/* ======================================================================== *\ ! ! * ! * This file is part of MARS, the MAGIC Analysis and Reconstruction ! * Software. It is distributed to you in the hope that it can be a useful ! * and timesaving tool in analysing Data of imaging Cerenkov telescopes. ! * It is distributed WITHOUT ANY WARRANTY. ! * ! * Permission to use, copy, modify and distribute this software and its ! * documentation for any purpose is hereby granted without fee, ! * provided that the above copyright notice appear in all copies and ! * that both that copyright notice and this permission notice appear ! * in supporting documentation. It is provided "as is" without express ! * or implied warranty. ! * ! ! Author(s): Robert Wagner, 2/2004 ! Javier López , 4/2004 ! Wolfgang Wittek, 8/2004 ! ! Copyright: MAGIC Software Development, 2000-2004 ! ! \* ======================================================================== */ ///////////////////////////////////////////////////////////////////////////// // // MFindStars // ///////////////////////////////////////////////////////////////////////////// #include "MFindStars.h" #include #include #include #include #include #include #include #include #include #include #include "MObservatory.h" #include "MAstroCamera.h" #include "MMcConfigRunHeader.h" #include "MLog.h" #include "MLogManip.h" #include "MHCamera.h" #include "MGeomCam.h" #include "MGeomPix.h" #include "MCameraDC.h" #include "MTime.h" #include "MReportDrive.h" #include "MStarCam.h" #include "MStarPos.h" #include "MParList.h" #include "MTaskList.h" ClassImp(MFindStars); using namespace std; const Float_t sqrt2 = sqrt(2.); const Float_t sqrt3 = sqrt(3.); const UInt_t lastInnerPixel = 396; //______________________________________________________________________________ // // The 2D uncorrelated gaussian function used to fit the spot of the star // static Double_t func(float x,float y,Double_t *par) { Double_t value=par[0]*exp( -(x-par[1])*(x-par[1])/(2*par[2]*par[2]) ) *exp( -(y-par[3])*(y-par[3])/(2*par[4]*par[4]) ); return value; } //______________________________________________________________________________ // // The 2D correlated gaussian function used to fit the spot of the star // static Double_t funcCG(float x,float y,Double_t *par) { Double_t temp = 1.0-par[5]*par[5]; // Double_t value = par[0] / (2.0*TMath::Pi()*par[2]*par[4]*sqrt(temp)) Double_t value = par[0] * exp( -0.5/temp * ( (x-par[1])*(x-par[1])/(par[2]*par[2]) -2.0*par[5] * (x-par[1])*(y-par[3])/(par[2]*par[4]) + (y-par[3])*(y-par[3])/(par[4]*par[4]) ) ); return value; } //______________________________________________________________________________ // // Function used by Minuit to do the fit // static void fcn(Int_t &npar, Double_t *gin, Double_t &f, Double_t *par, Int_t iflag) { MParList* plist = (MParList*)gMinuit->GetObjectFit(); MTaskList* tlist = (MTaskList*)plist->FindObject("MTaskList"); MFindStars* find = (MFindStars*)tlist->FindObject("MFindStars"); MStarCam* stars = (MStarCam*)plist->FindObject("MStarCam","MStarCam"); MGeomCam* geom = (MGeomCam*)plist->FindObject("MGeomCam"); MHCamera& display = (MHCamera&)find->GetDisplay(); Float_t innerped = stars->GetInnerPedestalDC(); Float_t innerrms = stars->GetInnerPedestalRMSDC(); Float_t outerped = stars->GetOuterPedestalDC(); Float_t outerrms = stars->GetOuterPedestalRMSDC(); UInt_t numPixels = geom->GetNumPixels(); //calculate chisquare Double_t chisq = 0; Double_t delta; Double_t x,y,z; Double_t errorz=0; UInt_t usedPx=0; for (UInt_t pixid=1; pixidlastInnerPixel?outerped:innerped); errorz=(pixid>lastInnerPixel?outerrms:innerrms); if (errorz > 0.0) { usedPx++; Double_t fu; if (find->GetUseCorrelatedGauss()) fu = funcCG(x,y,par); else fu = func(x,y,par); delta = (z-fu) / errorz; chisq += delta*delta; if (iflag == 3) { gLog << "fcn : usedPx, pixid, content, pedestal,z, fu, errorz, delta = " << usedPx << ", " << pixid << ", " << display.GetBinContent(pixid+1) << ", " << (pixid>lastInnerPixel?outerped:innerped) << ", " << z << ", " << fu << ", " << errorz << ", " << delta << endl; } } else cerr << " TMinuit::fcn errorz[" << pixid << "] " << errorz << endl; } } f = chisq; find->SetChisquare(chisq); find->SetDegreesofFreedom(usedPx); //gLog << "fcn : chisq, usedPx = " << chisq << ", " << usedPx << endl; } //------------------------------------------------------------------------- // // Constructor // MFindStars::MFindStars(const char *name, const char *title): fGeomCam(NULL), fCurr(NULL), fTimeCurr(NULL), fDrive(NULL), fStars(NULL), fNumVar(6) { fName = name ? name : "MFindStars"; fTitle = title ? title : "Tool to find stars from DC Currents"; // the correlated Gauss function // is fitted by default fNumVar = 6; fUseCorrelatedGauss = kTRUE; fNumIntegratedEvents=0; fMaxNumIntegratedEvents = 10; fRingInterest = 125.; //[mm] ~ 0.4 deg fDCTailCut = 4; fPixelsUsed.Set(577); fPixelsUsed.Reset((Char_t)kTRUE); //Fitting(Minuit) initialitation const Float_t pixelSize = 31.5; //[mm] fMinuitPrintOutLevel = -1; //fMinuitPrintOutLevel = 3; fVname = new TString[fNumVar]; fVinit.Set(fNumVar); fStep.Set(fNumVar); fLimlo.Set(fNumVar); fLimup.Set(fNumVar); fFix.Set(fNumVar); fVname[0] = "max"; fVinit[0] = 10.*fMaxNumIntegratedEvents; fStep[0] = fVinit[0]/sqrt2; fLimlo[0] = fMinDCForStars; fLimup[0] = 30.*fMaxNumIntegratedEvents; fFix[0] = 0; fVname[1] = "meanx"; fVinit[1] = 0.; fStep[1] = fVinit[1]/sqrt2; fLimlo[1] = -600.; fLimup[1] = 600.; fFix[1] = 0; fVname[2] = "sigmax"; fVinit[2] = pixelSize; fStep[2] = fVinit[2]/sqrt2; fLimlo[2] = pixelSize/(2*sqrt3); fLimup[2] = 500.; fFix[2] = 0; fVname[3] = "meany"; fVinit[3] = 0.; fStep[3] = fVinit[3]/sqrt2; fLimlo[3] = -600.; fLimup[3] = 600.; fFix[3] = 0; fVname[4] = "sigmay"; fVinit[4] = pixelSize; fStep[4] = fVinit[4]/sqrt2; fLimlo[4] = pixelSize/(2*sqrt3); fLimup[4] = 500.; fFix[4] = 0; if (fUseCorrelatedGauss) { fVname[5] = "xycorr"; fVinit[5] = 0.0; fStep[5] = 0.1; fLimlo[5] = -1.0; fLimup[5] = 1.0; fFix[5] = 0; } fObjectFit = NULL; // fMethod = "SIMPLEX"; fMethod = "MIGRAD"; // fMethod = "MINIMIZE"; fNulloutput = kFALSE; // Set output level // fLog->SetOutputLevel(3); // No dbg messages fGeometryFile=""; fBSCFile=""; } //------------------------------------------------------------------------- // // Set 'fUseCorrelatedGauss' flag // // if 'fUseCorrelatedGauss' is TRUE a 2dim Gaussian with correlation // will be fitted // void MFindStars::SetUseCorrelatedGauss(Bool_t usecorrgauss) { fUseCorrelatedGauss = usecorrgauss; if (usecorrgauss) fNumVar = 6; else fNumVar = 5; } //------------------------------------------------------------------------- // // PreProcess // Int_t MFindStars::PreProcess(MParList *pList) { fGeomCam = (MGeomCam*)pList->FindObject(AddSerialNumber("MGeomCam")); if (!fGeomCam) { *fLog << err << AddSerialNumber("MGeomCam") << " not found ... aborting" << endl; return kFALSE; } // Initialize camera display with the MGeomCam information fDisplay.SetGeometry(*fGeomCam,"FindStarsDisplay","FindStarsDisplay"); fDisplay.SetUsed(fPixelsUsed); fCurr = (MCameraDC*)pList->FindObject(AddSerialNumber("MCameraDC")); if (!fCurr) { *fLog << err << AddSerialNumber("MCameraDC") << " not found ... aborting" << endl; return kFALSE; } fTimeCurr = (MTime*)pList->FindObject(AddSerialNumber("MTimeCurrents")); if (!fTimeCurr) { *fLog << err << AddSerialNumber("MTimeCurrents") << " not found ... aborting" << endl; return kFALSE; } fDrive = (MReportDrive*)pList->FindObject(AddSerialNumber("MReportDrive")); if (!fDrive) { *fLog << warn << AddSerialNumber("MReportDrive") << " not found ... ignored." << endl; } else { MObservatory magic1; MMcConfigRunHeader *config=0; MGeomCam *geom=0; TFile file(fGeometryFile); TTree *tree = (TTree*)file.Get("RunHeaders"); tree->SetBranchAddress("MMcConfigRunHeader", &config); if (tree->GetBranch("MGeomCam")) tree->SetBranchAddress("MGeomCam", &geom); tree->GetEntry(0); fAstro.SetMirrors(*config->GetMirrors()); fAstro.SetGeom(*geom); fAstro.ReadBSC(fBSCFile); fAstro.SetObservatory(magic1); } fStars = (MStarCam*)pList->FindCreateObj(AddSerialNumber("MStarCam"),"MStarCam"); if (!fStars) { *fLog << err << AddSerialNumber("MStarCam") << " cannot be created ... aborting" << endl; return kFALSE; } fMinDCForStars = 1.*fMaxNumIntegratedEvents; //[uA] // Initialize the TMinuit object TMinuit *gMinuit = new TMinuit(fNumVar); //initialize TMinuit with a maximum of params gMinuit->SetFCN(fcn); Double_t arglist[10]; Int_t ierflg = 0; arglist[0] = 1; gMinuit->mnexcm("SET ERR", arglist ,1,ierflg); arglist[0] = fMinuitPrintOutLevel; gMinuit->mnexcm("SET PRI", arglist ,1,ierflg); // suppress warnings Int_t errWarn; Double_t tmpwar = 0; gMinuit->mnexcm("SET NOW", &tmpwar, 0, errWarn); // Set MParList object pointer to allow mimuit to access internally gMinuit->SetObjectFit(pList); return kTRUE; } //------------------------------------------------------------------------ // // Process : // // // // Int_t MFindStars::Process() { UInt_t numPixels = fGeomCam->GetNumPixels(); TArrayC origPixelsUsed; origPixelsUsed.Set(numPixels); if (fNumIntegratedEvents >= fMaxNumIntegratedEvents) { //Fist delete the previous stars in the list fStars->GetList()->Delete(); if (fDrive) { //If drive information is provided we take RaDec info //from the drive and let the star list fill by the astrocamera. //FIXME: rwagner: Doesn't work as expected //FIXME: rwagner: For the time being set manually. //fAstro.SetRaDec(fDrive->GetRa(), fDrive->GetDec()); fAstro.SetTime(*fTimeCurr); fAstro.SetGuiActive(); fAstro.FillStarList(fStars->GetList()); //cout << "Number of Stars added by astrocamera is " // <GetList()->GetSize() << endl; MStarPos* starpos; TIter Next(fStars->GetList()); while ((starpos=(MStarPos*)Next())) { //starpos->SetCalcValues(40,40,starpos->GetXExp(), starpos->GetYExp(), // fRingInterest/2, fRingInterest/2, // 0., 0., 0., 0.); //starpos->SetFitValues (40,40,starpos->GetXExp(), starpos->GetYExp(), // fRingInterest/2, fRingInterest/2, 0., // 0., 0., 0., 0., -1); } for (UInt_t pix=1; pixGetInnerPedestalDC()+fDCTailCut*fStars->GetInnerPedestalRMSDC(); Float_t outermin = fStars->GetOuterPedestalDC()+fDCTailCut*fStars->GetOuterPedestalRMSDC(); fMinDCForStars = innermin>outermin?innermin:outermin; if (fMinuitPrintOutLevel>=0) *fLog << dbg << "fMinDCForStars = " << fMinDCForStars << endl; // Find the star candidates searching the most brights pairs of pixels Float_t maxPixelDC; MGeomPix maxPixel; while(FindPixelWithMaxDC(maxPixelDC, maxPixel)) { MStarPos *starpos = new MStarPos; starpos->SetExpValues(maxPixelDC,maxPixel.GetX(),maxPixel.GetY()); //starpos->SetCalcValues(maxPixelDC, maxPixelDC, // maxPixel.GetX(), maxPixel.GetY(), // fRingInterest/2, fRingInterest/2, // 0., 0., 0., 0.); //starpos->SetFitValues(maxPixelDC, maxPixelDC, // maxPixel.GetX(), maxPixel.GetY(), // fRingInterest/2, fRingInterest/2, 0., // 0., 0., 0., 0., -1); fStars->GetList()->Add(starpos); ShadowStar(starpos); } fDisplay.SetUsed(origPixelsUsed); } } //Show the stars found //fStars->Print("namepossizechierr"); //loop to extract position of stars on the camera if (fStars->GetList()->GetSize() == 0) { *fLog << err << GetName() << "No stars candidates in the camera." << endl; return kCONTINUE; } else { //*fLog << inf << GetName() << " found " << fStars->GetList()->GetSize() // << " star candidates in the camera." << endl; } for (UInt_t pix=1; pixGetList()); MStarPos* star; while ((star=(MStarPos*)Next())) { FindStar(star); ShadowStar(star); } //Show the stars found: Here it is interesting to see what FindStars //made out of the positions we gave to it. if (fMinuitPrintOutLevel>=0) fStars->Print("namepossizchierr"); //After finding stars reset all variables fDisplay.Reset(); fStars->GetDisplay().Reset(); //FIXME: Put this display just in the container fDisplay.SetUsed(origPixelsUsed); fNumIntegratedEvents=0; } for (UInt_t pix=1; pix=0) *fLog << dbg << "MFindStars::SetBlindPixels fDisplay.IsUsed(" <GetNumPixels(); Float_t ped; Float_t rms; //TH1F **dchist = new TH1F*[2]; TH1F *dchist[2]; TString tit; TString nam; for (UInt_t i=0; i<2; i++) { nam = i; tit = "dchist["; tit += i; tit += "]"; dchist[i] = new TH1F(nam, tit, 26,0.4*fMaxNumIntegratedEvents,3.*fMaxNumIntegratedEvents); } for (UInt_t pix=1; pix<=lastInnerPixel; pix++) dchist[0]->Fill(fDisplay.GetBinContent(pix+1)); for (UInt_t pix=lastInnerPixel+1; pixFill(fDisplay.GetBinContent(pix+1)); // inner/outer pixels for (UInt_t i=0; i<2; i++) { Float_t nummaxprobdc = dchist[i]->GetBinContent(dchist[i]->GetMaximumBin()); Float_t maxprobdc = dchist[i]->GetBinCenter(dchist[i]->GetMaximumBin()); UInt_t bin = dchist[i]->GetMaximumBin(); do { bin++; } while(dchist[i]->GetBinContent(bin)/nummaxprobdc > 0.5); Float_t halfmaxprobdc = dchist[i]->GetBinCenter(bin); if (fMinuitPrintOutLevel>=0) *fLog << dbg << " maxprobdc[high] " << maxprobdc << "[" << nummaxprobdc << "] "; if (fMinuitPrintOutLevel>=0) *fLog << dbg << " halfmaxprobdc[high] " << halfmaxprobdc << "[" << dchist[i]->GetBinContent(bin) << "]" << endl; Float_t rmsguess = TMath::Abs(maxprobdc-halfmaxprobdc); Float_t min = maxprobdc-3*rmsguess; min = (min<0.?0.:min); Float_t max = maxprobdc+3*rmsguess; if (fMinuitPrintOutLevel>=0) *fLog << dbg << " maxprobdc " << maxprobdc << " rmsguess " << rmsguess << endl; TF1 func("func","gaus",min,max); func.SetParameters(nummaxprobdc, maxprobdc, rmsguess); dchist[i]->Fit("func","QR0"); UInt_t aproxnumdegrees = 6*(bin-dchist[i]->GetMaximumBin()); Float_t chiq = func.GetChisquare(); ped = func.GetParameter(1); rms = func.GetParameter(2); if (fMinuitPrintOutLevel>=0) *fLog << dbg << " ped " << ped << " rms " << rms << " chiq/ndof " << chiq << "/" << aproxnumdegrees << endl; Int_t numsigmas = 5; Axis_t minbin = ped-numsigmas*rms/dchist[i]->GetBinWidth(1); minbin=minbin<1?1:minbin; Axis_t maxbin = ped+numsigmas*rms/dchist[i]->GetBinWidth(1); if (fMinuitPrintOutLevel>=0) *fLog << dbg << " Number of pixels with dc under " << numsigmas << " sigmas = " << dchist[i]->Integral((int)minbin,(int)maxbin) << endl; //Check results from the fit are consistent if (ped < 0. || rms < 0.) { *fLog << dbg << "dchist[i]->GetEntries()" << dchist[i]->GetEntries(); // TCanvas *c1 = new TCanvas("c2","c2",500,800); // dchist[i]->Draw(); // c1->Print("dchist.ps"); // delete c1; // exit(1); } else if (TMath::Abs(ped-maxprobdc) > rmsguess || rms > rmsguess) { *fLog << warn << GetName() << " Pedestal DC fit give non consistent results for " << (i==0?"Inner":"Outer") << "pixels." << endl; *fLog << warn << " maxprobdc " << maxprobdc << " rmsguess " << rmsguess << endl; *fLog << warn << " ped " << ped << " rms " << rms << " chiq/ndof " << chiq << "/" << aproxnumdegrees << endl; ped = maxprobdc; rms = rmsguess/1.175; // FWHM=2.35*rms } if (i == 0) { fStars->SetInnerPedestalDC(ped); fStars->SetInnerPedestalRMSDC(rms); } else { fStars->SetOuterPedestalDC(ped); fStars->SetOuterPedestalRMSDC(rms); } } for (UInt_t i=0; i<2; i++) { delete dchist[i]; } //delete [] dchist; //================================================================= // reset gMinuit to the MINUIT object for optimizing the supercuts gMinuit = savePointer; //------------------------------------------- if (fStars->GetInnerPedestalDC() < 0. || fStars->GetInnerPedestalRMSDC() < 0. || fStars->GetOuterPedestalDC() < 0. || fStars->GetOuterPedestalRMSDC() < 0.) return kFALSE; return kTRUE; } Bool_t MFindStars::FindPixelWithMaxDC(Float_t &maxDC, MGeomPix &maxPix) { UInt_t numPixels = fGeomCam->GetNumPixels(); // Find the two close pixels with the maximun dc UInt_t maxPixIdx[2]; maxDC = 0; for (UInt_t pix=1; pix maxDC*2) { if(dc[0]>=dc[1]) { maxPixIdx[0] = pix; maxPixIdx[1] = swneighbor; maxDC = dc[0]; } else { maxPixIdx[1] = pix; maxPixIdx[0] = swneighbor; maxDC = dc[1]; } } } } } } if (maxDC == 0) { *fLog << warn << " No found pixels with maximum dc" << endl; return kFALSE; } maxPix = (*fGeomCam)[maxPixIdx[0]]; if (fMinuitPrintOutLevel>=0) *fLog << dbg << "Star candidate maxDC(" << setw(3) << maxDC << " uA) x position(" << setw(3) << maxPix.GetX() << " mm) x position(" << setw(3) << maxPix.GetY() << " mm) swnumber(" << maxPixIdx[0] << ")" << endl; return kTRUE; } //---------------------------------------------------------------------------- // // FindStar // // // Bool_t MFindStars::FindStar(MStarPos* star) { UInt_t numPixels = fGeomCam->GetNumPixels(); Float_t innerped = fStars->GetInnerPedestalDC(); Float_t outerped = fStars->GetOuterPedestalDC(); TArrayC origPixelsUsed; origPixelsUsed.Set(numPixels); for (UInt_t pix=1; pixGetXExp(); Float_t expY = star->GetYExp(); Float_t max =0; UInt_t pixmax =0; Float_t meanX =0; Float_t meanY =0; Float_t meanSqX =0; Float_t meanSqY =0; Float_t sumCharge =0; Float_t sumSqCharge =0; UInt_t usedInnerPx =0; UInt_t usedOuterPx =0; Float_t factor = 1.0; Float_t meanXold = 1.e10; Float_t meanYold = 1.e10; const Float_t meanPresition = 3.; //[mm] const UInt_t maxNumIterations = 10; UInt_t numIterations = 0; //-------------------- start of iteration loop ----------------------- for (UInt_t it=0; itmax) { max=charge; pixmax=pix; } } // 3.) make it new center expX = (*fGeomCam)[pixmax].GetX(); expY = (*fGeomCam)[pixmax].GetY(); for (UInt_t pix=1; pixlastInnerPixel?usedOuterPx++:usedInnerPx++; Float_t charge = fDisplay.GetBinContent(pix+1); Float_t pixXpos = (*fGeomCam)[pix].GetX(); Float_t pixYpos = (*fGeomCam)[pix].GetY(); if (charge>max) { max=charge; pixmax=pix; } meanX += charge*pixXpos; meanY += charge*pixYpos; meanSqX += charge*pixXpos*pixXpos; meanSqY += charge*pixYpos*pixYpos; sumCharge += charge; sumSqCharge += charge*charge; } } if (fMinuitPrintOutLevel>=0) *fLog << dbg << " usedInnerPx " << usedInnerPx << " usedOuterPx " << usedOuterPx << endl; meanX /= sumCharge; meanY /= sumCharge; meanSqX /= sumCharge; meanSqY /= sumCharge; factor = sqrt( sumSqCharge/(sumCharge*sumCharge) ); // stop iteration when (meanX, meanY) becomes stable if ( TMath::Abs(meanX-meanXold) < meanPresition && TMath::Abs(meanY-meanYold) < meanPresition ) break; meanXold = meanX; meanYold = meanY; numIterations++; } // this statement was commented out because the condition // was never fulfilled : //while(TMath::Abs(meanX-expX) > meanPresition || // TMath::Abs(meanY-expY) > meanPresition); //-------------------- end of iteration loop ----------------------- if (numIterations >= maxNumIterations) { *fLog << warn << GetName() << "Mean calculation not converged after " << maxNumIterations << " iterations" << endl; } //Float_t rmsX = (meanSqX - meanX*meanX) - fRingInterest*fRingInterest/12; //Float_t rmsY = (meanSqY - meanY*meanY) - fRingInterest*fRingInterest/12; Float_t rmsX = (meanSqX - meanX*meanX); Float_t rmsY = (meanSqY - meanY*meanY); if ( rmsX > 0) rmsX = TMath::Sqrt(rmsX); else { *fLog << warn << " MFindStars::FindStar negative rmsX² " << rmsX << endl; *fLog << warn << " meanSqX " << meanSqX << " meanX " << meanX << " fRingInterest " << fRingInterest << " sumCharge " << sumCharge << endl; rmsX = 0.; } if ( rmsY > 0) rmsY = TMath::Sqrt(rmsY); else { *fLog << warn << " MFindStars::FindStar negative rmsY² " << rmsY << endl; *fLog << warn << " meanSqY " << meanSqY << " meanY " << meanY << " fRingInterest " << fRingInterest << " sumCharge " << sumCharge<< endl; rmsY = 0.; } Float_t deltameanX = factor * rmsX; Float_t deltameanY = factor * rmsY; // Substrack pedestal DC sumCharge-= (usedInnerPx*innerped+usedOuterPx*outerped)/(usedInnerPx+usedOuterPx); max-=pixmax>lastInnerPixel?outerped:innerped; star->SetCalcValues( sumCharge, max, meanX, meanY, rmsX, rmsY, 0., deltameanX*deltameanX, 0., deltameanY*deltameanY); if (rmsX <= 0. || rmsY <= 0.) return kFALSE; // fit the star spot using TMinuit for (UInt_t pix=1; pix=0) *fLog << dbg << "[fit the star spot] fDisplay.IsUsed(" << pix << ") kTRUE" << endl; if (fMinuitPrintOutLevel>=0) *fLog << dbg << "fMinDCForStars " << fMinDCForStars << " pixmax>lastInnerPixel?outerped:innerped " << (pixmax>lastInnerPixel?outerped:innerped) << " fMaxNumIntegratedEvents " << fMaxNumIntegratedEvents << endl; //Initialize variables for fit fVinit[0] = max; fLimlo[0] = fMinDCForStars-(pixmax>lastInnerPixel?outerped:innerped); fLimup[0] = 30*fMaxNumIntegratedEvents-(pixmax>lastInnerPixel?outerped:innerped); fVinit[1] = meanX; fVinit[2] = rmsX; fVinit[3] = meanY; fVinit[4] = rmsY; //Init steps for(Int_t i=0; i=0) *fLog << dbg << " fVinit[" << i << "] " << fVinit[i]; if (fMinuitPrintOutLevel>=0) *fLog << dbg << " fStep[" << i << "] " << fStep[i]; if (fMinuitPrintOutLevel>=0) *fLog << dbg << " fLimlo[" << i << "] " << fLimlo[i]; if (fMinuitPrintOutLevel>=0) *fLog << dbg << " fLimup[" << i << "] " << fLimup[i] << endl; } // ------------------------------------------- // call MINUIT Double_t arglist[10]; Int_t ierflg = 0; for (Int_t i=0; imnparm(i, fVname[i], fVinit[i], fStep[i], fLimlo[i], fLimup[i], ierflg); TStopwatch clock; clock.Start(); // Now ready for minimization step arglist[0] = 500; arglist[1] = 1.; gMinuit->mnexcm(fMethod, arglist ,2,ierflg); // call fcn with iflag = 3 //arglist[0] = 3; //Int_t ierflg3; //gMinuit->mnexcm("CALL", arglist, 1, ierflg3); clock.Stop(); if(fMinuitPrintOutLevel>=0) { if (fMinuitPrintOutLevel>=0) *fLog << dbg << "Time spent for the minimization in MINUIT : " << endl;; clock.Print(); } //---------- for the uncorrelated Gauss fit (start) --------- if (!fUseCorrelatedGauss) { Double_t integratedCharge; Double_t maxFit, maxFitError; Double_t meanXFit, meanXFitError; Double_t sigmaX, sigmaXError; Double_t meanYFit, meanYFitError; Double_t sigmaY, sigmaYError; Float_t chisquare = GetChisquare(); Int_t degrees = GetDegreesofFreedom()-fNumVar; if (!ierflg) { gMinuit->GetParameter(0, maxFit, maxFitError); gMinuit->GetParameter(1, meanXFit, meanXFitError); gMinuit->GetParameter(2, sigmaX, sigmaXError); gMinuit->GetParameter(3, meanYFit, meanYFitError); gMinuit->GetParameter(4, sigmaY, sigmaYError); //FIXME: Do the integral properlly integratedCharge = 0.; } else { maxFit = 0.; meanXFit = 0.; sigmaX = 0.; meanYFit = 0.; sigmaY = 0.; integratedCharge = 0.; *fLog << err << "TMinuit::Call error " << ierflg << endl; } // get error matrix Double_t matrix[5][5]; gMinuit->mnemat(&matrix[0][0],5); star->SetFitValues(integratedCharge,maxFit, meanXFit, meanYFit, sigmaX, sigmaY, 0.0, matrix[1][1], matrix[1][3], matrix[3][3], chisquare, degrees); } //---------- for the uncorrelated Gauss fit (end) --------- //---------- for the correlated Gauss fit (start) --------- if (fUseCorrelatedGauss) { TArrayD fValues(fNumVar); TArrayD fErrors(fNumVar); const static Int_t fNdim = 6; Double_t matrix[fNdim][fNdim]; Double_t fmin = 0.0; Double_t fedm = 0.0; Double_t errdef = 0.0; Int_t npari = 0; Int_t nparx = 0; Int_t istat = 0; gMinuit->mnstat(fmin, fedm, errdef, npari, nparx, istat); if (fMinuitPrintOutLevel>=0) { *fLog << dbg << "Status of Correlated Gauss fit to the DC currents : " << endl; } if (fMinuitPrintOutLevel>=0) { *fLog << dbg << " fmin, fedm, errdef, npari, nparx, istat = " << fmin << ", " << fedm << ", " << errdef << ", " << npari << ", " << nparx << ", " << istat << endl; } if (!ierflg) { for (Int_t k=0; kGetParameter( k, fValues[k], fErrors[k] ); } else { *fLog << err << "Correlated Gauss fit failed : ierflg, istat = " << ierflg << ", " << istat << endl; } Float_t charge = 0.0; Float_t chi2 = fmin; Int_t ndof = GetDegreesofFreedom()-fNumVar; //get error matrix if (istat >= 1) { gMinuit->mnemat( &matrix[0][0], fNdim); // copy covariance matrix into a matrix which includes also the fixed // parameters TString name; Double_t bnd1, bnd2, val, err; Int_t jvarbl; Int_t kvarbl; for (Int_t j=0; jmnpout(j, name, val, err, bnd1, bnd2, jvarbl); for (Int_t k=0; kmnpout(k, name, val, err, bnd1, bnd2, kvarbl); matrix[j][k] = jvarbl==0 || kvarbl==0 ? 0 : matrix[jvarbl-1][kvarbl-1]; } } } else { // error matrix was not calculated, construct it if (fMinuitPrintOutLevel>=0) { *fLog << warn << "error matrix is not defined, construct it" << endl; } for (Int_t j=0; j=0) { *fLog << "Before calling SetFitValues : " << endl; *fLog << "fValues = " << fValues[0] << ", " << fValues[1] << ", " << fValues[2] << ", " << fValues[3] << ", " << fValues[4] << ", " << fValues[5] << endl; *fLog << "fErrors = " << fErrors[0] << ", " << fErrors[1] << ", " << fErrors[2] << ", " << fErrors[3] << ", " << fErrors[4] << ", " << fErrors[5] << endl; *fLog << "error matrix = " << matrix[0][0] << " " << matrix[0][1] << " " << matrix[0][2] << " " << matrix[0][3] << " " << matrix[0][4] << " " << matrix[0][5] << endl; *fLog << " " << matrix[1][0] << " " << matrix[1][1] << " " << matrix[1][2] << " " << matrix[1][3] << " " << matrix[1][4] << " " << matrix[1][5] << endl; *fLog << " " << matrix[2][0] << " " << matrix[2][1] << " " << matrix[2][2] << " " << matrix[2][3] << " " << matrix[2][4] << " " << matrix[2][5] << endl; *fLog << " " << matrix[3][0] << " " << matrix[3][1] << " " << matrix[3][2] << " " << matrix[3][3] << " " << matrix[3][4] << " " << matrix[3][5] << endl; *fLog << " " << matrix[4][0] << " " << matrix[4][1] << " " << matrix[4][2] << " " << matrix[4][3] << " " << matrix[4][4] << " " << matrix[4][5] << endl; *fLog << " " << matrix[5][0] << " " << matrix[5][1] << " " << matrix[5][2] << " " << matrix[5][3] << " " << matrix[5][4] << " " << matrix[5][5] << endl; } star->SetFitValues(charge, fValues[0], fValues[1], fValues[3], fValues[2], fValues[4], fValues[5], matrix[1][1], matrix[1][3],matrix[3][3], chi2, ndof); } //---------- for the correlated Gauss fit (end) --------- // reset the display to the starting values fDisplay.SetUsed(origPixelsUsed); if (ierflg) return kCONTINUE; return kTRUE; } Bool_t MFindStars::ShadowStar(MStarPos* star) { UInt_t numPixels = fGeomCam->GetNumPixels(); // Define an area around the star which will be set unused. UInt_t shadowPx=0; for (UInt_t pix=1; pixGetMeanX(); Float_t starYpos = star->GetMeanY(); Float_t starSize = 3*sqrt( star->GetSigmaX()*star->GetSigmaX() + star->GetSigmaY()*star->GetSigmaY() ); Float_t dist = sqrt((pixXpos-starXpos)*(pixXpos-starXpos)+ (pixYpos-starYpos)*(pixYpos-starYpos)); if (dist > starSize && fDisplay.IsUsed(pix)) fPixelsUsed[pix]=(Char_t)kTRUE; else { fPixelsUsed[pix]=(Char_t)kFALSE; shadowPx++; } } if (fMinuitPrintOutLevel>=0) *fLog << dbg << " shadowPx " << shadowPx << endl; fDisplay.SetUsed(fPixelsUsed); return kTRUE; }