSinus_Synchro.fits",PATHResults);
	469	FitsServer.sinus_picture_projection(TestMap,FileSinus);
	470	*/
	471
	472	/*
	473	// Diffuse Dust
	474	LightDiffDust DiffDust(256);
	475	SigCalcTool DiffDustTool(&DiffDust,&ConeLobe,&FlatFilter);
	476	compSkyMap(TestMap,DiffDustTool);
	477	sprintf(FileSinus,"%sMapSinus_DiffDust.fits",PATHResults);
	478	FitsServer.sinus_picture_projection(TestMap,FileSinus);
	479
	480	*/
	481
	482	/*
	483	LightGalaxResol Galaxresol(128);
	484	SigCalcTool GalacResolTool(&Galaxresol,&ConeLobe,&FlatFilter);
	485	compSkyMap(TestMap,GalacResolTool);
	486	sprintf(FileSinus,"%sMapSinus_GalaxResol.fits",PATHResults);
	487	FitsServer.sinus_picture_projection(TestMap,FileSinus);
	488	*/
	489
	490	/*
	491	// Fond galactique non resolues
	492	LightGalaxNoResol GalaxNoresol(128);
	493	SigCalcTool GalacNoResolTool(&GalaxNoresol,&ConeLobe,&FlatFilter);
	494	compSkyMap(TestMap,GalacNoResolTool);
	495	sprintf(FileSinus,"%sMapSinus_GalaxNOResol.fits",PATHResults);
	496	FitsServer.sinus_picture_projection(TestMap,FileSinus);
	497
	498	*/
	499
	500	return 0;
[798]	501	}

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