/* ======================================================================== *\ ! ! * ! * 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): Wolfgang Wittek, July 2003 ! ! Copyright: MAGIC Software Development, 2000-2003 ! ! \* ======================================================================== */ ///////////////////////////////////////////////////////////////////////////// // // MHFindSignificance // // determines the significance of a gamma signal in an |alpha| plot // // // Input : TH1 histogram of |alpha| : with 0 < |alpha| < 90 degrees // alphamin, alphamax : defining the background region // alphasig : defining the signal region for which // the significance is calculated // degree : the degree of the polynomial to be fitted to the background // ( a0 + a1*x + a2*x**2 + a3*x**3 + ...) // // Output : // // - polynomial which describes the background in the background region // - the number of events in the signal region (Non) // the number of background events in the signal region (Nbg) // - the number of excess events in the signal region (Nex = Non - Nbg) // - thew effective number of background events (Noff), and gamma : // Nbg = gamma * Noff // - the significance of the gamma signal according to Li & Ma // // // call member function 'FindSigma' // to fit the background and to determine the significance // // call the member function 'SigmaVsAlpha' // to determine the significance as a function of alphasig // ///////////////////////////////////////////////////////////////////////////// #include "MHFindSignificance.h" #include #include #include #include #include #include #include #include #include #include #include #include "MLog.h" #include "MLogManip.h" #include "MMinuitInterface.h" ClassImp(MHFindSignificance); using namespace std; const TString MHFindSignificance::gsDefName = "MHFindSignificance"; const TString MHFindSignificance::gsDefTitle = "Find Significance in alpha plot"; // -------------------------------------------------------------------------- // // fcnpoly // // calculates the chi2 for the fit of the polynomial function 'poly' // to the histogram 'fhist' // // it is called by CallMinuit() (which is called in FitPolynomial()) // // bins of fhist with huge errors are ignored in the calculation of the chi2 // (the huge errors were set in 'FitPolynomial()') // static void fcnpoly(Int_t &npar, Double_t *gin, Double_t &f, Double_t *par, Int_t iflag) { TH1 *fhist = (TH1*)gMinuit->GetObjectFit(); TF1 *fpoly = fhist->GetFunction("Poly"); //------------------------------------------- Double_t chi2 = 0.0; Int_t nbins = fhist->GetNbinsX(); Int_t mbins = 0; for (Int_t i=1; i<=nbins; i++) { Double_t content = fhist->GetBinContent(i); Double_t error = fhist->GetBinError(i); Double_t center = fhist->GetBinCenter(i); //----------------------------- // ignore unwanted points if (error > 1.e19) continue; if (content <= 0.0) { gLog << "fcnpoly : bin with zero content; i, content, error = " << i << ", " << content << ", " << error << endl; continue; } if (error <= 0.0) { gLog << "fcnpoly : bin with zero error; i, content, error = " <EvalPar(¢er, par); // the fitted function must not be negative if (fu <= 0.0) { chi2 = 1.e10; break; } Double_t temp = (content - fu) / error; chi2 += temp*temp; } //------------------------------------------- f = chi2; //------------------------------------------- // final calculations //if (iflag == 3) //{ //} //------------------------------------------------------------- } // -------------------------------------------------------------------------- // // fcnpolygauss // // calculates the chi2 for the fit of the (polynomial+Gauss) function // 'PolyGauss' to the histogram 'fhist' // // it is called by CallMinuit() (which is called in FitGaussPoly()) // // bins of fhist with huge errors are ignored in the calculation of the chi2 // (the huge errors were set in 'FitGaussPoly()') // static void fcnpolygauss(Int_t &npar, Double_t *gin, Double_t &f, Double_t *par, Int_t iflag) { TH1 *fhist = (TH1*)gMinuit->GetObjectFit(); TF1 *fpolygauss = fhist->GetFunction("PolyGauss"); //------------------------------------------- Double_t chi2 = 0.0; Int_t nbins = fhist->GetNbinsX(); Int_t mbins = 0; for (Int_t i=1; i<=nbins; i++) { Double_t content = fhist->GetBinContent(i); Double_t error = fhist->GetBinError(i); Double_t center = fhist->GetBinCenter(i); //----------------------------- // ignore unwanted points if (error > 1.e19) continue; if (content <= 0.0) { gLog << "fcnpolygauss : bin with zero content; i, content, error = " << i << ", " << content << ", " << error << endl; continue; } if (error <= 0.0) { gLog << "fcnpolygauss : bin with zero error; i, content, error = " <EvalPar(¢er, par); // the fitted function must not be negative if (fu <= 0.0) { chi2 = 1.e10; break; } Double_t temp = (content - fu) / error; chi2 += temp*temp; } //------------------------------------------- f = chi2; //------------------------------------------- // final calculations //if (iflag == 3) //{ //} //------------------------------------------------------------- } // -------------------------------------------------------------------------- // // Constructor // MHFindSignificance::MHFindSignificance(const char *name, const char *title) { fName = name ? name : gsDefName.Data(); fTitle = title ? title : gsDefTitle.Data(); fSigVsAlpha = NULL; fPoly = NULL; fGPoly = NULL; fGBackg = NULL; fHist = NULL; fHistOrig = NULL; // allow rebinning of the alpha plot fRebin = kTRUE; // allow reducing the degree of the polynomial fReduceDegree = kTRUE; fCanvas = NULL; } // -------------------------------------------------------------------------- // // Destructor. // // =====> it is not clear why one obtains sometimes a segmentation violation // when the destructor is active <======================= // // therefore the 'return'statement // MHFindSignificance::~MHFindSignificance() { return; *fLog << "destructor of MHFindSignificance is called" << endl; //delete fHist; delete fSigVsAlpha; delete fPoly; delete fGPoly; delete fGBackg; //delete fCanvas; } // -------------------------------------------------------------------------- // // Set flag fRebin // // if flag is kTRUE rebinning of the alpha plot is allowed // // void MHFindSignificance::SetRebin(Bool_t b) { fRebin = b; *fLog << "MHFindSignificance::SetRebin; flag fRebin set to " << (b? "kTRUE" : "kFALSE") << endl; } // -------------------------------------------------------------------------- // // Set flag fReduceDegree // // if flag is kTRUE reducing of the degree of the polynomial is allowed // // void MHFindSignificance::SetReduceDegree(Bool_t b) { fReduceDegree = b; *fLog << "MHFindSignificance::SetReduceDegree; flag fReduceDegree set to " << (b? "kTRUE" : "kFALSE") << endl; } // -------------------------------------------------------------------------- // // FindSigma // // calls FitPolynomial to fit the background in the background region // calls DetExcess to determine the number of excess events // using an extrapolation of the polynomial // into the signal region // calls SigmaLiMa to determine the significance of the gamma signal // in the range |alpha| < alphasig // calls FitGaussPoly to fit a (polynomial+Gauss) function in the // whole |alpha| region // // Bool_t MHFindSignificance::FindSigma(TH1 *fhist, Double_t alphamin, Double_t alphamax, Int_t degree, Double_t alphasig, Bool_t drawpoly, Bool_t fitgauss, Bool_t print) { //*fLog << "MHFindSignificance::FindSigma;" << endl; fHistOrig = fhist; fHist = (TH1*)fHistOrig->Clone(); fHist->SetName(fhist->GetName()); if ( !fHist ) { *fLog << "MHFindSignificance::FindSigma; Clone of histogram could not be generated" << endl; return kFALSE; } fHist->Sumw2(); //fHist->SetNameTitle("Alpha", "alpha plot"); fHist->SetXTitle("|alpha| [\\circ]"); fHist->SetYTitle("Counts"); fHist->UseCurrentStyle(); fAlphamin = alphamin; fAlphamax = alphamax; fAlphammm = (alphamin+alphamax)/2.0; fDegree = degree; fAlphasig = alphasig; fDraw = drawpoly; fFitGauss = fitgauss; //-------------------------------------------- // fit a polynomial in the background region //*fLog << "MHFindSignificance::FindSigma; calling FitPolynomial()" << endl; if ( !FitPolynomial() ) { *fLog << "MHFindSignificance::FindSigma; FitPolynomial failed" << endl; return kFALSE; } //-------------------------------------------- // calculate the number of excess events in the signal region //*fLog << "MHFindSignificance::FindSigma; calling DetExcess()" << endl; if ( !DetExcess() ) { *fLog << "MHFindSignificance::FindSigma; DetExcess failed" << endl; return kFALSE; } //-------------------------------------------- // calculate the significance of the excess //*fLog << "MHFindSignificance::FindSigma; calling SigmaLiMa()" << endl; Double_t siglima = 0.0; if ( !SigmaLiMa(fNon, fNoff, fGamma, &siglima) ) { *fLog << "MHFindSignificance::FindSigma; SigmaLiMa failed" << endl; return kFALSE; } fSigLiMa = siglima; //-------------------------------------------- // calculate the error of the number of excess events fdNex = fNex / fSigLiMa; //-------------------------------------------- //*fLog << "MHFindSignificance::FindSigma; calling PrintPoly()" << endl; if (print) PrintPoly(); //-------------------------------------------- // fit a (polynomial + Gauss) function if (fFitGauss) { //-------------------------------------------------- // delete objects from this fit // in order to have independent starting conditions for the next fit delete gMinuit; gMinuit = NULL; //-------------------------------------------------- //*fLog << "MHFindSignificance::FindSigma; calling FitGaussPoly()" // << endl; if ( !FitGaussPoly() ) { *fLog << "MHFindSignificance::FindSigma; FitGaussPoly failed" << endl; return kFALSE; } if (print) { //*fLog << "MHFindSignificance::FindSigma; calling PrintPolyGauss()" // << endl; PrintPolyGauss(); } } //-------------------------------------------------- // draw the histogram if requested if (fDraw) { //*fLog << "MHFindSignificance::FindSigma; calling DrawFit()" << endl; if ( !DrawFit() ) { *fLog << "MHFindSignificance::FindSigma; DrawFit failed" << endl; return kFALSE; } } //-------------------------------------------------- // delete objects from this fit // in order to have independent starting conditions for the next fit delete gMinuit; gMinuit = NULL; //-------------------------------------------------- return kTRUE; } // -------------------------------------------------------------------------- // // SigmaVsAlpha (like FindSigma. However, alphasig is scanned and // the significance is plotted versus alphasig) // // calls FitPolynomial to fit the background in the background region // // scan alphasig; for a given alphasig : // calls DetExcess to determine the number of excess events // calls SigmaLiMa to determine the significance of the gamma signal // in the range fAlphalow < |alpha| < alphasig // Bool_t MHFindSignificance::SigmaVsAlpha(TH1 *fhist, Double_t alphamin, Double_t alphamax, Int_t degree, Bool_t print) { //*fLog << "MHFindSignificance::SigmaVsAlpha;" << endl; fHistOrig = fhist; fHist = (TH1*)fHistOrig->Clone(); fHist->SetName(fhist->GetName()); fHist->Sumw2(); //fHist->SetNameTitle("alpha", "alpha plot"); fHist->SetXTitle("|alpha| [\\circ]"); fHist->SetYTitle("Counts"); fHist->UseCurrentStyle(); fAlphamin = alphamin; fAlphamax = alphamax; fAlphammm = (alphamin+alphamax)/2.0; fDegree = degree; //-------------------------------------------- // fit a polynomial in the background region //*fLog << "MHFindSignificance::SigmaVsAlpha calling FitPolynomial()" // << endl; if ( !FitPolynomial() ) { *fLog << "MHFindSignificance::SigmaVsAlpha; FitPolynomial() failed" << endl; return kFALSE; } //-------------------------------------------- // loop over different signal regions Int_t nsteps = 15; fSigVsAlpha = new TH1D("SigVsAlpha","Sigma vs Alpha", nsteps, 0.0, alphamin); fSigVsAlpha->SetXTitle("upper edge of signal region in |alpha| [\\circ]"); fSigVsAlpha->SetYTitle("Significance of gamma signal"); for (Int_t i=1; i<=nsteps; i++) { fAlphasig = fSigVsAlpha->GetBinCenter(i); if ( !DetExcess() ) { *fLog << "MHFindSignificance::SigmaVsAlpha; DetExcess() failed" << endl; continue; } Double_t siglima = 0.0; if ( !SigmaLiMa(fNon, fNoff, fGamma, &siglima) ) { *fLog << "MHFindSignificance::SigmaVsAlpha; SigmaLiMa() failed" << endl; continue; } fdNex = fNex / siglima; fSigVsAlpha->SetBinContent(i, siglima); if (print) PrintPoly(); } //-------------------------------------------- // plot significance versus alphasig TCanvas *ccc = new TCanvas("SigVsAlpha", "Sigma vs Alpha", 600, 600); gROOT->SetSelectedPad(NULL); gStyle->SetPadLeftMargin(0.05); ccc->cd(); fSigVsAlpha->DrawCopy(); ccc->Modified(); ccc->Update(); return kTRUE; } // -------------------------------------------------------------------------- // // FitPolynomial // // - create a clone 'fHist' of the |alpha| distribution 'fHistOrig' // - fit a polynomial of degree 'fDegree' to the alpha distribution // 'fHist' in the region alphamin < |alpha| < alphamax // // in pathological cases the histogram is rebinned before fitting // (this is done only if fRebin is kTRUE) // // if the highest coefficient of the polynomial is compatible with zero // the fit is repeated with a polynomial of lower degree // (this is done only if fReduceDegree is kTRUE) // // Bool_t MHFindSignificance::FitPolynomial() { //-------------------------------------------------- // check the histogram : // - calculate initial values of the parameters // - check for bins with zero entries // - set minimum errors // - save the original errors // - set errors huge outside the fit range // (in 'fcnpoly' points with huge errors will be ignored) Double_t dummy = 1.e20; Double_t mean; Double_t rms; Double_t nclose; Double_t nfar; Double_t a2init = 0.0; TArrayD saveError; Int_t nbins; Int_t nrebin = 1; //---------------- start while loop for rebinning ----------------- while(1) { fNzero = 0; fMbins = 0; fMlow = 0; fNbgtot = 0.0; fAlphami = 10000.0; fAlphamm = 10000.0; fAlphama = -10000.0; mean = 0.0; rms = 0.0; nclose = 0.0; nfar = 0.0; nbins = fHist->GetNbinsX(); saveError.Set(nbins); for (Int_t i=1; i<=nbins; i++) { saveError[i-1] = fHist->GetBinError(i); // bin should be completely contained in the fit range // (fAlphamin, fAlphamax) Double_t xlo = fHist->GetBinLowEdge(i); Double_t xup = fHist->GetBinLowEdge(i+1); if ( xlo >= fAlphamin-fEps && xlo <= fAlphamax+fEps && xup >= fAlphamin-fEps && xup <= fAlphamax+fEps ) { fMbins++; if ( xlo < fAlphami ) fAlphami = xlo; if ( xup > fAlphama ) fAlphama = xup; Double_t content = fHist->GetBinContent(i); fNbgtot += content; mean += content; rms += content*content; // count events in low-alpha and high-alpha region if ( xlo >= fAlphammm-fEps && xup >= fAlphammm-fEps) { nfar += content; if ( xlo < fAlphamm ) fAlphamm = xlo; if ( xup < fAlphamm ) fAlphamm = xup; } else { nclose += content; if ( xlo > fAlphamm ) fAlphamm = xlo; if ( xup > fAlphamm ) fAlphamm = xup; } // count bins with zero entry if (content <= 0.0) fNzero++; // set minimum error if (content < 9.0) { fMlow += 1; fHist->SetBinError(i, 3.0); } //*fLog << "Take : i, content, error = " <GetBinContent(i) << ", " // << fHist->GetBinError(i) << endl; continue; } // bin is not completely contained in the fit range : set error huge fHist->SetBinError(i, dummy); //*fLog << "Omit : i, content, error = " <GetBinContent(i) << ", " << fHist->GetBinError(i) // << endl; } // mean of entries/bin in the fit range if (fMbins > 0) { mean /= ((Double_t) fMbins); rms /= ((Double_t) fMbins); } rms = sqrt( rms - mean*mean ); // if there are no events in the background region // there is no reason for rebinning // and this is the condition for assuming a constant background (= 0) if (mean <= 0.0) break; Double_t helpmi = fAlphami*fAlphami*fAlphami; Double_t helpmm = fAlphamm*fAlphamm*fAlphamm; Double_t helpma = fAlphama*fAlphama*fAlphama; Double_t help = (helpma-helpmm) * (fAlphamm-fAlphami) - (helpmm-helpmi) * (fAlphama-fAlphamm); if (help != 0.0) a2init = ( (fAlphamm-fAlphami)*nfar - (fAlphama-fAlphamm)*nclose ) * 1.5 * fHist->GetBinWidth(1) / help; else a2init = 0.0; //-------------------------------------------- // rebin the histogram // - if a bin has no entries // - or if there are too many bins with too few entries // - or if the new bin width would exceed half the size of the // signal region if ( !fRebin || ( fNzero <= 0 && (Double_t)fMlow<0.05*(Double_t)fMbins ) || (Double_t)(nrebin+1)/(Double_t)nrebin * fHist->GetBinWidth(1) > fAlphasig/2.0 ) { //*fLog << "before break" << endl; break; } nrebin += 1; TString histname = fHist->GetName(); delete fHist; fHist = NULL; *fLog << "MHFindSignificance::FitPolynomial; rebin the |alpha| plot, grouping " << nrebin << " bins together" << endl; // TH1::Rebin doesn't work properly //fHist = fHistOrig->Rebin(nrebin, "Rebinned"); // use private routine RebinHistogram() fHist = new TH1F; fHist->Sumw2(); fHist->SetNameTitle(histname, histname); fHist->UseCurrentStyle(); // do rebinning such that x0 remains a lower bin edge Double_t x0 = 0.0; if ( !RebinHistogram(x0, nrebin) ) { *fLog << "MHFindSignificance::FitPolynomial; RebinHistgram() failed" << endl; return kFALSE; } fHist->SetXTitle("|alpha| [\\circ]"); fHist->SetYTitle("Counts"); } //---------------- end of while loop for rebinning ----------------- // if there are still too many bins with too few entries don't fit // and assume a constant background fConstantBackg = kFALSE; if ( fNzero > 0 || (Double_t)fMlow>0.05*(Double_t)fMbins ) { *fLog << "MHFindSignificance::FitPolynomial; polynomial fit not possible, fNzero, fMlow, fMbins = " << fNzero << ", " << fMlow << ", " << fMbins << endl; *fLog << " assume a constant background" << endl; fConstantBackg = kTRUE; fDegree = 0; TString funcname = "Poly"; Double_t xmin = 0.0; Double_t xmax = 90.0; TString formula = "[0]"; fPoly = new TF1(funcname, formula, xmin, xmax); TList *funclist = fHist->GetListOfFunctions(); funclist->Add(fPoly); //-------------------- Int_t nparfree = 1; fChisq = 0.0; fNdf = fMbins - nparfree; fProb = 0.0; fIstat = 0; fValues.Set(1); fErrors.Set(1); Double_t val, err; val = mean; err = sqrt( mean / (Double_t)fMbins ); fPoly->SetParameter(0, val); fPoly->SetParError (0, err); fValues[0] = val; fErrors[0] = err; fEma[0][0] = err*err; fCorr[0][0] = 1.0; //-------------------- //-------------------------------------------------- // reset the errors of the points in the histogram for (Int_t i=1; i<=nbins; i++) { fHist->SetBinError(i, saveError[i-1]); } return kTRUE; } //=========== start loop for reducing the degree ================== // of the polynomial while (1) { //-------------------------------------------------- // prepare fit of a polynomial : (a0 + a1*x + a2*x**2 + a3*x**3 + ...) TString funcname = "Poly"; Double_t xmin = 0.0; Double_t xmax = 90.0; TString formula = "[0]"; TString bra1 = "+["; TString bra2 = "]"; TString xpower = "*x"; TString newpower = "*x"; for (Int_t i=1; i<=fDegree; i++) { formula += bra1; formula += i; formula += bra2; formula += xpower; xpower += newpower; } //*fLog << "FitPolynomial : formula = " << formula << endl; fPoly = new TF1(funcname, formula, xmin, xmax); TList *funclist = fHist->GetListOfFunctions(); funclist->Add(fPoly); //------------------------ // attention : the dimensions must agree with those in CallMinuit() const UInt_t npar = fDegree+1; TString parname[npar]; TArrayD vinit(npar); TArrayD step(npar); TArrayD limlo(npar); TArrayD limup(npar); TArrayI fix(npar); vinit[0] = mean; vinit[2] = a2init; for (UInt_t j=0; jGetEntries(); // use the subsequernt loop if you want to apply the // constraint : uneven derivatives (at alpha=0) = zero for (UInt_t j=1; jmnstat(fmin, fedm, errdef, npari, nparx, fIstat); *fLog << "MHFindSignificance::FitPolynomial; fmin, fedm, errdef, npari, nparx, fIstat = " << fmin << ", " << fedm << ", " << errdef << ", " << npari << ", " << nparx << ", " << fIstat << endl; //------------------- // store the results Int_t nparfree = gMinuit!=NULL ? gMinuit->GetNumFreePars() : 0; fChisq = fmin; fNdf = fMbins - nparfree; fProb = TMath::Prob(fChisq, fNdf); // get fitted parameter values and errors fValues.Set(npar); fErrors.Set(npar); for (Int_t j=0; j<=fDegree; j++) { Double_t val, err; if (gMinuit) gMinuit->GetParameter(j, val, err); fPoly->SetParameter(j, val); fPoly->SetParError(j, err); fValues[j] = val; fErrors[j] = err; } //-------------------------------------------------- // if the highest coefficient (j0) of the polynomial // is consistent with zero reduce the degree of the polynomial Int_t j0 = 0; for (Int_t j=fDegree; j>1; j--) { // ignore fixed parameters if (fErrors[j] == 0) continue; // this is the highest coefficient j0 = j; break; } if (!fReduceDegree || j0==0 || TMath::Abs(fValues[j0]) > fErrors[j0]) break; // reduce the degree of the polynomial *fLog << "MHFindSignificance::FitPolynomial; reduce the degree of the polynomial from " << fDegree << " to " << (j0-2) << endl; fDegree = j0 - 2; funclist->Remove(fPoly); //if (fPoly) delete fPoly; fPoly = NULL; // delete the Minuit object in order to have independent starting // conditions for the next minimization //if (gMinuit) delete gMinuit; gMinuit = NULL; } //=========== end of loop for reducing the degree ================== // of the polynomial //-------------------------------------------------- // get the error matrix of the fitted parameters if (fIstat >= 1) { // error matrix was calculated if (gMinuit) gMinuit->mnemat(&fEmat[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; j<=fDegree; j++) { if (gMinuit) gMinuit->mnpout(j, name, val, err, bnd1, bnd2, jvarbl); for (Int_t k=0; k<=fDegree; k++) { if (gMinuit) gMinuit->mnpout(k, name, val, err, bnd1, bnd2, kvarbl); fEma[j][k] = jvarbl==0 || kvarbl==0 ? 0 : fEmat[jvarbl-1][kvarbl-1]; } } } else { // error matrix was not calculated, construct it *fLog << "MHFindSignificance::FitPolynomial; error matrix not defined" << endl; for (Int_t j=0; j<=fDegree; j++) { for (Int_t k=0; k<=fDegree; k++) fEma[j][k] = 0; fEma[j][j] = fErrors[j]*fErrors[j]; } } //-------------------------------------------------- // calculate correlation matrix for (Int_t j=0; j<=fDegree; j++) for (Int_t k=0; k<=fDegree; k++) { const Double_t sq = fEma[j][j]*fEma[k][k]; fCorr[j][k] = sq==0 ? 0 : fEma[j][k] / TMath::Sqrt(fEma[j][j]*fEma[k][k]); } //-------------------------------------------------- // reset the errors of the points in the histogram for (Int_t i=1; i<=nbins; i++) fHist->SetBinError(i, saveError[i-1]); return kTRUE; } // -------------------------------------------------------------------------- // // ReBinHistogram // // rebin the histogram 'fHistOrig' by grouping 'nrebin' bins together // put the result into the histogram 'fHist' // the rebinning is made such that 'x0' remains a lower bound of a bin // Bool_t MHFindSignificance::RebinHistogram(Double_t x0, Int_t nrebin) { //----------------------------------------- // search bin i0 which has x0 as lower edge Int_t i0 = -1; Int_t nbold = fHistOrig->GetNbinsX(); for (Int_t i=1; i<=nbold; i++) { if (TMath::Abs(fHistOrig->GetBinLowEdge(i) - x0) < 1.e-4 ) { i0 = i; break; } } if (i0 == -1) { i0 = 1; *fLog << "MHFindsignificance::Rebin; no bin found with " << x0 << " as lower edge, start rebinning with bin 1" << endl; } Int_t istart = i0 - nrebin * ( (i0-1)/nrebin ); //----------------------------------------- // get new bin edges const Int_t nbnew = (nbold-istart+1) / nrebin; const Double_t xmin = fHistOrig->GetBinLowEdge(istart); const Double_t xmax = xmin + (Double_t)nbnew * nrebin * fHistOrig->GetBinWidth(1); fHist->SetBins(nbnew, xmin, xmax); *fLog << "MHFindSignificance::ReBin; x0, i0, nbold, nbnew, xmin, xmax = " << x0 << ", " << i0 << ", " << nbold << ", " << nbnew << ", " << xmin << ", " << xmax << endl; //----------------------------------------- // get new bin entries for (Int_t i=1; i<=nbnew; i++) { Int_t j = nrebin*(i-1) + istart; Double_t content = 0; Double_t error2 = 0; for (Int_t k=0; kGetBinContent(j+k); error2 += fHistOrig->GetBinError(j+k) * fHistOrig->GetBinError(j+k); } fHist->SetBinContent(i, content); fHist->SetBinError (i, sqrt(error2)); } fHist->SetEntries( fHistOrig->GetEntries() ); return kTRUE; } // -------------------------------------------------------------------------- // // FitGaussPoly // // fits a (Gauss + polynomial function) to the alpha distribution 'fhist' // // Bool_t MHFindSignificance::FitGaussPoly() { *fLog << "Entry FitGaussPoly" << endl; //-------------------------------------------------- // check the histogram : // - calculate initial values of the parameters // - check for bins with zero entries // - set minimum errors // - save the original errors // - set errors huge outside the fit range // (in 'fcnpoly' points with huge errors will be ignored) Double_t dummy = 1.e20; fGNzero = 0; fGMbins = 0; //------------------------------------------ // if a constant background has been assumed (due to low statistics) // fit only in the signal region if ( !fConstantBackg ) { fAlphalow = 0.0; fAlphahig = fAlphamax; } else { fAlphalow = 0.0; fAlphahig = 2.0*fAlphasig>25.0 ? 25.0 : 2.0*fAlphasig; } //------------------------------------------ fAlphalo = 10000.0; fAlphahi = -10000.0; Int_t nbins = fHist->GetNbinsX(); TArrayD saveError(nbins); for (Int_t i=1; i<=nbins; i++) { saveError[i-1] = fHist->GetBinError(i); // bin should be completely contained in the fit range // (fAlphalow, fAlphahig) Double_t xlo = fHist->GetBinLowEdge(i); Double_t xup = fHist->GetBinLowEdge(i+1); if ( xlo >= fAlphalow-fEps && xlo <= fAlphahig+fEps && xup >= fAlphalow-fEps && xup <= fAlphahig+fEps ) { fGMbins++; if ( xlo < fAlphalo ) fAlphalo = xlo; if ( xup > fAlphahi ) fAlphahi = xup; Double_t content = fHist->GetBinContent(i); // count bins with zero entry if (content <= 0.0) fGNzero++; // set minimum error if (content < 9.0) fHist->SetBinError(i, 3.0); //*fLog << "Take : i, content, error = " <GetBinContent(i) << ", " // << fHist->GetBinError(i) << endl; continue; } // bin is not completely contained in the fit range : set error huge fHist->SetBinError(i, dummy); //*fLog << "Omit : i, content, error = " <GetBinContent(i) << ", " << fHist->GetBinError(i) // << endl; } // if a bin has no entries don't fit if (fGNzero > 0) { *fLog << "MHFindSignificance::FitGaussPoly; out of " << fGMbins << " bins there are " << fGNzero << " bins with zero entry" << endl; fGPoly = NULL; return kFALSE; } //-------------------------------------------------- // prepare fit of a (polynomial+Gauss) : // (a0 + a1*x + a2*x**2 + a3*x**3 + ...) + A*exp( -0.5*((x-x0)/sigma)**2 ) TString funcname = "PolyGauss"; Double_t xmin = 0.0; Double_t xmax = 90.0; TString xpower = "*x"; TString newpower = "*x"; TString formulaBackg = "[0]"; for (Int_t i=1; i<=fDegree; i++) formulaBackg += Form("+[%d]*x^%d", i, i); const TString formulaGauss = Form("[%d]/[%d]*exp(-0.5*((x-[%d])/[%d])^2)", fDegree+1, fDegree+3, fDegree+2, fDegree+3); TString formula = formulaBackg; formula += "+"; formula += formulaGauss; *fLog << "FitGaussPoly : formulaBackg = " << formulaBackg << endl; *fLog << "FitGaussPoly : formulaGauss = " << formulaGauss << endl; *fLog << "FitGaussPoly : formula = " << formula << endl; fGPoly = new TF1(funcname, formula, xmin, xmax); TList *funclist = fHist->GetListOfFunctions(); funclist->Add(fGPoly); fGBackg = new TF1("Backg", formulaBackg, xmin, xmax); funclist->Add(fGBackg); //------------------------ // attention : the dimensions must agree with those in CallMinuit() Int_t npar = fDegree+1 + 3; TString parname[npar]; TArrayD vinit(npar); TArrayD step(npar); TArrayD limlo(npar); TArrayD limup(npar); TArrayI fix(npar); // take as initial values for the polynomial // the result from the polynomial fit for (Int_t j=0; j<=fDegree; j++) vinit[j] = fPoly->GetParameter(j); Double_t sigma = 8; vinit[fDegree+1] = 2.0 * fNex * fHist->GetBinWidth(1) / TMath::Sqrt(TMath::Pi()*2); vinit[fDegree+2] = 0; vinit[fDegree+3] = sigma; *fLog << "FitGaussPoly : starting value for Gauss-amplitude = " << vinit[fDegree+1] << endl; for (Int_t j=0; jGetEntries()*10; // limit the sigma of the Gauss function limup[fDegree+3] = 20; // use the subsequernt loop if you want to apply the // constraint : uneven derivatives (at alpha=0) = zero for (Int_t j=1; j<=fDegree; j+=2) { vinit[j] = 0; step[j] = 0; fix[j] = 1; } // fix position of Gauss function vinit[fDegree+2] = 0; step[fDegree+2] = 0; fix[fDegree+2] = 1; // if a constant background has been assumed (due to low statistics) // fix the background if (fConstantBackg) { step[0] = 0; fix[0] = 1; } MMinuitInterface inter; const Bool_t rc = inter.CallMinuit(fcnpolygauss, parname, vinit, step, limlo, limup, fix, fHist, "Migrad", kFALSE); if (rc != 0) { // *fLog << "MHFindSignificance::FitGaussPoly; (polynomial+Gauss) fit failed" // << endl; // return kFALSE; } //------------------- // get status of the minimization Double_t fmin; Double_t fedm; Double_t errdef; Int_t npari; Int_t nparx; if (gMinuit) gMinuit->mnstat(fmin, fedm, errdef, npari, nparx, fGIstat); *fLog << "MHFindSignificance::FitGaussPoly; fmin, fedm, errdef, npari, nparx, fGIstat = " << fmin << ", " << fedm << ", " << errdef << ", " << npari << ", " << nparx << ", " << fGIstat << endl; //------------------- // store the results Int_t nparfree = gMinuit!=NULL ? gMinuit->GetNumFreePars() : 0; fGChisq = fmin; fGNdf = fGMbins - nparfree; fGProb = TMath::Prob(fGChisq, fGNdf); // get fitted parameter values and errors fGValues.Set(npar); fGErrors.Set(npar); for (Int_t j=0; jGetParameter(j, val, err); fGPoly->SetParameter(j, val); fGPoly->SetParError(j, err); fGValues[j] = val; fGErrors[j] = err; if (j <=fDegree) { fGBackg->SetParameter(j, val); fGBackg->SetParError(j, err); } } fSigmaGauss = fGValues[fDegree+3]; fdSigmaGauss = fGErrors[fDegree+3]; // fitted total number of excess events fNexGauss = fGValues[fDegree+1] * TMath::Sqrt(TMath::Pi()*2) / (fHist->GetBinWidth(1)*2 ); fdNexGauss = fNexGauss * fGErrors[fDegree+1]/fGValues[fDegree+1]; //-------------------------------------------------- // get the error matrix of the fitted parameters if (fGIstat >= 1) { // error matrix was calculated if (gMinuit) gMinuit->mnemat(&fGEmat[0][0], fGNdim); // 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); fGEma[j][k] = jvarbl==0 || kvarbl==0 ? 0 : fGEmat[jvarbl-1][kvarbl-1]; } } } else { // error matrix was not calculated, construct it *fLog << "MHFindSignificance::FitPolynomial; error matrix not defined" << endl; for (Int_t j=0; jSetBinError(i, saveError[i-1]); return kTRUE; } // -------------------------------------------------------------------------- // // DetExcess // // using the result of the polynomial fit (fValues), DetExcess determines // // - the total number of events in the signal region (fNon) // - the number of backgound events in the signal region (fNbg) // - the number of excess events (fNex) // - the effective number of background events (fNoff), and fGamma : // fNbg = fGamma * fNoff; fdNbg = fGamma * sqrt(fNoff); // // It assumed that the polynomial is defined as // a0 + a1*x + a2*x**2 + a3*x**3 + .. // // and that the alpha distribution has the range 0 < alpha < 90 degrees // Bool_t MHFindSignificance::DetExcess() { //*fLog << "MHFindSignificance::DetExcess;" << endl; //-------------------------------------------- // calculate the total number of events (fNon) in the signal region fNon = 0.0; fdNon = 0.0; Double_t alphaup = -1000.0; Double_t binwidth = fHist->GetBinWidth(1); Int_t nbins = fHist->GetNbinsX(); for (Int_t i=1; i<=nbins; i++) { Double_t xlo = fHist->GetBinLowEdge(i); Double_t xup = fHist->GetBinLowEdge(i+1); // bin must be completely contained in the signal region if ( xlo <= (fAlphasig+fEps) && xup <= (fAlphasig+fEps) ) { Double_t width = fabs(xup-xlo); if (fabs(width-binwidth) > fEps) { *fLog << "MHFindSignificance::DetExcess; alpha plot has variable binning, which is not allowed" << endl; return kFALSE; } if (xup > alphaup) alphaup = xup; fNon += fHist->GetBinContent(i); fdNon += fHist->GetBinError(i) * fHist->GetBinError(i); } } fdNon = sqrt(fdNon); // the actual signal range is : if (alphaup == -1000.0) return kFALSE; fAlphasi = alphaup; //*fLog << "fAlphasi, fNon, fdNon, binwidth, fDegree = " << fAlphasi << ", " // << fNon << ", " << fdNon << ", " << binwidth << ", " // << fDegree << endl; //-------------------------------------------- // calculate the number of background events (fNbg) in the signal region // and its error (fdNbg) Double_t fac = 1.0/binwidth; fNbg = 0.0; Double_t altothejplus1 = fAlphasi; for (Int_t j=0; j<=fDegree; j++) { fNbg += fValues[j] * altothejplus1 / ((Double_t)(j+1)); altothejplus1 *= fAlphasi; } fNbg *= fac; // derivative of Nbg Double_t facj; Double_t fack; Double_t sum = 0.0; altothejplus1 = fAlphasi; for (Int_t j=0; j<=fDegree; j++) { facj = altothejplus1 / ((Double_t)(j+1)); Double_t altothekplus1 = fAlphasi; for (Int_t k=0; k<=fDegree; k++) { fack = altothekplus1 / ((Double_t)(k+1)); sum += facj * fack * fEma[j][k]; altothekplus1 *= fAlphasi; } altothejplus1 *= fAlphasi; } sum *= fac*fac; if (sum < 0.0) { *fLog << "MHFindsignificance::DetExcess; error squared is negative" << endl; return kFALSE; } fdNbg = sqrt(sum); //-------------------------------------------- // AS A CHECK : // calculate the number of background events (fNbgtotFitted) in the // background region, and its error (fdNbgtotFitted) // expect fdnbg to be approximately equal to sqrt(fNbgtotFitted) Double_t fNmi = 0.0; altothejplus1 = fAlphami; for (Int_t j=0; j<=fDegree; j++) { fNmi += fValues[j] * altothejplus1 / ((Double_t)(j+1)); altothejplus1 *= fAlphami; } fNmi *= fac; Double_t fNma = 0.0; altothejplus1 = fAlphama; for (Int_t j=0; j<=fDegree; j++) { fNma += fValues[j] * altothejplus1 / ((Double_t)(j+1)); altothejplus1 *= fAlphama; } fNma *= fac; fNbgtotFitted = fNma - fNmi; //---------------------- sum = 0.0; Double_t altothejma = fAlphama; Double_t altothejmi = fAlphami; for (Int_t j=0; j<=fDegree; j++) { facj = (altothejma-altothejmi) / ((Double_t)(j+1)); Double_t altothekma = fAlphama; Double_t altothekmi = fAlphami; for (Int_t k=0; k<=fDegree; k++) { fack = (altothekma-altothekmi) / ((Double_t)(k+1)); sum += facj * fack * fEma[j][k]; altothekma *= fAlphama; altothekmi *= fAlphami; } altothejma *= fAlphama; altothejmi *= fAlphami; } sum *= fac*fac; fdNbgtotFitted = sqrt(sum); if ( fabs(fdNbgtotFitted - sqrt(fNbgtotFitted)) > 0.2 * sqrt(fNbgtotFitted) ) { *fLog << "MHFindSignificance::DetExcess; error of calculated number of background events (in the background region) does not agree with the expectation :" << endl; *fLog << " fNbgtotFitted, fdNbgtotFitted = " << fNbgtotFitted << ", " << fdNbgtotFitted << ", expected : " << sqrt(fNbgtotFitted) << endl; } //-------------------------------------------- // calculate the number of excess events in the signal region fNex = fNon - fNbg; //-------------------------------------------- // calculate the effective number of background events (fNoff) , and fGamma : // fNbg = fGamma * fNoff; dfNbg = fGamma * sqrt(fNoff); if (fNbg < 0.0) { *fLog << "MHFindSignificamce::DetExcess; number of background events is negative, fNbg, fdNbg = " << fNbg << ", " << fdNbg << endl; fGamma = 1.0; fNoff = 0.0; return kFALSE; } if (fNbg > 0.0) { fGamma = fdNbg*fdNbg / fNbg; fNoff = fNbg*fNbg / (fdNbg*fdNbg); } else { fGamma = 1.0; fNoff = 0.0; } //*fLog << "Exit DetExcess()" << endl; return kTRUE; } // -------------------------------------------------------------------------- // // SigmaLiMa // // calculates the significance according to Li & Ma // ApJ 272 (1983) 317 // Bool_t MHFindSignificance::SigmaLiMa(Double_t non, Double_t noff, Double_t gamma, Double_t *siglima) { if (gamma <= 0.0 || non <= 0.0 || noff <= 0.0) { *siglima = 0.0; return kFALSE; } Double_t help1 = non * log( (1.0+gamma)*non / (gamma*(non+noff)) ); Double_t help2 = noff * log( (1.0+gamma)*noff / ( non+noff ) ); *siglima = sqrt( 2.0 * (help1+help2) ); Double_t nex = non - gamma*noff; if (nex < 0.0) *siglima = - *siglima; //*fLog << "MHFindSignificance::SigmaLiMa; non, noff, gamma, *siglima = " // << non << ", " << noff << ", " << gamma << ", " << *siglima << endl; return kTRUE; } // -------------------------------------------------------------------------- // Bool_t MHFindSignificance::DrawFit(const Option_t *opt) { if (fHist == NULL) *fLog << "MHFindSignificance::DrawFit; fHist = NULL" << endl; //TCanvas *fCanvas = new TCanvas("Alpha", "Alpha plot", 600, 600); // fCanvas = new TCanvas(fHist->GetName(), "Alpha plot", 600, 600); TVirtualPad *c = gPad ? gPad : MakeDefCanvas(this); //gStyle->SetOptFit(1011); gROOT->SetSelectedPad(NULL); gStyle->SetPadLeftMargin(0.1); // fCanvas->cd(); c->cd(); if (fHist) { fHist->DrawCopy(); } TF1 *fpoly = fHist->GetFunction("Poly"); if (fpoly == NULL) *fLog << "MHFindSignificance::DrawFit; fpoly = NULL" << endl; if (fpoly) { // 2, 1 is red and solid fpoly->SetLineColor(2); fpoly->SetLineStyle(1); fpoly->SetLineWidth(2); fpoly->DrawCopy("same"); } if (fFitGauss) { TF1 *fpolygauss = fHist->GetFunction("PolyGauss"); if (fpolygauss == NULL) *fLog << "MHFindSignificance::DrawFit; fpolygauss = NULL" << endl; if (fpolygauss) { // 4, 1 is blue and solid fpolygauss->SetLineColor(4); fpolygauss->SetLineStyle(1); fpolygauss->SetLineWidth(4); fpolygauss->DrawCopy("same"); } TF1 *fbackg = fHist->GetFunction("Backg"); if (fbackg == NULL) *fLog << "MHFindSignificance::DrawFit; fbackg = NULL" << endl; if (fbackg) { // 6, 4 is pink and dotted fbackg->SetLineColor(4); fbackg->SetLineStyle(4); fbackg->SetLineWidth(4); fbackg->DrawCopy("same"); } } //------------------------------- // print results onto the figure TPaveText *pt = new TPaveText(0.30, 0.35, 0.70, 0.90, "NDC"); char tx[100]; sprintf(tx, "Results of polynomial fit (order %2d) :", fDegree); TText *t1 = pt->AddText(tx); t1->SetTextSize(0.03); t1->SetTextColor(2); sprintf(tx, " (%6.2f< |alpha| <%6.2f [\\circ])", fAlphami, fAlphama); pt->AddText(tx); sprintf(tx, " chi2 = %8.2f, Ndof = %4d, Prob = %6.2f", fChisq, fNdf, fProb); pt->AddText(tx); sprintf(tx, " Nbgtot(fit) = %8.1f #pm %8.1f", fNbgtotFitted, fdNbgtotFitted); pt->AddText(tx); sprintf(tx, " Nbgtot(meas) = %8.1f", fNbgtot); pt->AddText(tx); //sprintf(tx, " "); //pt->AddText(tx); //-------------- sprintf(tx, "Results for |alpha|< %6.2f [\\circ] :", fAlphasi); TText *t6 = pt->AddText(tx); t6->SetTextSize(0.03); t6->SetTextColor(8); sprintf(tx, " Non = %8.1f #pm %8.1f", fNon, fdNon); pt->AddText(tx); sprintf(tx, " Nex = %8.1f #pm %8.1f", fNex, fdNex); pt->AddText(tx); sprintf(tx, " Nbg = %8.1f #pm %8.1f, gamma = %6.1f", fNbg, fdNbg, fGamma); pt->AddText(tx); Double_t ratio = fNbg>0.0 ? fNex/fNbg : 0.0; sprintf(tx, " Significance = %6.2f, Nex/Nbg = %6.2f", fSigLiMa, ratio); pt->AddText(tx); //sprintf(tx, " "); //pt->AddText(tx); //-------------- if (fFitGauss) { sprintf(tx, "Results of (polynomial+Gauss) fit :"); TText *t7 = pt->AddText(tx); t7->SetTextSize(0.03); t7->SetTextColor(4); sprintf(tx, " chi2 = %8.2f, Ndof = %4d, Prob = %6.2f", fGChisq, fGNdf, fGProb); pt->AddText(tx); sprintf(tx, " Sigma of Gauss�= %8.1f #pm %8.1f [\\circ]", fSigmaGauss, fdSigmaGauss); pt->AddText(tx); sprintf(tx, " total no.of excess events = %8.1f #pm %8.1f", fNexGauss, fdNexGauss); pt->AddText(tx); } //-------------- pt->SetFillStyle(0); pt->SetBorderSize(0); pt->SetTextAlign(12); pt->Draw(); // fCanvas->Modified(); // fCanvas->Update(); c->Modified(); c->Update(); return kTRUE; } // -------------------------------------------------------------------------- // // Print the results of the polynomial fit to the alpha distribution // // void MHFindSignificance::PrintPoly(Option_t *o) { *fLog << "---------------------------" << endl; *fLog << "MHFindSignificance::PrintPoly :" << endl; *fLog << "fAlphami, fAlphama, fDegree, fAlphasi = " << fAlphami << ", " << fAlphama << ", " << fDegree << ", " << fAlphasi << endl; *fLog << "fMbins, fNzero, fIstat = " << fMbins << ", " << fNzero << ", " << fIstat << endl; *fLog << "fChisq, fNdf, fProb = " << fChisq << ", " << fNdf << ", " << fProb << endl; *fLog << "fNon, fNbg, fdNbg, fNbgtot, fNbgtotFitted, fdNbgtotFitted = " << fNon << ", " << fNbg << ", " << fdNbg << ", " << fNbgtot << ", " << fNbgtotFitted << ", " << fdNbgtotFitted << endl; Double_t sigtoback = fNbg>0.0 ? fNex/fNbg : 0.0; *fLog << "fNex, fdNex, fGamma, fNoff, fSigLiMa, sigtoback = " << fNex << ", " << fdNex << ", " << fGamma << ", " << fNoff << ", " << fSigLiMa << ", " << sigtoback << endl; //------------------------------------ // get errors /* Double_t eplus; Double_t eminus; Double_t eparab; Double_t gcc; Double_t errdiag; if ( !fConstantBackg ) { *fLog << "parameter value error eplus eminus eparab errdiag gcc" << endl; for (Int_t j=0; j<=fDegree; j++) { if (gMinuit) gMinuit->mnerrs(j, eplus, eminus, eparab, gcc); errdiag = sqrt(fEma[j][j]); *fLog << j << " " << fValues[j] << " " << fErrors[j] << " " << eplus << " " << eminus << " " << eparab << " " << errdiag << " " << gcc << endl; } } else { *fLog << "parameter value error errdiag " << endl; for (Int_t j=0; j<=fDegree; j++) { errdiag = sqrt(fEma[j][j]); *fLog << j << " " << fValues[j] << " " << fErrors[j] << " " << errdiag << endl; } } */ //---------------------------------------- /* *fLog << "Covariance matrix :" << endl; for (Int_t j=0; j<=fDegree; j++) { *fLog << "j = " << j << " : "; for (Int_t k=0; k<=fDegree; k++) { *fLog << fEma[j][k] << " "; } *fLog << endl; } *fLog << "Correlation matrix :" << endl; for (Int_t j=0; j<=fDegree; j++) { *fLog << "j = " << j << " : "; for (Int_t k=0; k<=fDegree; k++) { *fLog << fCorr[j][k] << " "; } *fLog << endl; } */ *fLog << "---------------------------" << endl; } // -------------------------------------------------------------------------- // // Print the results of the (polynomial+Gauss) fit to the alpha distribution // // void MHFindSignificance::PrintPolyGauss(Option_t *o) { *fLog << "---------------------------" << endl; *fLog << "MHFindSignificance::PrintPolyGauss :" << endl; *fLog << "fAlphalo, fAlphahi = " << fAlphalo << ", " << fAlphahi << endl; *fLog << "fGMbins, fGNzero, fGIstat = " << fGMbins << ", " << fGNzero << ", " << fGIstat << endl; *fLog << "fGChisq, fGNdf, fGProb = " << fGChisq << ", " << fGNdf << ", " << fGProb << endl; //------------------------------------ // get errors Double_t eplus; Double_t eminus; Double_t eparab; Double_t gcc; Double_t errdiag; *fLog << "parameter value error eplus eminus eparab errdiag gcc" << endl; for (Int_t j=0; j<=(fDegree+3); j++) { if (gMinuit) gMinuit->mnerrs(j, eplus, eminus, eparab, gcc); errdiag = sqrt(fGEma[j][j]); *fLog << j << " " << fGValues[j] << " " << fGErrors[j] << " " << eplus << " " << eminus << " " << eparab << " " << errdiag << " " << gcc << endl; } *fLog << "Covariance matrix :" << endl; for (Int_t j=0; j<=(fDegree+3); j++) { *fLog << "j = " << j << " : "; for (Int_t k=0; k<=(fDegree+3); k++) { *fLog << fGEma[j][k] << " "; } *fLog << endl; } *fLog << "Correlation matrix :" << endl; for (Int_t j=0; j<=(fDegree+3); j++) { *fLog << "j = " << j << " : "; for (Int_t k=0; k<=(fDegree+3); k++) { *fLog << fGCorr[j][k] << " "; } *fLog << endl; } *fLog << "---------------------------" << endl; } //============================================================================