Rivet Analyses Reference

ATLAS_2016_I1426523

Measurement of the $WZ$ production cross section at 8 TeV
Experiment: ATLAS (LHC)
Inspire ID: 1426523
Status: VALIDATED
Authors:
  • Elena Yatsenko
References:Beams: p+ p+
Beam energies: (4000.0, 4000.0) GeV
Run details:
  • pp -> WZ + X, diboson decays to electrons and muons

This paper presents measurements of $W^\pm Z$ production in pp collisions at a center-of-mass energy of 8 TeV. The gauge bosons are reconstructed using their leptonic decay modes into electrons and muons. The data were collected in 2012 by the ATLAS experiment at the Large Hadron Collider and correspond to an integrated luminosity of 20.3 fb${}^{-1}$. The measured inclusive cross section in the detector fiducial region is $\sigma(W^\pm Z\to \ell^\prime\nu\ell\ell) = 35.1\pm 0.9$(stat)$\pm 0.8$(sys)$\pm 0.8$(lumi) fb, for one leptonic decay channel. In comparison, the next-to-leading-order Standard Model expectation is $30.0\pm 2.1$ fb. Cross sections for $W^+ Z$ and $W^- Z$ production and their ratio are presented as well as differential cross sections for several kinematic observables. Limits on anomalous triple gauge boson couplings are derived from the transverse mass spectrum of the $W^\pm Z$ system. From the analysis of events with a $W$ and a $Z$ boson associated with two or more forward jets an upper limit at 95% confidence level on the $W^\pm Z$ scattering cross section of 0.63 fb, for each leptonic decay channel, is established, while the Standard Model prediction at next-to-leading order is $0.13\pm 0.01$ fb. Limits on anomalous quartic gauge boson couplings are also extracted. For distributions that include the infinity symbol ($\infty$) on the horizontal axis, the last bin will include the events from the overflow bin. Users should note that explicit matching of lepton flavour between individual SM neutrinos and charged leptons is used in this analysis routine, to match the MC-based correction to the fiducial region applied in the paper. The data are therefore only valid under the assumption of the Standard Model and cannot be used for BSM reinterpretation.

Source code: ATLAS_2016_I1426523.cc
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// -*- C++ -*-
#include "Rivet/Analysis.hh"
#include "Rivet/Projections/FinalState.hh"
#include "Rivet/Projections/FastJets.hh"
#include "Rivet/Projections/IdentifiedFinalState.hh"
#include "Rivet/Projections/PromptFinalState.hh"
#include "Rivet/Projections/DressedLeptons.hh"
#include "Rivet/Projections/VetoedFinalState.hh"

namespace Rivet {


  /// @brief Measurement of the WZ production cross section at 8 TeV
  class ATLAS_2016_I1426523 : public Analysis {
  public:

    /// Constructor
    RIVET_DEFAULT_ANALYSIS_CTOR(ATLAS_2016_I1426523);


    /// @name Analysis methods
    //@{

    /// Book histograms and initialise projections before the run
    void init() {

      // Lepton cuts
      Cut FS_Zlept = Cuts::abseta < 2.5 && Cuts::pT > 15*GeV;

      const FinalState fs;
      Cut fs_z = Cuts::abseta < 2.5 && Cuts::pT > 15*GeV;
      Cut fs_j = Cuts::abseta < 4.5 && Cuts::pT > 25*GeV;

      // Get photons to dress leptons
      PromptFinalState photons(Cuts::abspid == PID::PHOTON);

      // Electrons and muons in Fiducial PS
      PromptFinalState leptons(fs_z && (Cuts::abspid == PID::ELECTRON || Cuts::abspid == PID::MUON));
      leptons.acceptTauDecays(false);
      DressedLeptons dressedleptons(photons, leptons, 0.1, FS_Zlept, true);
      declare(dressedleptons, "DressedLeptons");

      // Electrons and muons in Total PS
      PromptFinalState leptons_total(Cuts::abspid == PID::ELECTRON || Cuts::abspid == PID::MUON);
      leptons_total.acceptTauDecays(false);
      DressedLeptons dressedleptonsTotal(photons, leptons_total, 0.1, Cuts::open(), true);
      declare(dressedleptonsTotal, "DressedLeptonsTotal");

      // Neutrinos
      IdentifiedFinalState nu_id;
      nu_id.acceptNeutrinos();
      PromptFinalState neutrinos(nu_id);
      neutrinos.acceptTauDecays(false);
      declare(neutrinos, "Neutrinos");
      MSG_WARNING("\033[91;1mLIMITED VALIDITY - check info file for details!\033[m");

      // Jets
      VetoedFinalState veto;
      veto.addVetoOnThisFinalState(dressedleptons);
      FastJets jets(veto, FastJets::ANTIKT, 0.4);
      declare(jets, "Jets");

      // Book histograms
      book(_h["eee"]       , 1, 1, 1);
      book(_h["mee"]       , 1, 1, 2);
      book(_h["emm"]       , 1, 1, 3);
      book(_h["mmm"]       , 1, 1, 4);
      book(_h["fid"]       , 1, 1, 5);
      book(_h["eee_Plus"]  , 2, 1, 1);
      book(_h["mee_Plus"]  , 2, 1, 2);
      book(_h["emm_Plus"]  , 2, 1, 3);
      book(_h["mmm_Plus"]  , 2, 1, 4);
      book(_h["fid_Plus"]  , 2, 1, 5);
      book(_h["eee_Minus"] , 3, 1, 1);
      book(_h["mee_Minus"] , 3, 1, 2);
      book(_h["emm_Minus"] , 3, 1, 3);
      book(_h["mmm_Minus"] , 3, 1, 4);
      book(_h["fid_Minus"] , 3, 1, 5);
      book(_h["total"]     , 5, 1, 1);
      book(_h["Njets"]     , 27, 1, 1);
      book(_h["Njets_norm"], 41, 1, 1);

      bookHandler("ZpT",	             12);
      bookHandler("ZpT_Plus",          13);
      bookHandler("ZpT_Minus",         14);
      bookHandler("WpT",	             15);
      bookHandler("WpT_Plus",          16);
      bookHandler("WpT_Minus",         17);
      bookHandler("mTWZ",              18);
      bookHandler("mTWZ_Plus",         19);
      bookHandler("mTWZ_Minus",        20);
      bookHandler("pTv",               21);
      bookHandler("pTv_Plus",          22);
      bookHandler("pTv_Minus",         23);
      bookHandler("Deltay",	           24);
      bookHandler("Deltay_Plus",       25);
      bookHandler("Deltay_Minus",      26);
      bookHandler("mjj",               28);
      bookHandler("Deltayjj",          29);
      bookHandler("ZpT_norm",          30);
      bookHandler("ZpT_Plus_norm",     31);
      bookHandler("ZpT_Minus_norm",    32);
      bookHandler("WpT_norm",          33);
      bookHandler("mTWZ_norm",         34);
      bookHandler("pTv_norm", 	       35);
      bookHandler("pTv_Plus_norm",	   36);
      bookHandler("pTv_Minus_norm",	   37);
      bookHandler("Deltay_norm",	     38);
      bookHandler("Deltay_Minus_norm", 39);
      bookHandler("Deltay_Plus_norm",  40);
      bookHandler("mjj_norm",          42);
      bookHandler("Deltayjj_norm",     43);
    }

    void bookHandler(const string& tag, size_t ID) {
      book(_s[tag], ID, 1, 1);
      const string code1 = mkAxisCode(ID, 1, 1);
      const string code2 = mkAxisCode(ID, 1, 2);
      book(_h[tag], code2, refData(code1));
    }


    /// Perform the per-event analysis
    void analyze(const Event& event) {

      const vector<DressedLepton>& dressedleptons = apply<DressedLeptons>(event, "DressedLeptons").dressedLeptons();
      const vector<DressedLepton>& dressedleptonsTotal = apply<DressedLeptons>(event, "DressedLeptonsTotal").dressedLeptons();
      const Particles& neutrinos = apply<PromptFinalState>(event, "Neutrinos").particlesByPt();
      Jets jets = apply<JetAlg>(event, "Jets").jetsByPt( (Cuts::abseta < 4.5) && (Cuts::pT > 25*GeV) );

      if ((dressedleptonsTotal.size()<3) || (neutrinos.size()<1)) vetoEvent;

      //---Total PS: assign leptons to W and Z bosons using Resonant shape algorithm
      // NB: This resonant shape algorithm assumes the Standard Model and can therefore
      // NOT be used for reinterpretation in terms of new-physics models.

      int i, j, k;
      double MassZ01 = 0., MassZ02 = 0., MassZ12 = 0.;
      double MassW0 = 0., MassW1 = 0., MassW2 = 0.;
      double WeightZ1, WeightZ2, WeightZ3;
      double WeightW1, WeightW2, WeightW3;
      double M1, M2, M3;
      double WeightTotal1, WeightTotal2, WeightTotal3;

      //try Z pair of leptons 01
      if ( (dressedleptonsTotal[0].pid()==-(dressedleptonsTotal[1].pid())) && (dressedleptonsTotal[2].abspid()==neutrinos[0].abspid()-1)){
        MassZ01 = (dressedleptonsTotal[0].momentum()+dressedleptonsTotal[1].momentum()).mass();
        MassW2 = (dressedleptonsTotal[2].momentum()+neutrinos[0].momentum()).mass();
      }
      //try Z pair of leptons 02
      if ( (dressedleptonsTotal[0].pid()==-(dressedleptonsTotal[2].pid())) && (dressedleptonsTotal[1].abspid()==neutrinos[0].abspid()-1)){
        MassZ02 = (dressedleptonsTotal[0].momentum()+dressedleptonsTotal[2].momentum()).mass();
        MassW1 = (dressedleptonsTotal[1].momentum()+neutrinos[0].momentum()).mass();
      }
      //try Z pair of leptons 12
      if ( (dressedleptonsTotal[1].pid()==-(dressedleptonsTotal[2].pid())) && (dressedleptonsTotal[0].abspid()==neutrinos[0].abspid()-1)){
        MassZ12 = (dressedleptonsTotal[1].momentum()+dressedleptonsTotal[2].momentum()).mass();
        MassW0 = (dressedleptonsTotal[0].momentum()+neutrinos[0].momentum()).mass();
      }
      WeightZ1 = 1/(pow(MassZ01*MassZ01 - MZ_PDG*MZ_PDG,2) + pow(MZ_PDG*GammaZ_PDG,2));
      WeightW1 = 1/(pow(MassW2*MassW2 - MW_PDG*MW_PDG,2) + pow(MW_PDG*GammaW_PDG,2));
      WeightTotal1 = WeightZ1*WeightW1;
      M1 = -1*WeightTotal1;

      WeightZ2 = 1/(pow(MassZ02*MassZ02- MZ_PDG*MZ_PDG,2) + pow(MZ_PDG*GammaZ_PDG,2));
      WeightW2 = 1/(pow(MassW1*MassW1- MW_PDG*MW_PDG,2) + pow(MW_PDG*GammaW_PDG,2));
      WeightTotal2 = WeightZ2*WeightW2;
      M2 = -1*WeightTotal2;

      WeightZ3 = 1/(pow(MassZ12*MassZ12 - MZ_PDG*MZ_PDG,2) + pow(MZ_PDG*GammaZ_PDG,2));
      WeightW3 = 1/(pow(MassW0*MassW0 - MW_PDG*MW_PDG,2) + pow(MW_PDG*GammaW_PDG,2));
      WeightTotal3 = WeightZ3*WeightW3;
      M3 = -1*WeightTotal3;
      bool found = false;

      if( (M1 < M2 && M1 < M3) || (MassZ01 != 0 && MassW2 != 0 && MassZ02 == 0 && MassZ12 == 0) ){
        i = 0; j = 1; k = 2;
        found = true;
      }
      if( (M2 < M1 && M2 < M3) || (MassZ02 != 0 && MassW1 != 0 && MassZ01 == 0 && MassZ12 == 0) ){
        i = 0; j = 2; k = 1;
        found = true;
      }
      if( (M3 < M1 && M3 < M2) || (MassZ12 != 0 && MassW0 != 0 && MassZ01 == 0 && MassZ02 == 0) ){
        i = 1; j = 2; k = 0;
        found = true;
      }
      if (!found) vetoEvent;

      FourMomentum ZbosonTotal   = dressedleptonsTotal[i].momentum()+dressedleptonsTotal[j].momentum();

      if ( (ZbosonTotal.mass() >= 66*GeV) && (ZbosonTotal.mass() <= 116*GeV) ) _h["total"]->fill(8000);

      //---end Total PS


      //---Fiducial PS: assign leptons to W and Z bosons using Resonant shape algorithm
      if (dressedleptons.size() < 3 || neutrinos.size() < 1)  vetoEvent;

      int EventType = -1;
      int Nel = 0, Nmu = 0;

      for (const DressedLepton& l : dressedleptons) {
        if (l.abspid() == 11)  ++Nel;
        if (l.abspid() == 13)  ++Nmu;
      }

      if ( Nel == 3  && Nmu==0 )  EventType = 3;
      if ( Nel == 2  && Nmu==1 )  EventType = 2;
      if ( Nel == 1  && Nmu==2 )  EventType = 1;
      if ( Nel == 0  && Nmu==3 )  EventType = 0;

      int EventCharge = -dressedleptons[0].charge()*dressedleptons[1].charge()*dressedleptons[2].charge();

      MassZ01 = 0; MassZ02 = 0; MassZ12 = 0;
      MassW0 = 0;  MassW1 = 0;  MassW2 = 0;

      //try Z pair of leptons 01
      if ( (dressedleptons[0].pid()==-(dressedleptons[1].pid())) && (dressedleptons[2].abspid()==neutrinos[0].abspid()-1)){
        MassZ01 = (dressedleptons[0].momentum()+dressedleptons[1].momentum()).mass();
        MassW2 = (dressedleptons[2].momentum()+neutrinos[0].momentum()).mass();
      }
      //try Z pair of leptons 02
      if ( (dressedleptons[0].pid()==-(dressedleptons[2].pid())) && (dressedleptons[1].abspid()==neutrinos[0].abspid()-1)){
        MassZ02 = (dressedleptons[0].momentum()+dressedleptons[2].momentum()).mass();
        MassW1 = (dressedleptons[1].momentum()+neutrinos[0].momentum()).mass();
      }
      //try Z pair of leptons 12
      if ( (dressedleptons[1].pid()==-(dressedleptons[2].pid())) && (dressedleptons[0].abspid()==neutrinos[0].abspid()-1)){
        MassZ12 = (dressedleptons[1].momentum()+dressedleptons[2].momentum()).mass();
        MassW0 = (dressedleptons[0].momentum()+neutrinos[0].momentum()).mass();
      }
      WeightZ1 = 1/(pow(MassZ01*MassZ01 - MZ_PDG*MZ_PDG,2) + pow(MZ_PDG*GammaZ_PDG,2));
      WeightW1 = 1/(pow(MassW2*MassW2 - MW_PDG*MW_PDG,2) + pow(MW_PDG*GammaW_PDG,2));
      WeightTotal1 = WeightZ1*WeightW1;
      M1 = -1*WeightTotal1;

      WeightZ2 = 1/(pow(MassZ02*MassZ02- MZ_PDG*MZ_PDG,2) + pow(MZ_PDG*GammaZ_PDG,2));
      WeightW2 = 1/(pow(MassW1*MassW1- MW_PDG*MW_PDG,2) + pow(MW_PDG*GammaW_PDG,2));
      WeightTotal2 = WeightZ2*WeightW2;
      M2 = -1*WeightTotal2;

      WeightZ3 = 1/(pow(MassZ12*MassZ12 - MZ_PDG*MZ_PDG,2) + pow(MZ_PDG*GammaZ_PDG,2));
      WeightW3 = 1/(pow(MassW0*MassW0 - MW_PDG*MW_PDG,2) + pow(MW_PDG*GammaW_PDG,2));
      WeightTotal3 = WeightZ3*WeightW3;
      M3 = -1*WeightTotal3;
      found = false;
      if( (M1 < M2 && M1 < M3) || (MassZ01 != 0 && MassW2 != 0 && MassZ02 == 0 && MassZ12 == 0) ){
        i = 0; j = 1; k = 2;
	found=true;
      }
      if( (M2 < M1 && M2 < M3) || (MassZ02 != 0 && MassW1 != 0 && MassZ01 == 0 && MassZ12 == 0) ){
        i = 0; j = 2; k = 1;
	found=true;
      }
      if( (M3 < M1 && M3 < M2) || (MassZ12 != 0 && MassW0 != 0 && MassZ01 == 0 && MassZ02 == 0) ){
        i = 1; j = 2; k = 0;
	found=true;
      }
      if(!found) vetoEvent;

      FourMomentum Zlepton1 = dressedleptons[i].momentum();
      FourMomentum Zlepton2 = dressedleptons[j].momentum();
      FourMomentum Wlepton  = dressedleptons[k].momentum();
      FourMomentum Zboson   = dressedleptons[i].momentum()+dressedleptons[j].momentum();
      FourMomentum Wboson   = dressedleptons[k].momentum()+neutrinos[0].momentum();

      double Wboson_mT = sqrt( 2 * Wlepton.pT() * neutrinos[0].pt() * (1 - cos(deltaPhi(Wlepton, neutrinos[0]))) )/GeV;

      if (fabs(Zboson.mass()-MZ_PDG)>=10.)  vetoEvent;
      if (Wboson_mT<=30.)                   vetoEvent;
      if (Wlepton.pT()<=20.)                vetoEvent;
      if (deltaR(Zlepton1,Zlepton2) < 0.2)  vetoEvent;
      if (deltaR(Zlepton1,Wlepton)  < 0.3)  vetoEvent;
      if (deltaR(Zlepton2,Wlepton)  < 0.3)  vetoEvent;

      double WZ_pt = Zlepton1.pt() + Zlepton2.pt() + Wlepton.pt() + neutrinos[0].pt();
      double WZ_px = Zlepton1.px() + Zlepton2.px() + Wlepton.px() + neutrinos[0].px();
      double WZ_py = Zlepton1.py() + Zlepton2.py() + Wlepton.py() + neutrinos[0].py();
      double mTWZ = sqrt( pow(WZ_pt, 2) - ( pow(WZ_px, 2) + pow(WZ_py,2) ) )/GeV;

      double AbsDeltay = fabs(Zboson.rapidity()-Wlepton.rapidity());

      if (EventType == 3) _h["eee"]->fill(8000.);
      if (EventType == 2) _h["mee"]->fill(8000.);
      if (EventType == 1) _h["emm"]->fill(8000.);
      if (EventType == 0) _h["mmm"]->fill(8000.);
      _h["fid"]->fill(8000.);

      if (EventCharge == 1) {

        if (EventType == 3) _h["eee_Plus"]->fill(8000.);
        if (EventType == 2) _h["mee_Plus"]->fill(8000.);
        if (EventType == 1) _h["emm_Plus"]->fill(8000.);
        if (EventType == 0) _h["mmm_Plus"]->fill(8000.);
        _h["fid_Plus"]->fill(8000.);

        _h["Deltay_Plus"]->fill(AbsDeltay);
        _h["Deltay_Plus_norm"]->fill(AbsDeltay);
        fillWithOverflow("ZpT_Plus", Zboson.pT()/GeV, 220);
        fillWithOverflow("WpT_Plus", Wboson.pT()/GeV, 220);
        fillWithOverflow("mTWZ_Plus", mTWZ, 600);
        fillWithOverflow("pTv_Plus", neutrinos[0].pt(), 90);
        fillWithOverflow("ZpT_Plus_norm", Zboson.pT()/GeV, 220);
        fillWithOverflow("pTv_Plus_norm", neutrinos[0].pt()/GeV, 90);

      } else {

        if (EventType == 3) _h["eee_Minus"]->fill(8000.);
        if (EventType == 2) _h["mee_Minus"]->fill(8000.);
        if (EventType == 1) _h["emm_Minus"]->fill(8000.);
        if (EventType == 0) _h["mmm_Minus"]->fill(8000.);
        _h["fid_Minus"]->fill(8000.);

        _h["Deltay_Minus"]->fill(AbsDeltay);
        _h["Deltay_Minus_norm"]->fill(AbsDeltay);
        fillWithOverflow("ZpT_Minus", Zboson.pT()/GeV, 220);
        fillWithOverflow("WpT_Minus", Wboson.pT()/GeV, 220);
        fillWithOverflow("mTWZ_Minus", mTWZ, 600);
        fillWithOverflow("pTv_Minus", neutrinos[0].pt()/GeV, 90);
        fillWithOverflow("ZpT_Minus_norm", Zboson.pT()/GeV, 220);
        fillWithOverflow("pTv_Minus_norm", neutrinos[0].pt()/GeV, 90);

      }

      fillWithOverflow("ZpT", Zboson.pT()/GeV, 220);
      fillWithOverflow("WpT", Wboson.pT()/GeV, 220);
      fillWithOverflow("mTWZ", mTWZ, 600);
      fillWithOverflow("pTv", neutrinos[0].pt()/GeV, 90);

      _h["Deltay"]->fill(AbsDeltay);

      fillWithOverflow("Njets", jets.size(), 5);
      fillWithOverflow("Njets_norm", jets.size(), 5);
      fillWithOverflow("ZpT_norm", Zboson.pT()/GeV, 220);
      fillWithOverflow("WpT_norm", Wboson.pT()/GeV, 220);
      fillWithOverflow("mTWZ_norm", mTWZ, 600);
      fillWithOverflow("pTv_norm", neutrinos[0].pt()/GeV, 90);

      _h["Deltay_norm"]->fill(AbsDeltay);

      if (jets.size()>1) {
        double mjj = (jets[0].momentum()+jets[1].momentum()).mass()/GeV;
        fillWithOverflow("mjj",      mjj, 800);
        fillWithOverflow("mjj_norm", mjj, 800);
        double DeltaYjj = fabs(jets[0].rapidity()-jets[1].rapidity());
        fillWithOverflow("Deltayjj",      DeltaYjj, 5);
        fillWithOverflow("Deltayjj_norm", DeltaYjj, 5);
      }

    }


    void fillWithOverflow(const string& tag, const double value, const double overflow){
      if (value < overflow) _h[tag]->fill(value);
      else _h[tag]->fill(overflow - 0.45);
    }


    /// Normalise histograms etc., after the run
    void finalize() {

      const double xs_pb(crossSection() / picobarn);
      const double xs_fb(crossSection() / femtobarn);
      const double sumw(sumOfWeights());
      MSG_DEBUG("Cross-Section/pb: " << xs_pb      );
      MSG_DEBUG("Cross-Section/fb: " << xs_fb      );
      MSG_DEBUG("Sum of weights  : " << sumw       );
      MSG_DEBUG("nEvents         : " << numEvents());

      const double sf_pb(xs_pb / sumw);
      const double sf_fb(xs_fb / sumw);

      MSG_DEBUG("sf_pb         : " << sf_pb);
      MSG_DEBUG("sf_fb         : " << sf_fb);

      float totalBR= 4*0.1086*0.033658; // W and Z leptonic branching fractions

      for (map<string, Histo1DPtr>::iterator it = _h.begin(); it != _h.end(); ++it) {
        if (it->first.find("total") != string::npos)        scale(it->second, sf_pb/totalBR);
        else if (it->first.find("norm") != string::npos)    normalize(it->second);
        else if (it->first.find("fid") != string::npos)     scale(it->second, sf_fb/4.);
        else if (it->first.find("Njets") != string::npos)   scale(it->second, sf_fb/4.);
        else if (it->first.find("ZpT") != string::npos)     scale(it->second, sf_fb/4.);
        else if (it->first.find("WpT") != string::npos)     scale(it->second, sf_fb/4.);
        else if (it->first.find("mTWZ") != string::npos)    scale(it->second, sf_fb/4.);
        else if (it->first.find("pTv") != string::npos)     scale(it->second, sf_fb/4.);
        else if (it->first.find("Deltay") != string::npos)  scale(it->second, sf_fb/4.);
        else if (it->first.find("mjj") != string::npos)     scale(it->second, sf_fb/4.);
        else                                                scale(it->second, sf_fb);
      }
      for (map<string, Scatter2DPtr>::iterator it = _s.begin(); it != _s.end(); ++it) {
        // @todo replace with new YODA object?
        makeScatterWithoutDividingByBinwidth(it->first);
        // @todo need this to disappear if we want reentrant safety
        removeAnalysisObject(_h[it->first]);
      }
    }

    void makeScatterWithoutDividingByBinwidth(const string& tag) {
      vector<Point2D> points;
      //size_t nBins = _dummy->numBins();
      for (const HistoBin1D &bin : _h[tag]->bins()) {
        double  x = bin.midpoint();
        double  y = bin.sumW();
        double ex = bin.xWidth()/2;
        double ey = sqrt(bin.sumW2());
        points.push_back(Point2D(x, y, ex, ey));
      }
      _s[tag]->addPoints(points);
    }


    //@}


  private:

    /// @name Histograms
    //@{

     map<string, Histo1DPtr> _h;
     map<string, Scatter2DPtr> _s;

     //@}

     double MZ_PDG = 91.1876;
     double MW_PDG = 83.385;
     double GammaZ_PDG = 2.4952;
     double GammaW_PDG = 2.085;

  };

  // The hook for the plugin system
  RIVET_DECLARE_PLUGIN(ATLAS_2016_I1426523);

}