pfeiffer
/
inclusive_detached_dilepton
1
0
Fork 0
Code Issues Pull Requests 1 Projects Releases Wiki Activity

Compare commits

base: pfeiffer:8733cb7027c176b6c8342c56b5c061f9ef120aec
Branches Tags
pfeiffer:master
pfeiffer:training_tryouts
...
compare: pfeiffer:2199ee01bf4888ba1d6f3463e2209ccc1970cca3
Branches Tags
pfeiffer:master
pfeiffer:training_tryouts

2 Commits
8733cb7027 ... 2199ee01bf

Author SHA1 Message Date
Marius Pfeiffer 2199ee01bf Merge pull request 'plotting, analysis for remaining triggers' (#1) from main into master
7 months ago
Marius Pfeiffer 52685588ec plotting, analysis for remaining triggers
7 months ago
7 changed files with 771 additions and 43 deletions
Whitespace
Show all changes Ignore whitespace when comparing lines Ignore changes in amount of whitespace Ignore changes in whitespace at EOL
Split View
Diff Options
Show Stats
  1. 3
      .gitignore
  2. 152
      basic_analysis.h
  3. 2
      bdt_classification.h
  4. 309
      new_analysis_b02hphmmumu.cpp
  5. 160
      new_analysis_b02kppimmumu.cpp
  6. 35
      new_analysis_bu2hpmumu.cpp
  7. 153
      new_analysis_bu2kpmumu.cpp

3
.gitignore
View File

@ -4,4 +4,5 @@ status_report/**
branchnames.txt
images/**
output_files/**
BuToHpMuMu_dataloader/**
BuToHpMuMu_dataloader/**
B0ToHpHmMuMu_dataloader/**

152
basic_analysis.h
View File

@ -65,6 +65,65 @@ public:
}
};
struct FittedParam
{
std::string title;
std::string name;
double value;
double error;
bool at_limit;
bool constant;
int decimals;
FittedParam(RooRealVar var, int decimals)
{
this->title = var.GetTitle();
this->name = var.GetName();
double val = var.getVal();
this->value = val;
this->constant = var.isConstant();
if (!this->constant)
{
this->error = var.getError();
this->at_limit = ((val == var.getMin()) || (val == var.getMax()));
}
else
{
this->error = 0.;
}
this->decimals = decimals;
}
std::string ToString() const
{
if (this->constant)
{
return TString::Format("%s = %.*f", this->title.c_str(), this->decimals, this->value).Data();
}
else
{
return TString::Format("%s = %.*f #pm %.*f", this->title.c_str(), this->decimals, this->value, this->decimals, this->error).Data();
}
}
};
struct ShapeParamters
{
double alpha_left;
double n_left;
double alpha_right;
double n_right;
};
struct RooFitSummary
{
RooPlot *fit_histogram;
RooPlot *pull_histogram;
std::map<std::string, std::string> pdf_names;
std::vector<FittedParam> fitted_params;
ShapeParamters shape_parameters;
};
void DrawInDefaultCanvas(TH1 *histogram, const char *folder, double margin_left = 0, Option_t *option = "")
{
std::filesystem::create_directory(TString::Format("output_files/analysis/%s", folder).Data());
@ -88,6 +147,52 @@ void DrawInDefaultCanvas(RooPlot *rooPlot, const char *folder, double margin_lef
c->SaveAs(TString::Format("output_files/analysis/%s/%s.pdf", folder, name.Data()).Data());
}
void DrawInDefaultCanvas(RooFitSummary fitSummary, const char *folder)
{
std::filesystem::create_directory(TString::Format("output_files/analysis/%s", folder).Data());
TString name = TString::Format("%s_canvas", fitSummary.fit_histogram->GetName());
TCanvas *c = new TCanvas(name, fitSummary.fit_histogram->GetTitle(), 0, 0, 800, 600);
TPad *pull_pad = new TPad(TString::Format("%s_canv_pull", fitSummary.fit_histogram->GetName()), "Pull Pad", 0., 0., 1., 0.3);
pull_pad->Draw();
pull_pad->SetTopMargin(0.001);
pull_pad->SetBottomMargin(0.3);
pull_pad->SetGrid();
TPad *fit_pad = new TPad(TString::Format("%s_canv_fit", fitSummary.fit_histogram->GetName()), "Fit Pad", 0., 0.3, 1., 1.);
fit_pad->Draw();
fit_pad->SetBottomMargin(0.001);
fit_pad->cd();
fitSummary.fit_histogram->Draw();
TLegend *leg1 = new TLegend(0.60, 0.55, 0.87, 0.89);
leg1->SetFillColor(kWhite);
leg1->SetLineColor(kBlack);
for (const auto &[name, title] : fitSummary.pdf_names)
{
leg1->AddEntry(fitSummary.fit_histogram->findObject(name.c_str()), title.c_str(), "LP");
}
for (const auto &par : fitSummary.fitted_params)
{
if (!par.constant)
{
leg1->AddEntry((TObject *)0, par.ToString().c_str(), "");
}
}
leg1->Draw();
pull_pad->cd();
fitSummary.pull_histogram->Draw();
c->Draw();
c->SaveAs(TString::Format("output_files/analysis/%s/%s.pdf", folder, name.Data()).Data());
}
void PrintProgress(const char *title, unsigned int total, unsigned int every, unsigned int current)
{
if ((current + 1) % every == 0 || current + 1 == total)
@ -112,21 +217,6 @@ RooPlot *CreateRooFitHistogram(TH1D *hist)
return roo_frame_mass;
}
struct ShapeParamters
{
double alpha_left;
double n_left;
double alpha_right;
double n_right;
};
struct RooFitSummary
{
RooPlot *fit_histogram;
RooPlot *pull_histogram;
ShapeParamters shape_parameters;
};
RooFitSummary CreateRooFitHistogramAndFitCB(TH1D *hist, bool hasExpBkg, bool useExtShape, ShapeParamters extShape)
{
auto suffix_name = [name = hist->GetName()](const char *text)
@ -154,7 +244,8 @@ RooFitSummary CreateRooFitHistogramAndFitCB(TH1D *hist, bool hasExpBkg, bool use
RooRealVar var_mass_alphaR(suffix_name("var_mass_alphaR"), "#alpha_{R}", 2., 0., 4.);
RooRealVar var_mass_nR(suffix_name("var_mass_nR"), "n_{R}", 5., 0., 15.);
if (useExtShape) {
if (useExtShape)
{
var_mass_alphaL.setConstant(true);
var_mass_alphaL.setVal(extShape.alpha_left);
@ -165,11 +256,16 @@ RooFitSummary CreateRooFitHistogramAndFitCB(TH1D *hist, bool hasExpBkg, bool use
var_mass_alphaR.setVal(extShape.alpha_right);
var_mass_nR.setConstant(true);
var_mass_nR.setVal(extShape.n_left);
var_mass_nR.setVal(extShape.n_right);
}
TString signal_name = suffix_name("sig_cb");
RooCrystalBall sig_cb(signal_name, "Signal Crystal Ball", roo_var_mass, var_mass_x0, var_mass_sigmaLR, var_mass_alphaL, var_mass_nL, var_mass_alphaR, var_mass_nR);
RooCrystalBall sig_cb(signal_name, "CB Signal", roo_var_mass, var_mass_x0, var_mass_sigmaLR, var_mass_alphaL, var_mass_nL, var_mass_alphaR, var_mass_nR);
std::vector<FittedParam> fitted_params{};
std::map<std::string, std::string> pdf_names{};
pdf_names[signal_name.Data()] = sig_cb.getTitle().Data();
TString pull_compare_name{};
if (hasExpBkg)
@ -179,12 +275,14 @@ RooFitSummary CreateRooFitHistogramAndFitCB(TH1D *hist, bool hasExpBkg, bool use
TString background_name = suffix_name("bgk_exp");
RooExponential bkg_exp(background_name, "Exp Background", roo_var_mass, var_mass_bkg_c);
pdf_names[background_name.Data()] = bkg_exp.getTitle().Data();
RooRealVar var_mass_nsig(suffix_name("nsig"), "N_{Sig}", 0., hist->GetEntries());
RooRealVar var_mass_nbkg(suffix_name("nbkg"), "N_{Bkg}", 0., hist->GetEntries());
TString fitted_pdf_name = suffix_name("sigplusbkg");
RooAddPdf fitted_pdf(fitted_pdf_name, "Sig and Bkg PDF", RooArgList(sig_cb, bkg_exp), RooArgList(var_mass_nsig, var_mass_nbkg));
RooAddPdf fitted_pdf(fitted_pdf_name, "Sig + Bkg", RooArgList(sig_cb, bkg_exp), RooArgList(var_mass_nsig, var_mass_nbkg));
pdf_names[fitted_pdf_name.Data()] = fitted_pdf.getTitle().Data();
RooFitResult *fitres = fitted_pdf.fitTo(roohist_B_M, RooFit::Save(), RooFit::PrintLevel(1), RooFit::Range(fitting_range_name));
@ -192,26 +290,36 @@ RooFitSummary CreateRooFitHistogramAndFitCB(TH1D *hist, bool hasExpBkg, bool use
fitted_pdf.plotOn(roo_frame_mass, RooFit::LineColor(kRed), RooFit::LineStyle(kSolid), RooFit::Range(fitting_range_name), RooFit::Name(fitted_pdf_name));
fitted_pdf.plotOn(roo_frame_mass, RooFit::Components(RooArgSet(bkg_exp)), RooFit::LineColor(kBlue - 7), RooFit::LineStyle(kDashed), RooFit::Range(fitting_range_name), RooFit::Name(background_name));
fitted_pdf.plotOn(roo_frame_mass, RooFit::Components(RooArgSet(sig_cb)), RooFit::LineColor(kRed - 7), RooFit::LineStyle(kDashed), RooFit::Range(fitting_range_name), RooFit::Name(signal_name));
fitted_pdf.paramOn(roo_frame_mass);
fitted_params.push_back(FittedParam(var_mass_bkg_c, 5));
fitted_params.push_back(FittedParam(var_mass_nsig, 2));
fitted_params.push_back(FittedParam(var_mass_nbkg, 2));
pull_compare_name = fitted_pdf_name;
}
else
{
RooFitResult *fitres = sig_cb.fitTo(roohist_B_M, RooFit::Save(), RooFit::PrintLevel(1), RooFit::Range(fitting_range_name));
// sigplusbkg.plotOn(roo_frame_mass, RooFit::VisualizeError(*fitres, 1), RooFit::FillColor(kOrange + 1), RooFit::FillStyle(3144));
sig_cb.plotOn(roo_frame_mass, RooFit::LineColor(kRed), RooFit::LineStyle(kSolid), RooFit::Range(fitting_range_name), RooFit::Name(signal_name));
pull_compare_name = signal_name;
sig_cb.paramOn(roo_frame_mass);
}
fitted_params.push_back(FittedParam(var_mass_x0, 2));
fitted_params.push_back(FittedParam(var_mass_sigmaLR, 2));
fitted_params.push_back(FittedParam(var_mass_alphaL, 2));
fitted_params.push_back(FittedParam(var_mass_nL, 2));
fitted_params.push_back(FittedParam(var_mass_alphaR, 2));
fitted_params.push_back(FittedParam(var_mass_nR, 2));
RooPlot *roo_frame_pull = roo_var_mass.frame(RooFit::Title("Pull Distribution"), RooFit::Name(TString::Format("%s_pull_rplt", hist->GetName())));
roo_frame_pull->addPlotable(roo_frame_mass->pullHist(hist_name, pull_compare_name), "P");
return RooFitSummary{
roo_frame_mass,
roo_frame_pull,
pdf_names,
fitted_params,
ShapeParamters{
var_mass_alphaL.getVal(),
var_mass_nL.getVal(),

2
bdt_classification.h
View File

@ -202,7 +202,7 @@ void ConnectVarsToData(std::vector<TV *> vars, TChain *data_chain, TChain *mc_ch
void TrainBDT(std::vector<TV *> vars, const char* unique_id, TTree *sig_tree, TTree *bkg_tree)
{
TString outfile_name = TString::Format("%s_out.root", unique_id);
TString outfile_name = TString::Format("%s_tmva_out.root", unique_id);
TFile *output_file = TFile::Open(outfile_name, "RECREATE");
TString factory_options("V:Silent:Color:DrawProgressBar:Transformations=I;D;P;G,D:AnalysisType=Auto");

309
new_analysis_b02hphmmumu.cpp
View File

@ -0,0 +1,309 @@
#include <string>
#include <iostream>
#include <cmath>
#include <algorithm>
#include <filesystem>
#include <string_view>
#include "TH1D.h"
#include "TH2D.h"
#include "THStack.h"
#include "TGraph.h"
#include "TTree.h"
#include "TChain.h"
#include "TFile.h"
#include "TCanvas.h"
#include "TROOT.h"
#include "TStyle.h"
#include "TColor.h"
#include "TLorentzVector.h"
#include "TRandom3.h"
#include "TLegend.h"
#include "RooDataHist.h"
#include "RooRealVar.h"
#include "RooPlot.h"
#include "RooGaussian.h"
#include "RooExponential.h"
#include "RooRealConstant.h"
#include "RooAddPdf.h"
#include "RooFitResult.h"
#include "RooProduct.h"
#include "RooCrystalBall.h"
#include "RooBreitWigner.h"
#include "RooArgSet.h"
#include "RooFFTConvPdf.h"
#include "RooNovosibirsk.h"
#include "constants.h"
#include "basic_analysis.h"
#include "hlt1_decision_analysis.h"
#include "bdt_classification.h"
// %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% Inclusive :: B0 To Hp Hm Mu Mu %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
int new_analysis_b02hphmmumu()
{
const char *analysis_name = "B0ToHpHmMuMu";
const char *data_tree_name = "B0ToHpHmMuMu";
const char *sim_tree_name = "B0ToHpHmMuMu_noPID";
const char *end_state_mass_literal = "m(#pi^{+}_{(#rightarrow K^{+})}#pi^{-}_{(#rightarrow K^{-})}#mu^{+}#mu^{-})";
const bool retrain_bdt = true;
TChain *data_chain = new TChain(TString::Format("%s/DecayTree", data_tree_name));
// data_chain->Add("/auto/data/pfeiffer/inclusive_detached_dilepton/data_samples/spruce_magdown_2023_v0_tuple_90000000_v0r0p6288631.root");
data_chain->Add("/auto/data/pfeiffer/inclusive_detached_dilepton/data_samples/spruce_magdown_2023_v0r1_tuple_90000000_2023_v0r0p6288631.root");
Double_t Hp_PID_K, Hm_PID_K;
data_chain->SetBranchAddress("Hp_PID_K", &Hp_PID_K);
data_chain->SetBranchAddress("Hm_PID_K", &Hm_PID_K);
FourVect *l14v_data = FourVect::Init(data_chain, "L1");
FourVect *l24v_data = FourVect::Init(data_chain, "L2");
FourVect *hp4v_data = FourVect::Init(data_chain, "Hp");
FourVect *hm4v_data = FourVect::Init(data_chain, "Hm");
TChain *sim_chain = new TChain(TString::Format("%s/DecayTree", sim_tree_name));
sim_chain->Add("/auto/data/pfeiffer/inclusive_detached_dilepton/MC/rd_btoxll_simulation_fullstream_v0r0p6671378_B0ToKpPimMuMu_11144002_magdown.root");
FourVect *l14v_sim = FourVect::Init(sim_chain, "L1");
FourVect *l24v_sim = FourVect::Init(sim_chain, "L2");
FourVect *hp4v_sim = FourVect::Init(sim_chain, "Hp");
FourVect *hm4v_sim = FourVect::Init(sim_chain, "Hm");
Int_t B_BKGCAT, L1_TRUEID, L2_TRUEID, Hp_TRUEID, Hm_TRUEID;
sim_chain->SetBranchAddress("L1_TRUEID", &L1_TRUEID);
sim_chain->SetBranchAddress("L2_TRUEID", &L2_TRUEID);
sim_chain->SetBranchAddress("Hp_TRUEID", &Hp_TRUEID);
sim_chain->SetBranchAddress("Hm_TRUEID", &Hm_TRUEID);
sim_chain->SetBranchAddress("B0_BKGCAT", &B_BKGCAT);
TH1D *h1_B_Mass_jpsi = new TH1D("h1_B_Mass_jpsi", TString::Format("B Mass, J/#psi Mode (%s)", analysis_name), B_MASS_HIST_BINS, B_MASS_VAR_MIN, B_MASS_VAR_MAX);
TH1D *h1_B_Mass_psi2s = new TH1D("h1_B_Mass_psi2s", TString::Format("B Mass, #psi(2S) Mode (%s)", analysis_name), B_MASS_HIST_BINS, B_MASS_VAR_MIN, B_MASS_VAR_MAX);
TH1D *h1_B_Mass_sim = new TH1D("h1_B_Mass_sim", TString::Format("B Mass, Simualted (%s_noPID)", analysis_name), B_MASS_HIST_BINS, B_MASS_VAR_MIN, B_MASS_VAR_MAX);
TH2D *h2_Hlt1_flags_B_Mass = new TH2D("h2_Hlt1_flags_B_Mass", "Hlt1 Decision vs B Mass", 50, 5100, 5400, 13, 1., 14.);
TH2D *h2_Hlt1_flags_excl_B_Mass = new TH2D("h2_Hlt1_flags_excl_B_Mass", "Excl Hlt1 Decision vs B Mass", 50, 5100, 5400, 13, 1., 14.);
TH1D *h1_bdt_probs = new TH1D("h1_bdt_probs", "BDT Probabilities", 100, -1, 1);
h1_B_Mass_jpsi->GetXaxis()->SetTitle(end_state_mass_literal);
h1_B_Mass_psi2s->GetXaxis()->SetTitle(end_state_mass_literal);
h2_Hlt1_flags_B_Mass->GetXaxis()->SetTitle(end_state_mass_literal);
h2_Hlt1_flags_excl_B_Mass->GetXaxis()->SetTitle(end_state_mass_literal);
ConnectHlt1Decisions(data_chain, h2_Hlt1_flags_B_Mass, h2_Hlt1_flags_excl_B_Mass);
auto hlt1_decision_histos = CreateHlt1DecisionHistos(analysis_name);
std::map<std::string, int> exclusive_hits{};
std::vector<TV *> vars{
TV::Float("B0_PT", "B0_PT"),
TV::Float("B0_BPVFDCHI2", "B0_BPVFDCHI2"),
TV::Float("B0_BPVDIRA", "B0_BPVDIRA"),
TV::Float("Jpsi_BPVIPCHI2", "Jpsi_BPVIPCHI2"),
// TV::Float("Jpsi_BPVDIRA", "Jpsi_BPVDIRA"),
TV::Float("Jpsi_PT", "Jpsi_PT"),
TV::Float("Hp_BPVIPCHI2", "Hp_BPVIPCHI2"),
TV::Float("Hp_PT", "Hp_PT"),
TV::Float("Hm_BPVIPCHI2", "Hm_BPVIPCHI2"),
TV::Float("Hm_PT", "Hm_PT"),
// TV::Double("Kplus_PID_K", "K_PID_K"),
TV::Double("Hp_PROBNN_K", "Hp_PROBNN_K"),
TV::Double("Hm_PROBNN_K", "Hm_PROBNN_K"),
TV::Float("L1_BPVIPCHI2", "L1_BPVIPCHI2"),
TV::Float("L2_BPVIPCHI2", "L2_BPVIPCHI2"),
};
TTree *sig_tree = new TTree("TreeS", "tree containing signal data");
TTree *bkg_tree = new TTree("TreeB", "tree containing background data");
ConnectVarsToData(vars, data_chain, sim_chain, sig_tree, bkg_tree);
unsigned int data_entries = data_chain->GetEntries();
unsigned int sim_entries = 100000; // sim_chain->GetEntries();
unsigned int bkg_events = 0;
if (retrain_bdt)
{
std::cout << "# Starting with BDT retrain." << std::endl;
for (unsigned int i = 0; i < data_entries; i++)
{
data_chain->GetEntry(i);
TLorentzVector reconstructed_Kstar{};
bool found_k_star = false;
if (Hp_PID_K > 0 && Hm_PID_K < 0)
{
reconstructed_Kstar = hp4v_data->LorentzVector(K_MASS) + hm4v_data->LorentzVector();
found_k_star = true;
}
else if (Hm_PID_K > 0 && Hp_PID_K < 0)
{
reconstructed_Kstar = hp4v_data->LorentzVector() + hm4v_data->LorentzVector(K_MASS);
found_k_star = true;
}
if (found_k_star)
{
Double_t reconstructed_B_Mass = (reconstructed_Kstar + l14v_data->LorentzVector() + l24v_data->LorentzVector()).M();
if (std::all_of(vars.begin(), vars.end(), [](TV *v)
{ return v->IsDataFinite(); }))
{
if (reconstructed_B_Mass > 5500.)
{
bkg_tree->Fill();
bkg_events++;
}
}
}
PrintProgress(TString::Format("%s BKG Collection", analysis_name), data_entries, 10000, i);
}
}
else
{
std::cout << "# Starting without BDT retrain." << std::endl;
}
for (unsigned int i = 0; i < sim_entries; i++)
{
sim_chain->GetEntry(i);
if (B_BKGCAT == 30 && TMath::Abs(L1_TRUEID) == PID_MUON && L2_TRUEID == -L1_TRUEID)
{
TLorentzVector reconstructed_Kstar{};
bool found_k_star = false;
if (TMath::Abs(Hp_TRUEID) == PID_KAON && TMath::Abs(Hm_TRUEID) == PID_PION)
{
reconstructed_Kstar = hp4v_sim->LorentzVector(K_MASS) + hm4v_sim->LorentzVector();
found_k_star = true;
}
else if (TMath::Abs(Hp_TRUEID) == PID_PION && TMath::Abs(Hm_TRUEID) == PID_KAON)
{
reconstructed_Kstar = hp4v_sim->LorentzVector() + hm4v_sim->LorentzVector(K_MASS);
found_k_star = true;
}
if (found_k_star)
{
Double_t reconstructed_B_Mass = (reconstructed_Kstar + l14v_sim->LorentzVector() + l24v_sim->LorentzVector()).M();
if (std::all_of(vars.begin(), vars.end(), [](TV *v)
{ return v->IsMCFinite(); }))
{
if (retrain_bdt)
{
sig_tree->Fill();
}
h1_B_Mass_sim->Fill(reconstructed_B_Mass);
}
}
}
PrintProgress(TString::Format("%s SIG Collection", analysis_name), sim_entries, 10000, i);
}
if (retrain_bdt)
{
TrainBDT(vars, analysis_name, sig_tree, bkg_tree);
std::cout << "# Finished BDT retrain." << std::endl;
}
std::cout << "# Starting evaluation of data." << std::endl;
Float_t *train_vars = new Float_t[vars.size()];
auto reader = SetupReader(vars, train_vars, analysis_name);
const double mva_cut_value = -0.12; // 0.09; // -0.02;
for (unsigned int i = 0; i < data_entries; i++)
{
data_chain->GetEntry(i);
TLorentzVector dimuon = l14v_data->LorentzVector() + l24v_data->LorentzVector();
TLorentzVector reconstructed_Kstar{};
bool found_k_star = false;
if (Hp_PID_K > 0 && Hm_PID_K < 0)
{
reconstructed_Kstar = hp4v_data->LorentzVector(K_MASS) + hm4v_data->LorentzVector();
found_k_star = true;
}
else if (Hm_PID_K > 0 && Hp_PID_K < 0)
{
reconstructed_Kstar = hp4v_data->LorentzVector() + hm4v_data->LorentzVector(K_MASS);
found_k_star = true;
}
if (found_k_star)
{
Double_t reconstructed_B_Mass = (reconstructed_Kstar + dimuon).M();
if (std::all_of(vars.begin(), vars.end(), [](TV *v)
{ return v->IsDataFinite(); }))
{
for (size_t j = 0; j < vars.size(); j++)
{
if (vars[j]->IsDouble())
{
train_vars[j] = vars[j]->GetDataDouble();
}
else if (vars[j]->IsFloat())
{
train_vars[j] = vars[j]->GetDataFloat();
}
}
}
if (TMath::Abs(dimuon.M() - JPSI_MASS) < 100.)
{
CheckHlt1Decisioins(h2_Hlt1_flags_B_Mass, h2_Hlt1_flags_excl_B_Mass, exclusive_hits, reconstructed_B_Mass);
FillHlt1DecisionHistos(hlt1_decision_histos, reconstructed_B_Mass);
}
double mva_response = reader->EvaluateMVA("BDT");
h1_bdt_probs->Fill(mva_response);
if (mva_response > mva_cut_value)
{
if (TMath::Abs(reconstructed_Kstar.M() - KSTAR_MASS) < 100.)
{
if (TMath::Abs(dimuon.M() - JPSI_MASS) < 100.)
{
h1_B_Mass_jpsi->Fill(reconstructed_B_Mass);
}
else if (TMath::Abs(dimuon.M() - PSI2S_MASS) < 100.)
{
h1_B_Mass_psi2s->Fill(reconstructed_B_Mass);
}
}
}
}
PrintProgress(TString::Format("%s BDT Evaluation", analysis_name), data_entries, 10000, i);
}
std::cout << "# Exclusive Hits" << std::endl;
for (const auto &[line, hits] : exclusive_hits)
{
std::cout << line << ": " << hits << std::endl;
}
// DrawInDefaultCanvas(h2_Hlt1_flags_B_Mass, analysis_name, 0.16, "COLZ");
// DrawInDefaultCanvas(h2_Hlt1_flags_excl_B_Mass, analysis_name, 0.16, "COLZ");
DrawInDefaultCanvas(h1_B_Mass_jpsi, analysis_name, 0.1);
DrawInDefaultCanvas(h1_B_Mass_psi2s, analysis_name, 0.1);
auto roofit_hist_sim = CreateRooFitHistogramAndFitCB(h1_B_Mass_sim, false, false, ShapeParamters{});
auto roofit_hist_jpsi_fitsum = CreateRooFitHistogramAndFitCB(h1_B_Mass_jpsi, true, true, roofit_hist_sim.shape_parameters);
auto roofit_hist_psi2s_fitsum = CreateRooFitHistogramAndFitCB(h1_B_Mass_psi2s, true, true, roofit_hist_sim.shape_parameters);
DrawInDefaultCanvas(roofit_hist_jpsi_fitsum, analysis_name);
DrawInDefaultCanvas(roofit_hist_psi2s_fitsum, analysis_name);
DrawInDefaultCanvas(roofit_hist_sim, analysis_name);
// DrawHlt1DecisionHistos(analysis_name, hlt1_decision_histos);
DrawBDTProbs(h1_bdt_probs, mva_cut_value, analysis_name);
return 0;
}

160
new_analysis_b02kppimmumu.cpp
View File

@ -0,0 +1,160 @@
#include <string>
#include <iostream>
#include <cmath>
#include <algorithm>
#include <filesystem>
#include <string_view>
#include "TH1D.h"
#include "TH2D.h"
#include "THStack.h"
#include "TGraph.h"
#include "TTree.h"
#include "TChain.h"
#include "TFile.h"
#include "TCanvas.h"
#include "TROOT.h"
#include "TStyle.h"
#include "TColor.h"
#include "TLorentzVector.h"
#include "TRandom3.h"
#include "TLegend.h"
#include "RooDataHist.h"
#include "RooRealVar.h"
#include "RooPlot.h"
#include "RooGaussian.h"
#include "RooExponential.h"
#include "RooRealConstant.h"
#include "RooAddPdf.h"
#include "RooFitResult.h"
#include "RooProduct.h"
#include "RooCrystalBall.h"
#include "RooBreitWigner.h"
#include "RooArgSet.h"
#include "RooFFTConvPdf.h"
#include "RooNovosibirsk.h"
#include "constants.h"
#include "basic_analysis.h"
#include "hlt1_decision_analysis.h"
#include "bdt_classification.h"
// %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% Exclusive B0 To Kp Pim Mu Mu %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
int new_analysis_b02kppimmumu()
{
const char *analysis_name = "B0ToKpPimMuMu";
const char *data_tree_name = "Hlt2RD_B0ToKpPimMuMu";
const char *sim_tree_name = "B0ToKpPimMuMu_noPID";
const char *end_state_mass_literal = "m(K^{+}#pi^{-}#mu^{+}#mu^{-})";
const bool retrain_bdt = true;
TChain *data_chain = new TChain(TString::Format("%s/DecayTree", data_tree_name));
data_chain->Add("/auto/data/pfeiffer/inclusive_detached_dilepton/data_samples/Collision23_Beam6800GeV-VeloClosed-MagDown-Excl-UT_RealData_SprucingPass23r1_94000000_RD.root");
FourVect *l14v_data = FourVect::Init(data_chain, "muplus");
FourVect *l24v_data = FourVect::Init(data_chain, "muminus");
FourVect *hp4v_data = FourVect::Init(data_chain, "Kplus");
FourVect *hm4v_data = FourVect::Init(data_chain, "piminus");
TChain *sim_chain = new TChain(TString::Format("%s/DecayTree", sim_tree_name));
sim_chain->Add("/auto/data/pfeiffer/inclusive_detached_dilepton/MC/rd_btoxll_simulation_turbo_v0r0p6657752_B0ToKpPimMuMu_11144002_magdown.root");
FourVect *l14v_sim = FourVect::Init(sim_chain, "L1");
FourVect *l24v_sim = FourVect::Init(sim_chain, "L2");
FourVect *hp4v_sim = FourVect::Init(sim_chain, "K");
FourVect *hm4v_sim = FourVect::Init(sim_chain, "Pi");
Int_t B_BKGCAT, L1_TRUEID, L2_TRUEID, Hp_TRUEID, Hm_TRUEID;
sim_chain->SetBranchAddress("L1_TRUEID", &L1_TRUEID);
sim_chain->SetBranchAddress("L2_TRUEID", &L2_TRUEID);
sim_chain->SetBranchAddress("K_TRUEID", &Hp_TRUEID);
sim_chain->SetBranchAddress("Pi_TRUEID", &Hm_TRUEID);
sim_chain->SetBranchAddress("B0_BKGCAT", &B_BKGCAT);
TH1D *h1_B_Mass_jpsi = new TH1D("h1_B_Mass_jpsi", TString::Format("B Mass, J/#psi Mode (%s)", analysis_name), B_MASS_HIST_BINS, B_MASS_VAR_MIN, B_MASS_VAR_MAX);
TH1D *h1_B_Mass_psi2s = new TH1D("h1_B_Mass_psi2s", TString::Format("B Mass, #psi(2S) Mode (%s)", analysis_name), B_MASS_HIST_BINS, B_MASS_VAR_MIN, B_MASS_VAR_MAX);
TH1D *h1_B_Mass_sim = new TH1D("h1_B_Mass_sim", TString::Format("B Mass, Simualted (%s_noPID)", analysis_name), B_MASS_HIST_BINS, B_MASS_VAR_MIN, B_MASS_VAR_MAX);
TH2D *h2_Hlt1_flags_B_Mass = new TH2D("h2_Hlt1_flags_B_Mass", "Hlt1 Decision vs B Mass", 50, 5100, 5400, 13, 1., 14.);
TH2D *h2_Hlt1_flags_excl_B_Mass = new TH2D("h2_Hlt1_flags_excl_B_Mass", "Excl Hlt1 Decision vs B Mass", 50, 5100, 5400, 13, 1., 14.);
h1_B_Mass_jpsi->GetXaxis()->SetTitle(end_state_mass_literal);
h1_B_Mass_psi2s->GetXaxis()->SetTitle(end_state_mass_literal);
h2_Hlt1_flags_B_Mass->GetXaxis()->SetTitle(end_state_mass_literal);
h2_Hlt1_flags_excl_B_Mass->GetXaxis()->SetTitle(end_state_mass_literal);
ConnectHlt1Decisions(data_chain, h2_Hlt1_flags_B_Mass, h2_Hlt1_flags_excl_B_Mass);
auto hlt1_decision_histos = CreateHlt1DecisionHistos(analysis_name);
std::map<std::string, int> exclusive_hits{};
unsigned int data_entries = data_chain->GetEntries();
unsigned int sim_entries = sim_chain->GetEntries();
for (unsigned int i = 0; i < sim_entries; i++)
{
sim_chain->GetEntry(i);
Double_t reconstructed_B_Mass = (hp4v_sim->LorentzVector() + hm4v_sim->LorentzVector() + l14v_sim->LorentzVector() + l24v_sim->LorentzVector()).M();
if (B_BKGCAT == 0 && TMath::Abs(L1_TRUEID) == PID_MUON && L2_TRUEID == -L1_TRUEID && TMath::Abs(Hp_TRUEID) == PID_KAON && TMath::Abs(Hm_TRUEID) == PID_PION)
{
h1_B_Mass_sim->Fill(reconstructed_B_Mass);
}
PrintProgress(TString::Format("%s SIG Collection", analysis_name), sim_entries, 10000, i);
}
std::cout << "# Starting evaluation of data." << std::endl;
for (unsigned int i = 0; i < data_entries; i++)
{
data_chain->GetEntry(i);
TLorentzVector dimuon = l14v_data->LorentzVector() + l24v_data->LorentzVector();
TLorentzVector reconstructed_Kstar = hp4v_data->LorentzVector() + hm4v_data->LorentzVector();
Double_t reconstructed_B_Mass = (reconstructed_Kstar + dimuon).M();
if (TMath::Abs(dimuon.M() - JPSI_MASS) < 100.)
{
CheckHlt1Decisioins(h2_Hlt1_flags_B_Mass, h2_Hlt1_flags_excl_B_Mass, exclusive_hits, reconstructed_B_Mass);
FillHlt1DecisionHistos(hlt1_decision_histos, reconstructed_B_Mass);
}
if (TMath::Abs(reconstructed_Kstar.M() - KSTAR_MASS) < 100.)
{
if (TMath::Abs(dimuon.M() - JPSI_MASS) < 100.)
{
h1_B_Mass_jpsi->Fill(reconstructed_B_Mass);
}
else if (TMath::Abs(dimuon.M() - PSI2S_MASS) < 100.)
{
h1_B_Mass_psi2s->Fill(reconstructed_B_Mass);
}
}
PrintProgress(TString::Format("%s Data Evaluation", analysis_name), data_entries, 10000, i);
}
std::cout << "# Exclusive Hits" << std::endl;
for (const auto &[line, hits] : exclusive_hits)
{
std::cout << line << ": " << hits << std::endl;
}
DrawInDefaultCanvas(h2_Hlt1_flags_B_Mass, analysis_name, 0.16, "COLZ");
DrawInDefaultCanvas(h2_Hlt1_flags_excl_B_Mass, analysis_name, 0.16, "COLZ");
DrawInDefaultCanvas(h1_B_Mass_jpsi, analysis_name, 0.1);
DrawInDefaultCanvas(h1_B_Mass_psi2s, analysis_name, 0.1);
auto roofit_hist_sim = CreateRooFitHistogramAndFitCB(h1_B_Mass_sim, false, false, ShapeParamters{});
auto roofit_hist_jpsi_fitsum = CreateRooFitHistogramAndFitCB(h1_B_Mass_jpsi, true, true, roofit_hist_sim.shape_parameters);
auto roofit_hist_psi2s_fitsum = CreateRooFitHistogramAndFitCB(h1_B_Mass_psi2s, true, true, roofit_hist_sim.shape_parameters);
DrawInDefaultCanvas(roofit_hist_jpsi_fitsum, analysis_name);
DrawInDefaultCanvas(roofit_hist_psi2s_fitsum, analysis_name);
DrawInDefaultCanvas(roofit_hist_sim, analysis_name);
DrawHlt1DecisionHistos(analysis_name, hlt1_decision_histos);
return 0;
}

35
new_analysis.cpp → new_analysis_bu2hpmumu.cpp
View File

@ -42,21 +42,23 @@
// %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% Bu To Hp Mu Mu %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
int analyze_bu2hpmumu_data()
int new_analysis_bu2hpmumu()
{
const char *analysis_name = "BuToHpMuMu";
const char *data_tree_name = "BuToHpMuMu";
const char *sim_tree_name = "BuToHpMuMu_noPID";
const char *end_state_mass_literal = "m(#pi^{+}_{(#rightarrow K^{+})}#mu^{+}#mu^{-})";
const bool retrain_bdt = false;
TChain *data_chain = new TChain(TString::Format("%s/DecayTree", analysis_name));
data_chain->Add("/auto/data/pfeiffer/inclusive_detached_dilepton/data_samples/spruce_magdown_2023_v0_tuple_90000000_v0r0p6288631.root");
TChain *data_chain = new TChain(TString::Format("%s/DecayTree", data_tree_name));
// data_chain->Add("/auto/data/pfeiffer/inclusive_detached_dilepton/data_samples/spruce_magdown_2023_v0_tuple_90000000_v0r0p6288631.root");
data_chain->Add("/auto/data/pfeiffer/inclusive_detached_dilepton/data_samples/spruce_magdown_2023_v0r1_tuple_90000000_2023_v0r0p6288631.root");
FourVect *l14v_data = FourVect::Init(data_chain, "L1");
FourVect *l24v_data = FourVect::Init(data_chain, "L2");
FourVect *hp4v_data = FourVect::Init(data_chain, "Hp");
TChain *sim_chain = new TChain(TString::Format("%s_noPID/DecayTree", analysis_name));
TChain *sim_chain = new TChain(TString::Format("%s/DecayTree", sim_tree_name));
sim_chain->Add("/auto/data/pfeiffer/inclusive_detached_dilepton/MC/rd_btoxll_simulation_fullstream_v0r0p6671378_BuToKpMuMu_12143001_magdown.root");
FourVect *l14v_sim = FourVect::Init(sim_chain, "L1");
@ -107,7 +109,7 @@ int analyze_bu2hpmumu_data()
ConnectVarsToData(vars, data_chain, sim_chain, sig_tree, bkg_tree);
unsigned int data_entries = data_chain->GetEntries();
unsigned int sim_entries = sim_chain->GetEntries();
unsigned int sim_entries = data_entries;// sim_chain->GetEntries();
unsigned int bkg_events = 0;
@ -167,7 +169,7 @@ int analyze_bu2hpmumu_data()
Float_t *train_vars = new Float_t[vars.size()];
auto reader = SetupReader(vars, train_vars, "BuToHpMuMu");
const double mva_cut_value = 0; // 0.09; // -0.02;
const double mva_cut_value = -0.03; // 0.09; // -0.02;
for (unsigned int i = 0; i < data_entries; i++)
{
@ -230,20 +232,15 @@ int analyze_bu2hpmumu_data()
auto roofit_hist_sim = CreateRooFitHistogramAndFitCB(h1_B_Mass_sim, false, false, ShapeParamters{});
auto roofit_hist_jpsi_fitsum = CreateRooFitHistogramAndFitCB(h1_B_Mass_jpsi, true, true, roofit_hist_sim.shape_parameters);
auto roofit_hist_psi2s_fitsum = CreateRooFitHistogramAndFitCB(h1_B_Mass_psi2s, true, true, roofit_hist_sim.shape_parameters);
DrawInDefaultCanvas(roofit_hist_jpsi_fitsum.fit_histogram, analysis_name, 0.1);
DrawInDefaultCanvas(roofit_hist_psi2s_fitsum.fit_histogram, analysis_name, 0.1);
DrawInDefaultCanvas(roofit_hist_sim.fit_histogram, analysis_name, 0.1);
DrawInDefaultCanvas(roofit_hist_jpsi_fitsum, analysis_name);
DrawInDefaultCanvas(roofit_hist_psi2s_fitsum, analysis_name);
DrawInDefaultCanvas(roofit_hist_sim, analysis_name);
DrawHlt1DecisionHistos(analysis_name, hlt1_decision_histos);
DrawBDTProbs(h1_bdt_probs, mva_cut_value, analysis_name);
// auto test_bkg_tree_file = TFile::Open("test_bkg_tree.root", "RECREATE");
// bkg_tree->Write();
// sig_tree->Write();
// test_bkg_tree_file->Close();
return 0;
}
@ -621,7 +618,7 @@ int analyze_Hlt2RD_B0ToKpPimMuMu()
return 0;
}
int new_analysis()
{
return analyze_bu2hpmumu_data();
}
// int new_analysis()
// {
// return analyze_bu2hpmumu_data();
// }

153
new_analysis_bu2kpmumu.cpp
View File

@ -0,0 +1,153 @@
#include <string>
#include <iostream>
#include <cmath>
#include <algorithm>
#include <filesystem>
#include <string_view>
#include "TH1D.h"
#include "TH2D.h"
#include "THStack.h"
#include "TGraph.h"
#include "TTree.h"
#include "TChain.h"
#include "TFile.h"
#include "TCanvas.h"
#include "TROOT.h"
#include "TStyle.h"
#include "TColor.h"
#include "TLorentzVector.h"
#include "TRandom3.h"
#include "TLegend.h"
#include "RooDataHist.h"
#include "RooRealVar.h"
#include "RooPlot.h"
#include "RooGaussian.h"
#include "RooExponential.h"
#include "RooRealConstant.h"
#include "RooAddPdf.h"
#include "RooFitResult.h"
#include "RooProduct.h"
#include "RooCrystalBall.h"
#include "RooBreitWigner.h"
#include "RooArgSet.h"
#include "RooFFTConvPdf.h"
#include "RooNovosibirsk.h"
#include "constants.h"
#include "basic_analysis.h"
#include "hlt1_decision_analysis.h"
#include "bdt_classification.h"
// %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% Exclusive Bu To Kp Mu Mu %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
int new_analysis_bu2kpmumu()
{
const char *analysis_name = "BuToKpMuMu";
const char *data_tree_name = "Hlt2RD_BuToKpMuMu";
const char *sim_tree_name = "BuToKpMuMu_noPID";
const char *end_state_mass_literal = "m(K^{+}#mu^{+}#mu^{-})";
const bool retrain_bdt = true;
TChain *data_chain = new TChain(TString::Format("%s/DecayTree", data_tree_name));
data_chain->Add("/auto/data/pfeiffer/inclusive_detached_dilepton/data_samples/Collision23_Beam6800GeV-VeloClosed-MagDown-Excl-UT_RealData_SprucingPass23r1_94000000_RD.root");
FourVect *l14v_data = FourVect::Init(data_chain, "muplus");
FourVect *l24v_data = FourVect::Init(data_chain, "muminus");
FourVect *hp4v_data = FourVect::Init(data_chain, "Kplus");
TChain *sim_chain = new TChain(TString::Format("%s/DecayTree", sim_tree_name));
sim_chain->Add("/auto/data/pfeiffer/inclusive_detached_dilepton/MC/rd_btoxll_simulation_turbo_v0r0p6657752_BuToKpMuMu_12143001_magdown.root");
FourVect *l14v_sim = FourVect::Init(sim_chain, "L1");
FourVect *l24v_sim = FourVect::Init(sim_chain, "L2");
FourVect *hp4v_sim = FourVect::Init(sim_chain, "K");
Int_t B_BKGCAT, L1_TRUEID, L2_TRUEID, Hp_TRUEID;
sim_chain->SetBranchAddress("L1_TRUEID", &L1_TRUEID);
sim_chain->SetBranchAddress("L2_TRUEID", &L2_TRUEID);
sim_chain->SetBranchAddress("K_TRUEID", &Hp_TRUEID);
sim_chain->SetBranchAddress("B_BKGCAT", &B_BKGCAT);
TH1D *h1_B_Mass_jpsi = new TH1D("h1_B_Mass_jpsi", TString::Format("B Mass, J/#psi Mode (%s)", analysis_name), B_MASS_HIST_BINS, B_MASS_VAR_MIN, B_MASS_VAR_MAX);
TH1D *h1_B_Mass_psi2s = new TH1D("h1_B_Mass_psi2s", TString::Format("B Mass, #psi(2S) Mode (%s)", analysis_name), B_MASS_HIST_BINS, B_MASS_VAR_MIN, B_MASS_VAR_MAX);
TH1D *h1_B_Mass_sim = new TH1D("h1_B_Mass_sim", TString::Format("B Mass, Simualted (%s_noPID)", analysis_name), B_MASS_HIST_BINS, B_MASS_VAR_MIN, B_MASS_VAR_MAX);
TH2D *h2_Hlt1_flags_B_Mass = new TH2D("h2_Hlt1_flags_B_Mass", "Hlt1 Decision vs B Mass", 50, 5100, 5400, 13, 1., 14.);
TH2D *h2_Hlt1_flags_excl_B_Mass = new TH2D("h2_Hlt1_flags_excl_B_Mass", "Excl Hlt1 Decision vs B Mass", 50, 5100, 5400, 13, 1., 14.);
h1_B_Mass_jpsi->GetXaxis()->SetTitle(end_state_mass_literal);
h1_B_Mass_psi2s->GetXaxis()->SetTitle(end_state_mass_literal);
h2_Hlt1_flags_B_Mass->GetXaxis()->SetTitle(end_state_mass_literal);
h2_Hlt1_flags_excl_B_Mass->GetXaxis()->SetTitle(end_state_mass_literal);
ConnectHlt1Decisions(data_chain, h2_Hlt1_flags_B_Mass, h2_Hlt1_flags_excl_B_Mass);
auto hlt1_decision_histos = CreateHlt1DecisionHistos(analysis_name);
std::map<std::string, int> exclusive_hits{};
unsigned int data_entries = data_chain->GetEntries();
unsigned int sim_entries = sim_chain->GetEntries();
for (unsigned int i = 0; i < sim_entries; i++)
{
sim_chain->GetEntry(i);
Double_t reconstructed_B_Mass = (hp4v_sim->LorentzVector() + l14v_sim->LorentzVector() + l24v_sim->LorentzVector()).M();
if (B_BKGCAT == 0 && TMath::Abs(L1_TRUEID) == PID_MUON && L2_TRUEID == -L1_TRUEID && TMath::Abs(Hp_TRUEID) == PID_KAON)
{
h1_B_Mass_sim->Fill(reconstructed_B_Mass);
}
PrintProgress(TString::Format("%s SIG Collection", analysis_name), sim_entries, 10000, i);
}
std::cout << "# Starting evaluation of data." << std::endl;
for (unsigned int i = 0; i < data_entries; i++)
{
data_chain->GetEntry(i);
TLorentzVector dimuon = l14v_data->LorentzVector() + l24v_data->LorentzVector();
Double_t reconstructed_B_Mass = (hp4v_data->LorentzVector() + dimuon).M();
if (TMath::Abs(dimuon.M() - JPSI_MASS) < 100.)
{
CheckHlt1Decisioins(h2_Hlt1_flags_B_Mass, h2_Hlt1_flags_excl_B_Mass, exclusive_hits, reconstructed_B_Mass);
FillHlt1DecisionHistos(hlt1_decision_histos, reconstructed_B_Mass);
}
if (TMath::Abs(dimuon.M() - JPSI_MASS) < 100.)
{
h1_B_Mass_jpsi->Fill(reconstructed_B_Mass);
}
else if (TMath::Abs(dimuon.M() - PSI2S_MASS) < 100.)
{
h1_B_Mass_psi2s->Fill(reconstructed_B_Mass);
}
PrintProgress(TString::Format("%s BDT Evaluation", analysis_name), data_entries, 10000, i);
}
std::cout << "# Exclusive Hits" << std::endl;
for (const auto &[line, hits] : exclusive_hits)
{
std::cout << line << ": " << hits << std::endl;
}
DrawInDefaultCanvas(h2_Hlt1_flags_B_Mass, analysis_name, 0.16, "COLZ");
DrawInDefaultCanvas(h2_Hlt1_flags_excl_B_Mass, analysis_name, 0.16, "COLZ");
DrawInDefaultCanvas(h1_B_Mass_jpsi, analysis_name, 0.1);
DrawInDefaultCanvas(h1_B_Mass_psi2s, analysis_name, 0.1);
auto roofit_hist_sim = CreateRooFitHistogramAndFitCB(h1_B_Mass_sim, false, false, ShapeParamters{});
auto roofit_hist_jpsi_fitsum = CreateRooFitHistogramAndFitCB(h1_B_Mass_jpsi, true, true, roofit_hist_sim.shape_parameters);
auto roofit_hist_psi2s_fitsum = CreateRooFitHistogramAndFitCB(h1_B_Mass_psi2s, true, true, roofit_hist_sim.shape_parameters);
DrawInDefaultCanvas(roofit_hist_jpsi_fitsum, analysis_name);
DrawInDefaultCanvas(roofit_hist_psi2s_fitsum, analysis_name);
DrawInDefaultCanvas(roofit_hist_sim, analysis_name);
DrawHlt1DecisionHistos(analysis_name, hlt1_decision_histos);
return 0;
}
Write Preview
Loading…
Cancel
Save