Jeng/scripts/qcd.C

#define qcd_cxx
#include "qcd.h"
#include <TH2.h>
#include <THStack.h>
#include <TStyle.h>
#include <TCanvas.h>
#include <TMath.h>
#include <TMultiGraph.h>
#include <TGraphErrors.h>
#include <TCanvas.h>
#include "Math/GSLIntegrator.h"
#include "Math/WrappedTF1.h"
#include <iostream>
#include <TLegend.h>
#include <TPaveStats.h>

// Histo range
double xMin = 0.0;
double xMax = 2.0;
// Jet bin:
Int_t jbin = 4; // 1-3, 4 for >=4. Put in number less than 5
double binwidth = 0.1; // 0.02,0.02,0.05,0.1
int nbin = (xMax-xMin)/binwidth;
// fit region weight
double wxmin = 1.9;
double wxmax = 0.7;
// Specify fitting function:
TString fitfunc = "landau"; // this version is cut for Landau
// Select New or Old reliso:
TString isoname = "New";
double d0sigCut = 3.;

void qcd::Loop()
{
  //   In a ROOT session, you can do:
  //      Modify jbin, binwidth, wxmin, wxmax
  //      Root > .L qcd.C++
  //      Root > qcd t
  //      Root > t.GetEntry(12); // Fill t data members with entry number 12
  //      Root > t.Show();       // Show values of entry 12
  //      Root > t.Show(16);     // Read and show values of entry 16
  //      Root > t.Loop();       // Loop on all entries
  
  TH1D *h_RelIso_ttbar = new TH1D("h_RelIso_ttbar","h_RelIso_ttbar",nbin,xMin,xMax);
  TH1D *h_RelIso_qcd = new TH1D("h_RelIso_qcd","h_RelIso_qcd",nbin,xMin,xMax);
  TH1D *h_RelIso_wjets = new TH1D("h_RelIso_wjets","h_RelIso_wjets",nbin,xMin,xMax);
  TH1D *h_RelIso_zjets = new TH1D("h_RelIso_zjets","h_RelIso_zjets",nbin,xMin,xMax);
  TH1D *h_RelIso_all = new TH1D("h_RelIso_all","h_RelIso_all",nbin,xMin,xMax);
    
  // define fit region:
  double AX0 = 0.;
  double AXf = 0.;
  double BX0 = 0.;
  double BXf = 0.;
  
  cout<<"Use "<<isoname<<" RelIso"<<endl;
  
  if ( isoname.Contains("Old") ) {
    // old
    AX0 = 0.95;
    AXf = 1.0;
    BX0 = 0.2;
    BXf = 0.8;
  }
  else if ( isoname.Contains("New") ) {
    // new
    AX0 = 0.0;
    AXf = 0.053;
    BX0 = 0.4;
    BXf = 2.0;
  }
  
  // weights
  double wttbar = 0.0101;
  double wqcd   = 1.3161;
  double wwjets = 0.0977;
  double wzjets = 0.078;
  
  // Na = num of qcd in signal region
  double Na,Nb,Nfac;
  Na = Nb = Nfac = 0;
  
  double Nttbar, NWjets, NZjets, Nqcd;
  Nttbar = NWjets = NZjets = Nqcd = 0;
  double reliso = 0.0;
  
  if (fChain == 0) return;
  
  Long64_t nentries = fChain->GetEntriesFast();
  
  Long64_t nbytes = 0, nb = 0;
  for (Long64_t jentry=0; jentry<nentries;jentry++) {
    Long64_t ientry = LoadTree(jentry);
    if (ientry < 0) break;
    nb = fChain->GetEntry(jentry);   nbytes += nb;
    // if (Cut(ientry) < 0) continue;
    bool signalRegion = false;
    bool fitRegion = false;
    
    TString filename(fChain->GetCurrentFile()->GetName());
    if (isoname.Contains("Old")) {
      reliso = top_muon_old_reliso[0];
      if ( reliso > AX0 ) signalRegion = true;
      else if ( reliso > BX0 && reliso < BXf ) fitRegion = true;
    }
    else if (isoname.Contains("New")) {
      reliso = top_muon_new_reliso[0];
      if ( reliso < AXf ) signalRegion = true;
      else if ( reliso > BX0 && reliso < BXf ) fitRegion = true;
    }
    else {
      cout<<"No RelIso defined!!!"<<endl;
      return;
    }
    
    double d0sig = TMath::Abs(top_muon_d0[0])/top_muon_d0Error[0];
    bool correctBin = false; // jet bin condition
    bool goodD0sig = false; // d0sig condition

    if ( jbin > 4 ) {cout<<"Don't mess around!!! jbin should be less than 5!"<<endl;return;}
    if (top_njets == jbin && jbin != 4) correctBin = true;
    else if (top_njets >= jbin && jbin == 4) correctBin = true;
    if ( d0sig < d0sigCut ) goodD0sig = true;
    
    // Jet bin
    if( correctBin && goodD0sig ) {
      if ( filename.Contains("TTJets") ) {
        h_RelIso_ttbar->Fill(reliso);
        if ( signalRegion ) { Nttbar += wttbar; }
        else if ( fitRegion ) Nfac += wttbar;
      }
      if ( filename.Contains("MuPt15") ) {
        h_RelIso_qcd->Fill(reliso);
        if ( signalRegion ) { Na += wqcd; Nqcd+= wqcd; } // QCD in signal region
        else if ( fitRegion ) {
          Nb += wqcd; // QCD in fitted background region
          Nfac += wqcd;
        }
      }
      if ( filename.Contains("WJets") ) {
        h_RelIso_wjets->Fill(reliso);
        if ( signalRegion ) { NWjets += wwjets; }       
        else if ( fitRegion ) Nfac += wwjets;
      }
      if ( filename.Contains("ZJets") ) {
        h_RelIso_zjets->Fill(reliso);
        if ( signalRegion ) { NZjets += wzjets; }
        else if ( fitRegion ) Nfac += wzjets;
      }
    }
  }
  cout << "\n";
  cout << " Nb = " << Nb << "; Nfac = " << Nfac << endl << endl;
  cout << " N ttbar = " << Nttbar << endl;
  cout << " N qcd = " << Nqcd << endl;
  cout << " N Wjets = " << NWjets << endl;
  cout << " N Zjets = " << NZjets << endl << endl;
  
  gStyle->SetOptFit(01111);
  
  TCanvas *cv1 = new TCanvas("cv1","cv1",800,600);  
  THStack *hs = new THStack("hs","RelIso (stacked)");
  
  // Take care of scaling
  h_RelIso_qcd->Scale(wqcd);
  h_RelIso_wjets->Scale(wwjets);
  h_RelIso_zjets->Scale(wzjets);
  h_RelIso_ttbar->Scale(wttbar);
  
  h_RelIso_qcd->SetXTitle("Combined Relative Isolation");
  h_RelIso_qcd->SetLineColor(40);
  h_RelIso_qcd->SetFillStyle(3018);
  h_RelIso_qcd->SetFillColor(38);
  hs->Add(h_RelIso_qcd);
  h_RelIso_wjets->SetMarkerColor(4);
  h_RelIso_wjets->SetLineColor(4);
  h_RelIso_wjets->SetFillColor(4);
  hs->Add(h_RelIso_wjets);
  h_RelIso_zjets->SetMarkerColor(5);
  h_RelIso_zjets->SetLineColor(5);
  h_RelIso_zjets->SetFillColor(5);
  hs->Add(h_RelIso_zjets);
  h_RelIso_ttbar->SetMarkerColor(2);
  h_RelIso_ttbar->SetLineColor(2);
  h_RelIso_ttbar->SetFillColor(2);
  hs->Add(h_RelIso_ttbar);
  hs->Draw();

  // Label histo
  TLegend * leg0 = new TLegend(0.3,0.3,0.6,0.55);
  leg0->AddEntry(h_RelIso_ttbar,"t#bar{t}");
  leg0->AddEntry(h_RelIso_qcd,"QCD (MuPt15) ");
  leg0->AddEntry(h_RelIso_wjets,"W+jets");
  leg0->AddEntry(h_RelIso_zjets,"Z+jets");
  leg0->Draw();
  
  h_RelIso_all->Add(h_RelIso_ttbar,1.);
  h_RelIso_all->Add(h_RelIso_qcd,1.);
  h_RelIso_all->Add(h_RelIso_wjets,1.);
  h_RelIso_all->Add(h_RelIso_zjets,1.);
  h_RelIso_all->SetLineWidth(2);
  
  if( jbin == 4)
    h_RelIso_all->SetTitle( isoname+" RelIso distribution (#geq 4 jets)");
  else if ( jbin < 4 ) {
    TString title = isoname+" RelIso distribution (";
    title += jbin;
    title += " jets)";
    h_RelIso_all->SetTitle(title);
  }
  else {
    cout<<"Don't mess around!!! jbin should be less than 5!"<<endl;
    return;
  }
  h_RelIso_all->SetMinimum(0);
  // Save for later use
  TFile *file0 = new TFile("extpQCDbin4.root","RECREATE");
  file0->mkdir("histos");
  file0->cd("histos");
  h_RelIso_all->Write();
  h_RelIso_ttbar->Write();
  h_RelIso_qcd->Write();
  h_RelIso_wjets->Write();
  h_RelIso_zjets->Write();
  file0->Write();
  file0->Close();
  // Fitting here:
  FitBKG(fitfunc,h_RelIso_all,h_RelIso_qcd,AX0,AXf,BX0,BXf,Na);
}

void  qcd::FitBKG(TString s0,TH1D *h0,TH1D *h1,
                  double ax0,double axf,double bx0,double bxf,double na) {
  int niter = 1;
  double pass[3] = {0.,0.,0.};
  double ns, ns2;
  ns = ns2 = 0.;
  
  TCanvas *cvf = new TCanvas("cvf","cvf",800,600);
  
  // Fit QCD in background region
  cout<<"Fitting with "<<s0<<" function!"<<endl;
  TH1D *h_all = (TH1D*)h0->Clone();
  TH1D *h_qcd = (TH1D*)h1->Clone();
  h_all->Draw();
  
  cout << "\n>>>>> Iteration step: "<< niter << endl;
  h_all->Fit(s0,"0","",bx0,bxf);
  
  // Very first fit function
  TF1 *f0 = (TF1*)h_all->GetFunction(s0);
  Int_t npar = f0->GetNpar();
  Double_t chi2 = f0->GetChisquare();
  Int_t ndof = f0->GetNDF();
  pass[0] = chi2/ndof;
  pass[1] = pass[0];
  cout << ">> Norm chi2 = " << pass[0] << endl;
  
  bx0 = f0->GetParameter(1) - wxmin*f0->GetParameter(2);
  bxf = f0->GetParameter(1) + wxmax*f0->GetParameter(2);
  
  double * par0 = new double [npar];
  double * parErr0 = new double [npar];

  double delta = pass[1]-pass[2];
  
  while (niter <= 20 && abs(pass[1]-pass[2]) > 0.00001) {
    if (niter > 1)
      pass[1]=pass[2];
    if (delta >= 0){
      niter++;
      cout << "\n>>>>> Iteration step: "<< niter << endl;
      cout << ">> Pass[1] = " << pass[1] << endl;
      
      h_all->Fit(s0,"0","",bx0,bxf);
      TF1 *fi = (TF1*)h_all->GetFunction(s0);    
      pass[2] = fi->GetChisquare()/fi->GetNDF();
      cout << ">> Norm chi2 = pass[2] = " << pass[2] << endl;
      delta = pass[1]-pass[2];
      cout << ">> Delta = " << delta << endl;
      
      if (delta >= 0) {
        printf("Function has %i parameters. Chisquare = %g\n",
               npar,
               fi->GetChisquare());
        for (Int_t i=0;i<npar;i++) {
          printf("%s = %g +- %g\n",
                 fi->GetParName(i),
                 fi->GetParameter(i),
                 fi->GetParError(i)
                 );
          par0[i] = fi->GetParameter(i);
          parErr0[i] = fi->GetParError(i);
          //       cout<<"Par["<<i<<"]="<<par0[i]<<"; Error="<<parErr0[i]<<endl;
        }
        bx0 = fi->GetParameter(1) - wxmin*fi->GetParameter(2);
        bxf = fi->GetParameter(1) + wxmax*fi->GetParameter(2);
        cout << ">> bx0, bxf = " << bx0 << ", " << bxf << endl;
      }
      else {
        cout << ">> Use previous fit!" << endl;
      }
    }
  }
  
  cout << ">>> Final fitting resion (bx0, bxf) = " << bx0 << ", " << bxf << endl;
  
  // Get number of events within fitted region
  TAxis *axis = h_all->GetXaxis();
  int bmin = axis->FindBin(bx0);
  int bmax = axis->FindBin(bxf);
  double nfac1 = h_all->Integral(bmin,bmax);
  nfac1 -= (h_all->GetBinContent(bmin))*(bx0-axis->GetBinLowEdge(bmin))/axis->GetBinWidth(bmin);
  nfac1 -= (h_all->GetBinContent(bmax))*(axis->GetBinUpEdge(bmax)-bxf)/axis->GetBinWidth(bmax);
  cout << ">>> Final Nfac = " << nfac1 << endl;
  
  // ////////////////////////
  // Histos and extrapolation
  
  TF1 *f1 = (TF1*)f0->Clone();
  f1->SetRange(bx0,bxf);
  for (int i=0;i<npar;i++) {
    cout<<" >> Par["<<i<<"]="<<par0[i]<<"; Error="<<parErr0[i]<<endl;
    f1->SetParameter(i,par0[i]);
  }
  
  f1->SetLineColor(2);
  h_qcd->SetLineColor(40);
  h_qcd->SetFillStyle(3018);
  h_qcd->SetFillColor(38);
  h_qcd->Draw("same");
  f1->Draw("same");

  // Connect fitted and extrapolated region
  TF1 *fin = (TF1*)f1->Clone();
  fin->SetRange(axf,bx0);
  fin->SetLineStyle(2);
  fin->SetLineColor(8);
  fin->Draw("same");
  
  TF1 *f2 = (TF1*)f1->Clone();
  f2->SetRange(ax0,axf);
  f2->SetLineColor(4);
  f2->Draw("same");
  int np = 100;
  double *x=new double[np];
  double *w=new double[np];
  f2->CalcGaussLegendreSamplingPoints(np,x,w,1e-15);
  ns = f2->IntegralFast(np,x,w,ax0,axf);
  ns/=(f2->Integral(bx0,bxf));
  ns*=nfac1;
  cout<<">>> Ns by usual integral = "<<ns<<endl;
  delete [] x;
  delete [] w;
  
  // Another way to do integration
  TF1 *g = (TF1*)f1->Clone();
  ROOT::Math::GSLIntegrator ig(1.E-8,1.E-8,1000); 
  ROOT::Math::WrappedTF1 wf(*g);
  ig.SetFunction(wf);
  ns2 = ig.Integral(ax0,axf);
  ns2/=(g->Integral(bx0,bxf));
  ns2*=nfac1;
  cout<<">>> Ns by MathMore integral = "<<ns2<<endl;
    
  cvf->Update();
  
  TPaveStats *p1 = (TPaveStats*)h_all->GetListOfFunctions()->FindObject("stats");
  p1->SetTextColor(kBlue);
  p1->SetX1NDC(0.6);
  p1->SetX2NDC(0.88);
  p1->SetY1NDC(0.62);
  p1->SetY2NDC(0.88);
  p1->Draw();
  
  // Label histo
  TLegend * leg1 = new TLegend(0.3,0.15,0.68,0.45);
  //   leg1->SetHeader("Fit with "+fitfunc);
  leg1->AddEntry(h_all,"All events (S+B)");
  leg1->AddEntry(h_qcd,"QCD events");
  leg1->AddEntry(f1,"Fit of all events in control region");
  leg1->AddEntry(f2,"Extrapolation to signal region");
  leg1->Draw();
  // Print results
  cout << ">>>>> Observed Ns = " << ns;
  cout <<"\n";
  cout << ">>>>> Expected Na = " << na << endl;
}
Revision:	1.2
Committed:	Wed Apr 15 04:15:54 2009 UTC (16 years ago) by jengbou
Content type:	text/plain
Branch:	MAIN
CVS Tags:	HEAD
Changes since 1.1:	+166 -72 lines
Log Message:	Update
#	Content
1	#define qcd_cxx
2	#include "qcd.h"
3	#include <TH2.h>
4	#include <THStack.h>
5	#include <TStyle.h>
6	#include <TCanvas.h>
7	#include <TMath.h>
8	#include <TMultiGraph.h>
9	#include <TGraphErrors.h>
10	#include <TCanvas.h>
11	#include "Math/GSLIntegrator.h"
12	#include "Math/WrappedTF1.h"
13	#include <iostream>
14	#include <TLegend.h>
15	#include <TPaveStats.h>
16
17	// Histo range
18	double xMin = 0.0;
19	double xMax = 2.0;
20	// Jet bin:
21	Int_t jbin = 4; // 1-3, 4 for >=4. Put in number less than 5
22	double binwidth = 0.1; // 0.02,0.02,0.05,0.1
23	int nbin = (xMax-xMin)/binwidth;
24	// fit region weight
25	double wxmin = 1.9;
26	double wxmax = 0.7;
27	// Specify fitting function:
28	TString fitfunc = "landau"; // this version is cut for Landau
29	// Select New or Old reliso:
30	TString isoname = "New";
31	double d0sigCut = 3.;
32
33	void qcd::Loop()
34	{
35	// In a ROOT session, you can do:
36	// Modify jbin, binwidth, wxmin, wxmax
37	// Root > .L qcd.C++
38	// Root > qcd t
39	// Root > t.GetEntry(12); // Fill t data members with entry number 12
40	// Root > t.Show(); // Show values of entry 12
41	// Root > t.Show(16); // Read and show values of entry 16
42	// Root > t.Loop(); // Loop on all entries
43
44	TH1D *h_RelIso_ttbar = new TH1D("h_RelIso_ttbar","h_RelIso_ttbar",nbin,xMin,xMax);
45	TH1D *h_RelIso_qcd = new TH1D("h_RelIso_qcd","h_RelIso_qcd",nbin,xMin,xMax);
46	TH1D *h_RelIso_wjets = new TH1D("h_RelIso_wjets","h_RelIso_wjets",nbin,xMin,xMax);
47	TH1D *h_RelIso_zjets = new TH1D("h_RelIso_zjets","h_RelIso_zjets",nbin,xMin,xMax);
48	TH1D *h_RelIso_all = new TH1D("h_RelIso_all","h_RelIso_all",nbin,xMin,xMax);
49
50	// define fit region:
51	double AX0 = 0.;
52	double AXf = 0.;
53	double BX0 = 0.;
54	double BXf = 0.;
55
56	cout<<"Use "<<isoname<<" RelIso"<<endl;
57
58	if ( isoname.Contains("Old") ) {
59	// old
60	AX0 = 0.95;
61	AXf = 1.0;
62	BX0 = 0.2;
63	BXf = 0.8;
64	}
65	else if ( isoname.Contains("New") ) {
66	// new
67	AX0 = 0.0;
68	AXf = 0.053;
69	BX0 = 0.4;
70	BXf = 2.0;
71	}
72
73	// weights
74	double wttbar = 0.0101;
75	double wqcd = 1.3161;
76	double wwjets = 0.0977;
77	double wzjets = 0.078;
78
79	// Na = num of qcd in signal region
80	double Na,Nb,Nfac;
81	Na = Nb = Nfac = 0;
82
83	double Nttbar, NWjets, NZjets, Nqcd;
84	Nttbar = NWjets = NZjets = Nqcd = 0;
85	double reliso = 0.0;
86
87	if (fChain == 0) return;
88
89	Long64_t nentries = fChain->GetEntriesFast();
90
91	Long64_t nbytes = 0, nb = 0;
92	for (Long64_t jentry=0; jentry<nentries;jentry++) {
93	Long64_t ientry = LoadTree(jentry);
94	if (ientry < 0) break;
95	nb = fChain->GetEntry(jentry); nbytes += nb;
96	// if (Cut(ientry) < 0) continue;
97	bool signalRegion = false;
98	bool fitRegion = false;
99
100	TString filename(fChain->GetCurrentFile()->GetName());
101	if (isoname.Contains("Old")) {
102	reliso = top_muon_old_reliso[0];
103	if ( reliso > AX0 ) signalRegion = true;
104	else if ( reliso > BX0 && reliso < BXf ) fitRegion = true;
105	}
106	else if (isoname.Contains("New")) {
107	reliso = top_muon_new_reliso[0];
108	if ( reliso < AXf ) signalRegion = true;
109	else if ( reliso > BX0 && reliso < BXf ) fitRegion = true;
110	}
111	else {
112	cout<<"No RelIso defined!!!"<<endl;
113	return;
114	}
115
116	double d0sig = TMath::Abs(top_muon_d0[0])/top_muon_d0Error[0];
117	bool correctBin = false; // jet bin condition
118	bool goodD0sig = false; // d0sig condition
119
120	if ( jbin > 4 ) {cout<<"Don't mess around!!! jbin should be less than 5!"<<endl;return;}
121	if (top_njets == jbin && jbin != 4) correctBin = true;
122	else if (top_njets >= jbin && jbin == 4) correctBin = true;
123	if ( d0sig < d0sigCut ) goodD0sig = true;
124
125	// Jet bin
126	if( correctBin && goodD0sig ) {
127	if ( filename.Contains("TTJets") ) {
128	h_RelIso_ttbar->Fill(reliso);
129	if ( signalRegion ) { Nttbar += wttbar; }
130	else if ( fitRegion ) Nfac += wttbar;
131	}
132	if ( filename.Contains("MuPt15") ) {
133	h_RelIso_qcd->Fill(reliso);
134	if ( signalRegion ) { Na += wqcd; Nqcd+= wqcd; } // QCD in signal region
135	else if ( fitRegion ) {
136	Nb += wqcd; // QCD in fitted background region
137	Nfac += wqcd;
138	}
139	}
140	if ( filename.Contains("WJets") ) {
141	h_RelIso_wjets->Fill(reliso);
142	if ( signalRegion ) { NWjets += wwjets; }
143	else if ( fitRegion ) Nfac += wwjets;
144	}
145	if ( filename.Contains("ZJets") ) {
146	h_RelIso_zjets->Fill(reliso);
147	if ( signalRegion ) { NZjets += wzjets; }
148	else if ( fitRegion ) Nfac += wzjets;
149	}
150	}
151	}
152	cout << "\n";
153	cout << " Nb = " << Nb << "; Nfac = " << Nfac << endl << endl;
154	cout << " N ttbar = " << Nttbar << endl;
155	cout << " N qcd = " << Nqcd << endl;
156	cout << " N Wjets = " << NWjets << endl;
157	cout << " N Zjets = " << NZjets << endl << endl;
158
159	gStyle->SetOptFit(01111);
160
161	TCanvas *cv1 = new TCanvas("cv1","cv1",800,600);
162	THStack *hs = new THStack("hs","RelIso (stacked)");
163
164	// Take care of scaling
165	h_RelIso_qcd->Scale(wqcd);
166	h_RelIso_wjets->Scale(wwjets);
167	h_RelIso_zjets->Scale(wzjets);
168	h_RelIso_ttbar->Scale(wttbar);
169
170	h_RelIso_qcd->SetXTitle("Combined Relative Isolation");
171	h_RelIso_qcd->SetLineColor(40);
172	h_RelIso_qcd->SetFillStyle(3018);
173	h_RelIso_qcd->SetFillColor(38);
174	hs->Add(h_RelIso_qcd);
175	h_RelIso_wjets->SetMarkerColor(4);
176	h_RelIso_wjets->SetLineColor(4);
177	h_RelIso_wjets->SetFillColor(4);
178	hs->Add(h_RelIso_wjets);
179	h_RelIso_zjets->SetMarkerColor(5);
180	h_RelIso_zjets->SetLineColor(5);
181	h_RelIso_zjets->SetFillColor(5);
182	hs->Add(h_RelIso_zjets);
183	h_RelIso_ttbar->SetMarkerColor(2);
184	h_RelIso_ttbar->SetLineColor(2);
185	h_RelIso_ttbar->SetFillColor(2);
186	hs->Add(h_RelIso_ttbar);
187	hs->Draw();
188
189	// Label histo
190	TLegend * leg0 = new TLegend(0.3,0.3,0.6,0.55);
191	leg0->AddEntry(h_RelIso_ttbar,"t#bar{t}");
192	leg0->AddEntry(h_RelIso_qcd,"QCD (MuPt15) ");
193	leg0->AddEntry(h_RelIso_wjets,"W+jets");
194	leg0->AddEntry(h_RelIso_zjets,"Z+jets");
195	leg0->Draw();
196
197	h_RelIso_all->Add(h_RelIso_ttbar,1.);
198	h_RelIso_all->Add(h_RelIso_qcd,1.);
199	h_RelIso_all->Add(h_RelIso_wjets,1.);
200	h_RelIso_all->Add(h_RelIso_zjets,1.);
201	h_RelIso_all->SetLineWidth(2);
202
203	if( jbin == 4)
204	h_RelIso_all->SetTitle( isoname+" RelIso distribution (#geq 4 jets)");
205	else if ( jbin < 4 ) {
206	TString title = isoname+" RelIso distribution (";
207	title += jbin;
208	title += " jets)";
209	h_RelIso_all->SetTitle(title);
210	}
211	else {
212	cout<<"Don't mess around!!! jbin should be less than 5!"<<endl;
213	return;
214	}
215	h_RelIso_all->SetMinimum(0);
216	// Save for later use
217	TFile *file0 = new TFile("extpQCDbin4.root","RECREATE");
218	file0->mkdir("histos");
219	file0->cd("histos");
220	h_RelIso_all->Write();
221	h_RelIso_ttbar->Write();
222	h_RelIso_qcd->Write();
223	h_RelIso_wjets->Write();
224	h_RelIso_zjets->Write();
225	file0->Write();
226	file0->Close();
227	// Fitting here:
228	FitBKG(fitfunc,h_RelIso_all,h_RelIso_qcd,AX0,AXf,BX0,BXf,Na);
229	}
230
231	void qcd::FitBKG(TString s0,TH1D h0,TH1D h1,
232	double ax0,double axf,double bx0,double bxf,double na) {
233	int niter = 1;
234	double pass[3] = {0.,0.,0.};
235	double ns, ns2;
236	ns = ns2 = 0.;
237
238	TCanvas *cvf = new TCanvas("cvf","cvf",800,600);
239
240	// Fit QCD in background region
241	cout<<"Fitting with "<<s0<<" function!"<<endl;
242	TH1D h_all = (TH1D)h0->Clone();
243	TH1D h_qcd = (TH1D)h1->Clone();
244	h_all->Draw();
245
246	cout << "\n>>>>> Iteration step: "<< niter << endl;
247	h_all->Fit(s0,"0","",bx0,bxf);
248
249	// Very first fit function
250	TF1 f0 = (TF1)h_all->GetFunction(s0);
251	Int_t npar = f0->GetNpar();
252	Double_t chi2 = f0->GetChisquare();
253	Int_t ndof = f0->GetNDF();
254	pass[0] = chi2/ndof;
255	pass[1] = pass[0];
256	cout << ">> Norm chi2 = " << pass[0] << endl;
257
258	bx0 = f0->GetParameter(1) - wxmin*f0->GetParameter(2);
259	bxf = f0->GetParameter(1) + wxmax*f0->GetParameter(2);
260
261	double * par0 = new double [npar];
262	double * parErr0 = new double [npar];
263
264	double delta = pass[1]-pass[2];
265
266	while (niter <= 20 && abs(pass[1]-pass[2]) > 0.00001) {
267	if (niter > 1)
268	pass[1]=pass[2];
269	if (delta >= 0){
270	niter++;
271	cout << "\n>>>>> Iteration step: "<< niter << endl;
272	cout << ">> Pass[1] = " << pass[1] << endl;
273
274	h_all->Fit(s0,"0","",bx0,bxf);
275	TF1 fi = (TF1)h_all->GetFunction(s0);
276	pass[2] = fi->GetChisquare()/fi->GetNDF();
277	cout << ">> Norm chi2 = pass[2] = " << pass[2] << endl;
278	delta = pass[1]-pass[2];
279	cout << ">> Delta = " << delta << endl;
280
281	if (delta >= 0) {
282	printf("Function has %i parameters. Chisquare = %g\n",
283	npar,
284	fi->GetChisquare());
285	for (Int_t i=0;i<npar;i++) {
286	printf("%s = %g +- %g\n",
287	fi->GetParName(i),
288	fi->GetParameter(i),
289	fi->GetParError(i)
290	);
291	par0[i] = fi->GetParameter(i);
292	parErr0[i] = fi->GetParError(i);
293	// cout<<"Par["<<i<<"]="<<par0[i]<<"; Error="<<parErr0[i]<<endl;
294	}
295	bx0 = fi->GetParameter(1) - wxmin*fi->GetParameter(2);
296	bxf = fi->GetParameter(1) + wxmax*fi->GetParameter(2);
297	cout << ">> bx0, bxf = " << bx0 << ", " << bxf << endl;
298	}
299	else {
300	cout << ">> Use previous fit!" << endl;
301	}
302	}
303	}
304
305	cout << ">>> Final fitting resion (bx0, bxf) = " << bx0 << ", " << bxf << endl;
306
307	// Get number of events within fitted region
308	TAxis *axis = h_all->GetXaxis();
309	int bmin = axis->FindBin(bx0);
310	int bmax = axis->FindBin(bxf);
311	double nfac1 = h_all->Integral(bmin,bmax);
312	nfac1 -= (h_all->GetBinContent(bmin))*(bx0-axis->GetBinLowEdge(bmin))/axis->GetBinWidth(bmin);
313	nfac1 -= (h_all->GetBinContent(bmax))*(axis->GetBinUpEdge(bmax)-bxf)/axis->GetBinWidth(bmax);
314	cout << ">>> Final Nfac = " << nfac1 << endl;
315
316	// ////////////////////////
317	// Histos and extrapolation
318
319	TF1 f1 = (TF1)f0->Clone();
320	f1->SetRange(bx0,bxf);
321	for (int i=0;i<npar;i++) {
322	cout<<" >> Par["<<i<<"]="<<par0[i]<<"; Error="<<parErr0[i]<<endl;
323	f1->SetParameter(i,par0[i]);
324	}
325
326	f1->SetLineColor(2);
327	h_qcd->SetLineColor(40);
328	h_qcd->SetFillStyle(3018);
329	h_qcd->SetFillColor(38);
330	h_qcd->Draw("same");
331	f1->Draw("same");
332
333	// Connect fitted and extrapolated region
334	TF1 fin = (TF1)f1->Clone();
335	fin->SetRange(axf,bx0);
336	fin->SetLineStyle(2);
337	fin->SetLineColor(8);
338	fin->Draw("same");
339
340	TF1 f2 = (TF1)f1->Clone();
341	f2->SetRange(ax0,axf);
342	f2->SetLineColor(4);
343	f2->Draw("same");
344	int np = 100;
345	double *x=new double[np];
346	double *w=new double[np];
347	f2->CalcGaussLegendreSamplingPoints(np,x,w,1e-15);
348	ns = f2->IntegralFast(np,x,w,ax0,axf);
349	ns/=(f2->Integral(bx0,bxf));
350	ns*=nfac1;
351	cout<<">>> Ns by usual integral = "<<ns<<endl;
352	delete [] x;
353	delete [] w;
354
355	// Another way to do integration
356	TF1 g = (TF1)f1->Clone();
357	ROOT::Math::GSLIntegrator ig(1.E-8,1.E-8,1000);
358	ROOT::Math::WrappedTF1 wf(*g);
359	ig.SetFunction(wf);
360	ns2 = ig.Integral(ax0,axf);
361	ns2/=(g->Integral(bx0,bxf));
362	ns2*=nfac1;
363	cout<<">>> Ns by MathMore integral = "<<ns2<<endl;
364
365	cvf->Update();
366
367	TPaveStats p1 = (TPaveStats)h_all->GetListOfFunctions()->FindObject("stats");
368	p1->SetTextColor(kBlue);
369	p1->SetX1NDC(0.6);
370	p1->SetX2NDC(0.88);
371	p1->SetY1NDC(0.62);
372	p1->SetY2NDC(0.88);
373	p1->Draw();
374
375	// Label histo
376	TLegend * leg1 = new TLegend(0.3,0.15,0.68,0.45);
377	// leg1->SetHeader("Fit with "+fitfunc);
378	leg1->AddEntry(h_all,"All events (S+B)");
379	leg1->AddEntry(h_qcd,"QCD events");
380	leg1->AddEntry(f1,"Fit of all events in control region");
381	leg1->AddEntry(f2,"Extrapolation to signal region");
382	leg1->Draw();
383	// Print results
384	cout << ">>>>> Observed Ns = " << ns;
385	cout <<"\n";
386	cout << ">>>>> Expected Na = " << na << endl;
387	}