diff --git a/include/HEJ/WWjets.hh b/include/HEJ/WWjets.hh new file mode 100644 index 0000000..a0d0621 --- /dev/null +++ b/include/HEJ/WWjets.hh @@ -0,0 +1,31 @@ +/** + * \authors The HEJ collaboration (see AUTHORS for details) + * \date 2019-2020 + * \copyright GPLv2 or later + */ +/** \file + * \brief Functions computing the square of current contractions in WW+Jets. + * + * This file contains the WW+jet specific code to compute current contractions. + */ + +#pragma once + +#include + +#include "CLHEP/Vector/LorentzVector.h" + +namespace HEJ { + struct ParticleProperties; + +namespace currents { + using HLV = CLHEP::HepLorentzVector; + + double ME_WW_qQ( + HLV const & p1out, HLV pl1bar, HLV pl1, HLV const & p1in, + HLV const & p2out, HLV pl2bar, HLV pl2, HLV const & p2in, + ParticleProperties const & wprop + ); + +} // namespace currents +} // namespace HEJ diff --git a/src/MatrixElement.cc b/src/MatrixElement.cc index bc06279..127d03c 100644 --- a/src/MatrixElement.cc +++ b/src/MatrixElement.cc @@ -1,2187 +1,2285 @@ /** * \authors The HEJ collaboration (see AUTHORS for details) * \date 2019-2020 * \copyright GPLv2 or later */ #include "HEJ/MatrixElement.hh" #include #include #include #include #include #include #include #include #include #include "CLHEP/Vector/LorentzVector.h" #include "fastjet/PseudoJet.hh" #include "HEJ/ConfigFlags.hh" #include "HEJ/Constants.hh" #include "HEJ/EWConstants.hh" #include "HEJ/Event.hh" #include "HEJ/HiggsCouplingSettings.hh" #include "HEJ/Hjets.hh" #include "HEJ/PDG_codes.hh" #include "HEJ/Particle.hh" #include "HEJ/Wjets.hh" +#include "HEJ/WWjets.hh" #include "HEJ/Zjets.hh" #include "HEJ/event_types.hh" #include "HEJ/exceptions.hh" #include "HEJ/jets.hh" #include "HEJ/utility.hh" namespace HEJ { double MatrixElement::omega0( double alpha_s, double mur, fastjet::PseudoJet const & q_j ) const { const double lambda = param_.regulator_lambda; const double result = - alpha_s*N_C/M_PI*std::log(q_j.perp2()/(lambda*lambda)); if(! param_.log_correction) return result; return ( 1. + alpha_s/(4.*M_PI)*BETA0*std::log(mur*mur/(q_j.perp()*lambda)) )*result; } Weights MatrixElement::operator()(Event const & event) const { std::vector tree_kin_part=tree_kin(event); std::vector virtual_part=virtual_corrections(event); if(tree_kin_part.size() != virtual_part.size()) { throw std::logic_error("tree and virtuals have different sizes"); } Weights sum = Weights{0., std::vector(event.variations().size(), 0.)}; for(size_t i=0; i tree_kin_part=tree_kin(event); double sum = 0.; for(double i : tree_kin_part) { sum += i; } return tree_param(event)*sum; } Weights MatrixElement::tree_param(Event const & event) const { if(! is_resummable(event.type())) { return Weights{0., std::vector(event.variations().size(), 0.)}; } Weights result; // only compute once for each renormalisation scale std::unordered_map known; result.central = tree_param(event, event.central().mur); known.emplace(event.central().mur, result.central); for(auto const & var: event.variations()) { const auto ME_it = known.find(var.mur); if(ME_it == end(known)) { const double wt = tree_param(event, var.mur); result.variations.emplace_back(wt); known.emplace(var.mur, wt); } else { result.variations.emplace_back(ME_it->second); } } return result; } std::vector MatrixElement::virtual_corrections(Event const & event) const { if(! is_resummable(event.type())) { return {Weights{0., std::vector(event.variations().size(), 0.)}}; } // only compute once for each renormalisation scale std::unordered_map > known_vec; std::vector central_vec=virtual_corrections(event, event.central().mur); known_vec.emplace(event.central().mur, central_vec); for(auto const & var: event.variations()) { const auto ME_it = known_vec.find(var.mur); if(ME_it == end(known_vec)) { known_vec.emplace(var.mur, virtual_corrections(event, var.mur)); } } // At this stage known_vec contains one vector of virtual corrections for each mur value // Now put this into a vector of Weights std::vector result_vec; for(size_t i=0; isecond.at(i)); } result_vec.emplace_back(result); } return result_vec; } double MatrixElement::virtual_corrections_W( Event const & event, const double mur, Particle const & WBoson ) const{ auto const & in = event.incoming(); const auto partons = filter_partons(event.outgoing()); fastjet::PseudoJet const & pa = in.front().p; #ifndef NDEBUG fastjet::PseudoJet const & pb = in.back().p; double const norm = (in.front().p + in.back().p).E(); #endif assert(std::is_sorted(partons.begin(), partons.end(), rapidity_less{})); assert(partons.size() >= 2); assert(pa.pz() < pb.pz()); fastjet::PseudoJet q = pa - partons[0].p; std::size_t first_idx = 0; std::size_t last_idx = partons.size() - 1; #ifndef NDEBUG bool wc = true; #endif bool wqq = false; // With extremal qqx or unordered gluon outside the extremal // partons then it is not part of the FKL ladder and does not // contribute to the virtual corrections. W emitted from the // most backward leg must be taken into account in t-channel if (event.type() == event_type::unob) { q -= partons[1].p; ++first_idx; if (in[0].type != partons[1].type ){ q -= WBoson.p; #ifndef NDEBUG wc=false; #endif } } else if (event.type() == event_type::qqxexb) { q -= partons[1].p; ++first_idx; if (std::abs(partons[0].type) != std::abs(partons[1].type)){ q -= WBoson.p; #ifndef NDEBUG wc=false; #endif } } else { if(event.type() == event_type::unof || event.type() == event_type::qqxexf){ --last_idx; } if (in[0].type != partons[0].type ){ q -= WBoson.p; #ifndef NDEBUG wc=false; #endif } } std::size_t first_idx_qqx = last_idx; std::size_t last_idx_qqx = last_idx; //if qqxMid event, virtual correction do not occur between //qqx pair. if(event.type() == event_type::qqxmid){ const auto backquark = std::find_if( begin(partons) + 1, end(partons) - 1 , [](Particle const & s){ return (s.type != pid::gluon); } ); if(backquark == end(partons) || (backquark+1)->type==pid::gluon) return 0; if(std::abs(backquark->type) != std::abs((backquark+1)->type)) { wqq=true; #ifndef NDEBUG wc=false; #endif } last_idx = std::distance(begin(partons), backquark); first_idx_qqx = last_idx+1; } double exponent = 0; const double alpha_s = alpha_s_(mur); for(std::size_t j = first_idx; j < last_idx; ++j){ exponent += omega0(alpha_s, mur, q)*( partons[j+1].rapidity() - partons[j].rapidity() ); q -=partons[j+1].p; } // End Loop one if (last_idx != first_idx_qqx) q -= partons[last_idx+1].p; if (wqq) q -= WBoson.p; for(std::size_t j = first_idx_qqx; j < last_idx_qqx; ++j){ exponent += omega0(alpha_s, mur, q)*( partons[j+1].rapidity() - partons[j].rapidity() ); q -= partons[j+1].p; } #ifndef NDEBUG if (wc) q -= WBoson.p; assert( nearby(q, -1*pb, norm) || is_AWZH_boson(partons.back().type) || event.type() == event_type::unof || event.type() == event_type::qqxexf ); #endif return std::exp(exponent); } std::vector MatrixElement::virtual_corrections_Z_qq( Event const & event, const double mur, Particle const & ZBoson ) const{ auto const & in = event.incoming(); const auto partons = filter_partons(event.outgoing()); fastjet::PseudoJet const & pa = in.front().p; #ifndef NDEBUG fastjet::PseudoJet const & pb = in.back().p; #endif assert(std::is_sorted(partons.begin(), partons.end(), rapidity_less{})); assert(partons.size() >= 2); assert(pa.pz() < pb.pz()); fastjet::PseudoJet q_t = pa - partons[0].p - ZBoson.p; fastjet::PseudoJet q_b = pa - partons[0].p; size_t first_idx = 0; size_t last_idx = partons.size() - 1; // Unordered gluon does not contribute to the virtual corrections if (event.type() == event_type::unob) { // Gluon is partons[0] and is already subtracted // partons[1] is the backward quark q_t -= partons[1].p; q_b -= partons[1].p; ++first_idx; } else if (event.type() == event_type::unof) { // End sum at forward quark --last_idx; } double sum_top=0.; double sum_bot=0.; double sum_mix=0.; const double alpha_s = alpha_s_(mur); for(size_t j = first_idx; j < last_idx; ++j){ const double dy = partons[j+1].rapidity() - partons[j].rapidity(); const double tmp_top = omega0(alpha_s, mur, q_t)*dy; const double tmp_bot = omega0(alpha_s, mur, q_b)*dy; sum_top += tmp_top; sum_bot += tmp_bot; sum_mix += (tmp_top + tmp_bot) / 2.; q_t -= partons[j+1].p; q_b -= partons[j+1].p; } return {exp(sum_top), exp(sum_bot), exp(sum_mix)}; } double MatrixElement::virtual_corrections_Z_qg( Event const & event, const double mur, Particle const & ZBoson, const bool is_gq_event ) const{ auto const & in = event.incoming(); const auto partons = filter_partons(event.outgoing()); fastjet::PseudoJet const & pa = in.front().p; #ifndef NDEBUG fastjet::PseudoJet const & pb = in.back().p; #endif assert(std::is_sorted(partons.begin(), partons.end(), rapidity_less{})); assert(partons.size() >= 2); assert(pa.pz() < pb.pz()); // If this is a gq event, don't subtract the Z momentum from first q fastjet::PseudoJet q = (is_gq_event ? pa - partons[0].p : pa - partons[0].p - ZBoson.p); size_t first_idx = 0; size_t last_idx = partons.size() - 1; // Unordered gluon does not contribute to the virtual corrections if (event.type() == event_type::unob) { // Gluon is partons[0] and is already subtracted // partons[1] is the backward quark q -= partons[1].p; ++first_idx; } else if (event.type() == event_type::unof) { // End sum at forward quark --last_idx; } double sum=0.; const double alpha_s = alpha_s_(mur); for(size_t j = first_idx; j < last_idx; ++j){ sum += omega0(alpha_s, mur, q)*(partons[j+1].rapidity() - partons[j].rapidity()); q -= partons[j+1].p; } return exp(sum); } std::vector MatrixElement::virtual_corrections( Event const & event, const double mur ) const{ auto const & in = event.incoming(); auto const & out = event.outgoing(); fastjet::PseudoJet const & pa = in.front().p; #ifndef NDEBUG fastjet::PseudoJet const & pb = in.back().p; double const norm = (in.front().p + in.back().p).E(); #endif const auto AWZH_boson = std::find_if( begin(out), end(out), [](Particle const & p){ return is_AWZH_boson(p); } ); if(AWZH_boson != end(out) && std::abs(AWZH_boson->type) == pid::Wp){ return {virtual_corrections_W(event, mur, *AWZH_boson)}; } if(AWZH_boson != end(out) && AWZH_boson->type == pid::Z_photon_mix){ if(is_gluon(in.back().type)){ // This is a qg event return {virtual_corrections_Z_qg(event, mur, *AWZH_boson, false)}; } if(is_gluon(in.front().type)){ // This is a gq event return {virtual_corrections_Z_qg(event, mur, *AWZH_boson, true)}; } // This is a qq event return virtual_corrections_Z_qq(event, mur, *AWZH_boson); } assert(std::is_sorted(out.begin(), out.end(), rapidity_less{})); assert(out.size() >= 2); assert(pa.pz() < pb.pz()); fastjet::PseudoJet q = pa - out[0].p; std::size_t first_idx = 0; std::size_t last_idx = out.size() - 1; // if there is a Higgs boson, extremal qqx or unordered gluon // outside the extremal partons then it is not part of the FKL // ladder and does not contribute to the virtual corrections if((out.front().type == pid::Higgs) || event.type() == event_type::unob || event.type() == event_type::qqxexb){ q -= out[1].p; ++first_idx; } if((out.back().type == pid::Higgs) || event.type() == event_type::unof || event.type() == event_type::qqxexf){ --last_idx; } std::size_t first_idx_qqx = last_idx; std::size_t last_idx_qqx = last_idx; //if qqxMid event, virtual correction do not occur between //qqx pair. if(event.type() == event_type::qqxmid){ const auto backquark = std::find_if( begin(out) + 1, end(out) - 1 , [](Particle const & s){ return (s.type != pid::gluon && is_parton(s.type)); } ); if(backquark == end(out) || (backquark+1)->type==pid::gluon) return {0.}; last_idx = std::distance(begin(out), backquark); first_idx_qqx = last_idx+1; } double exponent = 0; const double alpha_s = alpha_s_(mur); for(std::size_t j = first_idx; j < last_idx; ++j){ exponent += omega0(alpha_s, mur, q)*( out[j+1].rapidity() - out[j].rapidity() ); q -= out[j+1].p; } if (last_idx != first_idx_qqx) q -= out[last_idx+1].p; for(std::size_t j = first_idx_qqx; j < last_idx_qqx; ++j){ exponent += omega0(alpha_s, mur, q)*( out[j+1].rapidity() - out[j].rapidity() ); q -= out[j+1].p; } assert( nearby(q, -1*pb, norm) || out.back().type == pid::Higgs || event.type() == event_type::unof || event.type() == event_type::qqxexf ); return {std::exp(exponent)}; } namespace { //! Lipatov vertex for partons emitted into extremal jets CLHEP::HepLorentzVector CLipatov( CLHEP::HepLorentzVector const & qav, CLHEP::HepLorentzVector const & qbv, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & p2 ) { const CLHEP::HepLorentzVector p5 = qav-qbv; const CLHEP::HepLorentzVector CL = -(qav+qbv) + p1*(qav.m2()/p5.dot(p1) + 2.*p5.dot(p2)/p1.dot(p2)) - p2*(qbv.m2()/p5.dot(p2) + 2.*p5.dot(p1)/p1.dot(p2)); return CL; } double C2Lipatov( CLHEP::HepLorentzVector const & qav, CLHEP::HepLorentzVector const & qbv, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & p2 ){ const CLHEP::HepLorentzVector CL = CLipatov(qav, qbv, p1, p2); return -CL.dot(CL); } //! Lipatov vertex with soft subtraction for partons emitted into extremal jets double C2Lipatovots( CLHEP::HepLorentzVector const & qav, CLHEP::HepLorentzVector const & qbv, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & p2, const double lambda ) { const double Cls=(C2Lipatov(qav, qbv, p1, p2)/(qav.m2()*qbv.m2())); const double kperp=(qav-qbv).perp(); if (kperp>lambda) return Cls; return Cls-4./(kperp*kperp); } double C2Lipatov_Mix( CLHEP::HepLorentzVector const & qav_t, CLHEP::HepLorentzVector const & qbv_t, CLHEP::HepLorentzVector const & qav_b, CLHEP::HepLorentzVector const & qbv_b, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & p2 ) { const CLHEP::HepLorentzVector CL_t = CLipatov(qav_t, qbv_t, p1, p2); const CLHEP::HepLorentzVector CL_b = CLipatov(qav_b, qbv_b, p1, p2); return -CL_t.dot(CL_b); } double C2Lipatovots_Mix( CLHEP::HepLorentzVector const & qav_t, CLHEP::HepLorentzVector const & qbv_t, CLHEP::HepLorentzVector const & qav_b, CLHEP::HepLorentzVector const & qbv_b, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & p2, const double lambda ) { const double Cls = C2Lipatov_Mix(qav_t, qbv_t, qav_b, qbv_b, p1, p2) / sqrt(qav_t.m2() * qbv_t.m2() * qav_b.m2() * qbv_b.m2()); const double kperp = (qav_t - qbv_t).perp(); if (kperp > lambda){ return Cls; } return Cls - 4.0 / (kperp * kperp); } CLHEP::HepLorentzVector CLipatov( CLHEP::HepLorentzVector const & qav, CLHEP::HepLorentzVector const & qbv, CLHEP::HepLorentzVector const & pim, CLHEP::HepLorentzVector const & pip, CLHEP::HepLorentzVector const & pom, CLHEP::HepLorentzVector const & pop ){ const CLHEP::HepLorentzVector p5 = qav-qbv; const CLHEP::HepLorentzVector CL = -(qav+qbv) + qav.m2()*(1./p5.dot(pip)*pip + 1./p5.dot(pop)*pop)/2. - qbv.m2()*(1./p5.dot(pim)*pim + 1./p5.dot(pom)*pom)/2. + ( pip*(p5.dot(pim)/pip.dot(pim) + p5.dot(pom)/pip.dot(pom)) + pop*(p5.dot(pim)/pop.dot(pim) + p5.dot(pom)/pop.dot(pom)) - pim*(p5.dot(pip)/pip.dot(pim) + p5.dot(pop)/pop.dot(pim)) - pom*(p5.dot(pip)/pip.dot(pom) + p5.dot(pop)/pop.dot(pom)) )/2.; return CL; } //! Lipatov vertex double C2Lipatov( // B CLHEP::HepLorentzVector const & qav, CLHEP::HepLorentzVector const & qbv, CLHEP::HepLorentzVector const & pim, CLHEP::HepLorentzVector const & pip, CLHEP::HepLorentzVector const & pom, CLHEP::HepLorentzVector const & pop ){ const CLHEP::HepLorentzVector CL = CLipatov(qav, qbv, pim, pip, pom, pop); return -CL.dot(CL); } //! Lipatov vertex with soft subtraction double C2Lipatovots( CLHEP::HepLorentzVector const & qav, CLHEP::HepLorentzVector const & qbv, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & pb, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & p2, const double lambda ) { const double Cls=(C2Lipatov(qav, qbv, pa, pb, p1, p2)/(qav.m2()*qbv.m2())); const double kperp=(qav-qbv).perp(); if (kperp>lambda) return Cls; return Cls-4./(kperp*kperp); } double C2Lipatov_Mix( CLHEP::HepLorentzVector const & qav_t, CLHEP::HepLorentzVector const & qbv_t, CLHEP::HepLorentzVector const & qav_b, CLHEP::HepLorentzVector const & qbv_b, CLHEP::HepLorentzVector const & pim, CLHEP::HepLorentzVector const & pip, CLHEP::HepLorentzVector const & pom, CLHEP::HepLorentzVector const & pop ) { const CLHEP::HepLorentzVector CL_t = CLipatov(qav_t, qbv_t, pim, pip, pom, pop); const CLHEP::HepLorentzVector CL_b = CLipatov(qav_b, qbv_b, pim, pip, pom, pop); return -CL_t.dot(CL_b); } double C2Lipatovots_Mix( CLHEP::HepLorentzVector const & qav_t, CLHEP::HepLorentzVector const & qbv_t, CLHEP::HepLorentzVector const & qav_b, CLHEP::HepLorentzVector const & qbv_b, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & pb, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & p2, const double lambda ) { const double Cls = C2Lipatov_Mix(qav_t, qbv_t, qav_b, qbv_b, pa, pb, p1, p2) / sqrt(qav_t.m2() * qbv_t.m2() * qav_b.m2() * qbv_b.m2()); const double kperp = (qav_t - qbv_t).perp(); if (kperp > lambda) { return Cls; } return Cls - 4.0 / (kperp * kperp); } /** Matrix element squared for tree-level current-current scattering * @param aptype Particle a PDG ID * @param bptype Particle b PDG ID * @param pg Unordered gluon momentum * @param pn Particle n Momentum * @param pb Particle b Momentum * @param p1 Particle 1 Momentum * @param pa Particle a Momentum * @returns ME Squared for Tree-Level Current-Current Scattering * * @note The unof contribution can be calculated by reversing the argument ordering. */ double ME_uno_current( ParticleID aptype, ParticleID bptype, CLHEP::HepLorentzVector const & pg, CLHEP::HepLorentzVector const & pn, CLHEP::HepLorentzVector const & pb, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & pa ){ using namespace currents; assert(aptype!=pid::gluon); // aptype cannot be gluon if (bptype==pid::gluon) { if (is_quark(aptype)) return ME_unob_qg(pg,p1,pa,pn,pb); return ME_unob_qbarg(pg,p1,pa,pn,pb); } if (is_antiquark(bptype)) { if (is_quark(aptype)) return ME_unob_qQbar(pg,p1,pa,pn,pb); return ME_unob_qbarQbar(pg,p1,pa,pn,pb); } //bptype == quark if (is_quark(aptype)) return ME_unob_qQ(pg,p1,pa,pn,pb); return ME_unob_qbarQ(pg,p1,pa,pn,pb); } /** Matrix element squared for tree-level current-current scattering * @param bptype Particle b PDG ID * @param pgin Incoming gluon momentum * @param pq Quark from splitting Momentum * @param pqbar Anti-quark from splitting Momentum * @param pn Particle n Momentum * @param pb Particle b Momentum * @param swap_q_qx Boolean. Ordering of qqbar pair. False: pqbar extremal. * @returns ME Squared for Tree-Level Current-Current Scattering * * @note The qqxf contribution can be calculated by reversing the argument ordering. */ double ME_qqx_current( ParticleID bptype, CLHEP::HepLorentzVector const & pgin, CLHEP::HepLorentzVector const & pq, CLHEP::HepLorentzVector const & pqbar, CLHEP::HepLorentzVector const & pn, CLHEP::HepLorentzVector const & pb, bool const swap_q_qx ){ using namespace currents; if (bptype==pid::gluon) { if (swap_q_qx) // pq extremal return ME_Exqqx_qqbarg(pgin,pq,pqbar,pn,pb); // pqbar extremal return ME_Exqqx_qbarqg(pgin,pq,pqbar,pn,pb); } // b leg quark line if (swap_q_qx) //extremal pq return ME_Exqqx_qqbarQ(pgin,pq,pqbar,pn,pb); return ME_Exqqx_qbarqQ(pgin,pq,pqbar,pn,pb); } /* \brief Matrix element squared for central qqx tree-level current-current * scattering * * @param aptype Particle a PDG ID * @param bptype Particle b PDG ID * @param nabove Number of gluons emitted before central qqxpair * @param nbelow Number of gluons emitted after central qqxpair * @param pa Initial state a Momentum * @param pb Initial state b Momentum * @param pq Final state qbar Momentum * @param pqbar Final state q Momentum * @param partons Vector of all outgoing partons * @returns ME Squared for qqxmid Tree-Level Current-Current Scattering */ double ME_qqxmid_current( ParticleID aptype, ParticleID bptype, int nabove, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & pb, CLHEP::HepLorentzVector const & pq, CLHEP::HepLorentzVector const & pqbar, std::vector const & partons ){ using namespace currents; // CAM factors for the qqx amps, and qqbar ordering (default, pq backwards) const bool swap_q_qx=pqbar.rapidity() < pq.rapidity(); double wt=1.; if (aptype==pid::gluon) wt*=K_g(partons.front(),pa)/C_F; if (bptype==pid::gluon) wt*=K_g(partons.back(),pb)/C_F; return wt*ME_Cenqqx_qq(pa, pb, partons, is_antiquark(bptype), is_antiquark(aptype), swap_q_qx, nabove); } /** Matrix element squared for tree-level current-current scattering * @param aptype Particle a PDG ID * @param bptype Particle b PDG ID * @param pn Particle n Momentum * @param pb Particle b Momentum * @param p1 Particle 1 Momentum * @param pa Particle a Momentum * @returns ME Squared for Tree-Level Current-Current Scattering */ double ME_current( ParticleID aptype, ParticleID bptype, CLHEP::HepLorentzVector const & pn, CLHEP::HepLorentzVector const & pb, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & pa ){ using namespace currents; if (aptype==pid::gluon && bptype==pid::gluon) { return ME_gg(pn,pb,p1,pa); } if (aptype==pid::gluon && bptype!=pid::gluon) { if (is_quark(bptype)) return ME_qg(pn,pb,p1,pa); return ME_qbarg(pn,pb,p1,pa); } if (bptype==pid::gluon && aptype!=pid::gluon) { if (is_quark(aptype)) return ME_qg(p1,pa,pn,pb); return ME_qbarg(p1,pa,pn,pb); } // they are both quark if (is_quark(bptype)) { if (is_quark(aptype)) return ME_qQ(pn,pb,p1,pa); return ME_qQbar(pn,pb,p1,pa); } if (is_quark(aptype)) return ME_qQbar(p1,pa,pn,pb); return ME_qbarQbar(pn,pb,p1,pa); } /** Matrix element squared for tree-level current-current scattering With W+Jets * @param aptype Particle a PDG ID * @param bptype Particle b PDG ID * @param pn Particle n Momentum * @param pb Particle b Momentum * @param p1 Particle 1 Momentum * @param pa Particle a Momentum * @param wc Boolean. True->W Emitted from b. Else; emitted from leg a * @returns ME Squared for Tree-Level Current-Current Scattering */ double ME_W_current( ParticleID aptype, ParticleID bptype, CLHEP::HepLorentzVector const & pn, CLHEP::HepLorentzVector const & pb, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & plbar, CLHEP::HepLorentzVector const & pl, bool const wc, ParticleProperties const & Wprop ){ using namespace currents; // We know it cannot be gg incoming. assert(!(aptype==pid::gluon && bptype==pid::gluon)); if (aptype==pid::gluon && bptype!=pid::gluon) { if (is_quark(bptype)) return ME_W_qg(pn,plbar,pl,pb,p1,pa,Wprop); return ME_W_qbarg(pn,plbar,pl,pb,p1,pa,Wprop); } if (bptype==pid::gluon && aptype!=pid::gluon) { if (is_quark(aptype)) return ME_W_qg(p1,plbar,pl,pa,pn,pb,Wprop); return ME_W_qbarg(p1,plbar,pl,pa,pn,pb,Wprop); } // they are both quark if (wc){ // emission off b, (first argument pbout) if (is_quark(bptype)) { if (is_quark(aptype)) return ME_W_qQ(pn,plbar,pl,pb,p1,pa,Wprop); return ME_W_qQbar(pn,plbar,pl,pb,p1,pa,Wprop); } if (is_quark(aptype)) return ME_W_qbarQ(pn,plbar,pl,pb,p1,pa,Wprop); return ME_W_qbarQbar(pn,plbar,pl,pb,p1,pa,Wprop); } // emission off a, (first argument paout) if (is_quark(aptype)) { if (is_quark(bptype)) return ME_W_qQ(p1,plbar,pl,pa,pn,pb,Wprop); return ME_W_qQbar(p1,plbar,pl,pa,pn,pb,Wprop); } // a is anti-quark if (is_quark(bptype)) return ME_W_qbarQ(p1,plbar,pl,pa,pn,pb,Wprop); return ME_W_qbarQbar(p1,plbar,pl,pa,pn,pb,Wprop); } /** Matrix element squared for backwards uno tree-level current-current * scattering With W+Jets * * @param aptype Particle a PDG ID * @param bptype Particle b PDG ID * @param pn Particle n Momentum * @param pb Particle b Momentum * @param p1 Particle 1 Momentum * @param pa Particle a Momentum * @param pg Unordered gluon momentum * @param wc Boolean. True->W Emitted from b. Else; emitted from leg a * @returns ME Squared for unob Tree-Level Current-Current Scattering * * @note The unof contribution can be calculated by reversing the argument ordering. */ double ME_W_uno_current( ParticleID aptype, ParticleID bptype, CLHEP::HepLorentzVector const & pn, CLHEP::HepLorentzVector const & pb, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & pg, CLHEP::HepLorentzVector const & plbar, CLHEP::HepLorentzVector const & pl, bool const wc, ParticleProperties const & Wprop ){ using namespace currents; // we know they are not both gluons assert(bptype != pid::gluon || aptype != pid::gluon); if (bptype == pid::gluon && aptype != pid::gluon) { // b gluon => W emission off a if (is_quark(aptype)) return ME_Wuno_qg(p1,pa,pn,pb,pg,plbar,pl,Wprop); return ME_Wuno_qbarg(p1,pa,pn,pb,pg,plbar,pl,Wprop); } // they are both quark if (wc) {// emission off b, i.e. b is first current if (is_quark(bptype)){ if (is_quark(aptype)) return ME_W_unob_qQ(p1,pa,pn,pb,pg,plbar,pl,Wprop); return ME_W_unob_qQbar(p1,pa,pn,pb,pg,plbar,pl,Wprop); } if (is_quark(aptype)) return ME_W_unob_qbarQ(p1,pa,pn,pb,pg,plbar,pl,Wprop); return ME_W_unob_qbarQbar(p1,pa,pn,pb,pg,plbar,pl,Wprop); } // wc == false, emission off a, i.e. a is first current if (is_quark(aptype)) { if (is_quark(bptype)) //qq return ME_Wuno_qQ(p1,pa,pn,pb,pg,plbar,pl,Wprop); //qqbar return ME_Wuno_qQbar(p1,pa,pn,pb,pg,plbar,pl,Wprop); } // a is anti-quark if (is_quark(bptype)) //qbarq return ME_Wuno_qbarQ(p1,pa,pn,pb,pg,plbar,pl,Wprop); //qbarqbar return ME_Wuno_qbarQbar(p1,pa,pn,pb,pg,plbar,pl,Wprop); } /** \brief Matrix element squared for backward qqx tree-level current-current * scattering With W+Jets * * @param aptype Particle a PDG ID * @param bptype Particle b PDG ID * @param pa Initial state a Momentum * @param pb Initial state b Momentum * @param pq Final state q Momentum * @param pqbar Final state qbar Momentum * @param pn Final state n Momentum * @param plbar Final state anti-lepton momentum * @param pl Final state lepton momentum * @param swap_q_qx Boolean. Ordering of qqbar pair. False: pqbar extremal. * @param wc Boolean. True->W Emitted from b. Else; emitted from leg a * @returns ME Squared for qqxb Tree-Level Current-Current Scattering * * @note calculate forwards qqx contribution by reversing argument ordering. */ double ME_W_qqx_current( ParticleID aptype, ParticleID bptype, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & pb, CLHEP::HepLorentzVector const & pq, CLHEP::HepLorentzVector const & pqbar, CLHEP::HepLorentzVector const & pn, CLHEP::HepLorentzVector const & plbar, CLHEP::HepLorentzVector const & pl, bool const swap_q_qx, bool const wc, ParticleProperties const & Wprop ){ using namespace currents; // CAM factors for the qqx amps, and qqbar ordering (default, qbar extremal) const double CFbackward = K_g( (swap_q_qx)?pq:pqbar ,pa)/C_F; // With qqbar we could have 2 incoming gluons and W Emission if (aptype==pid::gluon && bptype==pid::gluon) { //a gluon, b gluon gg->qqbarWg // This will be a wqqx emission as there is no other possible W Emission // Site. if (swap_q_qx) return ME_WExqqx_qqbarg(pa, pqbar, plbar, pl, pq, pn, pb, Wprop) * CFbackward; return ME_WExqqx_qbarqg(pa, pq, plbar, pl, pqbar, pn, pb, Wprop) * CFbackward; } assert(aptype==pid::gluon && bptype!=pid::gluon ); //a gluon => W emission off b leg or qqx if (!wc){ // W Emitted from backwards qqx if (swap_q_qx) return ME_WExqqx_qqbarQ(pa, pqbar, plbar, pl, pq, pn, pb, Wprop) * CFbackward; return ME_WExqqx_qbarqQ(pa, pq, plbar, pl, pqbar, pn, pb, Wprop) * CFbackward; } // W Must be emitted from forwards leg. if (swap_q_qx) return ME_W_Exqqx_QQq(pb, pa, pn, pqbar, pq, plbar, pl, is_antiquark(bptype), Wprop) * CFbackward; return ME_W_Exqqx_QQq(pb, pa, pn, pq, pqbar, plbar, pl, is_antiquark(bptype), Wprop) * CFbackward; throw std::logic_error("unreachable"); } /* \brief Matrix element squared for central qqx tree-level current-current * scattering With W+Jets * * @param aptype Particle a PDG ID * @param bptype Particle b PDG ID * @param nabove Number of gluons emitted before central qqxpair * @param nbelow Number of gluons emitted after central qqxpair * @param pa Initial state a Momentum * @param pb Initial state b Momentum\ * @param pq Final state qbar Momentum * @param pqbar Final state q Momentum * @param partons Vector of all outgoing partons * @param plbar Final state anti-lepton momentum * @param pl Final state lepton momentum * @param wqq Boolean. True siginfies W boson is emitted from Central qqx * @param wc Boolean. wc=true signifies w boson emitted from leg b; if wqq=false. * @returns ME Squared for qqxmid Tree-Level Current-Current Scattering */ double ME_W_qqxmid_current( ParticleID aptype, ParticleID bptype, int nabove, int nbelow, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & pb, CLHEP::HepLorentzVector const & pq, CLHEP::HepLorentzVector const & pqbar, std::vector const & partons, CLHEP::HepLorentzVector const & plbar, CLHEP::HepLorentzVector const & pl, bool const wqq, bool const wc, ParticleProperties const & Wprop ){ using namespace currents; // CAM factors for the qqx amps, and qqbar ordering (default, pq backwards) const bool swap_q_qx=pqbar.rapidity() < pq.rapidity(); double wt=1.; if (aptype==pid::gluon) wt*=K_g(partons.front(),pa)/C_F; if (bptype==pid::gluon) wt*=K_g(partons.back(),pb)/C_F; if(wqq) return wt*ME_WCenqqx_qq(pa, pb, pl, plbar, partons, is_antiquark(bptype),is_antiquark(aptype), swap_q_qx, nabove, Wprop); return wt*ME_W_Cenqqx_qq(pa, pb, pl, plbar, partons, is_antiquark(bptype), is_antiquark(aptype), swap_q_qx, nabove, nbelow, wc, Wprop); } /** Matrix element squared for tree-level current-current scattering With Z+Jets * @param aptype Particle a PDG ID * @param bptype Particle b PDG ID * @param pn Particle n Momentum * @param pb Particle b Momentum * @param p1 Particle 1 Momentum * @param pa Particle a Momentum * @param plbar Final state positron momentum * @param pl Final state electron momentum * @param Zprop Z properties * @param stw2 Value of sin(theta_w)^2 * @param ctw Value of cos(theta_w) * @returns ME Squared for Tree-Level Current-Current Scattering */ std::vector ME_Z_current( const ParticleID aptype, const ParticleID bptype, CLHEP::HepLorentzVector const & pn, CLHEP::HepLorentzVector const & pb, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & plbar, CLHEP::HepLorentzVector const & pl, ParticleProperties const & Zprop, const double stw2, const double ctw ){ using namespace currents; // we know they are not both gluons assert(!is_gluon(aptype) || !is_gluon(bptype)); if(is_anyquark(aptype) && is_gluon(bptype)){ // This is a qg event return { ME_Z_qg(pa,pb,p1,pn,plbar,pl,aptype,bptype,Zprop,stw2,ctw) }; } if(is_gluon(aptype) && is_anyquark(bptype)){ // This is a gq event return { ME_Z_qg(pb,pa,pn,p1,plbar,pl,bptype,aptype,Zprop,stw2,ctw) }; } assert(is_anyquark(aptype) && is_anyquark(bptype)); // This is a qq event return ME_Z_qQ(pa,pb,p1,pn,plbar,pl,aptype,bptype,Zprop,stw2,ctw); } /** Matrix element squared for backwards uno tree-level current-current * scattering With Z+Jets * * @param aptype Particle a PDG ID * @param bptype Particle b PDG ID * @param pn Particle n Momentum * @param pb Particle b Momentum * @param p1 Particle 1 Momentum * @param pa Particle a Momentum * @param pg Unordered gluon momentum * @param plbar Final state positron momentum * @param pl Final state electron momentum * @param Zprop Z properties * @param stw2 Value of sin(theta_w)^2 * @param ctw Value of cos(theta_w) * @returns ME Squared for unob Tree-Level Current-Current Scattering * * @note The unof contribution can be calculated by reversing the argument ordering. */ std::vector ME_Z_uno_current( const ParticleID aptype, const ParticleID bptype, CLHEP::HepLorentzVector const & pn, CLHEP::HepLorentzVector const & pb, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & pg, CLHEP::HepLorentzVector const & plbar, CLHEP::HepLorentzVector const & pl, ParticleProperties const & Zprop, const double stw2, const double ctw ){ using namespace currents; // we know they are not both gluons assert(!is_gluon(aptype) || !is_gluon(bptype)); if (is_anyquark(aptype) && is_gluon(bptype)) { // This is a qg event return { ME_Zuno_qg(pa,pb,pg,p1,pn,plbar,pl,aptype,bptype,Zprop,stw2,ctw) }; } if (is_gluon(aptype) && is_anyquark(bptype)) { // This is a gq event return { ME_Zuno_qg(pb,pa,pg,pn,p1,plbar,pl,bptype,aptype,Zprop,stw2,ctw) }; } assert(is_anyquark(aptype) && is_anyquark(bptype)); // This is a qq event return ME_Zuno_qQ(pa,pb,pg,p1,pn,plbar,pl,aptype,bptype,Zprop,stw2,ctw); } /** \brief Matrix element squared for tree-level current-current scattering with Higgs * @param aptype Particle a PDG ID * @param bptype Particle b PDG ID * @param pn Particle n Momentum * @param pb Particle b Momentum * @param p1 Particle 1 Momentum * @param pa Particle a Momentum * @param qH t-channel momentum before Higgs * @param qHp1 t-channel momentum after Higgs * @returns ME Squared for Tree-Level Current-Current Scattering with Higgs */ double ME_Higgs_current( ParticleID aptype, ParticleID bptype, CLHEP::HepLorentzVector const & pn, CLHEP::HepLorentzVector const & pb, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & qH, // t-channel momentum before Higgs CLHEP::HepLorentzVector const & qHp1, // t-channel momentum after Higgs double mt, bool include_bottom, double mb, double vev ){ using namespace currents; if (aptype==pid::gluon && bptype==pid::gluon) // gg initial state return ME_H_gg(pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb,vev); if (aptype==pid::gluon&&bptype!=pid::gluon) { if (is_quark(bptype)) return ME_H_qg(pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb,vev)*4./9.; return ME_H_qbarg(pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb,vev)*4./9.; } if (bptype==pid::gluon && aptype!=pid::gluon) { if (is_quark(aptype)) return ME_H_qg(p1,pa,pn,pb,-qH,-qHp1,mt,include_bottom,mb,vev)*4./9.; return ME_H_qbarg(p1,pa,pn,pb,-qH,-qHp1,mt,include_bottom,mb,vev)*4./9.; } // they are both quark if (is_quark(bptype)) { if (is_quark(aptype)) return ME_H_qQ(pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb,vev)*4.*4./(9.*9.); return ME_H_qQbar(pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb,vev)*4.*4./(9.*9.); } if (is_quark(aptype)) return ME_H_qbarQ(pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb,vev)*4.*4./(9.*9.); return ME_H_qbarQbar(pn,pb,p1,pa,-qHp1,-qH,mt,include_bottom,mb,vev)*4.*4./(9.*9.); } /** \brief Current matrix element squared with Higgs and unordered backward emission * @param aptype Particle A PDG ID * @param bptype Particle B PDG ID * @param pn Particle n Momentum * @param pb Particle b Momentum * @param pg Unordered back Particle Momentum * @param p1 Particle 1 Momentum * @param pa Particle a Momentum * @param qH t-channel momentum before Higgs * @param qHp1 t-channel momentum after Higgs * @returns ME Squared with Higgs and unordered backward emission * * @note This function assumes unordered gluon backwards from pa-p1 current. * For unof, reverse call order */ double ME_Higgs_current_uno( ParticleID aptype, ParticleID bptype, CLHEP::HepLorentzVector const & pg, CLHEP::HepLorentzVector const & pn, CLHEP::HepLorentzVector const & pb, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & qH, // t-channel momentum before Higgs CLHEP::HepLorentzVector const & qHp1, // t-channel momentum after Higgs double mt, bool include_bottom, double mb, double vev ){ using namespace currents; if (bptype==pid::gluon && aptype!=pid::gluon) { if (is_quark(aptype)) return ME_H_unob_gQ(pg,p1,pa,pn,pb,-qH,-qHp1,mt,include_bottom,mb,vev); return ME_H_unob_gQbar(pg,p1,pa,pn,pb,-qH,-qHp1,mt,include_bottom,mb,vev); } // they are both quark if (is_quark(aptype)) { if (is_quark(bptype)) return ME_H_unob_qQ(pg,p1,pa,pn,pb,-qH,-qHp1,mt,include_bottom,mb,vev); return ME_H_unob_qbarQ(pg,p1,pa,pn,pb,-qH,-qHp1,mt,include_bottom,mb,vev); } if (is_quark(bptype)) return ME_H_unob_qQbar(pg,p1,pa,pn,pb,-qH,-qHp1,mt,include_bottom,mb,vev); return ME_H_unob_qbarQbar(pg,p1,pa,pn,pb,-qH,-qHp1,mt,include_bottom,mb,vev); } + /** Matrix element squared for tree-level scattering with WW+Jets + * @param aptype Particle a PDG ID + * @param bptype Particle b PDG ID + * @param pn Particle n Momentum + * @param pb Particle b Momentum + * @param p1 Particle 1 Momentum + * @param pa Particle a Momentum + * @param pl1bar Particle l1bar Momentum + * @param pl1 Particle l1 Momentum + * @param pl2bar Particle l2bar Momentum + * @param pl2 Particle l2 Momentum + * @returns ME Squared for Tree-Level Current-Current Scattering + */ + double ME_WW_current( + ParticleID /*aptype*/, ParticleID /*bptype*/, + CLHEP::HepLorentzVector const & pn, + CLHEP::HepLorentzVector const & pb, + CLHEP::HepLorentzVector const & p1, + CLHEP::HepLorentzVector const & pa, + CLHEP::HepLorentzVector const & pl1bar, + CLHEP::HepLorentzVector const & pl1, + CLHEP::HepLorentzVector const & pl2bar, + CLHEP::HepLorentzVector const & pl2, + ParticleProperties const & Wprop + ){ + using namespace currents; + return ME_WW_qQ(p1, pl1bar, pl1, pa, + pn, pl2bar, pl2, pb, Wprop); + } + CLHEP::HepLorentzVector to_HepLorentzVector(Particle const & particle){ return {particle.p.px(), particle.p.py(), particle.p.pz(), particle.p.E()}; } void validate(MatrixElementConfig const & config) { #ifndef HEJ_BUILD_WITH_QCDLOOP if(!config.Higgs_coupling.use_impact_factors) { throw std::invalid_argument{ "Invalid Higgs coupling settings.\n" "HEJ without QCDloop support can only use impact factors.\n" "Set use_impact_factors to true or recompile HEJ.\n" }; } #endif if(config.Higgs_coupling.use_impact_factors && config.Higgs_coupling.mt != std::numeric_limits::infinity()) { throw std::invalid_argument{ "Conflicting settings: " "impact factors may only be used in the infinite top mass limit" }; } } } // namespace MatrixElement::MatrixElement( std::function alpha_s, MatrixElementConfig conf ): alpha_s_{std::move(alpha_s)}, param_{std::move(conf)} { validate(param_); } std::vector MatrixElement::tree_kin( Event const & ev ) const { if(! is_resummable(ev.type())) return {0.}; std::vector bosons = filter_AWZH_bosons(ev.outgoing()); if(bosons.empty()) { return {tree_kin_jets(ev)}; } if(bosons.size() == 1) { switch(bosons[0].type){ case pid::Higgs: return {tree_kin_Higgs(ev)}; case pid::Wp: case pid::Wm: return {tree_kin_W(ev)}; case pid::Z_photon_mix: return tree_kin_Z(ev); // TODO case pid::photon: case pid::Z: default: throw not_implemented("Emission of boson of unsupported type"); } } if(bosons.size() == 2) { if(bosons[0].type == pid::Wp && bosons[1].type == pid::Wp){ return {tree_kin_WW(ev)}; } throw not_implemented("Emission of bosons of unsupported type"); } throw not_implemented("Emission of >2 bosons is unsupported"); } namespace { constexpr int EXTREMAL_JET_IDX = 1; constexpr int NO_EXTREMAL_JET_IDX = 0; bool treat_as_extremal(Particle const & parton){ return parton.p.user_index() == EXTREMAL_JET_IDX; } template double FKL_ladder_weight( InputIterator begin_gluon, InputIterator end_gluon, CLHEP::HepLorentzVector const & q0, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & pb, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & pn, double lambda ){ double wt = 1; auto qi = q0; for(auto gluon_it = begin_gluon; gluon_it != end_gluon; ++gluon_it){ assert(gluon_it->type == pid::gluon); const auto g = to_HepLorentzVector(*gluon_it); const auto qip1 = qi - g; if(treat_as_extremal(*gluon_it)){ wt *= C2Lipatovots(qip1, qi, pa, pb, lambda)*C_A; } else{ wt *= C2Lipatovots(qip1, qi, pa, pb, p1, pn, lambda)*C_A; } qi = qip1; } return wt; } template std::vector FKL_ladder_weight_mix( InputIterator begin_gluon, InputIterator end_gluon, CLHEP::HepLorentzVector const & q0_t, CLHEP::HepLorentzVector const & q0_b, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & pb, CLHEP::HepLorentzVector const & p1, CLHEP::HepLorentzVector const & pn, const double lambda ){ double wt_top = 1; double wt_bot = 1; double wt_mix = 1; auto qi_t = q0_t; auto qi_b = q0_b; for(auto gluon_it = begin_gluon; gluon_it != end_gluon; ++gluon_it){ assert(gluon_it->type == pid::gluon); const auto g = to_HepLorentzVector(*gluon_it); const auto qip1_t = qi_t - g; const auto qip1_b = qi_b - g; if(treat_as_extremal(*gluon_it)){ wt_top *= C2Lipatovots(qip1_t, qi_t, pa, pb, lambda)*C_A; wt_bot *= C2Lipatovots(qip1_b, qi_b, pa, pb, lambda)*C_A; wt_mix *= C2Lipatovots_Mix(qip1_t, qi_t, qip1_b, qi_b, pa, pb, lambda)*C_A; } else{ wt_top *= C2Lipatovots(qip1_t, qi_t, pa, pb, p1, pn, lambda)*C_A; wt_bot *= C2Lipatovots(qip1_b, qi_b, pa, pb, p1, pn, lambda)*C_A; wt_mix *= C2Lipatovots_Mix(qip1_t, qi_t, qip1_b, qi_b, pa, pb, p1, pn, lambda)*C_A; } qi_t = qip1_t; qi_b = qip1_b; } return {wt_top, wt_bot, wt_mix}; } std::vector tag_extremal_jet_partons( Event const & ev ){ auto out_partons = filter_partons(ev.outgoing()); if(out_partons.size() == ev.jets().size()){ // no additional emissions in extremal jets, don't need to tag anything for(auto & parton: out_partons){ parton.p.set_user_index(NO_EXTREMAL_JET_IDX); } return out_partons; } auto const & jets = ev.jets(); assert(jets.size() >= 2); auto most_backward = begin(jets); auto most_forward = end(jets) - 1; // skip jets caused by unordered emission or qqx if(ev.type() == event_type::unob || ev.type() == event_type::qqxexb){ assert(jets.size() >= 3); ++most_backward; } else if(ev.type() == event_type::unof || ev.type() == event_type::qqxexf){ assert(jets.size() >= 3); --most_forward; } const auto extremal_jet_indices = ev.particle_jet_indices( {*most_backward, *most_forward} ); assert(extremal_jet_indices.size() == out_partons.size()); for(std::size_t i = 0; i < out_partons.size(); ++i){ assert(is_parton(out_partons[i])); const int idx = (extremal_jet_indices[i]>=0)? EXTREMAL_JET_IDX: NO_EXTREMAL_JET_IDX; out_partons[i].p.set_user_index(idx); } return out_partons; } double tree_kin_jets_qqxmid( ParticleID aptype, ParticleID bptype, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & pb, std::vector const & partons, double lambda ){ CLHEP::HepLorentzVector pq; CLHEP::HepLorentzVector pqbar; const auto backmidquark = std::find_if( begin(partons)+1, end(partons)-1, [](Particle const & s){ return s.type != pid::gluon; } ); assert(backmidquark!=end(partons)-1); if (is_quark(backmidquark->type)){ pq = to_HepLorentzVector(*backmidquark); pqbar = to_HepLorentzVector(*(backmidquark+1)); } else { pqbar = to_HepLorentzVector(*backmidquark); pq = to_HepLorentzVector(*(backmidquark+1)); } auto p1 = to_HepLorentzVector(partons[0]); auto pn = to_HepLorentzVector(partons[partons.size() - 1]); auto q0 = pa - p1; // t-channel momentum after qqx auto qqxt = q0; const auto begin_ladder = cbegin(partons) + 1; const auto end_ladder_1 = (backmidquark); const auto begin_ladder_2 = (backmidquark+2); const auto end_ladder = cend(partons) - 1; for(auto parton_it = begin_ladder; parton_it < begin_ladder_2; ++parton_it){ qqxt -= to_HepLorentzVector(*parton_it); } const int nabove = std::distance(begin_ladder, backmidquark); std::vector partonsHLV; partonsHLV.reserve(partons.size()); for (std::size_t i = 0; i != partons.size(); ++i) { partonsHLV.push_back(to_HepLorentzVector(partons[i])); } const double current_factor = ME_qqxmid_current( aptype, bptype, nabove, pa, pb, pq, pqbar, partonsHLV ); const double ladder_factor = FKL_ladder_weight( begin_ladder, end_ladder_1, q0, pa, pb, p1, pn, lambda )*FKL_ladder_weight( begin_ladder_2, end_ladder, qqxt, pa, pb, p1, pn, lambda ); return current_factor*ladder_factor; } template double tree_kin_jets_qqx(InIter BeginIn, InIter EndIn, partIter BeginPart, partIter EndPart, double lambda){ const bool swap_q_qx = is_quark(*BeginPart); const auto pgin = to_HepLorentzVector(*BeginIn); const auto pb = to_HepLorentzVector(*(EndIn-1)); const auto pq = to_HepLorentzVector(*(BeginPart+(swap_q_qx?0:1))); const auto pqbar = to_HepLorentzVector(*(BeginPart+(swap_q_qx?1:0))); const auto p1 = to_HepLorentzVector(*(BeginPart)); const auto pn = to_HepLorentzVector(*(EndPart-1)); assert((BeginIn)->type==pid::gluon); // Incoming a must be gluon. const double current_factor = ME_qqx_current( (EndIn-1)->type, pgin, pq, pqbar, pn, pb, swap_q_qx )/(4.*(N_C*N_C - 1.)); const double ladder_factor = FKL_ladder_weight( (BeginPart+2), (EndPart-1), pgin-pq-pqbar, pgin, pb, p1, pn, lambda ); return current_factor*ladder_factor; } template double tree_kin_jets_uno(InIter BeginIn, InIter EndIn, partIter BeginPart, partIter EndPart, double lambda ){ const auto pa = to_HepLorentzVector(*BeginIn); const auto pb = to_HepLorentzVector(*(EndIn-1)); const auto pg = to_HepLorentzVector(*BeginPart); const auto p1 = to_HepLorentzVector(*(BeginPart+1)); const auto pn = to_HepLorentzVector(*(EndPart-1)); const double current_factor = ME_uno_current( (BeginIn)->type, (EndIn-1)->type, pg, pn, pb, p1, pa )/(4.*(N_C*N_C - 1.)); const double ladder_factor = FKL_ladder_weight( (BeginPart+2), (EndPart-1), pa-p1-pg, pa, pb, p1, pn, lambda ); return current_factor*ladder_factor; } } // namespace double MatrixElement::tree_kin_jets(Event const & ev) const { auto const & incoming = ev.incoming(); const auto partons = tag_extremal_jet_partons(ev); if (ev.type()==event_type::FKL){ const auto pa = to_HepLorentzVector(incoming[0]); const auto pb = to_HepLorentzVector(incoming[1]); const auto p1 = to_HepLorentzVector(partons.front()); const auto pn = to_HepLorentzVector(partons.back()); return ME_current( incoming[0].type, incoming[1].type, pn, pb, p1, pa )/(4.*(N_C*N_C - 1.))*FKL_ladder_weight( begin(partons) + 1, end(partons) - 1, pa - p1, pa, pb, p1, pn, param_.regulator_lambda ); } if (ev.type()==event_type::unordered_backward){ return tree_kin_jets_uno(incoming.begin(), incoming.end(), partons.begin(), partons.end(), param_.regulator_lambda); } if (ev.type()==event_type::unordered_forward){ return tree_kin_jets_uno(incoming.rbegin(), incoming.rend(), partons.rbegin(), partons.rend(), param_.regulator_lambda); } if (ev.type()==event_type::extremal_qqxb){ return tree_kin_jets_qqx(incoming.begin(), incoming.end(), partons.begin(), partons.end(), param_.regulator_lambda); } if (ev.type()==event_type::extremal_qqxf){ return tree_kin_jets_qqx(incoming.rbegin(), incoming.rend(), partons.rbegin(), partons.rend(), param_.regulator_lambda); } if (ev.type()==event_type::central_qqx){ return tree_kin_jets_qqxmid(incoming[0].type, incoming[1].type, to_HepLorentzVector(incoming[0]), to_HepLorentzVector(incoming[1]), partons, param_.regulator_lambda); } throw std::logic_error("Cannot reweight non-resummable processes in Pure Jets"); } namespace { double tree_kin_W_FKL( ParticleID aptype, ParticleID bptype, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & pb, std::vector const & partons, CLHEP::HepLorentzVector const & plbar, CLHEP::HepLorentzVector const & pl, double lambda, ParticleProperties const & Wprop ){ auto p1 = to_HepLorentzVector(partons[0]); auto pn = to_HepLorentzVector(partons[partons.size() - 1]); const auto begin_ladder = cbegin(partons) + 1; const auto end_ladder = cend(partons) - 1; bool wc = aptype==partons[0].type; //leg b emits w auto q0 = pa - p1; if(!wc) q0 -= pl + plbar; const double current_factor = ME_W_current( aptype, bptype, pn, pb, p1, pa, plbar, pl, wc, Wprop ); const double ladder_factor = FKL_ladder_weight( begin_ladder, end_ladder, q0, pa, pb, p1, pn, lambda ); return current_factor*ladder_factor; } template double tree_kin_W_uno(InIter BeginIn, partIter BeginPart, partIter EndPart, const CLHEP::HepLorentzVector & plbar, const CLHEP::HepLorentzVector & pl, double lambda, ParticleProperties const & Wprop ){ const auto pa = to_HepLorentzVector(*BeginIn); const auto pb = to_HepLorentzVector(*(BeginIn+1)); const auto pg = to_HepLorentzVector(*BeginPart); const auto p1 = to_HepLorentzVector(*(BeginPart+1)); const auto pn = to_HepLorentzVector(*(EndPart-1)); bool wc = (BeginIn)->type==(BeginPart+1)->type; //leg b emits w auto q0 = pa - p1 - pg; if(!wc) q0 -= pl + plbar; const double current_factor = ME_W_uno_current( (BeginIn)->type, (BeginIn+1)->type, pn, pb, p1, pa, pg, plbar, pl, wc, Wprop ); const double ladder_factor = FKL_ladder_weight( BeginPart+2, EndPart-1, q0, pa, pb, p1, pn, lambda ); return current_factor*C_A*C_A/(N_C*N_C-1.)*ladder_factor; } template double tree_kin_W_qqx(InIter BeginIn, partIter BeginPart, partIter EndPart, const CLHEP::HepLorentzVector & plbar, const CLHEP::HepLorentzVector & pl, double lambda, ParticleProperties const & Wprop ){ const bool swap_q_qx=is_quark(*BeginPart); const auto pa = to_HepLorentzVector(*BeginIn); const auto pb = to_HepLorentzVector(*(BeginIn+1)); const auto pq = to_HepLorentzVector(*(BeginPart+(swap_q_qx?0:1))); const auto pqbar = to_HepLorentzVector(*(BeginPart+(swap_q_qx?1:0))); const auto p1 = to_HepLorentzVector(*(BeginPart)); const auto pn = to_HepLorentzVector(*(EndPart-1)); const bool wc = (BeginIn+1)->type!=(EndPart-1)->type; //leg b emits w auto q0 = pa - pq - pqbar; if(!wc) q0 -= pl + plbar; const double current_factor = ME_W_qqx_current( (BeginIn)->type, (BeginIn+1)->type, pa, pb, pq, pqbar, pn, plbar, pl, swap_q_qx, wc, Wprop ); const double ladder_factor = FKL_ladder_weight( BeginPart+2, EndPart-1, q0, pa, pb, p1, pn, lambda ); return current_factor*C_A*C_A/(N_C*N_C-1.)*ladder_factor; } double tree_kin_W_qqxmid( ParticleID aptype, ParticleID bptype, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & pb, std::vector const & partons, CLHEP::HepLorentzVector const & plbar, CLHEP::HepLorentzVector const & pl, double lambda, ParticleProperties const & Wprop ){ CLHEP::HepLorentzVector pq; CLHEP::HepLorentzVector pqbar; const auto backmidquark = std::find_if( begin(partons)+1, end(partons)-1, [](Particle const & s){ return s.type != pid::gluon; } ); assert(backmidquark!=end(partons)-1); if (is_quark(backmidquark->type)){ pq = to_HepLorentzVector(*backmidquark); pqbar = to_HepLorentzVector(*(backmidquark+1)); } else { pqbar = to_HepLorentzVector(*backmidquark); pq = to_HepLorentzVector(*(backmidquark+1)); } auto p1 = to_HepLorentzVector(partons.front()); auto pn = to_HepLorentzVector(partons.back()); auto q0 = pa - p1; // t-channel momentum after qqx auto qqxt = q0; bool wqq = backmidquark->type != -(backmidquark+1)->type; // qqx emit W bool wc = !wqq && (aptype==partons.front().type); //leg b emits w assert(!wqq || !wc); if(wqq){ // emission from qqx qqxt -= pl + plbar; } else if(!wc) { // emission from leg a q0 -= pl + plbar; qqxt -= pl + plbar; } const auto begin_ladder = cbegin(partons) + 1; const auto end_ladder_1 = (backmidquark); const auto begin_ladder_2 = (backmidquark+2); const auto end_ladder = cend(partons) - 1; for(auto parton_it = begin_ladder; parton_it < begin_ladder_2; ++parton_it){ qqxt -= to_HepLorentzVector(*parton_it); } const int nabove = std::distance(begin_ladder, backmidquark); const int nbelow = std::distance(begin_ladder_2, end_ladder); std::vector partonsHLV; partonsHLV.reserve(partons.size()); for (std::size_t i = 0; i != partons.size(); ++i) { partonsHLV.push_back(to_HepLorentzVector(partons[i])); } const double current_factor = ME_W_qqxmid_current( aptype, bptype, nabove, nbelow, pa, pb, pq, pqbar, partonsHLV, plbar, pl, wqq, wc, Wprop ); const double ladder_factor = FKL_ladder_weight( begin_ladder, end_ladder_1, q0, pa, pb, p1, pn, lambda )*FKL_ladder_weight( begin_ladder_2, end_ladder, qqxt, pa, pb, p1, pn, lambda ); return current_factor*C_A*C_A/(N_C*N_C-1.)*ladder_factor; } } // namespace double MatrixElement::tree_kin_W(Event const & ev) const { using namespace event_type; auto const & incoming(ev.incoming()); #ifndef NDEBUG // assert that there is exactly one decay corresponding to the W assert(ev.decays().size() == 1); auto const & w_boson{ std::find_if(ev.outgoing().cbegin(), ev.outgoing().cend(), [] (Particle const & p) -> bool { return std::abs(p.type) == ParticleID::Wp; }) }; assert(w_boson != ev.outgoing().cend()); assert( static_cast(ev.decays().cbegin()->first) == std::distance(ev.outgoing().cbegin(), w_boson) ); #endif // find decay products of W auto const & decay{ ev.decays().cbegin()->second }; assert(decay.size() == 2); assert( ( is_anylepton(decay.at(0)) && is_anyneutrino(decay.at(1)) ) || ( is_anylepton(decay.at(1)) && is_anyneutrino(decay.at(0)) ) ); // get lepton & neutrino CLHEP::HepLorentzVector plbar; CLHEP::HepLorentzVector pl; if (decay.at(0).type < 0){ plbar = to_HepLorentzVector(decay.at(0)); pl = to_HepLorentzVector(decay.at(1)); } else{ pl = to_HepLorentzVector(decay.at(0)); plbar = to_HepLorentzVector(decay.at(1)); } const auto pa = to_HepLorentzVector(incoming[0]); const auto pb = to_HepLorentzVector(incoming[1]); const auto partons = tag_extremal_jet_partons(ev); if(ev.type() == FKL){ return tree_kin_W_FKL(incoming[0].type, incoming[1].type, pa, pb, partons, plbar, pl, param_.regulator_lambda, param_.ew_parameters.Wprop()); } if(ev.type() == unordered_backward){ return tree_kin_W_uno(cbegin(incoming), cbegin(partons), cend(partons), plbar, pl, param_.regulator_lambda, param_.ew_parameters.Wprop()); } if(ev.type() == unordered_forward){ return tree_kin_W_uno(crbegin(incoming), crbegin(partons), crend(partons), plbar, pl, param_.regulator_lambda, param_.ew_parameters.Wprop()); } if(ev.type() == extremal_qqxb){ return tree_kin_W_qqx(cbegin(incoming), cbegin(partons), cend(partons), plbar, pl, param_.regulator_lambda, param_.ew_parameters.Wprop()); } if(ev.type() == extremal_qqxf){ return tree_kin_W_qqx(crbegin(incoming), crbegin(partons), crend(partons), plbar, pl, param_.regulator_lambda, param_.ew_parameters.Wprop()); } assert(ev.type() == central_qqx); return tree_kin_W_qqxmid(incoming[0].type, incoming[1].type, pa, pb, partons, plbar, pl, param_.regulator_lambda, param_.ew_parameters.Wprop()); } + namespace /* WW */ { + double tree_kin_WW_FKL( + ParticleID aptype, ParticleID bptype, + CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & pb, + std::vector const & partons, + CLHEP::HepLorentzVector const & pl1bar, CLHEP::HepLorentzVector const & pl1, + CLHEP::HepLorentzVector const & pl2bar, CLHEP::HepLorentzVector const & pl2, + double lambda, ParticleProperties const & Wprop + ){ + auto p1 = to_HepLorentzVector(partons[0]); + auto pn = to_HepLorentzVector(partons[partons.size() - 1]); + + const double current_factor = ME_WW_current( + aptype, bptype, pn, pb, p1, pa, + pl1bar, pl1, pl2bar, pl2, + Wprop + ); + + // pa -> W1 p1, pb -> W2 + pn + auto q0 = pa - p1 - (pl1 + pl1bar); + auto const begin_ladder = cbegin(partons) + 1; + auto const end_ladder = cend(partons) - 1; + + const double ladder_factor = FKL_ladder_weight( + begin_ladder, end_ladder, + q0, pa, pb, p1, pn, + lambda + ); + + return current_factor*ladder_factor; + } + } // WW namespace (anon) + double MatrixElement::tree_kin_WW(Event const & ev) const { using namespace event_type; + auto const & incoming(ev.incoming()); + + auto const pa = to_HepLorentzVector(incoming[0]); + auto const pb = to_HepLorentzVector(incoming[1]); + + auto const partons = tag_extremal_jet_partons(ev); + + // W1 & W2 + assert(ev.decays().size() == 2); + + std::vector plbar; + std::vector pl; + + for(auto const & decay_pair : ev.decays()) { + auto const decay = decay_pair.second; + // TODO: how to label W1, W2 + if(decay.at(0).type < 0) { + plbar.emplace_back(to_HepLorentzVector(decay.at(0))); + pl .emplace_back(to_HepLorentzVector(decay.at(1))); + } + else { + pl .emplace_back(to_HepLorentzVector(decay.at(0))); + plbar.emplace_back(to_HepLorentzVector(decay.at(1))); + } + } + if(ev.type() == FKL) { - return 1.0; + + return tree_kin_WW_FKL( + incoming[0].type, incoming[1].type, + pa, pb, partons, + plbar[0], pl[0], plbar[1], pl[1], + param_.regulator_lambda, + param_.ew_parameters.Wprop() + ); + } return 0.; } namespace{ std::vector tree_kin_Z_FKL( const ParticleID aptype, const ParticleID bptype, CLHEP::HepLorentzVector const & pa, CLHEP::HepLorentzVector const & pb, std::vector const & partons, CLHEP::HepLorentzVector const & plbar, CLHEP::HepLorentzVector const & pl, const double lambda, ParticleProperties const & Zprop, const double stw2, const double ctw ){ const auto p1 = to_HepLorentzVector(partons[0]); const auto pn = to_HepLorentzVector(partons[partons.size() - 1]); const auto begin_ladder = cbegin(partons) + 1; const auto end_ladder = cend(partons) - 1; const std::vector current_factor = ME_Z_current( aptype, bptype, pn, pb, p1, pa, plbar, pl, Zprop, stw2, ctw ); std::vector ladder_factor; if(is_gluon(bptype)){ // This is a qg event const auto q0 = pa-p1-plbar-pl; ladder_factor.push_back(FKL_ladder_weight(begin_ladder, end_ladder, q0, pa, pb, p1, pn, lambda)); } else if(is_gluon(aptype)){ // This is a gq event const auto q0 = pa-p1; ladder_factor.push_back(FKL_ladder_weight(begin_ladder, end_ladder, q0, pa, pb, p1, pn, lambda)); } else { // This is a qq event const auto q0 = pa-p1-plbar-pl; const auto q1 = pa-p1; ladder_factor=FKL_ladder_weight_mix(begin_ladder, end_ladder, q0, q1, pa, pb, p1, pn, lambda); } std::vector result; for(size_t i=0; i std::vector tree_kin_Z_uno(InIter BeginIn, partIter BeginPart, partIter EndPart, const CLHEP::HepLorentzVector & plbar, const CLHEP::HepLorentzVector & pl, const double lambda, ParticleProperties const & Zprop, const double stw2, const double ctw){ const auto pa = to_HepLorentzVector(*BeginIn); const auto pb = to_HepLorentzVector(*(BeginIn+1)); const auto pg = to_HepLorentzVector(*BeginPart); const auto p1 = to_HepLorentzVector(*(BeginPart+1)); const auto pn = to_HepLorentzVector(*(EndPart-1)); const ParticleID aptype = (BeginIn)->type; const ParticleID bptype = (BeginIn+1)->type; const std::vector current_factor = ME_Z_uno_current( aptype, bptype, pn, pb, p1, pa, pg, plbar, pl, Zprop, stw2, ctw ); std::vector ladder_factor; if(is_gluon(bptype)){ // This is a qg event const auto q0 = pa-pg-p1-plbar-pl; ladder_factor.push_back(FKL_ladder_weight(BeginPart+2, EndPart-1, q0, pa, pb, p1, pn, lambda)); }else if(is_gluon(aptype)){ // This is a gq event const auto q0 = pa-pg-p1; ladder_factor.push_back(FKL_ladder_weight(BeginPart+2, EndPart-1, q0, pa, pb, p1, pn, lambda)); }else{ // This is a qq event const auto q0 = pa-pg-p1-plbar-pl; const auto q1 = pa-pg-p1; ladder_factor=FKL_ladder_weight_mix(BeginPart+2, EndPart-1, q0, q1, pa, pb, p1, pn, lambda); } std::vector result; for(size_t i=0; i MatrixElement::tree_kin_Z(Event const & ev) const { using namespace event_type; auto const & incoming(ev.incoming()); // find decay products of Z auto const & decay{ ev.decays().cbegin()->second }; assert(decay.size() == 2); assert(is_anylepton(decay.at(0)) && !is_anyneutrino(decay.at(0)) && decay.at(0).type==-decay.at(1).type); // get leptons CLHEP::HepLorentzVector plbar; CLHEP::HepLorentzVector pl; if (decay.at(0).type < 0){ plbar = to_HepLorentzVector(decay.at(0)); pl = to_HepLorentzVector(decay.at(1)); } else{ pl = to_HepLorentzVector(decay.at(0)); plbar = to_HepLorentzVector(decay.at(1)); } const auto pa = to_HepLorentzVector(incoming[0]); const auto pb = to_HepLorentzVector(incoming[1]); const auto partons = tag_extremal_jet_partons(ev); const double stw2 = param_.ew_parameters.sin2_tw(); const double ctw = param_.ew_parameters.cos_tw(); if(ev.type() == FKL){ return tree_kin_Z_FKL(incoming[0].type, incoming[1].type, pa, pb, partons, plbar, pl, param_.regulator_lambda, param_.ew_parameters.Zprop(), stw2, ctw); } if(ev.type() == unordered_backward){ return tree_kin_Z_uno(cbegin(incoming), cbegin(partons), cend(partons), plbar, pl, param_.regulator_lambda, param_.ew_parameters.Zprop(), stw2, ctw); } if(ev.type() == unordered_forward){ return tree_kin_Z_uno(crbegin(incoming), crbegin(partons), crend(partons), plbar, pl, param_.regulator_lambda, param_.ew_parameters.Zprop(), stw2, ctw); } throw std::logic_error("Can only reweight FKL or uno processes in Z+Jets"); } double MatrixElement::tree_kin_Higgs(Event const & ev) const { if(is_uno(ev.type())){ return tree_kin_Higgs_between(ev); } if(ev.outgoing().front().type == pid::Higgs){ return tree_kin_Higgs_first(ev); } if(ev.outgoing().back().type == pid::Higgs){ return tree_kin_Higgs_last(ev); } return tree_kin_Higgs_between(ev); } namespace { // Colour acceleration multipliers, for gluons see eq. (7) in arXiv:0910.5113 #ifdef HEJ_BUILD_WITH_QCDLOOP double K( ParticleID type, CLHEP::HepLorentzVector const & pout, CLHEP::HepLorentzVector const & pin ){ if(type == pid::gluon) return currents::K_g(pout, pin); return C_F; } #endif // Colour factor in strict MRK limit double K_MRK(ParticleID type) { return (type == pid::gluon)?C_A:C_F; } } // namespace double MatrixElement::MH2_forwardH( CLHEP::HepLorentzVector const & p1out, CLHEP::HepLorentzVector const & p1in, ParticleID type2, CLHEP::HepLorentzVector const & p2out, CLHEP::HepLorentzVector const & p2in, CLHEP::HepLorentzVector const & pH, double t1, double t2 ) const{ using namespace currents; ignore(p2out, p2in); const double shat = p1in.invariantMass2(p2in); const double vev = param_.ew_parameters.vev(); // gluon case #ifdef HEJ_BUILD_WITH_QCDLOOP if(!param_.Higgs_coupling.use_impact_factors){ return K(type2, p2out, p2in)*C_A*1./(16*M_PI*M_PI)*t1/t2*ME_Houtside_gq( p1out, p1in, p2out, p2in, pH, param_.Higgs_coupling.mt, param_.Higgs_coupling.include_bottom, param_.Higgs_coupling.mb, vev )/(4*(N_C*N_C - 1)); } #endif return K_MRK(type2)/C_A*9./2.*shat*shat*( C2gHgp(p1in,p1out,pH,vev) + C2gHgm(p1in,p1out,pH,vev) )/(t1*t2); } double MatrixElement::tree_kin_Higgs_first(Event const & ev) const { auto const & incoming = ev.incoming(); auto const & outgoing = ev.outgoing(); assert(outgoing.front().type == pid::Higgs); if(outgoing[1].type != pid::gluon) { assert(incoming.front().type == outgoing[1].type); return tree_kin_Higgs_between(ev); } const auto pH = to_HepLorentzVector(outgoing.front()); const auto partons = tag_extremal_jet_partons( ev ); const auto pa = to_HepLorentzVector(incoming[0]); const auto pb = to_HepLorentzVector(incoming[1]); const auto p1 = to_HepLorentzVector(partons.front()); const auto pn = to_HepLorentzVector(partons.back()); const auto q0 = pa - p1 - pH; const double t1 = q0.m2(); const double t2 = (pn - pb).m2(); return MH2_forwardH( p1, pa, incoming[1].type, pn, pb, pH, t1, t2 )*FKL_ladder_weight( begin(partons) + 1, end(partons) - 1, q0, pa, pb, p1, pn, param_.regulator_lambda ); } double MatrixElement::tree_kin_Higgs_last(Event const & ev) const { auto const & incoming = ev.incoming(); auto const & outgoing = ev.outgoing(); assert(outgoing.back().type == pid::Higgs); if(outgoing[outgoing.size()-2].type != pid::gluon) { assert(incoming.back().type == outgoing[outgoing.size()-2].type); return tree_kin_Higgs_between(ev); } const auto pH = to_HepLorentzVector(outgoing.back()); const auto partons = tag_extremal_jet_partons( ev ); const auto pa = to_HepLorentzVector(incoming[0]); const auto pb = to_HepLorentzVector(incoming[1]); auto p1 = to_HepLorentzVector(partons.front()); const auto pn = to_HepLorentzVector(partons.back()); auto q0 = pa - p1; const double t1 = q0.m2(); const double t2 = (pn + pH - pb).m2(); return MH2_forwardH( pn, pb, incoming[0].type, p1, pa, pH, t2, t1 )*FKL_ladder_weight( begin(partons) + 1, end(partons) - 1, q0, pa, pb, p1, pn, param_.regulator_lambda ); } namespace { template double tree_kin_Higgs_uno(InIter BeginIn, InIter EndIn, partIter BeginPart, partIter EndPart, CLHEP::HepLorentzVector const & qH, CLHEP::HepLorentzVector const & qHp1, double mt, bool inc_bot, double mb, double vev ){ const auto pa = to_HepLorentzVector(*BeginIn); const auto pb = to_HepLorentzVector(*(EndIn-1)); const auto pg = to_HepLorentzVector(*BeginPart); const auto p1 = to_HepLorentzVector(*(BeginPart+1)); const auto pn = to_HepLorentzVector(*(EndPart-1)); return ME_Higgs_current_uno( (BeginIn)->type, (EndIn-1)->type, pg, pn, pb, p1, pa, qH, qHp1, mt, inc_bot, mb, vev ); } } // namespace double MatrixElement::tree_kin_Higgs_between(Event const & ev) const { using namespace event_type; auto const & incoming = ev.incoming(); auto const & outgoing = ev.outgoing(); const auto the_Higgs = std::find_if( begin(outgoing), end(outgoing), [](Particle const & s){ return s.type == pid::Higgs; } ); assert(the_Higgs != end(outgoing)); const auto pH = to_HepLorentzVector(*the_Higgs); const auto partons = tag_extremal_jet_partons(ev); const auto pa = to_HepLorentzVector(incoming[0]); const auto pb = to_HepLorentzVector(incoming[1]); auto p1 = to_HepLorentzVector( partons[(ev.type() == unob)?1:0] ); auto pn = to_HepLorentzVector( partons[partons.size() - ((ev.type() == unof)?2:1)] ); auto first_after_Higgs = begin(partons) + (the_Higgs-begin(outgoing)); assert( (first_after_Higgs == end(partons) && ( (ev.type() == unob) || partons.back().type != pid::gluon )) || first_after_Higgs->rapidity() >= the_Higgs->rapidity() ); assert( (first_after_Higgs == begin(partons) && ( (ev.type() == unof) || partons.front().type != pid::gluon )) || (first_after_Higgs-1)->rapidity() <= the_Higgs->rapidity() ); // always treat the Higgs as if it were in between the extremal FKL partons if(first_after_Higgs == begin(partons)) ++first_after_Higgs; else if(first_after_Higgs == end(partons)) --first_after_Higgs; // t-channel momentum before Higgs auto qH = pa; for(auto parton_it = begin(partons); parton_it != first_after_Higgs; ++parton_it){ qH -= to_HepLorentzVector(*parton_it); } auto q0 = pa - p1; auto begin_ladder = begin(partons) + 1; auto end_ladder = end(partons) - 1; double current_factor = NAN; if(ev.type() == FKL){ current_factor = ME_Higgs_current( incoming[0].type, incoming[1].type, pn, pb, p1, pa, qH, qH - pH, param_.Higgs_coupling.mt, param_.Higgs_coupling.include_bottom, param_.Higgs_coupling.mb, param_.ew_parameters.vev() ); } else if(ev.type() == unob){ current_factor = C_A*C_A/2*tree_kin_Higgs_uno( begin(incoming), end(incoming), begin(partons), end(partons), qH, qH-pH, param_.Higgs_coupling.mt, param_.Higgs_coupling.include_bottom, param_.Higgs_coupling.mb, param_.ew_parameters.vev() ); const auto p_unob = to_HepLorentzVector(partons.front()); q0 -= p_unob; p1 += p_unob; ++begin_ladder; } else if(ev.type() == unof){ current_factor = C_A*C_A/2*tree_kin_Higgs_uno( rbegin(incoming), rend(incoming), rbegin(partons), rend(partons), qH-pH, qH, param_.Higgs_coupling.mt, param_.Higgs_coupling.include_bottom, param_.Higgs_coupling.mb, param_.ew_parameters.vev() ); pn += to_HepLorentzVector(partons.back()); --end_ladder; } else{ throw std::logic_error("Can only reweight FKL or uno processes in H+Jets"); } const double ladder_factor = FKL_ladder_weight( begin_ladder, first_after_Higgs, q0, pa, pb, p1, pn, param_.regulator_lambda )*FKL_ladder_weight( first_after_Higgs, end_ladder, qH - pH, pa, pb, p1, pn, param_.regulator_lambda ); return current_factor*C_A*C_A/(N_C*N_C-1.)*ladder_factor; } namespace { double get_AWZH_coupling(Event const & ev, double alpha_s, double alpha_w) { std::vector bosons = filter_AWZH_bosons(ev.outgoing()); if(bosons.empty()) { return 1.; } if(bosons.size() == 1) { switch(bosons[0].type){ case pid::Higgs: return alpha_s*alpha_s; case pid::Wp: case pid::Wm: return alpha_w*alpha_w; case pid::Z_photon_mix: return alpha_w*alpha_w; // TODO case pid::photon: case pid::Z: default: throw not_implemented("Emission of boson of unsupported type"); } } if(bosons.size() == 2) { if(bosons[0].type == pid::Wp && bosons[1].type == pid::Wp) { return alpha_w*alpha_w*alpha_w*alpha_w; } throw not_implemented("Emission of bosons of unsupported type"); } throw not_implemented("Emission of >2 bosons is unsupported"); } } // namespace double MatrixElement::tree_param(Event const & ev, double mur) const { assert(is_resummable(ev.type())); const auto begin_partons = ev.begin_partons(); const auto end_partons = ev.end_partons(); const auto num_partons = std::distance(begin_partons, end_partons); const double alpha_s = alpha_s_(mur); const double gs2 = 4.*M_PI*alpha_s; double res = std::pow(gs2, num_partons); if(param_.log_correction){ // use alpha_s(q_perp), evolved to mur assert(num_partons >= 2); const auto first_emission = std::next(begin_partons); const auto last_emission = std::prev(end_partons); for(auto parton = first_emission; parton != last_emission; ++parton){ res *= 1. + alpha_s/(2.*M_PI)*BETA0*std::log(mur/parton->perp()); } } return get_AWZH_coupling(ev, alpha_s, param_.ew_parameters.alpha_w())*res; } } // namespace HEJ diff --git a/src/WWjets.cc b/src/WWjets.cc new file mode 100644 index 0000000..4b6f168 --- /dev/null +++ b/src/WWjets.cc @@ -0,0 +1,90 @@ +/** + * \authors The HEJ collaboration (see AUTHORS for details) + * \date 2020 + * \copyright GPLv2 or later + */ +#include "HEJ/WWjets.hh" + +#include +#include +#include +#include +#include + +#include "HEJ/Constants.hh" +#include "HEJ/EWConstants.hh" +#include "HEJ/LorentzVector.hh" +#include "HEJ/exceptions.hh" +#include "HEJ/jets.hh" + +// generated headers +#include "HEJ/currents/jV_jV.hh" + +namespace HEJ { +namespace currents { + + namespace { + using std::conj; + + // W Propagator + double WProp(const HLV & plbar, const HLV & pl, + ParticleProperties const & wprop + ){ + COM propW = COM(0.,-1.)/( (pl+plbar).m2() - wprop.mass*wprop.mass + + COM(0.,1.)*wprop.mass*wprop.width); + double PropFactor=(propW*conj(propW)).real(); + return PropFactor; + } + //! WW+Jets FKL Contributions + /** + * @brief WW+Jets Currents + * @param p1out Outgoing Particle 1 (W1 emission) + * @param pl1bar Outgoing anti-lepton 1 momenta + * @param pl1 Outgoing lepton 1 momenta + * @param p1in Incoming Particle 1 (W1 emission) + * @param p2out Outgoing Particle 2 (W2 emission) + * @param pl2bar Outgoing anti-lepton 2 momenta + * @param pl2 Outgoing lepton 2 momenta + * @param p2in Incoming Particle 2 (W2 emission) + * @param aqlineb Bool. Is Backwards quark line an anti-quark line? + * @param aqlinef Bool. Is Forwards quark line an anti-quark line? + * + * Calculates jW^\mu jW_\mu + */ + double jW_jW( + HLV const & p1out, HLV pl1bar, HLV pl1, HLV const & p1in, + HLV const & p2out, HLV pl2bar, HLV pl2, HLV const & p2in, + bool aqlineb, bool aqlinef, + ParticleProperties const & wprop + ){ + using helicity::minus; + using helicity::plus; + HLV const q1 = (p1in-p1out-pl1bar-pl1); + HLV const q2 = -(p2in-p2out-pl2bar-pl2); + + double const wProp1 = WProp(pl1bar, pl1, wprop); + double const wProp2 = WProp(pl2bar, pl2, wprop); + + if(aqlineb) std::swap(pl1, pl1bar); + if(aqlinef) std::swap(pl2, pl2bar); + + COM const amp = jV_jV(p1in,p1out,p2in,p2out,pl1,pl1bar,pl2,pl2bar); + + double const Msqr = std::norm(amp); + + // Division by colour and Helicity average (Nc2-1)(4) + // Multiply by Cf^2 + return C_F*C_F*wProp1*wProp2*Msqr/(q1.m2()*q2.m2()*(N_C*N_C - 1)*4); + } + } + + double ME_WW_qQ( + HLV const & p1out, HLV pl1bar, HLV pl1, HLV const & p1in, + HLV const & p2out, HLV pl2bar, HLV pl2, HLV const & p2in, + ParticleProperties const & wprop + ){ + return jW_jW(p1out, pl1bar, pl1, p1in, p2out, pl2bar, pl2, p2in, false, false, wprop); + } + +} // namespace currents +} // namespace HEJ