dqmTnP::AbstractFitter Class Reference

#include <GenericTnPFitter.h>

Inheritance diagram for dqmTnP::AbstractFitter:

Public Member Functions
	AbstractFitter (bool verbose_=false)
TString	calculateEfficiency (TH3 *pass, TH3 *all, int massDimension, TProfile2D *&eff, TProfile2D *&effChi2, TString plotName="")
TString	calculateEfficiency (TH2 *pass, TH2 *all, int massDimension, TProfile *&eff, TProfile *&effChi2, TString plotName="")
virtual void	fit (TH1 *num, TH1 *den)=0
double	getChi2 ()
double	getEfficiency ()
double	getEfficiencyError ()
void	savePlot (TString name)
void	setup (double expectedMean_, double massLow, double massHigh, double expectedSigma_)
virtual	~AbstractFitter ()

Protected Attributes
RooCategory	category
double	chi2
RooDataHist *	data
RooRealVar	efficiency
double	expectedMean
double	expectedSigma
RooRealVar	mass
RooRealVar	mean
RooRealVar	nBackgroundFail
RooRealVar	nBackgroundPass
RooRealVar	nSignalAll
RooFormulaVar	nSignalFail
RooFormulaVar	nSignalPass
RooRealVar	sigma
RooSimultaneous	simPdf
bool	verbose

Detailed Description

Definition at line 23 of file GenericTnPFitter.h.

Constructor & Destructor Documentation

dqmTnP::AbstractFitter::AbstractFitter ( bool  verbose_ = false )

inline

Definition at line 43 of file GenericTnPFitter.h.

References category, i, and instance.

                                       :
    mass("mass","mass",0.,100.,"GeV"),
    mean("mean","mean",0.,100.,"GeV"),
    sigma("sigma","sigma",0.,100.,"GeV"),
    efficiency("efficiency","efficiency",0.5,0.0,1.0),
    nSignalAll("nSignalAll","nSignalAll",0.,1e10),
    nSignalPass("nSignalPass","nSignalAll*efficiency",RooArgList(nSignalAll,efficiency)),
    nSignalFail("nSignalFail","nSignalAll*(1-efficiency)",RooArgList(nSignalAll,efficiency)),
    nBackgroundFail("nBackgroundFail","nBackgroundFail",0.,1e10),
    nBackgroundPass("nBackgroundPass","nBackgroundPass",0.,1e10),
    category("category","category"),
    simPdf("simPdf","simPdf",category),
    data(0),
    verbose(verbose_)
  {
    //turn on/off default messaging of roofit
    RooMsgService::instance().setSilentMode( !verbose?kTRUE:kFALSE );
    for(int i=0; i<RooMsgService::instance().numStreams(); i++){
      RooMsgService::instance().setStreamStatus( i, verbose?kTRUE:kFALSE );
    }
    category.defineType("pass");
    category.defineType("fail");
  };

virtual dqmTnP::AbstractFitter::~AbstractFitter ( )

inlinevirtual

Definition at line 66 of file GenericTnPFitter.h.

{};

Member Function Documentation

TString dqmTnP::AbstractFitter::calculateEfficiency ( TH3 *  pass, TH3 *  all, int  massDimension, TProfile2D *&  eff, TProfile2D *&  effChi2, TString  plotName = ""  )

inline

Definition at line 90 of file GenericTnPFitter.h.

References fit(), getChi2(), getEfficiency(), getEfficiencyError(), getHLTprescales::index, mass, savePlot(), and mathSSE::sqrt().

                                                                                                                                  {
    //sort out the TAxis
    TAxis *par1Axis, *par2Axis, *massAxis;
    int par1C, par2C, massC;
    if(massDimension==1){
      massAxis = all->GetXaxis();
      massC = 1;
      par1Axis = all->GetYaxis();
      par1C = all->GetXaxis()->GetNbins()+2;
      par2Axis = all->GetZaxis();
      par2C = (all->GetXaxis()->GetNbins()+2)*(all->GetYaxis()->GetNbins()+2);
    }else if(massDimension==2){
      par1Axis = all->GetXaxis();
      par1C = 1;
      massAxis = all->GetYaxis();
      massC = all->GetXaxis()->GetNbins()+2;
      par2Axis = all->GetZaxis();
      par2C = (all->GetXaxis()->GetNbins()+2)*(all->GetYaxis()->GetNbins()+2);
    }else if(massDimension==3){
      par1Axis = all->GetXaxis();
      par1C = 1;
      par2Axis = all->GetYaxis();
      par2C = all->GetXaxis()->GetNbins()+2;
      massAxis = all->GetZaxis();
      massC = (all->GetXaxis()->GetNbins()+2)*(all->GetYaxis()->GetNbins()+2);
    }else{
      return "massDimension > 3 !, skipping...";
    }

    //create eff and effChi2 TProfiles
    if(!par1Axis || !par2Axis) return "No par1Axis or par2Axis!";
    if( par1Axis->GetXbins()->GetSize()==0 && par2Axis->GetXbins()->GetSize()==0 ){
      eff = new TProfile2D("efficiency","efficiency",par1Axis->GetNbins(),par1Axis->GetXmin(),par1Axis->GetXmax(),par2Axis->GetNbins(),par2Axis->GetXmin(),par2Axis->GetXmax());
    }else if( par1Axis->GetXbins()->GetSize()==0 ){
      eff = new TProfile2D("efficiency","efficiency",par1Axis->GetNbins(),par1Axis->GetXmin(),par1Axis->GetXmax(),par2Axis->GetNbins(),par2Axis->GetXbins()->GetArray());
    }else if( par2Axis->GetXbins()->GetSize()==0 ){
      eff = new TProfile2D("efficiency","efficiency",par1Axis->GetNbins(),par1Axis->GetXbins()->GetArray(),par2Axis->GetNbins(),par2Axis->GetXmin(),par2Axis->GetXmax());
    }else{
      eff = new TProfile2D("efficiency","efficiency",par1Axis->GetNbins(),par1Axis->GetXbins()->GetArray(),par2Axis->GetNbins(),par2Axis->GetXbins()->GetArray());
    }
    eff->SetTitle("");
    eff->SetXTitle( par1Axis->GetTitle() );
    eff->SetYTitle( par2Axis->GetTitle() );
    eff->SetStats(kFALSE);
    effChi2 = (TProfile2D*)eff->Clone("efficiencyChi2");
    eff->SetZTitle("Efficiency");
    eff->SetOption("colztexte");
    eff->GetZaxis()->SetRangeUser(-0.001,1.001);
    effChi2->SetZTitle("Chi^2/NDF");
    effChi2->SetOption("colztext");

    //create the 1D mass distribution container histograms
    TH1D* all1D = (massAxis->GetXbins()->GetSize()==0) ?
      new TH1D("all1D","all1D",massAxis->GetNbins(),massAxis->GetXmin(),massAxis->GetXmax()):
      new TH1D("all1D","all1D",massAxis->GetNbins(),massAxis->GetXbins()->GetArray()); 
    TH1D* pass1D = (TH1D *)all1D->Clone("pass1D");

    //for each parameter bin fit the mass distributions
    for(int par1=1; par1<=par1Axis->GetNbins(); par1++){
      for(int par2=1; par2<=par2Axis->GetNbins(); par2++){
        for(int mass=1; mass<=massAxis->GetNbins(); mass++){
          int index = par1*par1C + par2*par2C + mass*massC;
          all1D->SetBinContent(mass,all->GetBinContent(index));
          pass1D->SetBinContent(mass,pass->GetBinContent(index));
        }
        fit( pass1D, all1D );
        int index = par1 + par2*(par1Axis->GetNbins()+2);
        eff->SetBinContent( index, getEfficiency() );
        eff->SetBinEntries( index, 1 );
        eff->SetBinError( index, sqrt( getEfficiency()*getEfficiency() + getEfficiencyError()*getEfficiencyError() ) );
        effChi2->SetBinContent( index, getChi2() );
        effChi2->SetBinEntries( index, 1 );
        if(plotName!=""){
          savePlot( TString::Format("%s_%d_%d",plotName.Data(),par1,par2) );
        }
      }
    }
    delete all1D;
    delete pass1D;
    return "";//OK
  }

TString dqmTnP::AbstractFitter::calculateEfficiency ( TH2 *  pass, TH2 *  all, int  massDimension, TProfile *&  eff, TProfile *&  effChi2, TString  plotName = ""  )

inline

Definition at line 172 of file GenericTnPFitter.h.

References fit(), getChi2(), getEfficiency(), getEfficiencyError(), getHLTprescales::index, mass, savePlot(), and mathSSE::sqrt().

                                                                                                                              {
    //sort out the TAxis
    TAxis *par1Axis, *massAxis;
    int par1C, massC;
    if(massDimension==1){
      massAxis = all->GetXaxis();
      massC = 1;
      par1Axis = all->GetYaxis();
      par1C = all->GetXaxis()->GetNbins()+2;
    }else if(massDimension==2){
      par1Axis = all->GetXaxis();
      par1C = 1;
      massAxis = all->GetYaxis();
      massC = all->GetXaxis()->GetNbins()+2;
    }else{
      return "massDimension > 2 !, skipping...";
    }

    //create eff and effChi2 TProfiles
    if(!par1Axis) return "No par1Axis!";
    eff = (par1Axis->GetXbins()->GetSize()==0)?
      new TProfile("efficiency","efficiency",par1Axis->GetNbins(),par1Axis->GetXmin(),par1Axis->GetXmax()):
      new TProfile("efficiency","efficiency",par1Axis->GetNbins(),par1Axis->GetXbins()->GetArray());
    eff->SetTitle("");
    eff->SetXTitle( par1Axis->GetTitle() );
    eff->SetLineColor(2);
    eff->SetLineWidth(2);
    eff->SetMarkerStyle(20);
    eff->SetMarkerSize(0.8);
    eff->SetStats(kFALSE);
    effChi2 = (TProfile*)eff->Clone("efficiencyChi2");
    eff->SetYTitle("Efficiency");
    eff->SetOption("PE");
    eff->GetYaxis()->SetRangeUser(-0.001,1.001);
    effChi2->SetYTitle("Chi^2/NDF");
    effChi2->SetOption("HIST");

    //create the 1D mass distribution container histograms
    TH1D * all1D = (massAxis->GetXbins()->GetSize()==0) ?
      new TH1D("all1D","all1D",massAxis->GetNbins(),massAxis->GetXmin(),massAxis->GetXmax()):
      new TH1D("all1D","all1D",massAxis->GetNbins(),massAxis->GetXbins()->GetArray()); 
    TH1D * pass1D = (TH1D *)all1D->Clone("pass1D");

    //for each parameter bin fit the mass distributions
    for(int par1=1; par1<=par1Axis->GetNbins(); par1++){
      for(int mass=1; mass<=massAxis->GetNbins(); mass++){
        int index = par1*par1C + mass*massC;
        all1D->SetBinContent(mass,all->GetBinContent(index));
        pass1D->SetBinContent(mass,pass->GetBinContent(index));
      }
      fit( pass1D, all1D );
      int index = par1;
      eff->SetBinContent( index, getEfficiency() );
      eff->SetBinEntries( index, 1 );
      eff->SetBinError( index, sqrt( getEfficiency()*getEfficiency() + getEfficiencyError()*getEfficiencyError() ) );
      effChi2->SetBinContent( index, getChi2() );
      effChi2->SetBinEntries( index, 1 );
      if(plotName!=""){
        savePlot( TString::Format("%s_%d",plotName.Data(),par1) );
      }
    }
    delete all1D;
    delete pass1D;
    return "";//OK
  }

virtual void dqmTnP::AbstractFitter::fit ( TH1 *  num, TH1 *  den  )

pure virtual

Implemented in dqmTnP::VoigtianPlusExponentialFitter, and dqmTnP::GaussianPlusLinearFitter.

Referenced by calculateEfficiency().

double dqmTnP::AbstractFitter::getChi2 ( )

inline

Definition at line 76 of file GenericTnPFitter.h.

References chi2.

Referenced by calculateEfficiency().

{ return chi2; }

double dqmTnP::AbstractFitter::getEfficiency ( )

inline

Definition at line 74 of file GenericTnPFitter.h.

References efficiency.

Referenced by calculateEfficiency().

{ return efficiency.getVal(); }

double dqmTnP::AbstractFitter::getEfficiencyError ( )

inline

Definition at line 75 of file GenericTnPFitter.h.

References efficiency.

Referenced by calculateEfficiency().

{ return efficiency.getError(); }

void dqmTnP::AbstractFitter::savePlot ( TString  name )

inline

Definition at line 77 of file GenericTnPFitter.h.

References category, data, mass, and simPdf.

Referenced by calculateEfficiency().

                             {
    using namespace RooFit;
    RooPlot* frame = mass.frame(Name(name), Title("Failing and Passing Probe Distributions"));
    data->plotOn(frame,Cut("category==category::pass"),LineColor(kGreen),MarkerColor(kGreen));
    data->plotOn(frame,Cut("category==category::fail"),LineColor(kRed),MarkerColor(kRed));
    simPdf.plotOn(frame,Slice(category,"pass"),ProjWData(category,*data),LineColor(kGreen));
    simPdf.plotOn(frame,Slice(category,"fail"),ProjWData(category,*data),LineColor(kRed));
    simPdf.paramOn(frame,Layout(0.58,0.99,0.99));
    data->statOn(frame,Layout(0.70,0.99,0.5));
    frame->Write();
    delete frame;
  }

void dqmTnP::AbstractFitter::setup ( double  expectedMean_, double  massLow, double  massHigh, double  expectedSigma_  )

inline

Definition at line 67 of file GenericTnPFitter.h.

References expectedMean, expectedSigma, mass, and mean.

Referenced by DQMGenericTnPClient::calculateEfficiency().

                                                                                          {
    expectedMean = expectedMean_;
    expectedSigma = expectedSigma_;
    mass.setRange(massLow,massHigh);
    mean.setRange(massLow,massHigh);
  }

Member Data Documentation

RooCategory dqmTnP::AbstractFitter::category

protected

Definition at line 36 of file GenericTnPFitter.h.

Referenced by AbstractFitter(), dqmTnP::GaussianPlusLinearFitter::fit(), dqmTnP::VoigtianPlusExponentialFitter::fit(), and savePlot().

double dqmTnP::AbstractFitter::chi2

protected

Definition at line 39 of file GenericTnPFitter.h.

Referenced by dqmTnP::GaussianPlusLinearFitter::fit(), dqmTnP::VoigtianPlusExponentialFitter::fit(), and getChi2().

RooDataHist* dqmTnP::AbstractFitter::data

protected

Definition at line 38 of file GenericTnPFitter.h.

Referenced by confdb.HLTProcess::customize(), confdb.HLTProcess::dump(), dqmTnP::GaussianPlusLinearFitter::fit(), dqmTnP::VoigtianPlusExponentialFitter::fit(), confdb.HLTProcess::getRawConfigurationFromDB(), confdb.HLTProcess::releaseSpecificCustomize(), and savePlot().

RooRealVar dqmTnP::AbstractFitter::efficiency

protected

Definition at line 30 of file GenericTnPFitter.h.

Referenced by dqmTnP::GaussianPlusLinearFitter::fit(), dqmTnP::VoigtianPlusExponentialFitter::fit(), getEfficiency(), and getEfficiencyError().

double dqmTnP::AbstractFitter::expectedMean

protected

Definition at line 27 of file GenericTnPFitter.h.

Referenced by dqmTnP::GaussianPlusLinearFitter::fit(), dqmTnP::VoigtianPlusExponentialFitter::fit(), setup(), and dqmTnP::VoigtianPlusExponentialFitter::setup().

double dqmTnP::AbstractFitter::expectedSigma

protected

Definition at line 29 of file GenericTnPFitter.h.

Referenced by dqmTnP::GaussianPlusLinearFitter::fit(), dqmTnP::VoigtianPlusExponentialFitter::fit(), setup(), and dqmTnP::VoigtianPlusExponentialFitter::setup().

RooRealVar dqmTnP::AbstractFitter::mass

protected

Definition at line 25 of file GenericTnPFitter.h.

Referenced by calculateEfficiency(), dqmTnP::GaussianPlusLinearFitter::fit(), dqmTnP::VoigtianPlusExponentialFitter::fit(), savePlot(), setup(), and dqmTnP::VoigtianPlusExponentialFitter::setup().

RooRealVar dqmTnP::AbstractFitter::mean

protected

Definition at line 26 of file GenericTnPFitter.h.

Referenced by dqmTnP::GaussianPlusLinearFitter::fit(), dqmTnP::VoigtianPlusExponentialFitter::fit(), setup(), and dqmTnP::VoigtianPlusExponentialFitter::setup().

RooRealVar dqmTnP::AbstractFitter::nBackgroundFail

protected

Definition at line 34 of file GenericTnPFitter.h.

Referenced by dqmTnP::GaussianPlusLinearFitter::fit(), and dqmTnP::VoigtianPlusExponentialFitter::fit().

RooRealVar dqmTnP::AbstractFitter::nBackgroundPass

protected

Definition at line 35 of file GenericTnPFitter.h.

Referenced by dqmTnP::GaussianPlusLinearFitter::fit(), and dqmTnP::VoigtianPlusExponentialFitter::fit().

RooRealVar dqmTnP::AbstractFitter::nSignalAll

protected

Definition at line 31 of file GenericTnPFitter.h.

Referenced by dqmTnP::GaussianPlusLinearFitter::fit(), and dqmTnP::VoigtianPlusExponentialFitter::fit().

RooFormulaVar dqmTnP::AbstractFitter::nSignalFail

protected

Definition at line 33 of file GenericTnPFitter.h.

RooFormulaVar dqmTnP::AbstractFitter::nSignalPass

protected

Definition at line 32 of file GenericTnPFitter.h.

RooRealVar dqmTnP::AbstractFitter::sigma

protected

Definition at line 28 of file GenericTnPFitter.h.

Referenced by dqmTnP::GaussianPlusLinearFitter::fit(), and dqmTnP::VoigtianPlusExponentialFitter::fit().

RooSimultaneous dqmTnP::AbstractFitter::simPdf

protected

Definition at line 37 of file GenericTnPFitter.h.

Referenced by dqmTnP::GaussianPlusLinearFitter::fit(), dqmTnP::VoigtianPlusExponentialFitter::fit(), dqmTnP::GaussianPlusLinearFitter::GaussianPlusLinearFitter(), savePlot(), and dqmTnP::VoigtianPlusExponentialFitter::VoigtianPlusExponentialFitter().

bool dqmTnP::AbstractFitter::verbose

protected

Definition at line 40 of file GenericTnPFitter.h.

Referenced by python.diff_provenance.difference::list_diff(), python.diffProv.difference::list_diff(), python.diff_provenance.difference::module_diff(), python.diffProv.difference::module_diff(), python.diff_provenance.difference::onefilemodules(), and python.diffProv.difference::onefilemodules().