[u/mrichter/AliRoot.git] / FASTSIM / uncorrBg.C

void uncorrBg(Int_t nev = 1000000, Double_t bmin = 0., Double_t bmax = 5.)
{
//
//
//
    AliFastGlauber*  glauber = new AliFastGlauber();
    glauber->Init(1);
    
    Float_t lumi   = 5.e26;   // cm^-2 s^-1
    Float_t time   = 1.e6;    // s
    Float_t rate   = lumi/1.e24 * glauber->CrossSection(bmin, bmax); // Hz
    Float_t fhard  = glauber->FractionOfHardCrossSection(bmin, bmax);
    Float_t fgeo   = glauber->CrossSection(bmin, bmax) / glauber->CrossSection(0, 100.);
    Float_t events = rate * time;

    printf("-------------------------------------------------------------------\n");
    printf("Impact parameter range: %10.3f - %10.3f fm \n", bmin, bmax);
    printf("Luminosity: %10.3e cm^-2 s^-1 \n", lumi);
    printf("Rate: %10.3f Hz\n", rate);
    printf("Fraction of hard  cross-section: %10.3f %\n", fhard * 100.);
    printf("Fraction of geom. cross-section: %10.3f %\n", fgeo  * 100.);
    printf("Events in 10^6 s: %10.3e %\n", events);
    printf("-------------------------------------------------------------------\n");

//
//    
    Float_t ptMinCut  = 1.;
    Float_t etamin    = 2.543;
    Float_t etar      = 1.457;
    Float_t ptUp      = 20.;   // GeV
    Float_t dpt       = 0.1;   // GeV
//    
//  For b = 0
//  (factor 1.28 to scale from 10% most central to b=0)
//    
    Float_t scaleC0 = 1.28 * ptUp / dpt;
    Float_t scaleB0 = 1.28 * ptUp / dpt;
    Float_t scaleD0 = 1.28 * etar * ptUp / 1.35; // scaled by 1.35 to match ALICE-INT-2002-6
    
//
//
//  Fast response
//    
    AliFastMuonTriggerEff  *trigeff = new AliFastMuonTriggerEff();
    AliFastMuonTrackingAcc *acc     = new AliFastMuonTrackingAcc();
    AliFastMuonTrackingEff *eff     = new AliFastMuonTrackingEff();
    AliFastMuonTrackingRes *res     = new AliFastMuonTrackingRes();
    acc->SetBackground(1.);
    eff->SetBackground(1.);
    res->SetBackground(1.);  

    acc    ->Init(); 
    eff    ->Init(); 
    res    ->Init(); 
    trigeff->Init();
    
/*
//  To be improved
//
    AliFastDetector* tracker = new AliFastDetector("Tracker", "Muon Tracker");
    tracker->AddResponse(acc);
    tracker->AddResponse(eff);
    tracker->AddResponse(res);

    AliFastDetector* trigger = new AliFastDetector("Trigger", "Muon Trigger");
    trigger->AddResponse(trigeff);

    AliFastDetector* spectro = new AliFastDetector("Spectro", "Muon Spectrometer");
    spectro->AddSubdetector(tracker, "");
    spectro->AddSubdetector(trigger, "");    
    spectro->Init();
*/
	    
//
//  Heavy Flavors
//
    
    TF1*  ptBBLf = new TF1("ptBBLf", "[0] * x / (1. + (x/[1])**2)**[2]", 0., 2.);
    ptBBLf->SetParameter(0, 1.4651e-02);
    ptBBLf->SetParameter(1, 9.3409e-01);
    ptBBLf->SetParameter(2, 1.3583e+00);

    TF1*  ptBBHf = new TF1("ptBBHf", "[0] * x / (1. + (x/[1])**2)**[2]", 2., ptUp);
    ptBBHf->SetParameter(0, 7.7122e-03);
    ptBBHf->SetParameter(1, 2.38);
    ptBBHf->SetParameter(2, 3.32);

    TF1*  ptCCHf = new TF1("ptCCHf", "[0] * x / (1. + (x/[1])**2)**([2] + [3] * x)", 1.5, ptUp);
    ptCCHf->SetParameter(0, 8.6675e-01);
    ptCCHf->SetParameter(1, 8.1384e-01);
    ptCCHf->SetParameter(2, 2.8933e+00);
    ptCCHf->SetParameter(3, 1.4865e-02);

    TF1*  ptCCLf = new TF1("ptCCLf", "[0] * x / (1. + (x/[1])**2)**([2] + [3] * x)", 0., 1.5);
    ptCCLf->SetParameter(0, 2.4899e+00);
    ptCCLf->SetParameter(1, 3.8394e-01);
    ptCCLf->SetParameter(2, 1.5505e+00);
    ptCCLf->SetParameter(3, 2.4679e-01);
    
    TF1*  ptBf = new TF1("ptBf", "[0] * x / (1. + (x/[1])**2)**[2]", 0., ptUp);
    ptBf->SetParameter(0, 1.e5 * 0.7 * 1.125);
    ptBf->SetParameter(1, 6.27);
    ptBf->SetParameter(2, 3.2);
//
//  pi/K -> mu
//
    f = new TFile("$(ALICE_ROOT)/FASTSIM/data/pikmu.root");
    TH2F*  etaptPiK = (TH2F*) f->Get("etaptH");
    TAxis* etaAxis  = etaptPiK->GetXaxis();
    TAxis* ptAxis   = etaptPiK->GetYaxis();    
//
//
// Book histograms
    TH1F* massBBH = new TH1F("massBBH", "Mass Spectrum: b-b        ", 150, 0., 15.);
    TH1F* massCCH = new TH1F("massCCH", "Mass Spectrum: c-c        ", 150, 0., 15.);
    TH1F* massBCH = new TH1F("massBCH", "Mass Spectrum: b-c        ", 150, 0., 15.);
    TH1F* massDDH = new TH1F("massDDH", "Mass Spectrum: decay-decay", 150, 0., 15.);
    TH1F* massBDH = new TH1F("massBDH", "Mass Spectrum: decay-b    ", 150, 0., 15.);
    TH1F* massCDH = new TH1F("massCDH", "Mass Spectrum: decay-c    ", 150, 0., 15.);    
    TH1F* ptCH    = new TH1F("ptCH", "pt Spectrum mu from c",          20, 0., 10.);    
    TH1F* ptBH    = new TH1F("ptBH", "pt Spectrum mu from b",          20, 0., 10.);    
    TH1F* ptDH    = new TH1F("ptDH", "pt Spectrum mu from pi/K",       20, 0., 10.);    
    TH1F* ptBH2   = new TH1F("ptBH2", "pt Spectrum mu from b",         20, 0., 10.);    
//
// Event Loop
//
    Int_t iev;
    for (iev = 0; iev < nev; iev++) {
//
//  Collision geometry
//
	Float_t b;
	b = glauber->GetRandomImpactParameter(bmin, bmax);
	Double_t nbinary = glauber->Binaries(b);
	Float_t  scaleC  = scaleC0 * nbinary;
	Float_t  scaleB  = scaleB0 * nbinary;
	Float_t  scaleD  = scaleD0 * nbinary;
//
// pT
	Float_t pT1 = ptUp * gRandom->Rndm();
	Float_t pT2 = ptUp * gRandom->Rndm();
//
// phi
	Float_t phi1 = 2. * TMath::Pi() * gRandom->Rndm() - TMath::Pi();
	Float_t phi2 = 2. * TMath::Pi() * gRandom->Rndm() - TMath::Pi();
	Float_t dphi = phi1 - phi2;
//
// eta
	Float_t eta1 = etar * gRandom->Rndm() + etamin;
	Float_t eta2 = etar * gRandom->Rndm() + etamin;	
	Float_t deta = eta1 - eta2;
//
// invariant mass
	Float_t m2 = 2. * pT1 * pT2 * (TMath::CosH(deta) - TMath::Cos(dphi));
	Float_t m  = TMath::Sqrt(m2);

//
// Smearing (to be improved)
	Float_t dm = m * 0.01;
	m += gRandom->Gaus(0., dm);	
//
// Weights
//
//      Heavy Flavour
//
	Int_t ibin;
	Float_t wgtB1, wgtB2;
	Float_t wgtC1, wgtC2;

	if (pT1 > 1.5) {
	    wgtC1 = ptCCHf->Eval(pT1) * scaleC;
	} else {
	    wgtC1 = ptCCLf->Eval(pT1) * scaleC;
	}
	if (pT2 > 1.5) {
	    wgtC2 = ptCCHf->Eval(pT2) * scaleC;
	} else {
	    wgtC2 = ptCCLf->Eval(pT2) * scaleC;
	}


	if (pT1 > 2.) {
	    wgtB1 = ptBBHf->Eval(pT1) * scaleB;
	} else {
	    wgtB1 = ptBBLf->Eval(pT1) * scaleB;
	}
	if (pT2 > 2.) {
	    wgtB2 = ptBBHf->Eval(pT2) * scaleB;
	} else {
	    wgtB2 = ptBBLf->Eval(pT2) * scaleB;
	}


//
//      Weight  for decays
//
	Int_t etaBin, ptBin;
	Float_t wgtD1, wgtD2;
	
	etaBin = etaAxis->FindBin(eta1);
	ptBin  = ptAxis ->FindBin(pT1);	
	wgtD1  = etaptPiK->GetBinContent(etaBin, ptBin) * scaleD;
	
	etaBin = etaAxis->FindBin(eta2);
	ptBin  = ptAxis ->FindBin(pT2);	
	wgtD2  = etaptPiK->GetBinContent(etaBin, ptBin) * scaleD;
	
//
//      Efficiencies
//	
	Float_t theta1 = 2. * TMath::ATan(TMath::Exp(-eta1)) * 180./TMath::Pi();
	Float_t theta2 = 2. * TMath::ATan(TMath::Exp(-eta2)) * 180./TMath::Pi();
	Float_t phid1  = phi1 * 180./TMath::Pi();
	Float_t phid2  = phi2 * 180./TMath::Pi();
	Float_t p1     = pT1/TMath::Sin(theta1 * TMath::Pi()/180.);
	Float_t p2     = pT2/TMath::Sin(theta2 * TMath::Pi()/180.);
	
	res->SetCharge(1);
	eff->SetCharge(1);
	acc->SetCharge(1);
	Float_t eff1  = eff->Evaluate(pT1, theta1, phid1);
	Float_t acc1  = acc->Evaluate(pT1, theta1, phid1);
	Float_t tri1  = trigeff->Evaluate(1, pT1, theta1, phid1);
	res->SetCharge(-1);
	eff->SetCharge(-1);
	acc->SetCharge(-1);
	Float_t eff2  = eff->Evaluate(pT2, theta2, phid2);
	Float_t acc2  = acc->Evaluate(pT2, theta2, phid2);
	Float_t tri2  = trigeff->Evaluate(-1, pT2, theta2, phid2);

	Float_t effA   = eff1 * eff2 * acc1 * acc2 * tri1 * tri2;

	Float_t ptMax = pT1;
	Float_t ptMin = pT2;
	if (pT2 > pT1) {
	    Float_t ptMax = pT2;
	    Float_t ptMin = pT1;
	}
	
	if (ptMin > ptMinCut && p1 > 4. && p2 > 4.) {
	    massBBH->Fill(m, wgtB1 * wgtB2 / 4. * effA);
	    massCCH->Fill(m, wgtC1 * wgtC2 / 4. * effA);
	    massBCH->Fill(m, wgtC1 * wgtB2 / 4. * effA);
	    massBCH->Fill(m, wgtC2 * wgtB1 / 4. * effA);
	    massDDH->Fill(m, wgtD1 * wgtD2 / 4. * effA);
	    massBDH->Fill(m, wgtB1 * wgtD2 / 4. * effA);
	    massBDH->Fill(m, wgtB2 * wgtD1 / 4. * effA);
	    massCDH->Fill(m, wgtC1 * wgtD2 / 4. * effA);
	    massCDH->Fill(m, wgtC2 * wgtD1 / 4. * effA);
	}
	//
	// pT - Spectra
	//
	for (Int_t ipt = 0; ipt < 20; ipt++)
	{
	    Float_t pt = 0.5 * ipt;
	    ptBH2->Fill(pT1, wgtB1);		
	    if (pT1 > pt) {
		ptCH->Fill(pt, wgtC1);
		ptBH->Fill(pt, wgtB1);
		ptDH->Fill(pt, wgtD1);
	    }
	} // bins
    } // event loop

    Float_t evtWgt = events / Float_t(nev);
    
    massBBH->Scale(evtWgt);
    massCCH->Scale(evtWgt);
    massBCH->Scale(evtWgt);
    massDDH->Scale(evtWgt);
    massBDH->Scale(evtWgt);
    massCDH->Scale(evtWgt);
    
    TH1F * massALH = new TH1F(*massCDH);
    massALH->Add(massBDH);
    massALH->Add(massDDH);
    massALH->Add(massBCH);    
    massALH->Add(massCCH);
    massALH->Add(massBBH);     

    TCanvas *c0 = new TCanvas("c0","Canvas 1",400,10,600,700);
    massCCH->SetLineColor(4);
    massCCH->SetMinimum(1.);
    massCCH->SetMaximum(1.e4);
    massCCH->SetXTitle("m_{#mu#mu} [GeV]");
    massCCH->SetYTitle("Entries/100 MeV /10^{6} s");
    massCCH->Draw("");
    massALH->SetLineColor(3);
    massALH->Draw("same");
    massBBH->SetLineColor(6);
    massBBH->Draw("same");

    TCanvas *c2 = new TCanvas("c2","Canvas 3",400,10,600,700);
    massDDH->SetLineColor(2);
    massDDH->SetMinimum(1.e2);
    massDDH->SetMaximum(1.e6);
    massDDH->SetXTitle("m_{#mu#mu} [GeV]");
    massDDH->SetYTitle("Entries/100 MeV /10^{6} s");
    massDDH->Draw("");
    massALH->SetLineColor(3);
    massALH->Draw("same");
    massCCH->SetLineColor(4);
    massCCH->Draw("same");
    massBBH->SetLineColor(6);
    massBBH->Draw("same");

    TCanvas *c3 = new TCanvas("c3","Canvas 4",400,10,600,700);
    ptCH->Scale(1./float(nev));
    ptBH->Scale(1./float(nev));    
    ptDH->Scale(1./float(nev));    
    ptCH->SetLineColor(4);
    ptBH->SetLineColor(6);
    ptDH->SetLineColor(2);
    ptCH->SetXTitle("p_{T}^{min} [GeV]");
    ptCH->SetYTitle("<n>_{#mu}/event");
    
    ptDH->Draw();
    ptBH->Draw("same");
    ptCH->Draw("same");
    TCanvas *c4 = new TCanvas("c4","Canvas 5",400,10,600,700);
    ptBH2->Draw();
 
}
Commit	Line	Data
a51eecef	1	void uncorrBg(Int_t nev = 1000000, Double_t bmin = 0., Double_t bmax = 5.)
d0768bbb	2	{
d0768bbb	3	//
d0768bbb	4	//
d0768bbb	5	//
a51eecef	6	AliFastGlauber* glauber = new AliFastGlauber();
	7	glauber->Init(1);
	8
	9	Float_t lumi = 5.e26; // cm^-2 s^-1
	10	Float_t time = 1.e6; // s
	11	Float_t rate = lumi/1.e24 * glauber->CrossSection(bmin, bmax); // Hz
	12	Float_t fhard = glauber->FractionOfHardCrossSection(bmin, bmax);
	13	Float_t fgeo = glauber->CrossSection(bmin, bmax) / glauber->CrossSection(0, 100.);
	14	Float_t events = rate * time;
	15
	16	printf("-------------------------------------------------------------------\n");
	17	printf("Impact parameter range: %10.3f - %10.3f fm \n", bmin, bmax);
	18	printf("Luminosity: %10.3e cm^-2 s^-1 \n", lumi);
	19	printf("Rate: %10.3f Hz\n", rate);
	20	printf("Fraction of hard cross-section: %10.3f %\n", fhard * 100.);
	21	printf("Fraction of geom. cross-section: %10.3f %\n", fgeo * 100.);
	22	printf("Events in 10^6 s: %10.3e %\n", events);
	23	printf("-------------------------------------------------------------------\n");
	24
	25	//
	26	//
	27	Float_t ptMinCut = 1.;
	28	Float_t etamin = 2.543;
	29	Float_t etar = 1.457;
	30	Float_t ptUp = 20.; // GeV
	31	Float_t dpt = 0.1; // GeV
	32	//
	33	// For b = 0
ce839c0a	34	// (factor 1.28 to scale from 10% most central to b=0)
a51eecef	35	//
ce839c0a	36	Float_t scaleC0 = 1.28 * ptUp / dpt;
	37	Float_t scaleB0 = 1.28 * ptUp / dpt;
	38	Float_t scaleD0 = 1.28 * etar * ptUp / 1.35; // scaled by 1.35 to match ALICE-INT-2002-6
a51eecef	39
a51eecef	40	//
d0768bbb	41	//
	42	// Fast response
	43	//
a51eecef	44	AliFastMuonTriggerEff *trigeff = new AliFastMuonTriggerEff();
	45	AliFastMuonTrackingAcc *acc = new AliFastMuonTrackingAcc();
	46	AliFastMuonTrackingEff *eff = new AliFastMuonTrackingEff();
	47	AliFastMuonTrackingRes *res = new AliFastMuonTrackingRes();
d0768bbb	48	acc->SetBackground(1.);
	49	eff->SetBackground(1.);
	50	res->SetBackground(1.);
a51eecef	51
	52	acc ->Init();
	53	eff ->Init();
	54	res ->Init();
	55	trigeff->Init();
	56
	57	/*
	58	// To be improved
	59	//
d0768bbb	60	AliFastDetector* tracker = new AliFastDetector("Tracker", "Muon Tracker");
d0768bbb	61	tracker->AddResponse(acc);
	62	tracker->AddResponse(eff);
	63	tracker->AddResponse(res);
d0768bbb	64
a51eecef	65	AliFastDetector* trigger = new AliFastDetector("Trigger", "Muon Trigger");
	66	trigger->AddResponse(trigeff);
	67
	68	AliFastDetector* spectro = new AliFastDetector("Spectro", "Muon Spectrometer");
	69	spectro->AddSubdetector(tracker, "");
	70	spectro->AddSubdetector(trigger, "");
	71	spectro->Init();
	72	*/
d0768bbb	73
	74	//
	75	// Heavy Flavors
	76	//
a51eecef	77
50b05144	78	TF1* ptBBLf = new TF1("ptBBLf", "[0] * x / (1. + (x/[1])2)[2]", 0., 2.);
	79	ptBBLf->SetParameter(0, 1.4651e-02);
	80	ptBBLf->SetParameter(1, 9.3409e-01);
	81	ptBBLf->SetParameter(2, 1.3583e+00);
d0768bbb	82
50b05144	83	TF1* ptBBHf = new TF1("ptBBHf", "[0] * x / (1. + (x/[1])2)[2]", 2., ptUp);
	84	ptBBHf->SetParameter(0, 7.7122e-03);
	85	ptBBHf->SetParameter(1, 2.38);
	86	ptBBHf->SetParameter(2, 3.32);
d0768bbb	87
a51eecef	88	TF1* ptCCHf = new TF1("ptCCHf", "[0] * x / (1. + (x/[1])2)([2] + [3] * x)", 1.5, ptUp);
50b05144	89	ptCCHf->SetParameter(0, 8.6675e-01);
	90	ptCCHf->SetParameter(1, 8.1384e-01);
	91	ptCCHf->SetParameter(2, 2.8933e+00);
	92	ptCCHf->SetParameter(3, 1.4865e-02);
d0768bbb	93
d0768bbb	94	TF1* ptCCLf = new TF1("ptCCLf", "[0] * x / (1. + (x/[1])2)([2] + [3] * x)", 0., 1.5);
50b05144	95	ptCCLf->SetParameter(0, 2.4899e+00);
	96	ptCCLf->SetParameter(1, 3.8394e-01);
	97	ptCCLf->SetParameter(2, 1.5505e+00);
	98	ptCCLf->SetParameter(3, 2.4679e-01);
d0768bbb	99
a51eecef	100	TF1* ptBf = new TF1("ptBf", "[0] * x / (1. + (x/[1])2)[2]", 0., ptUp);
d0768bbb	101	ptBf->SetParameter(0, 1.e5 * 0.7 * 1.125);
	102	ptBf->SetParameter(1, 6.27);
	103	ptBf->SetParameter(2, 3.2);
d0768bbb	104	//
	105	// pi/K -> mu
	106	//
a51eecef	107	f = new TFile("$(ALICE_ROOT)/FASTSIM/data/pikmu.root");
	108	TH2F* etaptPiK = (TH2F*) f->Get("etaptH");
	109	TAxis* etaAxis = etaptPiK->GetXaxis();
	110	TAxis* ptAxis = etaptPiK->GetYaxis();
	111	//
d0768bbb	112	//
	113	// Book histograms
	114	TH1F* massBBH = new TH1F("massBBH", "Mass Spectrum: b-b ", 150, 0., 15.);
	115	TH1F* massCCH = new TH1F("massCCH", "Mass Spectrum: c-c ", 150, 0., 15.);
	116	TH1F* massBCH = new TH1F("massBCH", "Mass Spectrum: b-c ", 150, 0., 15.);
	117	TH1F* massDDH = new TH1F("massDDH", "Mass Spectrum: decay-decay", 150, 0., 15.);
	118	TH1F* massBDH = new TH1F("massBDH", "Mass Spectrum: decay-b ", 150, 0., 15.);
	119	TH1F* massCDH = new TH1F("massCDH", "Mass Spectrum: decay-c ", 150, 0., 15.);
a51eecef	120	TH1F* ptCH = new TH1F("ptCH", "pt Spectrum mu from c", 20, 0., 10.);
	121	TH1F* ptBH = new TH1F("ptBH", "pt Spectrum mu from b", 20, 0., 10.);
	122	TH1F* ptDH = new TH1F("ptDH", "pt Spectrum mu from pi/K", 20, 0., 10.);
	123	TH1F* ptBH2 = new TH1F("ptBH2", "pt Spectrum mu from b", 20, 0., 10.);
d0768bbb	124	//
	125	// Event Loop
	126	//
	127	Int_t iev;
	128	for (iev = 0; iev < nev; iev++) {
	129	//
a51eecef	130	// Collision geometry
	131	//
	132	Float_t b;
	133	b = glauber->GetRandomImpactParameter(bmin, bmax);
	134	Double_t nbinary = glauber->Binaries(b);
	135	Float_t scaleC = scaleC0 * nbinary;
	136	Float_t scaleB = scaleB0 * nbinary;
	137	Float_t scaleD = scaleD0 * nbinary;
	138	//
d0768bbb	139	// pT
a51eecef	140	Float_t pT1 = ptUp * gRandom->Rndm();
a51eecef	141	Float_t pT2 = ptUp * gRandom->Rndm();
d0768bbb	142	//
	143	// phi
	144	Float_t phi1 = 2. * TMath::Pi() * gRandom->Rndm() - TMath::Pi();
	145	Float_t phi2 = 2. * TMath::Pi() * gRandom->Rndm() - TMath::Pi();
	146	Float_t dphi = phi1 - phi2;
	147	//
	148	// eta
a51eecef	149	Float_t eta1 = etar * gRandom->Rndm() + etamin;
a51eecef	150	Float_t eta2 = etar * gRandom->Rndm() + etamin;
d0768bbb	151	Float_t deta = eta1 - eta2;
	152	//
	153	// invariant mass
	154	Float_t m2 = 2. * pT1 * pT2 * (TMath::CosH(deta) - TMath::Cos(dphi));
	155	Float_t m = TMath::Sqrt(m2);
	156
	157	//
a51eecef	158	// Smearing (to be improved)
d0768bbb	159	Float_t dm = m * 0.01;
	160	m += gRandom->Gaus(0., dm);
	161	//
	162	// Weights
	163	//
	164	// Heavy Flavour
	165	//
	166	Int_t ibin;
	167	Float_t wgtB1, wgtB2;
	168	Float_t wgtC1, wgtC2;
	169
ce839c0a	170	if (pT1 > 1.5) {
d0768bbb	171	wgtC1 = ptCCHf->Eval(pT1) * scaleC;
	172	} else {
	173	wgtC1 = ptCCLf->Eval(pT1) * scaleC;
	174	}
ce839c0a	175	if (pT2 > 1.5) {
d0768bbb	176	wgtC2 = ptCCHf->Eval(pT2) * scaleC;
	177	} else {
	178	wgtC2 = ptCCLf->Eval(pT2) * scaleC;
	179	}
	180
	181
50b05144	182	if (pT1 > 2.) {
d0768bbb	183	wgtB1 = ptBBHf->Eval(pT1) * scaleB;
	184	} else {
	185	wgtB1 = ptBBLf->Eval(pT1) * scaleB;
	186	}
50b05144	187	if (pT2 > 2.) {
d0768bbb	188	wgtB2 = ptBBHf->Eval(pT2) * scaleB;
	189	} else {
	190	wgtB2 = ptBBLf->Eval(pT2) * scaleB;
	191	}
	192
	193
	194	//
	195	// Weight for decays
	196	//
	197	Int_t etaBin, ptBin;
	198	Float_t wgtD1, wgtD2;
	199
	200	etaBin = etaAxis->FindBin(eta1);
	201	ptBin = ptAxis ->FindBin(pT1);
	202	wgtD1 = etaptPiK->GetBinContent(etaBin, ptBin) * scaleD;
	203
	204	etaBin = etaAxis->FindBin(eta2);
	205	ptBin = ptAxis ->FindBin(pT2);
	206	wgtD2 = etaptPiK->GetBinContent(etaBin, ptBin) * scaleD;
a51eecef	207
d0768bbb	208	//
a51eecef	209	// Efficiencies
d0768bbb	210	//
	211	Float_t theta1 = 2. * TMath::ATan(TMath::Exp(-eta1)) * 180./TMath::Pi();
	212	Float_t theta2 = 2. * TMath::ATan(TMath::Exp(-eta2)) * 180./TMath::Pi();
	213	Float_t phid1 = phi1 * 180./TMath::Pi();
	214	Float_t phid2 = phi2 * 180./TMath::Pi();
a51eecef	215	Float_t p1 = pT1/TMath::Sin(theta1 * TMath::Pi()/180.);
	216	Float_t p2 = pT2/TMath::Sin(theta2 * TMath::Pi()/180.);
	217
d0768bbb	218	res->SetCharge(1);
	219	eff->SetCharge(1);
	220	acc->SetCharge(1);
	221	Float_t eff1 = eff->Evaluate(pT1, theta1, phid1);
	222	Float_t acc1 = acc->Evaluate(pT1, theta1, phid1);
	223	Float_t tri1 = trigeff->Evaluate(1, pT1, theta1, phid1);
	224	res->SetCharge(-1);
	225	eff->SetCharge(-1);
	226	acc->SetCharge(-1);
	227	Float_t eff2 = eff->Evaluate(pT2, theta2, phid2);
	228	Float_t acc2 = acc->Evaluate(pT2, theta2, phid2);
3e1ba7de	229	Float_t tri2 = trigeff->Evaluate(-1, pT2, theta2, phid2);
d0768bbb	230
d0768bbb	231	Float_t effA = eff1 * eff2 * acc1 * acc2 * tri1 * tri2;
a51eecef	232
d0768bbb	233	Float_t ptMax = pT1;
	234	Float_t ptMin = pT2;
	235	if (pT2 > pT1) {
	236	Float_t ptMax = pT2;
	237	Float_t ptMin = pT1;
	238	}
	239
a51eecef	240	if (ptMin > ptMinCut && p1 > 4. && p2 > 4.) {
d0768bbb	241	massBBH->Fill(m, wgtB1 * wgtB2 / 4. * effA);
	242	massCCH->Fill(m, wgtC1 * wgtC2 / 4. * effA);
	243	massBCH->Fill(m, wgtC1 * wgtB2 / 4. * effA);
	244	massBCH->Fill(m, wgtC2 * wgtB1 / 4. * effA);
	245	massDDH->Fill(m, wgtD1 * wgtD2 / 4. * effA);
	246	massBDH->Fill(m, wgtB1 * wgtD2 / 4. * effA);
	247	massBDH->Fill(m, wgtB2 * wgtD1 / 4. * effA);
	248	massCDH->Fill(m, wgtC1 * wgtD2 / 4. * effA);
	249	massCDH->Fill(m, wgtC2 * wgtD1 / 4. * effA);
	250	}
	251	//
	252	// pT - Spectra
	253	//
	254	for (Int_t ipt = 0; ipt < 20; ipt++)
	255	{
	256	Float_t pt = 0.5 * ipt;
	257	ptBH2->Fill(pT1, wgtB1);
	258	if (pT1 > pt) {
	259	ptCH->Fill(pt, wgtC1);
	260	ptBH->Fill(pt, wgtB1);
	261	ptDH->Fill(pt, wgtD1);
	262	}
a51eecef	263	} // bins
d0768bbb	264	} // event loop
a51eecef	265
a51eecef	266	Float_t evtWgt = events / Float_t(nev);
d0768bbb	267
	268	massBBH->Scale(evtWgt);
	269	massCCH->Scale(evtWgt);
	270	massBCH->Scale(evtWgt);
	271	massDDH->Scale(evtWgt);
	272	massBDH->Scale(evtWgt);
	273	massCDH->Scale(evtWgt);
	274
	275	TH1F * massALH = new TH1F(*massCDH);
	276	massALH->Add(massBDH);
	277	massALH->Add(massDDH);
	278	massALH->Add(massBCH);
	279	massALH->Add(massCCH);
	280	massALH->Add(massBBH);
	281
	282	TCanvas *c0 = new TCanvas("c0","Canvas 1",400,10,600,700);
	283	massCCH->SetLineColor(4);
	284	massCCH->SetMinimum(1.);
	285	massCCH->SetMaximum(1.e4);
	286	massCCH->SetXTitle("m_{#mu#mu} [GeV]");
	287	massCCH->SetYTitle("Entries/100 MeV /10^{6} s");
	288	massCCH->Draw("");
	289	massALH->SetLineColor(3);
	290	massALH->Draw("same");
	291	massBBH->SetLineColor(6);
	292	massBBH->Draw("same");
	293
	294	TCanvas *c2 = new TCanvas("c2","Canvas 3",400,10,600,700);
	295	massDDH->SetLineColor(2);
	296	massDDH->SetMinimum(1.e2);
	297	massDDH->SetMaximum(1.e6);
	298	massDDH->SetXTitle("m_{#mu#mu} [GeV]");
	299	massDDH->SetYTitle("Entries/100 MeV /10^{6} s");
	300	massDDH->Draw("");
	301	massALH->SetLineColor(3);
	302	massALH->Draw("same");
	303	massCCH->SetLineColor(4);
	304	massCCH->Draw("same");
	305	massBBH->SetLineColor(6);
	306	massBBH->Draw("same");
	307
	308	TCanvas *c3 = new TCanvas("c3","Canvas 4",400,10,600,700);
	309	ptCH->Scale(1./float(nev));
	310	ptBH->Scale(1./float(nev));
	311	ptDH->Scale(1./float(nev));
	312	ptCH->SetLineColor(4);
	313	ptBH->SetLineColor(6);
	314	ptDH->SetLineColor(2);
	315	ptCH->SetXTitle("p_{T}^{min} [GeV]");
	316	ptCH->SetYTitle("<n>_{#mu}/event");
	317
	318	ptDH->Draw();
	319	ptBH->Draw("same");
	320	ptCH->Draw("same");
	321	TCanvas *c4 = new TCanvas("c4","Canvas 5",400,10,600,700);
	322	ptBH2->Draw();
	323
	324	}