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treccyl.cc@ 3356

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Last change on this file since 3356 was 3192, checked in by legoff, 19 years ago

input file read with DVcards by treccyl.cc

and by multiCylinders(char* filename)

using real units (meter and GHz)
using _ for member variables (e.g. x_)

File size: 9.9 KB

Rev	Line
[3160]	1	#include "sopnamsp.h"
	2	#include "machdefs.h"
	3	#include <math.h>
	4	#include <iostream>
	5	#include <typeinfo>
	6
	7	#include "tvector.h"
	8	#include "srandgen.h"
	9	#include "fioarr.h"
	10	#include "sopemtx.h"
	11	#include "pexceptions.h"
	12	#include "matharr.h"
	13
	14	#include "sambainit.h"
	15
	16	// #include "tarrinit.h"
	17
	18	#include "timing.h"
[3192]	19	#include "datacards.h"
	20	#include <dvlist.h>
[3160]	21
	22	#include "multicyl.h"
	23	#include "mbeamcyl.h"
[3192]	24	#define LENGTH 1024
[3160]	25
[3165]	26	/*
	27	Projet BAORadio / HSHS
	28	Programme de simulation pour reconstruction de lobe radio.
	29	programme principal de test
[3160]	30
[3165]	31	R. Ansari - LAL Jan 2007
	32
	33	*/
	34
[3160]	35	// Declaration des fonctions de ce fichier
	36	static int test1cyl(string& ppfname);
[3192]	37	static int testmulticyl(string& ppfname);
	38	int ReadParam(char* fileName);
[3160]	39
	40	//-----------------------------------------------------------
	41	// -------------- Parametres de simulation -----------------
	42	//-----------------------------------------------------------
[3192]	43	static double tClock = 2.; // should come from param file !!!!
	44	static double cLight=0.3; // in 1E9 m/s
	45	//static double tClock = 1.; // should come from param file !!!!
	46	//static double cLight=1.; // in 1E9 m/s
	47	//
[3160]	48	static int MR = 256; // Nombre de recepteur
[3192]	49	static int NE = 64; // Nombre d'echantillon en temps;
[3160]	50	static double freq0 = 2.; // frequence de base
	51	static double da = 0.25; // pas des antennes le long du cylindre
[3165]	52	// ATTENTION : les parametres suivants sont relies a MR/da
	53	static double maxangX = M_PI/3.; // angle max en X ( +/- )
	54	static double maxangY = M_PI/60.; // angle max en Y ( +/- )
[3192]	55	static int halfNY;
	56	static int NX;
[3165]	57	static int nsrcmax = 50; // Nb total de sources - en un plan
	58
[3164]	59	static double snoise = 1.0; // sigma du bruit
	60	static double tjit = 0.05; // sigma du jitter en temps
	61	static double tos = 0.02; // sigma des offsets en temps
[3160]	62	static double gmean = 1.; // gain moyen
	63	static double gsig = 0.; // sigma des gains
	64	static int nantgz = 0; // nb d'antennes morts (-> gain=0)
	65	static int prtlevel = 0; // niveau de print
[3192]	66
	67	static int nCyl;
	68	static double xCyl[1000];
	69	static double yCyl[1000];
[3160]	70	//-----------------------------------------------------------
	71
	72
	73	/* --------------------------------------------------------
	74	Le main programme de test des classes de reconstruction
	75	multilobe radio - R. Ansari , Sep06 -- 2007
	76	--------------------------------------------------------- */
	77
	78	int main(int narg, char* arg[])
	79	{
	80
[3192]	81	SophyaInit();
	82	InitTim(); // Initializing the CPU timer
	83	ReadParam("telescope.in");
	84	cout <<"MR="<< MR <<" NE="<<NE<<" freq0="<<freq0<<" "<<da<<" "<<maxangX <<endl;
	85	cout << maxangY<<" "<<nsrcmax <<" "<< snoise<<" "<< tjit<<" "<< tos<<" "<<gmean <<endl;
	86	cout << gsig<<" "<<nantgz <<" "<< prtlevel<<endl;
	87	// return 1;
[3160]	88
[3192]	89	string ppfname = "treccyl.ppf";
	90	int act = 1;
	91	// int ncyl = 5;
	92	if (narg < 2) {
	93	cout << "Usage: treccyl act ppfname \n"
	94	<< " -act= X ou XY \n"
[3165]	95	<< " -ppfname= treccyl.ppf par defaut" << endl;
[3192]	96	return 1;
	97	}
	98	if (strcmp(arg[1],"XY") == 0) { act = 2 ;}
	99	if (narg > 2) ppfname = arg[2];
[3160]	100
[3192]	101	int rc = 0;
	102	cout << ">>>> treccyl : " << arg[1] << " PPFName=" << ppfname << endl;
	103	try {
	104	if (act == 2) rc = testmulticyl(ppfname);
	105	else rc = test1cyl(ppfname);
	106	}
[3160]	107	catch (PThrowable& exc) {
	108	cerr << " treccyl.cc catched Exception " << exc.Msg() << endl;
	109	rc = 77;
	110	}
	111	catch (std::exception& sex) {
	112	cerr << "\n treccyl.cc std::exception :"
	113	<< (string)typeid(sex).name() << "\n msg= "
	114	<< sex.what() << endl;
	115	}
	116	catch (...) {
	117	cerr << " treccyl.cc catched unknown (...) exception " << endl;
	118	rc = 78;
	119	}
	120
[3192]	121	cout << ">>>> treccyl ------- FIN ----------- Rc=" << rc << endl;
	122	return rc;
[3160]	123	}
	124
	125
[3192]	126	//-----------------------------------------------------------------------------
[3160]	127	//--- Fonction de test : reconstruction plan AngX-Frequence (1 cylindre)
	128	int test1cyl(string& ppfname)
	129	{
	130
	131	// BRSourceGen sg;
[3192]	132	// int nsrc = 60;
[3165]	133	BRSourceGen sg(nsrcmax, maxangX, 0.);
[3160]	134	// sg.WritePPF(string("brsrc1.ppf"));
	135
	136	cout << "=== test1cyl: BRSourceGen NbSrc= " << sg.NbSources()
	137	<< " NbRecep=" << MR << " NSamples=" << NE << endl;
	138
	139	// BRSourceGen sg(string("brsrc1.ppf"));
	140	if (prtlevel > 1) sg.Print(cout);
	141
	142
	143	MultiBeamCyl mb(MR, NE);
	144	mb.SetPrintLevel(prtlevel);
	145	mb.SetBaseFreqDa(freq0, da);
	146	mb.SetNoiseSigma(snoise);
	147	mb.SetTimeJitter(tjit);
	148	mb.SetTimeOffsetSigma(tos);
	149	mb.SetGains(gmean, gsig, nantgz);
	150
	151	mb.SetSources(sg);
	152
	153	mb.ComputeTimeVectors();
	154	mb.ComputeSignalVector(0, true);
	155	cout << "treccy/test1cyl: signal vectors OK " << endl;
	156	PrtTim("test1cyl:[1] ");
[3165]	157
	158	cout << "--- treccy/test1cyl: Saving to PPF file " << ppfname << endl;
[3160]	159
	160	POutPersist po(ppfname);
[3192]	161	// direct access to variables members !!!!
	162	po << PPFNameTag("signal") << mb.signal_;
	163	po << PPFNameTag("sigjitt") << mb.sigjitt_;
	164	po << PPFNameTag("f_sig") << mb.f_sig_;
	165	po << PPFNameTag("f_sigjit") << mb.f_sigjit_;
[3160]	166
	167	NTuple ntsrc = sg.Convert2Table(freq0);
	168	po << PPFNameTag("ntsrc") << ntsrc;
	169
	170	cout << "treccy/test1cyl: - sig/f_sig,ntsrc to OutPPF OK " << endl;
	171	PrtTim("test1cyl[2] ");
	172
	173	mb.ReconstructSourcePlane(true);
	174	{
	175	TMatrix<r_4> srcplane = module(mb.getRecSrcPlane() );
	176	po << PPFNameTag("recsrcplane") << srcplane;
	177	}
	178	PrtTim("test1cyl[3] ");
	179
	180	return 0;
	181
	182	}
	183
	184
[3192]	185	//-----------------------------------------------------------------------------
[3160]	186	//--- Fonction de test : reconstruction cube AngX-AngY-Frequence (multi-cylindre)
[3192]	187	int testmulticyl(string& ppfname)
[3160]	188	{
	189
[3192]	190	//............. sources
[3160]	191	// BRSourceGen sg;
[3164]	192	int nsf = 6;
[3160]	193	vector<double> frq;
[3192]	194	frq.push_back(0.1/tClock);
	195	frq.push_back(0.27/tClock);
	196	frq.push_back(0.38/tClock);
[3160]	197
	198
[3165]	199	cout << "testmulticyl: BRSourceGen sg([frq=0.1,0.27,0.38], " << nsf
	200	<< "," << maxangX << "," << maxangY << ")" << endl;
	201	BRSourceGen sg(frq, nsf, maxangX, maxangY);
	202
[3163]	203	int is;
[3165]	204	double fay[6] = {-0.7,-0.5,0.,0.,0.5,0.7};
[3192]	205	// double fay[6] = {-0.2,0.5,-0.3,0.6,-0.1,0.7};
	206	// double fax[6] = {0.6,-0.2,-0.5,0.4,-0.1,0.3};
[3165]	207	for(is=0; is<3*nsf; is++) {
	208	int ism = is%nsf;
[3192]	209	sg.angX(is) = maxangX*(ism-2.5)/3.; // accessing data member
	210	sg.angY(is) = maxangY*fay[ism]; // directly !!!
	211	// sg.angX(is) = maxangX*fax[ism]; // accessing data member
[3165]	212	}
[3160]	213	// sg.WritePPF(string("brsrcm.ppf"));
	214	// BRSourceGen sg(string("brsrcm.ppf"));
[3165]	215	cout << "=== testmulticyl: NbSrc= " << sg.NbSources()
[3192]	216	<< " NbRecep=" << MR << " NSamples=" << NE << " NCyl=" << nCyl << endl;
[3160]	217	if (prtlevel > 1) sg.Print(cout);
	218
[3192]	219	//.......................... cylinders
	220	MultiCylinders mcyl ("telescope.in");
	221	// MultiCylinders mcyl (MR, NE);
	222	// mcyl.SetPrintLevel(prtlevel);
	223	// mcyl.SetBaseFreqDa(freq0, da);
	224	// mcyl.SetNoiseSigma(snoise);
	225	// mcyl.SetTimeJitter(tjit);
	226	// mcyl.SetTimeOffsetSigma(tos);
	227	// mcyl.SetGains(gmean, gsig, nantgz);
[3160]	228
[3192]	229	// for (int iCyl=0; iCyl<nCyl; iCyl++)
	230	// {
	231	// mcyl.AddCylinder(xCyl[iCyl],yCyl[iCyl]);
	232	// }
[3165]	233
[3192]	234
[3160]	235	mcyl.SetSources(sg);
	236
	237	PrtTim("testmulticyl[1] ");
	238
	239	// mcyl.ReconstructCylinderPlaneS(true);
[3192]	240	mcyl.ReconstructSourceBox(halfNY, maxangY/halfNY, NX, maxangX/NX);
[3160]	241
[3165]	242	cout << "--- treccy/testmulticyl: Saving to PPF file " << ppfname << endl;
[3160]	243	POutPersist po(ppfname);
	244
[3192]	245	DVList dvl;
	246	dvl("Da") = da;
	247	po << PPFNameTag("dvl") <<dvl;
	248
[3160]	249	NTuple ntsrc = sg.Convert2Table(freq0);
	250	po << PPFNameTag("ntsrc") << ntsrc;
	251
[3163]	252	// TMatrix<r_4> srcplane0 = module(mcyl.GetCylinder(0).getRecSrcPlane());
	253	TMatrix< complex<r_4> > srcplane0 = mcyl.GetCylinder(0).getRecSrcPlane();
[3160]	254	po << PPFNameTag("recsrcplane0") << srcplane0;
[3192]	255	TMatrix< complex<r_4> > srcplane1 = mcyl.GetCylinder(1).getRecSrcPlane();
	256	po << PPFNameTag("recsrcplane1") << srcplane1;
	257	// TMatrix< complex<r_4> > srcplane3 = mcyl.GetCylinder(3).getRecSrcPlane();
	258	// po << PPFNameTag("recsrcplane3") << srcplane3;
[3160]	259	PrtTim("testmulticyl[2] ");
	260
	261	po << PPFNameTag("recsrcbox") << mcyl.getRecSrcBox();
[3192]	262
	263	// k= N T frq with N=2*SizeZ()
	264	int kfmin = (int)(2.frq[0]tClock*(float)mcyl.getRecSrcBox().SizeZ() - 2.);
	265	int kfmax = kfmin+2;
[3164]	266	cout << "testmulticyl/Info: slice0 kfmin=" << kfmin << " kfmax=" << kfmax << endl;
[3160]	267	TMatrix<r_4> slice0 = mcyl.getRecXYSlice(kfmin, kfmax);
	268	po << PPFNameTag("recXYf0") << slice0;
[3192]	269	kfmin = (int)(2frq[1]tClock*(float)mcyl.getRecSrcBox().SizeZ() - 2.);
	270	kfmax = kfmin+2;
[3164]	271	cout << "testmulticyl/Info: slice1 kfmin=" << kfmin << " kfmax=" << kfmax << endl;
[3160]	272	TMatrix<r_4> slice1 = mcyl.getRecXYSlice(kfmin, kfmax);
	273	po << PPFNameTag("recXYf1") << slice1;
[3192]	274	kfmin = (int)(2frq[2]tClock*(float)mcyl.getRecSrcBox().SizeZ() - 2.);
	275	kfmax = kfmin+2;
[3164]	276	cout << "testmulticyl/Info: slice2 kfmin=" << kfmin << " kfmax=" << kfmax << endl;
[3160]	277	TMatrix<r_4> slice2 = mcyl.getRecXYSlice(kfmin, kfmax);
	278	po << PPFNameTag("recXYf2") << slice2;
	279
	280	PrtTim("testmulticyl[3] ");
	281
	282	return 0;
	283
	284	}
[3192]	285
	286	//---------------------------------------------------------------------
	287	int ReadParam(char* fileName)
	288	{
	289	DataCards dc;
	290	dc.ReadFile(fileName);
	291	// frequences are in units of 1/T = 0.5 GHz
	292	// distance are in units of cT =3E8 * 2E-9=0.60 m
	293	// double fUnit=0.5; // 0.5 GHz <=> T = 2 ns
	294	// double dUnit=0.6; // distance unit in m.
	295	double fUnit=1.; // 0.5 GHz <=> T = 2 ns
	296	double dUnit=1.; // distance unit in m.
	297
	298	NE=dc.IParam("nSample");
	299	freq0=dc.DParam("freq0")/fUnit;
	300	// tClock=dc.DParam("tClock");
	301	nCyl=dc.IParam("nCyl");
	302	for (int i=0; i<nCyl; i++){
	303	xCyl[i]=dc.DParam("xCyl",i)/dUnit;
	304	yCyl[i]=dc.DParam("yCyl",i)/dUnit;
	305	}
	306	MR=dc.IParam("nAntenna");
	307	da=dc.DParam("dAntenna")/dUnit;
	308	maxangX=dc.DParam("angMaxX");
	309	double cylDiam=dc.DParam("cylinderDiam")/dUnit;
	310	// thetaMax = lambda_M/d = c/freq_min/d; freq_min = freq0 + 1/2T
	311	maxangY=cLight/(freq0+1./2./tClock)/cylDiam;
	312	// cout << "*************** maxangY = " <<maxangY << endl;
	313	// maxangY=dc.DParam("angMaxY");
	314	snoise=dc.DParam("noiseSigma");
	315	tjit=dc.DParam("sigmaTimeJitt");
	316	tos=dc.DParam("sigmaClockJitt");
	317	gmean=dc.DParam("meanGain");
	318	gsig=dc.DParam("sigmaGain");
	319	nantgz=dc.IParam("nDeadAntenna");
	320	prtlevel=dc.IParam("printLevel");
	321	halfNY=dc.IParam("halfNY");
	322	NX=dc.IParam("NX");
	323	return 1;
	324	}

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