diff --git a/analyses/pluginATLAS/ATLAS_2015_CONF_2015_041.cc b/analyses/pluginATLAS/ATLAS_2015_CONF_2015_041.cc
--- a/analyses/pluginATLAS/ATLAS_2015_CONF_2015_041.cc
+++ b/analyses/pluginATLAS/ATLAS_2015_CONF_2015_041.cc
@@ -1,150 +1,150 @@
// -*- C++ -*-
#include "Rivet/Analysis.hh"
#include "Rivet/Projections/ZFinder.hh"
#include "Rivet/Projections/FastJets.hh"
#include "Rivet/Projections/VetoedFinalState.hh"
namespace Rivet {
/// Z + jets in pp at 13 TeV
/// @note This base class contains a "mode" variable for combined, e, and mu channel derived classes
class ATLAS_2015_CONF_2015_041 : public Analysis {
public:
/// @name Constructors etc.
//@{
/// Constructor
ATLAS_2015_CONF_2015_041(const string name="ATLAS_2015_CONF_2015_041", size_t channel = 0,
const string ref_data="ATLAS_2015_CONF_2015_041")
: Analysis(name), _weights(5, 0.0) {
- _mode = 0; // This class uses the combined e+mu mode
+ _mode = channel; // This class uses the combined e+mu mode
setRefDataName(ref_data);
}
//@}
/// Book histograms and initialise projections before the run
void init() {
const FinalState fs;
Cut cuts = (Cuts::pT > 25*GeV) & (Cuts::abseta < 2.5);
ZFinder zfinder(fs, cuts, _mode? PID::MUON : PID::ELECTRON, 66*GeV, 116*GeV);
declare(zfinder, "zfinder");
// Define veto FS in order to prevent Z-decay products entering the jet algorithm
VetoedFinalState had_fs;
had_fs.addVetoOnThisFinalState(zfinder);
FastJets jets(had_fs, FastJets::ANTIKT, 0.4);
jets.useInvisibles(true);
declare(jets, "jets");
// individual channels
_hNjets = bookHisto1D(1, 1, _mode + 1);
_hNjetsRatio = bookScatter2D(2, 1, _mode + 1, true);
// combination
_hNjets_comb = bookHisto1D(1, 2, _mode + 1);
_hNjetsRatio_comb = bookScatter2D(2, 2, _mode + 1, true);
}
/// Perform the per-event analysis
void analyze(const Event& event) {
const double weight = event.weight();
const ZFinder& zfinder = apply<ZFinder>(event, "zfinder");
const Particles& leptons = zfinder.constituents();
if (leptons.size() != 2) vetoEvent;
Jets jets;
foreach (Jet j, apply<JetAlg>(event, "jets").jetsByPt(Cuts::pT > 30*GeV && Cuts::absrap < 2.5)) {
bool keep = true;
foreach(const Particle& l, leptons) keep &= deltaR(j, l) > 0.4;
if (keep) jets += j;
}
size_t njets = jets.size();
for(size_t i = 0; i <= njets; ++i) {
_hNjets->fill(i + 0.5, weight);
_hNjets_comb->fill(i + 0.5, weight);
}
for (size_t i = 0; i < 5; ++i) {
if (njets >= i) _weights[i] += weight;
}
}
/// @name Ratio calculator util functions
//@{
/// Calculate the ratio, being careful about div-by-zero
double ratio(double a, double b) {
return (b != 0) ? a/b : 0;
}
/// Calculate the ratio error, being careful about div-by-zero
double ratio_err(double a, double b) {
return (b != 0) ? sqrt(a/b*(1-a/b)/b) : 0;
}
//@}
void finalize() {
for (size_t i = 0; i < 4; ++i) {
double n = _hNjets->bin(i + 1).sumW();
double dN = _hNjets->bin(i + 1).sumW2();
double d = _hNjets->bin(i).sumW();
double dD = _hNjets->bin(i).sumW2();
double r = safediv(n, d);
double e = sqrt( safediv(r * (1 - r), d) );
if ( _hNjets->effNumEntries() != _hNjets->numEntries() ) {
// use F. James's approximation for weighted events:
e = sqrt( safediv((1 - 2 * r) * dN + r * r * dD, d * d) );
}
_hNjetsRatio->point(i).setY(r, e);
_hNjetsRatio_comb->point(i).setY(r, e);
}
scale(_hNjets, crossSectionPerEvent() );
scale(_hNjets_comb, crossSectionPerEvent() );
}
//@}
protected:
size_t _mode;
private:
vector<double> _weights;
Scatter2DPtr _hNjetsRatio, _hNjetsRatio_comb;
Histo1DPtr _hNjets, _hNjets_comb;
};
class ATLAS_2015_CONF_2015_041_EL : public ATLAS_2015_CONF_2015_041 {
public:
ATLAS_2015_CONF_2015_041_EL() : ATLAS_2015_CONF_2015_041("ATLAS_2015_CONF_2015_041_EL", 0) { }
};
class ATLAS_2015_CONF_2015_041_MU : public ATLAS_2015_CONF_2015_041 {
public:
ATLAS_2015_CONF_2015_041_MU() : ATLAS_2015_CONF_2015_041("ATLAS_2015_CONF_2015_041_MU", 1) { }
};
DECLARE_RIVET_PLUGIN(ATLAS_2015_CONF_2015_041);
DECLARE_RIVET_PLUGIN(ATLAS_2015_CONF_2015_041_EL);
DECLARE_RIVET_PLUGIN(ATLAS_2015_CONF_2015_041_MU);
}