#include <BSFitter.h>
_________________________________________________________________ class: BSFitter.h package: RecoVertex/BeamSpotProducer
author: Francisco Yumiceva, Fermilab (yumiceva@fnal.gov)
version
________________________________________________________________
Definition at line 32 of file BSFitter.h.
BSFitter::BSFitter | ( | ) |
Definition at line 43 of file BSFitter.cc.
References Unknown.
{ fbeamtype = reco::BeamSpot::Unknown; }
BSFitter::BSFitter | ( | const std::vector< BSTrkParameters > & | BSvector | ) |
Definition at line 48 of file BSFitter.cc.
References Pi, and mathSSE::sqrt().
{ ffit_type = "default"; ffit_variable = "default"; fBSvector = BSvector; fsqrt2pi = sqrt(2.* TMath::Pi()); fpar_name[0] = "z0 "; fpar_name[1] = "SigmaZ0 "; fpar_name[2] = "X0 "; fpar_name[3] = "Y0 "; fpar_name[4] = "dxdz "; fpar_name[5] = "dydz "; fpar_name[6] = "SigmaBeam "; //if (theGausszFcn == 0 ) { thePDF = new BSpdfsFcn(); //} //if (theFitter == 0 ) { theFitter = new VariableMetricMinimizer(); //} fapplyd0cut = false; fapplychi2cut = false; ftmprow = 0; ftmp.ResizeTo(4,1); ftmp.Zero(); fnthite=0; fMaxZ = 50.; //cm fconvergence = 0.5; // stop fit when 50% of the input collection has been removed. fminNtrks = 100; finputBeamWidth = -1; // no input h1z = new TH1F("h1z","z distribution",200,-fMaxZ, fMaxZ); }
BSFitter::~BSFitter | ( | ) | [virtual] |
Definition at line 92 of file BSFitter.cc.
void BSFitter::d0phi_Init | ( | ) | [inline] |
reco::BeamSpot BSFitter::Fit | ( | ) |
Definition at line 101 of file BSFitter.cc.
Referenced by BeamFitter::runAllFitter(), BeamFitter::runBeamWidthFitter(), and BeamFitter::runFitterNoTxt().
{ return this->Fit(0); }
reco::BeamSpot BSFitter::Fit | ( | double * | inipar = 0 | ) |
Definition at line 108 of file BSFitter.cc.
References reco::BeamSpot::BeamWidthX(), reco::BeamSpot::covariance(), reco::BeamSpot::dxdz(), reco::BeamSpot::dydz(), Exception, edm::isNotFinite(), makeMuonMisalignmentScenario::matrix, funct::pow(), alignCSCRings::s, reco::BeamSpot::setType(), reco::BeamSpot::sigmaZ(), Unknown, reco::BeamSpot::Unknown, reco::BeamSpot::x0(), reco::BeamSpot::y0(), and reco::BeamSpot::z0().
{ fbeamtype = reco::BeamSpot::Unknown; if ( ffit_variable == "z" ) { if ( ffit_type == "chi2" ) { return Fit_z_chi2(inipar); } else if ( ffit_type == "likelihood" ) { return Fit_z_likelihood(inipar); } else if ( ffit_type == "combined" ) { reco::BeamSpot tmp_beamspot = Fit_z_chi2(inipar); double tmp_par[2] = {tmp_beamspot.z0(), tmp_beamspot.sigmaZ()}; return Fit_z_likelihood(tmp_par); } else { throw cms::Exception("LogicError") << "Error in BeamSpotProducer/BSFitter: " << "Illegal fit type, options are chi2,likelihood or combined(ie. first chi2 then likelihood)"; } } else if ( ffit_variable == "d" ) { if ( ffit_type == "d0phi" ) { this->d0phi_Init(); return Fit_d0phi(); } else if ( ffit_type == "likelihood" ) { return Fit_d_likelihood(inipar); } else if ( ffit_type == "combined" ) { this->d0phi_Init(); reco::BeamSpot tmp_beamspot = Fit_d0phi(); double tmp_par[4] = {tmp_beamspot.x0(), tmp_beamspot.y0(), tmp_beamspot.dxdz(), tmp_beamspot.dydz()}; return Fit_d_likelihood(tmp_par); } else { throw cms::Exception("LogicError") << "Error in BeamSpotProducer/BSFitter: " << "Illegal fit type, options are d0phi, likelihood or combined"; } } else if ( ffit_variable == "d*z" || ffit_variable == "default" ) { if ( ffit_type == "likelihood" || ffit_type == "default" ) { reco::BeamSpot::CovarianceMatrix matrix; // we are now fitting Z inside d0phi fitter // first fit z distribution using a chi2 fit //reco::BeamSpot tmp_z = Fit_z_chi2(inipar); //for (int j = 2 ; j < 4 ; ++j) { //for(int k = j ; k < 4 ; ++k) { // matrix(j,k) = tmp_z.covariance()(j,k); //} //} // use d0-phi algorithm to extract transverse position this->d0phi_Init(); //reco::BeamSpot tmp_d0phi= Fit_d0phi(); // change to iterative procedure: this->Setd0Cut_d0phi(4.0); reco::BeamSpot tmp_d0phi= Fit_ited0phi(); //for (int j = 0 ; j < 2 ; ++j) { // for(int k = j ; k < 2 ; ++k) { // matrix(j,k) = tmp_d0phi.covariance()(j,k); //} //} // slopes //for (int j = 4 ; j < 6 ; ++j) { // for(int k = j ; k < 6 ; ++k) { // matrix(j,k) = tmp_d0phi.covariance()(j,k); // } //} // put everything into one object reco::BeamSpot spot(reco::BeamSpot::Point(tmp_d0phi.x0(), tmp_d0phi.y0(), tmp_d0phi.z0()), tmp_d0phi.sigmaZ(), tmp_d0phi.dxdz(), tmp_d0phi.dydz(), 0., tmp_d0phi.covariance(), fbeamtype ); //reco::BeamSpot tmp_z = Fit_z_chi2(inipar); //reco::BeamSpot tmp_d0phi = Fit_d0phi(); // log-likelihood fit if (ffit_type == "likelihood") { double tmp_par[7] = {tmp_d0phi.x0(), tmp_d0phi.y0(), tmp_d0phi.z0(), tmp_d0phi.sigmaZ(), tmp_d0phi.dxdz(), tmp_d0phi.dydz(),0.0}; double tmp_error_par[7]; for(int s=0;s<6;s++){ tmp_error_par[s] = pow( tmp_d0phi.covariance()(s,s),0.5);} tmp_error_par[6]=0.0; reco::BeamSpot tmp_lh = Fit_d_z_likelihood(tmp_par,tmp_error_par); if (edm::isNotFinite(ff_minimum)) { edm::LogWarning("BSFitter") << "BSFitter: Result is non physical. Log-Likelihood fit to extract beam width did not converge." << std::endl; tmp_lh.setType(reco::BeamSpot::Unknown); return tmp_lh; } return tmp_lh; } else { edm::LogInfo("BSFitter") << "default track-based fit does not extract beam width." << std::endl; return spot; } } else if ( ffit_type == "resolution" ) { reco::BeamSpot tmp_z = Fit_z_chi2(inipar); this->d0phi_Init(); reco::BeamSpot tmp_d0phi = Fit_d0phi(); double tmp_par[7] = {tmp_d0phi.x0(), tmp_d0phi.y0(), tmp_z.z0(), tmp_z.sigmaZ(), tmp_d0phi.dxdz(), tmp_d0phi.dydz(),0.0}; double tmp_error_par[7]; for(int s=0;s<6;s++){ tmp_error_par[s] = pow(tmp_par[s],0.5);} tmp_error_par[6]=0.0; reco::BeamSpot tmp_beam = Fit_d_z_likelihood(tmp_par,tmp_error_par); double tmp_par2[7] = {tmp_beam.x0(), tmp_beam.y0(), tmp_beam.z0(), tmp_beam.sigmaZ(), tmp_beam.dxdz(), tmp_beam.dydz(), tmp_beam.BeamWidthX()}; reco::BeamSpot tmp_lh = Fit_dres_z_likelihood(tmp_par2); if (edm::isNotFinite(ff_minimum)) { edm::LogWarning("BSFitter") << "Result is non physical. Log-Likelihood fit did not converge." << std::endl; tmp_lh.setType(reco::BeamSpot::Unknown); return tmp_lh; } return tmp_lh; } else { throw cms::Exception("LogicError") << "Error in BeamSpotProducer/BSFitter: " << "Illegal fit type, options are likelihood or resolution"; } } else { throw cms::Exception("LogicError") << "Error in BeamSpotProducer/BSFitter: " << "Illegal variable type, options are \"z\", \"d\", or \"d*z\""; } }
reco::BeamSpot BSFitter::Fit_d0phi | ( | ) |
Definition at line 448 of file BSFitter.cc.
References abs, b, align::BeamSpot, funct::cos(), alignCSCRings::e, g, j, gen::k, makeMuonMisalignmentScenario::matrix, funct::sin(), mathSSE::sqrt(), and groupFilesInBlocks::temp.
Referenced by BeamFitter::runAllFitter().
{ //LogDebug ("BSFitter") << " we will use " << fBSvector.size() << " tracks."; if (fnthite > 0) edm::LogInfo("BSFitter") << " number of tracks used: " << ftmprow << std::endl; //std::cout << " ftmp = matrix("<<ftmp.GetNrows()<<","<<ftmp.GetNcols()<<")"<<std::endl; //std::cout << " ftmp(0,0)="<<ftmp(0,0)<<std::endl; //std::cout << " ftmp(1,0)="<<ftmp(1,0)<<std::endl; //std::cout << " ftmp(2,0)="<<ftmp(2,0)<<std::endl; //std::cout << " ftmp(3,0)="<<ftmp(3,0)<<std::endl; h1z->Reset(); TMatrixD x_result(4,1); TMatrixDSym V_result(4); TMatrixDSym Vint(4); TMatrixD b(4,1); //Double_t weightsum = 0; Vint.Zero(); b.Zero(); TMatrixD g(4,1); TMatrixDSym temp(4); std::vector<BSTrkParameters>::iterator iparam = fBSvector.begin(); ftmprow=0; //edm::LogInfo ("BSFitter") << " test"; //std::cout << "BSFitter: fit" << std::endl; for( iparam = fBSvector.begin() ; iparam != fBSvector.end() ; ++iparam) { //if(i->weight2 == 0) continue; //if (ftmprow==0) { //std::cout << "d0=" << iparam->d0() << " sigd0=" << iparam->sigd0() //<< " phi0="<< iparam->phi0() << " z0=" << iparam->z0() << std::endl; //std::cout << "d0phi_d0=" << iparam->d0phi_d0() << " d0phi_chi2="<<iparam->d0phi_chi2() << std::endl; //} g(0,0) = sin(iparam->phi0()); g(1,0) = -cos(iparam->phi0()); g(2,0) = iparam->z0() * g(0,0); g(3,0) = iparam->z0() * g(1,0); // average transverse beam width double sigmabeam2 = 0.006 * 0.006; if (finputBeamWidth > 0 ) sigmabeam2 = finputBeamWidth * finputBeamWidth; else { edm::LogWarning("BSFitter") << "using in fit beam width = " << sqrt(sigmabeam2) << std::endl; } //double sigma2 = sigmabeam2 + (iparam->sigd0())* (iparam->sigd0()) / iparam->weight2; // this should be 2*sigmabeam2? double sigma2 = sigmabeam2 + (iparam->sigd0())* (iparam->sigd0()); TMatrixD ftmptrans(1,4); ftmptrans = ftmptrans.Transpose(ftmp); TMatrixD dcor = ftmptrans * g; double chi2tmp = (iparam->d0() - dcor(0,0)) * (iparam->d0() - dcor(0,0))/sigma2; (*iparam) = BSTrkParameters(iparam->z0(),iparam->sigz0(),iparam->d0(),iparam->sigd0(), iparam->phi0(), iparam->pt(),dcor(0,0),chi2tmp); bool pass = true; if (fapplyd0cut && fnthite>0 ) { if ( std::abs(iparam->d0() - dcor(0,0)) > fd0cut ) pass = false; } if (fapplychi2cut && fnthite>0 ) { if ( chi2tmp > fchi2cut ) pass = false; } if (pass) { temp.Zero(); for(int j = 0 ; j < 4 ; ++j) { for(int k = j ; k < 4 ; ++k) { temp(j,k) += g(j,0) * g(k,0); } } Vint += (temp * (1 / sigma2)); b += (iparam->d0() / sigma2 * g); //weightsum += sqrt(i->weight2); ftmprow++; h1z->Fill( iparam->z0() ); } } Double_t determinant; TDecompBK bk(Vint); bk.SetTol(1e-11); //FIXME: find a better way to solve x_result if (!bk.Decompose()) { goodfit = false; edm::LogWarning("BSFitter") << "Decomposition failed, matrix singular ?" << std::endl << "condition number = " << bk.Condition() << std::endl; } else { V_result = Vint.InvertFast(&determinant); x_result = V_result * b; } // for(int j = 0 ; j < 4 ; ++j) { // for(int k = 0 ; k < 4 ; ++k) { // std::cout<<"V_result("<<j<<","<<k<<")="<<V_result(j,k)<<std::endl; // } // } // for (int j=0;j<4;++j){ // std::cout<<"x_result("<<j<<",0)="<<x_result(j,0)<<std::endl; // } //LogDebug ("BSFitter") << " d0-phi fit done."; //std::cout<< " d0-phi fit done." << std::endl; h1z->Fit("gaus","QLM0","",h1z->GetMean() -2.*h1z->GetRMS(),h1z->GetMean() +2.*h1z->GetRMS()); //std::cout << "fitted "<< std::endl; TF1 *fgaus = h1z->GetFunction("gaus"); //std::cout << "got function" << std::endl; if (!fgaus){ edm::LogError("NoBeamSpotFit")<<"gaussian fit failed. no BS d0 fit"; return reco::BeamSpot(); } double fpar[2] = {fgaus->GetParameter(1), fgaus->GetParameter(2) }; reco::BeamSpot::CovarianceMatrix matrix; // first two parameters for (int j = 0 ; j < 2 ; ++j) { for(int k = j ; k < 2 ; ++k) { matrix(j,k) = V_result(j,k); } } // slope parameters for (int j = 4 ; j < 6 ; ++j) { for(int k = j ; k < 6 ; ++k) { matrix(j,k) = V_result(j-2,k-2); } } // Z0 and sigmaZ matrix(2,2) = fgaus->GetParError(1) * fgaus->GetParError(1); matrix(3,3) = fgaus->GetParError(2) * fgaus->GetParError(2); ftmp = x_result; // x0 and y0 are *not* x,y at z=0, but actually at z=0 // to correct for this, we need to translate them to z=z0 // using the measured slopes // double x0tmp = x_result(0,0); double y0tmp = x_result(1,0); x0tmp += x_result(2,0)*fpar[0]; y0tmp += x_result(3,0)*fpar[0]; return reco::BeamSpot( reco::BeamSpot::Point(x0tmp, y0tmp, fpar[0]), fpar[1], x_result(2,0), x_result(3,0), 0., matrix, fbeamtype ); }
reco::BeamSpot BSFitter::Fit_d_likelihood | ( | double * | inipar | ) |
Definition at line 642 of file BSFitter.cc.
References align::BeamSpot, j, gen::k, and makeMuonMisalignmentScenario::matrix.
{ thePDF->SetPDFs("PDFGauss_d"); thePDF->SetData(fBSvector); MnUserParameters upar; upar.Add("X0", inipar[0],0.001); upar.Add("Y0", inipar[1],0.001); upar.Add("Z0", 0.,0.001); upar.Add("sigmaZ",0.,0.001); upar.Add("dxdz",inipar[2],0.001); upar.Add("dydz",inipar[3],0.001); MnMigrad migrad(*thePDF, upar); FunctionMinimum fmin = migrad(); ff_minimum = fmin.Fval(); reco::BeamSpot::CovarianceMatrix matrix; for (int j = 0 ; j < 6 ; ++j) { for(int k = j ; k < 6 ; ++k) { matrix(j,k) = fmin.Error().Matrix()(j,k); } } return reco::BeamSpot( reco::BeamSpot::Point(fmin.Parameters().Vec()(0), fmin.Parameters().Vec()(1), 0.), 0., fmin.Parameters().Vec()(4), fmin.Parameters().Vec()(5), 0., matrix, fbeamtype ); }
reco::BeamSpot BSFitter::Fit_d_z_likelihood | ( | double * | inipar, |
double * | error_par | ||
) |
Definition at line 771 of file BSFitter.cc.
References align::BeamSpot, j, gen::k, and makeMuonMisalignmentScenario::matrix.
{ int tracksFailed=0; //estimate first guess of beam width and tame 20% extra of it to start inipar[6]=scanPDF(inipar,tracksFailed,1); error_par[6]=(inipar[6])*0.20; //Here remove the tracks which give low pdf and fill into a new vector //std::cout<<"Size of Old vector = "<<(fBSvector.size())<<std::endl; /* double junk= */ scanPDF(inipar,tracksFailed,2); //std::cout<<"Size of New vector = "<<(fBSvectorBW.size())<<std::endl; //Refill the fBSVector again with new sets of tracks fBSvector.clear(); std::vector<BSTrkParameters>::const_iterator iparamBW = fBSvectorBW.begin(); for( iparamBW = fBSvectorBW.begin(); iparamBW != fBSvectorBW.end(); ++iparamBW) { fBSvector.push_back(*iparamBW); } thePDF->SetPDFs("PDFGauss_d*PDFGauss_z"); thePDF->SetData(fBSvector); MnUserParameters upar; upar.Add("X0", inipar[0],error_par[0]); upar.Add("Y0", inipar[1],error_par[1]); upar.Add("Z0", inipar[2],error_par[2]); upar.Add("sigmaZ",inipar[3],error_par[3]); upar.Add("dxdz",inipar[4],error_par[4]); upar.Add("dydz",inipar[5],error_par[5]); upar.Add("BeamWidthX",inipar[6],error_par[6]); MnMigrad migrad(*thePDF, upar); FunctionMinimum fmin = migrad(); // std::cout<<"-----how the fit evoves------"<<std::endl; // std::cout<<fmin<<std::endl; ff_minimum = fmin.Fval(); bool ff_nfcn=fmin.HasReachedCallLimit(); bool ff_cov=fmin.HasCovariance(); bool testing=fmin.IsValid(); //Print WARNINGS if minimum did not converged if( ! testing ) { edm::LogWarning("BSFitter") <<"===========>>>>>** WARNING: MINUIT DID NOT CONVERGES PROPERLY !!!!!!"<<std::endl; if(ff_nfcn) edm::LogWarning("BSFitter") <<"===========>>>>>** WARNING: No. of Calls Exhausted"<<std::endl; if(!ff_cov) edm::LogWarning("BSFitter") <<"===========>>>>>** WARNING: Covariance did not found"<<std::endl; } edm::LogInfo("BSFitter") <<"The Total # Tracks used for beam width fit = "<<(fBSvectorBW.size())<<std::endl; //Checks after fit is performed double lastIter_pars[7]; for(int ip=0;ip<7;ip++){ lastIter_pars[ip]=fmin.Parameters().Vec()(ip); } tracksFailed=0; /* double lastIter_scan= */ scanPDF(lastIter_pars,tracksFailed,2); edm::LogWarning("BSFitter") <<"WARNING: # of tracks which have very low pdf value (pdf_d < 1.0e-05) are = "<<tracksFailed<<std::endl; //std::cout << " eval= " << ff_minimum // << "/n params[0]= " << fmin.Parameters().Vec()(0) << std::endl; reco::BeamSpot::CovarianceMatrix matrix; for (int j = 0 ; j < 7 ; ++j) { for(int k = j ; k < 7 ; ++k) { matrix(j,k) = fmin.Error().Matrix()(j,k); } } return reco::BeamSpot( reco::BeamSpot::Point(fmin.Parameters().Vec()(0), fmin.Parameters().Vec()(1), fmin.Parameters().Vec()(2)), fmin.Parameters().Vec()(3), fmin.Parameters().Vec()(4), fmin.Parameters().Vec()(5), fmin.Parameters().Vec()(6), matrix, fbeamtype ); }
reco::BeamSpot BSFitter::Fit_dres_z_likelihood | ( | double * | inipar | ) |
Definition at line 874 of file BSFitter.cc.
References align::BeamSpot, j, gen::k, makeMuonMisalignmentScenario::matrix, and mathSSE::sqrt().
{ thePDF->SetPDFs("PDFGauss_d_resolution*PDFGauss_z"); thePDF->SetData(fBSvector); MnUserParameters upar; upar.Add("X0", inipar[0],0.001); upar.Add("Y0", inipar[1],0.001); upar.Add("Z0", inipar[2],0.001); upar.Add("sigmaZ",inipar[3],0.001); upar.Add("dxdz",inipar[4],0.001); upar.Add("dydz",inipar[5],0.001); upar.Add("BeamWidthX",inipar[6],0.0001); upar.Add("c0",0.0010,0.0001); upar.Add("c1",0.0090,0.0001); // fix beam width upar.Fix("BeamWidthX"); // number of parameters in fit are 9-1 = 8 MnMigrad migrad(*thePDF, upar); FunctionMinimum fmin = migrad(); ff_minimum = fmin.Fval(); reco::BeamSpot::CovarianceMatrix matrix; for (int j = 0 ; j < 6 ; ++j) { for(int k = j ; k < 6 ; ++k) { matrix(j,k) = fmin.Error().Matrix()(j,k); } } //std::cout << " fill resolution values" << std::endl; //std::cout << " matrix size= " << fmin.Error().Matrix().size() << std::endl; //std::cout << " vec(6)="<< fmin.Parameters().Vec()(6) << std::endl; //std::cout << " vec(7)="<< fmin.Parameters().Vec()(7) << std::endl; fresolution_c0 = fmin.Parameters().Vec()(6); fresolution_c1 = fmin.Parameters().Vec()(7); fres_c0_err = sqrt( fmin.Error().Matrix()(6,6) ); fres_c1_err = sqrt( fmin.Error().Matrix()(7,7) ); for (int j = 6 ; j < 8 ; ++j) { for(int k = 6 ; k < 8 ; ++k) { fres_matrix(j-6,k-6) = fmin.Error().Matrix()(j,k); } } return reco::BeamSpot( reco::BeamSpot::Point(fmin.Parameters().Vec()(0), fmin.Parameters().Vec()(1), fmin.Parameters().Vec()(2)), fmin.Parameters().Vec()(3), fmin.Parameters().Vec()(4), fmin.Parameters().Vec()(5), inipar[6], matrix, fbeamtype ); }
reco::BeamSpot BSFitter::Fit_ited0phi | ( | ) |
Definition at line 392 of file BSFitter.cc.
References reco::BeamSpot::Fake, reco::BeamSpot::setType(), align::Tracker, and Unknown.
Referenced by BeamFitter::runAllFitter().
{ this->d0phi_Init(); edm::LogInfo("BSFitter") << "number of total input tracks: " << fBSvector.size() << std::endl; reco::BeamSpot theanswer; if ( (int)fBSvector.size() <= fminNtrks ) { edm::LogWarning("BSFitter") << "need at least " << fminNtrks << " tracks to run beamline fitter." << std::endl; fbeamtype = reco::BeamSpot::Fake; theanswer.setType(fbeamtype); return theanswer; } theanswer = Fit_d0phi(); //get initial ftmp and ftmprow if ( goodfit ) fnthite++; //std::cout << "Initial tempanswer (iteration 0): " << theanswer << std::endl; reco::BeamSpot preanswer = theanswer; while ( goodfit && ftmprow > fconvergence * fBSvector.size() && ftmprow > fminNtrks ) { theanswer = Fit_d0phi(); fd0cut /= 1.5; fchi2cut /= 1.5; if ( goodfit && ftmprow > fconvergence * fBSvector.size() && ftmprow > fminNtrks ) { preanswer = theanswer; //std::cout << "Iteration " << fnthite << ": " << preanswer << std::endl; fnthite++; } } // FIXME: return fit results from previous iteration for both bad fit and for >50% tracks thrown away //std::cout << "The last iteration, theanswer: " << theanswer << std::endl; theanswer = preanswer; //std::cout << "Use previous results from iteration #" << ( fnthite > 0 ? fnthite-1 : 0 ) << std::endl; //if ( fnthite > 1 ) std::cout << theanswer << std::endl; edm::LogInfo("BSFitter") << "Total number of successful iterations = " << ( goodfit ? (fnthite+1) : fnthite ) << std::endl; if (goodfit) { fbeamtype = reco::BeamSpot::Tracker; theanswer.setType(fbeamtype); } else { edm::LogWarning("BSFitter") << "Fit doesn't converge!!!" << std::endl; fbeamtype = reco::BeamSpot::Unknown; theanswer.setType(fbeamtype); } return theanswer; }
reco::BeamSpot BSFitter::Fit_z | ( | std::string | type, |
double * | inipar | ||
) |
reco::BeamSpot BSFitter::Fit_z_chi2 | ( | double * | inipar | ) |
Definition at line 342 of file BSFitter.cc.
References align::BeamSpot, and makeMuonMisalignmentScenario::matrix.
{ // N.B. this fit is not performed anymore but now // Z is fitted in the same track set used in the d0-phi fit after // each iteration //std::cout << "Fit_z_chi2() called" << std::endl; // FIXME: include whole tracker z length for the time being // ==> add protection and z0 cut h1z = new TH1F("h1z","z distribution",200,-fMaxZ, fMaxZ); std::vector<BSTrkParameters>::const_iterator iparam = fBSvector.begin(); // HERE check size of track vector for( iparam = fBSvector.begin(); iparam != fBSvector.end(); ++iparam) { h1z->Fill( iparam->z0() ); //std::cout<<"z0="<<iparam->z0()<<"; sigZ0="<<iparam->sigz0()<<std::endl; } h1z->Fit("gaus","QLM0"); //std::cout << "fitted "<< std::endl; TF1 *fgaus = h1z->GetFunction("gaus"); //std::cout << "got function" << std::endl; double fpar[2] = {fgaus->GetParameter(1), fgaus->GetParameter(2) }; //std::cout<<"Debug fpar[2] = (" <<fpar[0]<<","<<fpar[1]<<")"<<std::endl; reco::BeamSpot::CovarianceMatrix matrix; // add matrix values. matrix(2,2) = fgaus->GetParError(1) * fgaus->GetParError(1); matrix(3,3) = fgaus->GetParError(2) * fgaus->GetParError(2); //delete h1z; return reco::BeamSpot( reco::BeamSpot::Point(0., 0., fpar[0]), fpar[1], 0., 0., 0., matrix, fbeamtype ); }
reco::BeamSpot BSFitter::Fit_z_likelihood | ( | double * | inipar | ) |
Definition at line 273 of file BSFitter.cc.
References align::BeamSpot, j, gen::k, and makeMuonMisalignmentScenario::matrix.
{ //std::cout << "Fit_z(double *) called" << std::endl; //std::cout << "inipar[0]= " << inipar[0] << std::endl; //std::cout << "inipar[1]= " << inipar[1] << std::endl; std::vector<double> par(2,0); std::vector<double> err(2,0); par.push_back(0.0); par.push_back(7.0); err.push_back(0.0001); err.push_back(0.0001); //par[0] = 0.0; err[0] = 0.0; //par[1] = 7.0; err[1] = 0.0; thePDF->SetPDFs("PDFGauss_z"); thePDF->SetData(fBSvector); //std::cout << "data loaded"<< std::endl; //FunctionMinimum fmin = theFitter->Minimize(*theGausszFcn, par, err, 1, 500, 0.1); MnUserParameters upar; upar.Add("X0", 0.,0.); upar.Add("Y0", 0.,0.); upar.Add("Z0", inipar[0],0.001); upar.Add("sigmaZ",inipar[1],0.001); MnMigrad migrad(*thePDF, upar); FunctionMinimum fmin = migrad(); ff_minimum = fmin.Fval(); //std::cout << " eval= " << ff_minimum // << "/n params[0]= " << fmin.Parameters().Vec()(0) << std::endl; /* TMinuit *gmMinuit = new TMinuit(2); //gmMinuit->SetFCN(z_fcn); gmMinuit->SetFCN(myFitz_fcn); int ierflg = 0; double step[2] = {0.001,0.001}; for (int i = 0; i<2; i++) { gmMinuit->mnparm(i,fpar_name[i].c_str(),inipar[i],step[i],0,0,ierflg); } gmMinuit->Migrad(); */ reco::BeamSpot::CovarianceMatrix matrix; for (int j = 2 ; j < 4 ; ++j) { for(int k = j ; k < 4 ; ++k) { matrix(j,k) = fmin.Error().Matrix()(j,k); } } return reco::BeamSpot( reco::BeamSpot::Point(0., 0., fmin.Parameters().Vec()(2)), fmin.Parameters().Vec()(3), 0., 0., 0., matrix, fbeamtype ); }
int BSFitter::GetAcceptedTrks | ( | ) | [inline] |
std::vector< BSTrkParameters > BSFitter::GetData | ( | ) | [inline] |
double BSFitter::GetMinimum | ( | ) | [inline] |
reco::BeamSpot::ResCovMatrix BSFitter::GetResMatrix | ( | ) | [inline] |
double BSFitter::GetResPar0 | ( | ) | [inline] |
double BSFitter::GetResPar0Err | ( | ) | [inline] |
double BSFitter::GetResPar1 | ( | ) | [inline] |
double BSFitter::GetResPar1Err | ( | ) | [inline] |
TH1F* BSFitter::GetVzHisto | ( | ) | [inline] |
Definition at line 106 of file BSFitter.h.
References h1z.
Referenced by BeamFitter::runFitterNoTxt().
{ return h1z; }
double BSFitter::scanPDF | ( | double * | init_pars, |
int & | tracksFailed, | ||
int | option | ||
) |
Definition at line 680 of file BSFitter.cc.
References abs, funct::cos(), alignCSCRings::e, create_public_lumi_plots::exp, root::function(), create_public_lumi_plots::log, AlCaHLTBitMon_ParallelJobs::p, Pi, funct::sin(), and mathSSE::sqrt().
{ if(option==1)init_pars[6]=0.0005; //starting value for any given configuration //local vairables with initial values double fsqrt2pi=0.0; double d_sig=0.0; double d_dprime=0.0; double d_result=0.0; double z_sig=0.0; double z_result=0.0; double function=0.0; double tot_pdf=0.0; double last_minvalue=1.0e+10; double init_bw=-99.99; int iters=0; //used to remove tracks if far away from bs by this double DeltadCut=0.1000; if(init_pars[6]<0.0200){DeltadCut=0.0900; } //worked for high 2.36TeV if(init_pars[6]<0.0100){DeltadCut=0.0700;} //just a guesss for 7 TeV but one should scan for actual values std::vector<BSTrkParameters>::const_iterator iparam = fBSvector.begin(); if(option==1)iters=500; if(option==2)iters=1; for(int p=0;p<iters;p++){ if(iters==500)init_pars[6]+=0.0002; tracksfixed=0; for( iparam = fBSvector.begin(); iparam != fBSvector.end(); ++iparam) { fsqrt2pi = sqrt(2.* TMath::Pi()); d_sig = sqrt(init_pars[6]*init_pars[6] + (iparam->sigd0())*(iparam->sigd0())); d_dprime = iparam->d0() - ( ( (init_pars[0] + iparam->z0()*(init_pars[4]))*sin(iparam->phi0()) ) - ( (init_pars[1] + iparam->z0()*(init_pars[5]))*cos(iparam->phi0()) ) ); //***Remove tracks before the fit which gives low pdf values to blow up the pdf if(std::abs(d_dprime)<DeltadCut && option==2){ fBSvectorBW.push_back(*iparam);} d_result = (exp(-(d_dprime*d_dprime)/(2.0*d_sig*d_sig)))/(d_sig*fsqrt2pi); z_sig = sqrt(iparam->sigz0() * iparam->sigz0() + init_pars[3]*init_pars[3]); z_result = (exp(-((iparam->z0() - init_pars[2])*(iparam->z0() - init_pars[2]))/(2.0*z_sig*z_sig)))/(z_sig*fsqrt2pi); tot_pdf=z_result*d_result; //for those trcks which gives problems due to very tiny pdf_d values. //Update: This protection will NOT be used with the dprime cut above but still kept here to get // the intial value of beam width reasonably //A warning will appear if there were any tracks with < 10^-5 for pdf_d so that (d-dprime) cut can be lowered if(d_result < 1.0e-05){ tot_pdf=z_result*1.0e-05; //if(option==2)std::cout<<"last Iter d-d' = "<<(std::abs(d_dprime))<<std::endl; tracksfixed++; } function = function + log(tot_pdf); tot_pdf=0.0; }//loop over tracks function= -2.0*function; if(function<last_minvalue){init_bw=init_pars[6]; last_minvalue=function; } function=0.0; }//loop over beam width if(init_bw>0) { init_bw=init_bw+(0.20*init_bw); //start with 20 % more } else{ if(option==1){ edm::LogWarning("BSFitter") <<"scanPDF:====>>>> WARNING***: The initial guess value of Beam width is negative!!!!!!"<<std::endl <<"scanPDF:====>>>> Assigning beam width a starting value of "<<init_bw<<" cm"<<std::endl; init_bw=0.0200; } } return init_bw; }
void BSFitter::SetChi2Cut_d0phi | ( | double | chi2cut | ) |
Definition at line 633 of file BSFitter.cc.
{ fapplychi2cut = true; //fBSforCuts = BSfitted; fchi2cut = chi2cut; }
void BSFitter::SetConvergence | ( | double | val | ) | [inline] |
Definition at line 63 of file BSFitter.h.
References fconvergence.
Referenced by BeamFitter::runBeamWidthFitter(), and BeamFitter::runFitterNoTxt().
{ fconvergence = val; }
void BSFitter::Setd0Cut_d0phi | ( | double | d0cut | ) |
Definition at line 624 of file BSFitter.cc.
Referenced by BeamFitter::runAllFitter().
{ fapplyd0cut = true; //fBSforCuts = BSfitted; fd0cut = d0cut; }
void BSFitter::SetFitType | ( | std::string | type | ) | [inline] |
Definition at line 42 of file BSFitter.h.
References ffit_type.
Referenced by BeamFitter::runAllFitter(), and BeamFitter::runBeamWidthFitter().
void BSFitter::SetFitVariable | ( | std::string | name | ) | [inline] |
Definition at line 46 of file BSFitter.h.
References ffit_variable, and mergeVDriftHistosByStation::name.
Referenced by BeamFitter::runAllFitter(), and BeamFitter::runBeamWidthFitter().
{ ffit_variable = name; }
void BSFitter::SetInputBeamWidth | ( | double | val | ) | [inline] |
Definition at line 67 of file BSFitter.h.
References finputBeamWidth.
Referenced by BeamFitter::runBeamWidthFitter(), and BeamFitter::runFitterNoTxt().
{ finputBeamWidth = val; }
void BSFitter::SetMaximumZ | ( | double | z | ) | [inline] |
Definition at line 62 of file BSFitter.h.
Referenced by BeamFitter::runBeamWidthFitter(), and BeamFitter::runFitterNoTxt().
void BSFitter::SetMinimumNTrks | ( | int | n | ) | [inline] |
Definition at line 64 of file BSFitter.h.
Referenced by BeamFitter::runBeamWidthFitter(), and BeamFitter::runFitterNoTxt().
bool BSFitter::fapplychi2cut [private] |
Definition at line 137 of file BSFitter.h.
bool BSFitter::fapplyd0cut [private] |
Definition at line 136 of file BSFitter.h.
reco::BeamSpot::BeamType BSFitter::fbeamtype [private] |
Definition at line 114 of file BSFitter.h.
std::vector< BSTrkParameters > BSFitter::fBSvector [private] |
Definition at line 126 of file BSFitter.h.
Referenced by GetData().
std::vector< BSTrkParameters > BSFitter::fBSvectorBW [private] |
Definition at line 127 of file BSFitter.h.
double BSFitter::fchi2cut [private] |
Definition at line 139 of file BSFitter.h.
double BSFitter::fconvergence [private] |
Definition at line 144 of file BSFitter.h.
Referenced by SetConvergence().
double BSFitter::fd0cut [private] |
Definition at line 138 of file BSFitter.h.
const int BSFitter::fdim = 7 [static, private] |
Definition at line 120 of file BSFitter.h.
double BSFitter::ff_minimum [private] |
Definition at line 118 of file BSFitter.h.
Referenced by GetMinimum().
std::string BSFitter::ffit_type [private] |
Definition at line 115 of file BSFitter.h.
Referenced by SetFitType().
std::string BSFitter::ffit_variable [private] |
Definition at line 116 of file BSFitter.h.
Referenced by SetFitVariable().
double BSFitter::finputBeamWidth [private] |
Definition at line 146 of file BSFitter.h.
Referenced by SetInputBeamWidth().
double BSFitter::fMaxZ [private] |
Definition at line 143 of file BSFitter.h.
Referenced by SetMaximumZ().
int BSFitter::fminNtrks [private] |
Definition at line 145 of file BSFitter.h.
Referenced by SetMinimumNTrks().
int BSFitter::fnthite [private] |
Definition at line 141 of file BSFitter.h.
Referenced by d0phi_Init().
std::string BSFitter::fpar_name[fdim] [private] |
Definition at line 122 of file BSFitter.h.
double BSFitter::fres_c0_err [private] |
Definition at line 131 of file BSFitter.h.
Referenced by GetResPar0Err().
double BSFitter::fres_c1_err [private] |
Definition at line 132 of file BSFitter.h.
Referenced by GetResPar1Err().
Definition at line 133 of file BSFitter.h.
Referenced by GetResMatrix().
double BSFitter::fresolution_c0 [private] |
Definition at line 129 of file BSFitter.h.
Referenced by GetResPar0().
double BSFitter::fresolution_c1 [private] |
Definition at line 130 of file BSFitter.h.
Referenced by GetResPar1().
Double_t BSFitter::fsqrt2pi [private] |
Definition at line 124 of file BSFitter.h.
TMatrixD BSFitter::ftmp [private] |
Definition at line 135 of file BSFitter.h.
Referenced by d0phi_Init().
int BSFitter::ftmprow [private] |
Definition at line 140 of file BSFitter.h.
Referenced by d0phi_Init(), and GetAcceptedTrks().
bool BSFitter::goodfit [private] |
Definition at line 142 of file BSFitter.h.
Referenced by d0phi_Init().
TH1F* BSFitter::h1z [private] |
Definition at line 147 of file BSFitter.h.
Referenced by GetVzHisto().
ROOT::Minuit2::ModularFunctionMinimizer* BSFitter::theFitter [private] |
Definition at line 110 of file BSFitter.h.
BSpdfsFcn* BSFitter::thePDF [private] |
Definition at line 112 of file BSFitter.h.