Page Menu
Home
HEPForge
Search
Configure Global Search
Log In
Files
F7879016
No One
Temporary
Actions
View File
Edit File
Delete File
View Transforms
Subscribe
Mute Notifications
Award Token
Flag For Later
Size
116 KB
Subscribers
None
View Options
diff --git a/MatrixElement/EW/ElectroWeakReweighter.cc b/MatrixElement/EW/ElectroWeakReweighter.cc
--- a/MatrixElement/EW/ElectroWeakReweighter.cc
+++ b/MatrixElement/EW/ElectroWeakReweighter.cc
@@ -1,1985 +1,1989 @@
// -*- C++ -*-
//
// This is the implementation of the non-inlined, non-templated member
// functions of the ElectroWeakReweighter class.
//
#include "ElectroWeakReweighter.h"
#include "ThePEG/Interface/ClassDocumentation.h"
#include "ThePEG/Interface/Reference.h"
#include "ThePEG/Interface/Switch.h"
#include "ThePEG/EventRecord/Particle.h"
#include "ThePEG/Repository/UseRandom.h"
#include "ThePEG/Repository/EventGenerator.h"
#include "ThePEG/Utilities/DescribeClass.h"
#include "ThePEG/Persistency/PersistentOStream.h"
#include "ThePEG/Persistency/PersistentIStream.h"
#include "boost/numeric/ublas/matrix.hpp"
#include "boost/numeric/ublas/operation.hpp"
#include "EWProcess.h"
#include "HighEnergyMatching.h"
#include "ElectroWeakMatching.h"
#include "ThePEG/Helicity/WaveFunction/SpinorWaveFunction.h"
#include "ThePEG/Helicity/WaveFunction/SpinorBarWaveFunction.h"
#include "ThePEG/Helicity/WaveFunction/VectorWaveFunction.h"
#include "ThePEG/Helicity/epsilon.h"
#include "Herwig/MatrixElement/Matchbox/Base/SubtractedME.h"
#include "Herwig/MatrixElement/Matchbox/MatchboxFactory.h"
#include "ThePEG/Handlers/StandardXComb.h"
using namespace Herwig;
tEWCouplingsPtr ElectroWeakReweighter::staticEWCouplings_ = tEWCouplingsPtr();
ElectroWeakReweighter::ElectroWeakReweighter() : testing_(false)
{}
ElectroWeakReweighter::~ElectroWeakReweighter() {}
IBPtr ElectroWeakReweighter::clone() const {
return new_ptr(*this);
}
IBPtr ElectroWeakReweighter::fullclone() const {
return new_ptr(*this);
}
void ElectroWeakReweighter::persistentOutput(PersistentOStream & os) const {
os << EWCouplings_ << collinearSudakov_ << softSudakov_ << testing_;
}
void ElectroWeakReweighter::persistentInput(PersistentIStream & is, int) {
is >> EWCouplings_ >> collinearSudakov_ >> softSudakov_ >> testing_;
}
// The following static variable is needed for the type
// description system in ThePEG.
DescribeClass<ElectroWeakReweighter,ReweightBase>
describeHerwigElectroWeakReweighter("Herwig::ElectroWeakReweighter", "HwMEEW.so");
void ElectroWeakReweighter::Init() {
static ClassDocumentation<ElectroWeakReweighter> documentation
("There is no documentation for the ElectroWeakReweighter class");
static Reference<ElectroWeakReweighter,EWCouplings> interfaceEWCouplings
("EWCouplings",
"The object to calculate the electroweak couplings",
&ElectroWeakReweighter::EWCouplings_, false, false, true, false, false);
static Reference<ElectroWeakReweighter,CollinearSudakov> interfaceCollinearSudakov
("CollinearSudakov",
"The collinear Sudakov",
&ElectroWeakReweighter::collinearSudakov_, false, false, true, false, false);
static Reference<ElectroWeakReweighter,SoftSudakov> interfaceSoftSudakov
("SoftSudakov",
"The soft Sudakov",
&ElectroWeakReweighter::softSudakov_, false, false, true, false, false);
static Switch<ElectroWeakReweighter,bool> interfaceTesting
("Testing",
"Whether or not to output testing information",
&ElectroWeakReweighter::testing_, false, false, false);
static SwitchOption interfaceTestingYes
(interfaceTesting,
"Yes",
"Output the information",
true);
static SwitchOption interfaceTestingNo
(interfaceTesting,
"No",
"Don't output the information",
false);
}
void ElectroWeakReweighter::doinit() {
ReweightBase::doinit();
if(!testing_) return;
// testing output
cerr << "aEM\n";
for(Energy scale=10.*GeV; scale<10*TeV; scale *= 1.1) {
cerr << scale/GeV << " "
<< EWCouplings_->aEM(scale) << "\n";
}
cerr << "aS\n";
for(Energy scale=10.*GeV; scale<10*TeV; scale *= 1.4) {
cerr << scale/GeV << " "
<< EWCouplings_->aS(scale) << "\n";
}
cerr << "y_t\n";
for(Energy scale=10.*GeV; scale<10*TeV; scale *= 1.4) {
cerr << scale/GeV << " "
<< EWCouplings_->y_t(scale) << "\n";
}
cerr << "lambda\n";
for(Energy scale=91.2*GeV; scale<10*TeV; scale *= 1.4) {
cerr << scale/GeV << " "
<< EWCouplings_->lambda(scale) << "\n";
}
cerr << "vev\n";
for(Energy scale=91.2*GeV; scale<10*TeV; scale *= 1.4) {
cerr << scale/GeV << " "
<< EWCouplings_->vev(scale)/GeV << "\n";
}
collinearSudakov_->makePlots();
Energy2 s = sqr(5000.*GeV);
Energy2 t = -0.25*s;
Energy2 u = -0.75*s;
testEvolution(s,t,u);
}
namespace {
#ifdef ThePEG_HAS_UNITS_CHECKING
void axpy_prod_local(const boost::numeric::ublas::matrix<Complex> & A,
const boost::numeric::ublas::matrix<complex<InvEnergy2> > & B,
boost::numeric::ublas::matrix<complex<InvEnergy2> > & C) {
assert(A.size2()==B.size1());
C.resize(A.size1(),B.size2());
for(unsigned int ix=0;ix<A.size1();++ix) {
for(unsigned int iy=0;iy<B.size2();++iy) {
C(ix,iy) = ZERO;
for(unsigned int iz=0;iz<A.size2();++iz) {
C(ix,iy) += A(ix,iz)*B(iz,iy);
}
}
}
}
void axpy_prod_local(const boost::numeric::ublas::matrix<complex<InvEnergy2> > & A,
const boost::numeric::ublas::vector<complex<Energy2> > & B,
boost::numeric::ublas::vector<Complex > & C) {
assert(A.size2()==B.size());
C.resize(A.size1());
for(unsigned int ix=0;ix<A.size1();++ix) {
C(ix) = ZERO;
for(unsigned int iz=0;iz<A.size2();++iz) {
C(ix) += A(ix,iz)*B(iz);
}
}
}
void axpy_prod_local(const boost::numeric::ublas::matrix<complex<InvEnergy2> > & A,
const boost::numeric::ublas::matrix<Complex> & B,
boost::numeric::ublas::matrix<complex<InvEnergy2> > & C) {
assert(A.size2()==B.size1());
C.resize(A.size1(),B.size2());
for(unsigned int ix=0;ix<A.size1();++ix) {
for(unsigned int iy=0;iy<B.size2();++iy) {
C(ix,iy) = ZERO;
for(unsigned int iz=0;iz<A.size2();++iz) {
C(ix,iy) += A(ix,iz)*B(iz,iy);
}
}
}
}
#else
void axpy_prod_local(const boost::numeric::ublas::matrix<Complex> & A,
const boost::numeric::ublas::matrix<Complex> & B,
boost::numeric::ublas::matrix<Complex> & C) {
+ assert(A.size2()==B.size1());
+ C.resize(A.size1(),B.size2());
axpy_prod(A,B,C);
}
void axpy_prod_local(const boost::numeric::ublas::matrix<Complex> & A,
const boost::numeric::ublas::vector<Complex> & B,
boost::numeric::ublas::vector<Complex> & C) {
+ assert(A.size2()==B.size());
+ C.resize(A.size1());
axpy_prod(A,B,C);
}
#endif
}
double ElectroWeakReweighter::weight() const {
EWCouplings_->initialize();
staticEWCouplings_ = EWCouplings_;
// cast the XComb
Ptr<StandardXComb>::ptr sxc = dynamic_ptr_cast<Ptr<StandardXComb>::ptr>(lastXCombPtr());
// if the Herwig XComb
if(sxc) {
// get information about the type of event
Ptr<SubtractedME>::tptr subme = dynamic_ptr_cast<Ptr<SubtractedME>::tptr>(sxc->matrixElement());
Ptr<MatchboxMEBase>::tptr me = dynamic_ptr_cast<Ptr<MatchboxMEBase>::tptr>(sxc->matrixElement());
Ptr<SubtractionDipole>::tptr dipme = dynamic_ptr_cast<Ptr<SubtractionDipole>::tptr>(sxc->matrixElement());
bool isHEvent(false),isSEvent(false);
if(subme) {
if ( subme->realShowerSubtraction() )
isHEvent = true;
else if ( subme->virtualShowerSubtraction() || subme->loopSimSubtraction() )
isSEvent = true;
}
// H or S event of virtual return 1.
if(isHEvent || isSEvent || (me && me->oneLoopNoBorn()))
return 1.;
// cerr << "testing after type check\n";
// cerr << "testing pointers " << subme << " " << me << " " << dipme << "\n";
// cerr << "testing event type " << isHEvent << " " << isSEvent << " " << "\n";
// if(subme) cerr << subme->fullName() << "\n";
// if( me) {
// cerr << me->fullName() << "\n";
// cerr << me->oneLoopNoBorn() << " " << me->oneLoopNoLoops() << "\n";
// }
// if(dipme) cerr << dipme->fullName() << "\n";
}
// cerr << subProcess() << "\n";
// cerr << *subProcess() << "\n";
// only 2->2 processes
if(subProcess()->outgoing().size()!=2) return 1.;
// processes with gg initial-state
if(subProcess()->incoming().first->id()==ParticleID::g &&
subProcess()->incoming().second->id()==ParticleID::g) {
if(subProcess()->outgoing()[0]->id()==ParticleID::g &&
subProcess()->outgoing()[1]->id()==ParticleID::g)
return 1.;
else if(abs(subProcess()->outgoing()[0]->id())<=6 &&
subProcess()->outgoing()[0]->id()==-subProcess()->outgoing()[1]->id()) {
return reweightggqqbar();
}
else
assert(false);
}
// processes with q qbar initial-state
else if((subProcess()->incoming().first ->id() > 0 &&
subProcess()->incoming().first ->id()<= 5 &&
subProcess()->incoming().second->id() < 0 &&
subProcess()->incoming().second->id()>=-5) ||
(subProcess()->incoming().second->id() > 0 &&
subProcess()->incoming().second->id()<= 5 &&
subProcess()->incoming().first ->id() < 0 &&
subProcess()->incoming().first ->id()>=-5)) {
// identical flavour q qbar
if(subProcess()->incoming().first ->id() == -subProcess()->incoming().second->id()) {
// q qbar -> gg
if(subProcess()->outgoing()[0]->id()==ParticleID::g &&
subProcess()->outgoing()[1]->id()==ParticleID::g)
return reweightqqbargg();
// q qbar -> q' q'bar
else if(subProcess()->outgoing()[0]->id() == -subProcess()->outgoing()[1]->id() &&
abs(subProcess()->outgoing()[0]->id())<=6)
return reweightqqbarqqbarS();
}
// different flavour q qbar
else {
if((subProcess()->outgoing()[0]->id() > 0 &&
subProcess()->outgoing()[0]->id()<= 5 &&
subProcess()->outgoing()[1]->id() < 0 &&
subProcess()->outgoing()[1]->id()>=-5) ||
(subProcess()->outgoing()[1]->id() > 0 &&
subProcess()->outgoing()[1]->id()<= 5 &&
subProcess()->outgoing()[0]->id() < 0 &&
subProcess()->outgoing()[0]->id()>=-5)) {
return reweightqqbarqqbarT();
}
else
assert(false);
}
}
// processes with q g initial-state
else if((subProcess()->incoming().first ->id()> 0 &&
subProcess()->incoming().first ->id()<=5 &&
subProcess()->incoming().second->id()==ParticleID::g) ||
(subProcess()->incoming().second->id()> 0 &&
subProcess()->incoming().second->id()<=5 &&
subProcess()->incoming().first ->id()==ParticleID::g)) {
// qg -> qg
if((subProcess()->outgoing()[0]->id()> 0 &&
subProcess()->outgoing()[0]->id()<=5 &&
subProcess()->outgoing()[1]->id()==ParticleID::g) ||
(subProcess()->outgoing()[1]->id()> 0 &&
subProcess()->outgoing()[1]->id()<=5 &&
subProcess()->outgoing()[0]->id()==ParticleID::g))
return reweightqgqg();
// unknown
else
assert(false);
}
// processes with qbar g initial-state
else if((subProcess()->incoming().first ->id()>=-5 &&
subProcess()->incoming().first ->id()< 0 &&
subProcess()->incoming().second->id()==ParticleID::g) ||
(subProcess()->incoming().second->id()>=-5 &&
subProcess()->incoming().second->id()< 0 &&
subProcess()->incoming().first ->id()==ParticleID::g)) {
if((subProcess()->outgoing()[0]->id()>=-5 &&
subProcess()->outgoing()[0]->id()< 0 &&
subProcess()->outgoing()[1]->id()==ParticleID::g) ||
(subProcess()->outgoing()[1]->id()>=-5 &&
subProcess()->outgoing()[1]->id()< 0 &&
subProcess()->outgoing()[0]->id()==ParticleID::g))
return reweightqbargqbarg();
else
assert(false);
}
// processes with q q initial-state
else if( subProcess()->incoming().first ->id()> 0 &&
subProcess()->incoming().first ->id()<=5 &&
subProcess()->incoming().second->id()> 0 &&
subProcess()->incoming().second->id()<=5 ) {
if(subProcess()->outgoing()[0]->id()> 0 &&
subProcess()->outgoing()[0]->id()<=5 &&
subProcess()->outgoing()[1]->id()> 0 &&
subProcess()->outgoing()[1]->id()<=5)
return reweightqqqq();
else
assert(false);
}
// processes with qbar qbar initial-state
else if( subProcess()->incoming().first ->id()< 0 &&
subProcess()->incoming().first ->id()>= -5 &&
subProcess()->incoming().second->id()< 0 &&
subProcess()->incoming().second->id()>= -5 ) {
if(subProcess()->outgoing()[0]->id()< 0 &&
subProcess()->outgoing()[0]->id()>= -5 &&
subProcess()->outgoing()[1]->id()< 0 &&
subProcess()->outgoing()[1]->id()>= -5)
return reweightqbarqbarqbarqbar();
else
assert(false);
}
// unknown initial-state
else
assert(false);
assert(false);
staticEWCouplings_ = tEWCouplingsPtr();
}
void ElectroWeakReweighter::testEvolution(Energy2 s,Energy2 t, Energy2 u) const {
Energy highScale = sqrt(s);
Energy ewScale = coupling()->mZ();
Energy lowScale = 50.0*GeV;
for (unsigned int i=0; i<45;++i) {
EWProcess::Process process = (EWProcess::Process)i;
cerr << "process " << process << "\n";
// result for all EW and QCD SCET contributions:
boost::numeric::ublas::matrix<complex<InvEnergy2> > highMatch_val
= HighEnergyMatching::highEnergyMatching(highScale,s,t,u,process,true,true);
boost::numeric::ublas::matrix<Complex> highRunning_val
= softSudakov_->highEnergyRunning(highScale,ewScale,s,t,u,process,0);
boost::numeric::ublas::matrix<Complex> ewMatch_val =
ElectroWeakMatching::electroWeakMatching(ewScale,s,t,u,process,true,0);
boost::numeric::ublas::matrix<Complex> lowRunning_val =
softSudakov_->lowEnergyRunning(ewScale,lowScale,s,t,u,process,0);
boost::numeric::ublas::matrix<Complex> collinearHighRunning_val =
collinearSudakov_->highEnergyRunning(highScale,ewScale,s,process,false);
boost::numeric::ublas::matrix<Complex> collinearEWMatch_val =
collinearSudakov_->electroWeakMatching(ewScale,s,process,true);
boost::numeric::ublas::matrix<Complex> collinearLowRunning_val =
collinearSudakov_->lowEnergyRunning(ewScale,lowScale,s,process);
boost::numeric::ublas::matrix<Complex> lowMatchTemp_val =
boost::numeric::ublas::zero_matrix<Complex>(ewMatch_val.size1(),ewMatch_val.size2());
for (unsigned int ii=0; ii<ewMatch_val.size1(); ++ii) {
for (unsigned int jj=0; jj<ewMatch_val.size2(); ++jj) {
lowMatchTemp_val(ii,jj) = collinearEWMatch_val(ii,jj)*ewMatch_val(ii,jj);
}
}
boost::numeric::ublas::matrix<Complex> temp(highRunning_val.size1(),collinearHighRunning_val.size2());
boost::numeric::ublas::axpy_prod(highRunning_val,collinearHighRunning_val,temp);
boost::numeric::ublas::matrix<Complex> temp2(collinearLowRunning_val.size1(),lowRunning_val.size2());
boost::numeric::ublas::axpy_prod(collinearLowRunning_val,lowRunning_val,temp2);
boost::numeric::ublas::matrix<Complex> temp3(temp2.size1(),lowMatchTemp_val.size2());
boost::numeric::ublas::axpy_prod(temp2,lowMatchTemp_val,temp3);
temp2.resize(temp3.size1(),temp.size2());
boost::numeric::ublas::axpy_prod(temp3,temp,temp2);
boost::numeric::ublas::matrix<complex<InvEnergy2> > result(temp2.size1(),highMatch_val.size2());
axpy_prod_local(temp2,highMatch_val,result);
for(unsigned int ix=0;ix<result.size1();++ix) {
for(unsigned int iy=0;iy<result.size2();++iy) {
cerr << s*result(ix,iy) << " ";
}
cerr << "\n";
}
}
}
namespace {
void SackGluonPolarizations(Lorentz5Momentum &p1,
Lorentz5Momentum &p2,
Lorentz5Momentum &p3,
Lorentz5Momentum &p4,
Energy2 s, Energy2 t, Energy2 u, Energy2 m2,
vector<LorentzVector<Complex> > & eps3,
vector<LorentzVector<Complex> > & eps4,
unsigned int iopt) {
static const Complex I(0.,1.);
// p1 is p-, p2 is p+
// p3 is k-, p4 is k+
// both final-state
if(iopt==0) {
// swap t and u due Aneesh's defn
Energy3 den1 = sqrt((u*t-sqr(m2))*(s-4.*m2));
Energy3 den2 = sqrt(s*(u*t-sqr(m2)));
LorentzVector<Complex> eps3Para = (m2+t)/den1*p1 -(m2+u)/den1*p2 +(u-t)/den1*p3;
LorentzVector<Complex> eps3Perp = 2./den2*epsilon(p1,p2,p3);
LorentzVector<Complex> eps4Para = (m2+t)/den1*p2 -(m2+u)/den1*p1 +(u-t)/den1*p4;
LorentzVector<Complex> eps4Perp = 2./den2*epsilon(p1,p2,p4);
eps3.push_back(sqrt(0.5)*(eps3Para+I*eps3Perp));
eps3.push_back(sqrt(0.5)*(eps3Para-I*eps3Perp));
eps4.push_back(sqrt(0.5)*(eps4Para+I*eps4Perp));
eps4.push_back(sqrt(0.5)*(eps4Para-I*eps4Perp));
if(m2!=ZERO) assert(false);
}
// both initial-state
else if(iopt==1) {
if(m2!=ZERO) assert(false);
LorentzVector<Complex> eps3Para( 1., 0.,0.,0.);
LorentzVector<Complex> eps3Perp( 0.,-1.,0.,0.);
LorentzVector<Complex> eps4Para(-1.,0.,0., 0.);
LorentzVector<Complex> eps4Perp( 0., 1.,0.,0.);
eps3.push_back(sqrt(0.5)*(eps3Para+I*eps3Perp));
eps3.push_back(sqrt(0.5)*(eps3Para-I*eps3Perp));
eps4.push_back(sqrt(0.5)*(eps4Para+I*eps4Perp));
eps4.push_back(sqrt(0.5)*(eps4Para-I*eps4Perp));
}
else if(iopt==2) {
// rotation into the 2,3 Breit frame
Lorentz5Momentum pa = p3-p2;
Axis axis(pa.vect().unit());
LorentzRotation rot;
double sinth(sqrt(sqr(axis.x())+sqr(axis.y())));
if ( sinth > 1.e-9 )
rot.setRotate(-acos(axis.z()),Axis(-axis.y()/sinth,axis.x()/sinth,0.));
rot.rotateX(Constants::pi);
rot.boostZ( pa.e()/pa.vect().mag());
Lorentz5Momentum ptemp=rot*p2;
Boost trans = -1./ptemp.e()*ptemp.vect();
trans.setZ(0.);
rot.boost(trans);
LorentzVector<Complex> eps3Para( 1., 0.,0.,0.);
LorentzVector<Complex> eps3Perp( 0.,-1.,0.,0.);
LorentzVector<Complex> eps4Para(-1.,0.,0., 0.);
LorentzVector<Complex> eps4Perp( 0., 1.,0.,0.);
eps3.push_back(sqrt(0.5)*(eps3Para+I*eps3Perp));
eps3.push_back(sqrt(0.5)*(eps3Para-I*eps3Perp));
eps4.push_back(sqrt(0.5)*(eps4Para+I*eps4Perp));
eps4.push_back(sqrt(0.5)*(eps4Para-I*eps4Perp));
rot = rot.invert();
for(unsigned int ix=0;ix<2;++ix) {
eps3[ix] *=rot;
eps4[ix] *=rot;
}
}
else if(iopt==3) {
// rotation into the 1,4 Breit frame
Lorentz5Momentum pa = p4-p1;
Axis axis(pa.vect().unit());
LorentzRotation rot;
double sinth(sqrt(sqr(axis.x())+sqr(axis.y())));
if ( sinth > 1.e-9 )
rot.setRotate(-acos(axis.z()),Axis(-axis.y()/sinth,axis.x()/sinth,0.));
rot.rotateX(Constants::pi);
rot.boostZ( pa.e()/pa.vect().mag());
Lorentz5Momentum ptemp=rot*p1;
Boost trans = -1./ptemp.e()*ptemp.vect();
trans.setZ(0.);
rot.boost(trans);
LorentzVector<Complex> eps3Para( 1., 0.,0.,0.);
LorentzVector<Complex> eps3Perp( 0.,-1.,0.,0.);
LorentzVector<Complex> eps4Para(-1.,0.,0., 0.);
LorentzVector<Complex> eps4Perp( 0., 1.,0.,0.);
eps3.push_back(sqrt(0.5)*(eps3Para+I*eps3Perp));
eps3.push_back(sqrt(0.5)*(eps3Para-I*eps3Perp));
eps4.push_back(sqrt(0.5)*(eps4Para+I*eps4Perp));
eps4.push_back(sqrt(0.5)*(eps4Para-I*eps4Perp));
rot = rot.invert();
for(unsigned int ix=0;ix<2;++ix) {
eps3[ix] *=rot;
eps4[ix] *=rot;
}
}
else
assert(false);
}
}
double ElectroWeakReweighter::reweightqqbargg() const {
// momenta and invariants
Lorentz5Momentum p1 = subProcess()->incoming().first ->momentum();
tcPDPtr q = subProcess()->incoming().first ->dataPtr();
Lorentz5Momentum p2 = subProcess()->incoming().second->momentum();
tcPDPtr qbar = subProcess()->incoming().second->dataPtr();
if(subProcess()->incoming().first->id()<0) {
swap(p1,p2 );
swap(q ,qbar);
}
Lorentz5Momentum p3 = subProcess()->outgoing()[0]->momentum();
Lorentz5Momentum p4 = subProcess()->outgoing()[1]->momentum();
tcPDPtr g = subProcess()->outgoing()[1]->dataPtr();
Energy2 s = (p1+p2).m2();
Energy2 t = (p1-p4).m2();
Energy2 u = (p1-p3).m2();
// boost to partonci rest frame
Lorentz5Momentum psum=p1+p2;
LorentzRotation boost(-psum.boostVector());
p1 *= boost;
p2 *= boost;
p3 *= boost;
p4 *= boost;
// LO and EW corrected matrix element coefficients
boost::numeric::ublas::matrix<complex<InvEnergy2> >
bornQQGGweights,bornRRGGweights,EWQQGGweights,EWRRGGweights;
// quark left doublet
if(q->id()!=5) {
bornQQGGweights = evaluateRunning(EWProcess::QQGG,s,t,u,true ,0);
EWQQGGweights = evaluateRunning(EWProcess::QQGG,s,t,u,false,0);
}
else {
bornQQGGweights = evaluateRunning(EWProcess::QtQtGG,s,t,u,true ,0);
EWQQGGweights = evaluateRunning(EWProcess::QtQtGG,s,t,u,false,0);
}
// quark right singlet
if(abs(subProcess()->incoming().first->id())%2==0) {
bornRRGGweights = evaluateRunning(EWProcess::UUGG,s,t,u,true ,0);
EWRRGGweights = evaluateRunning(EWProcess::UUGG,s,t,u,false,0);
}
else {
bornRRGGweights = evaluateRunning(EWProcess::DDGG,s,t,u,true ,0);
EWRRGGweights = evaluateRunning(EWProcess::DDGG,s,t,u,false,0);
}
SpinorWaveFunction qw(p1,q ,incoming);
SpinorBarWaveFunction qbarw(p2,qbar,incoming);
vector<LorentzVector<Complex> > eps3,eps4;
SackGluonPolarizations(p1,p2,p3,p4,s,t,u,ZERO,eps3,eps4,0);
boost::numeric::ublas::matrix<Complex>
bornME = boost::numeric::ublas::zero_matrix<Complex>(3,3),
EWME = boost::numeric::ublas::zero_matrix<Complex>(3,3);
for(unsigned int iq=0;iq<2;++iq) {
if(iq==0) {
qw.reset (0);
qbarw.reset(1);
}
else {
qw.reset (1);
qbarw.reset(0);
}
LorentzVector<complex<Energy> > current = iq==0 ?
qw.dimensionedWave(). leftCurrent(qbarw.dimensionedWave()) :
qw.dimensionedWave().rightCurrent(qbarw.dimensionedWave());
for(unsigned int i1=0;i1<2;++i1) {
complex<Energy> d31 = eps3[i1].dot(p1);
for(unsigned int i2=0;i2<2;++i2) {
// g1w.reset(2*i1);
// g2w.reset(2*i2);
boost::numeric::ublas::vector<complex<Energy2> > M(5);
Complex d34 = eps3[i1].dot(eps4[i2]);
complex<Energy> d42 = eps4[i2].dot(p2);
// M0 in paper
M(0) = qw.dimensionedWave().slash(eps3[i1])
.slash(p4-p2).vectorCurrent(qbarw.dimensionedWave()).dot(eps4[i2]);
// M4 in paper
M(2) = current.dot(eps4[i2])*d31;
// M5 in paper
M(3) = -current.dot(eps3[i1])*d42;
// M1 in paper (missing factor)
M(1) = current.dot(p4);
// M6 in paper
M(4) = M(1)*d31*d42/GeV2;
// M1 final factor
M(1) *= d34;
// coefficient of different contributions
boost::numeric::ublas::vector<Complex> Cborn(3),CEW(3),Ctest(3);
// Ctest(0) = 1./6.*( MEU+MET);
// Ctest(1) = 0.5*( MEU+MET);
// Ctest(2) = 0.5*(MEU+MES-MET+MES);
if(iq==0) {
axpy_prod_local(bornQQGGweights,M,Cborn);
axpy_prod_local(EWQQGGweights ,M,CEW );
}
else {
axpy_prod_local(bornRRGGweights,M,Cborn);
axpy_prod_local(EWRRGGweights ,M,CEW );
}
unsigned int ioff = (Cborn.size()==6 && q->id()%2!=0) ? 3 : 0;
for(unsigned int ix=0;ix<3;++ix) {
for(unsigned int iy=0;iy<3;++iy) {
bornME(ix,iy) += Cborn(ix+ioff)*conj(Cborn(iy+ioff));
EWME (ix,iy) += CEW (ix+ioff)*conj(CEW (iy+ioff));
}
}
}
}
}
double born = 24.*real(bornME(0,0))+20./3.*real(bornME(1,1))+12.*real(bornME(2,2));
double EW = 24.*real(EWME(0,0))+20./3.*real(EWME(1,1))+12.*real(EWME(2,2));
return EW/born;
}
boost::numeric::ublas::matrix<complex<InvEnergy2> >
ElectroWeakReweighter::evaluateRunning(EWProcess::Process process, Energy2 s,
Energy2 t, Energy2 u, bool born,
unsigned int iswap) const {
using namespace boost::numeric::ublas;
bool SU3save = coupling()->SU3();
bool EWsave = coupling()-> EW();
Energy highScale = sqrt(s);
Energy ewScale = coupling()->mZ();
Energy lowScale = ewScale;
// result for all EW and QCD SCET contributions:
// MATCHING CONTRIBUTIONS
// high energy matching
matrix<complex<InvEnergy2> > highMatch_val;
if(iswap==0)
highMatch_val = HighEnergyMatching::highEnergyMatching(highScale,s,t,u,process,!born,false);
else if(iswap==1)
highMatch_val = HighEnergyMatching::highEnergyMatching(highScale,t,s,u,process,!born,false);
else if(iswap==2)
highMatch_val = HighEnergyMatching::highEnergyMatching(highScale,u,t,s,process,!born,false);
else
assert(false);
// low energy matching
matrix<Complex>
ewMatch_val = ElectroWeakMatching::electroWeakMatching(ewScale,s,t,u,process,!born,iswap);
matrix<Complex> collinearEWMatch_val =
collinearSudakov_->electroWeakMatching(ewScale,s,process,!born);
// EVOLUTION
matrix<Complex> highRunning_val,lowRunning_val,
collinearHighRunning_val,collinearLowRunning_val;
// born process
if(born) {
highRunning_val = identity_matrix<Complex>(softSudakov_->numberGauge(process));
lowRunning_val = identity_matrix<Complex>(softSudakov_->numberBrokenGauge(process));
collinearHighRunning_val = identity_matrix<Complex>(softSudakov_->numberGauge(process));
collinearLowRunning_val = identity_matrix<Complex>(softSudakov_->numberBrokenGauge(process));
}
// EW corrected
else {
coupling()->SU3(false);
coupling()-> EW( true);
highRunning_val = softSudakov_->highEnergyRunning(highScale, ewScale,s,t,u,process,iswap);
lowRunning_val = softSudakov_->lowEnergyRunning ( ewScale,lowScale,s,t,u,process,iswap);
collinearHighRunning_val = collinearSudakov_->highEnergyRunning(highScale,ewScale,s,process,false);
collinearLowRunning_val = collinearSudakov_->lowEnergyRunning(ewScale,lowScale,s,process);
};
matrix<Complex> lowMatchTemp_val =
zero_matrix<Complex>(ewMatch_val.size1(),ewMatch_val.size2());
for (unsigned int ii=0; ii<ewMatch_val.size1(); ++ii) {
for (unsigned int jj=0; jj<ewMatch_val.size2(); ++jj) {
lowMatchTemp_val(ii,jj) = collinearEWMatch_val(ii,jj)*ewMatch_val(ii,jj);
}
}
// perform all the multiplications
matrix<Complex> temp(highRunning_val.size1(),collinearHighRunning_val.size2());
axpy_prod(highRunning_val,collinearHighRunning_val,temp);
matrix<Complex> temp2(collinearLowRunning_val.size1(),lowRunning_val.size2());
axpy_prod(collinearLowRunning_val,lowRunning_val,temp2);
matrix<Complex> temp3(temp2.size1(),lowMatchTemp_val.size2());
axpy_prod(temp2,lowMatchTemp_val,temp3);
temp2.resize(temp3.size1(),temp.size2());
axpy_prod(temp3,temp,temp2);
matrix<complex<InvEnergy2> > result(temp2.size1(),highMatch_val.size2());
axpy_prod_local(temp2,highMatch_val,result);
// reset the couplings
coupling()->SU3(SU3save);
coupling()-> EW( EWsave);
// return the answer
return result;
}
double ElectroWeakReweighter::reweightggqqbar() const {
// momenta and invariants
Lorentz5Momentum p1 = subProcess()->incoming().first ->momentum();
Lorentz5Momentum p2 = subProcess()->incoming().second->momentum();
Lorentz5Momentum p3 = subProcess()->outgoing()[0]->momentum();
Lorentz5Momentum p4 = subProcess()->outgoing()[1]->momentum();
tcPDPtr qbar = subProcess()->outgoing()[0]->dataPtr();
tcPDPtr q = subProcess()->outgoing()[1]->dataPtr();
if(q->id()<0) {
swap(p3,p4 );
swap(q ,qbar);
}
Energy2 s = (p1+p2).m2();
Energy2 t = (p1-p4).m2();
Energy2 u = (p1-p3).m2();
// boost to partonic rest frame and rescale momenta of outgoing
// so zero mass
Lorentz5Momentum psum=p1+p2;
LorentzRotation boost(-psum.boostVector());
p1 *= boost;
p2 *= boost;
p3 *= boost;
p4 *= boost;
p3.setMass(ZERO);
p3.rescaleRho();
p4.setMass(ZERO);
p4.rescaleRho();
// LO and EW matrix element coefficents
boost::numeric::ublas::matrix<complex<InvEnergy2> >
bornQQGGweights,bornRRGGweights,EWQQGGweights,EWRRGGweights;
// quark left doublet
if(q->id()<5) {
bornQQGGweights = evaluateRunning(EWProcess::QQGG,s,t,u,true ,0);
EWQQGGweights = evaluateRunning(EWProcess::QQGG,s,t,u,false,0);
}
else {
bornQQGGweights = evaluateRunning(EWProcess::QtQtGG,s,t,u,true ,0);
EWQQGGweights = evaluateRunning(EWProcess::QtQtGG,s,t,u,false,0);
}
// quark right singlet
if(q->id()==0) {
if(q->id()==6) {
bornRRGGweights = evaluateRunning(EWProcess::tRtRGG,s,t,u,true ,0);
EWRRGGweights = evaluateRunning(EWProcess::tRtRGG,s,t,u,false,0);
}
else {
bornRRGGweights = evaluateRunning(EWProcess::UUGG,s,t,u,true ,0);
EWRRGGweights = evaluateRunning(EWProcess::UUGG,s,t,u,false,0);
}
}
else {
bornRRGGweights = evaluateRunning(EWProcess::DDGG,s,t,u,true ,0);
EWRRGGweights = evaluateRunning(EWProcess::DDGG,s,t,u,false,0);
}
SpinorWaveFunction qw(p4,qbar,incoming);
SpinorBarWaveFunction qbarw(p3,q ,incoming);
vector<LorentzVector<Complex> > eps1,eps2;
SackGluonPolarizations(p1,p2,p3,p4,s,t,u,ZERO,eps1,eps2,1);
boost::numeric::ublas::matrix<Complex>
bornME = boost::numeric::ublas::zero_matrix<Complex>(3,3),
EWME = boost::numeric::ublas::zero_matrix<Complex>(3,3);
// helicities of outgoing quarks
for(unsigned int iq=0;iq<2;++iq) {
if(iq==0) {
qw.reset (0);
qbarw.reset(1);
}
else {
qw.reset (1);
qbarw.reset(0);
}
LorentzVector<complex<Energy> > current = iq==0 ?
qw.dimensionedWave(). leftCurrent(qbarw.dimensionedWave()) :
qw.dimensionedWave().rightCurrent(qbarw.dimensionedWave());
for(unsigned int i1=0;i1<2;++i1) {
complex<Energy> d31 = eps1[i1].dot(p3);
for(unsigned int i2=0;i2<2;++i2) {
boost::numeric::ublas::vector<complex<Energy2> > M(5);
Complex d34 = eps1[i1].dot(eps2[i2]);
complex<Energy> d42 = eps2[i2].dot(p4);
// M0 in paper
M(0) = qw.dimensionedWave().slash(eps1[i1])
.slash(p2-p4).vectorCurrent(qbarw.dimensionedWave()).dot(eps2[i2]);
// M4 in paper
M(2) = current.dot(eps2[i2])*d31;
// M5 in paper
M(3) = -current.dot(eps1[i1])*d42;
// M1 in paper (missing factor)
M(1) = current.dot(p2);
// M6 in paper
M(4) = M(1)*d31*d42/GeV2;
// M1 final factor
M(1) *= d34;
// coefficient of different contributions
boost::numeric::ublas::vector<Complex> Cborn(3),CEW(3);
if(iq==0) {
axpy_prod_local(bornQQGGweights,M,Cborn);
axpy_prod_local(EWQQGGweights ,M,CEW );
}
else {
axpy_prod_local(bornRRGGweights,M,Cborn);
axpy_prod_local(EWRRGGweights ,M,CEW );
}
unsigned int ioff = (Cborn.size()==6 && q->id()%2!=0) ? 3 : 0;
for(unsigned int ix=0;ix<3;++ix) {
for(unsigned int iy=0;iy<3;++iy) {
bornME(ix,iy) += Cborn(ix+ioff)*conj(Cborn(iy+ioff));
EWME (ix,iy) += CEW (ix+ioff)*conj(CEW (iy+ioff));
}
}
}
}
}
double born = 24.*real(bornME(0,0))+20./3.*real(bornME(1,1))+12.*real(bornME(2,2));
double EW = 24.*real(EWME(0,0))+20./3.*real(EWME(1,1))+12.*real(EWME(2,2));
return EW/born;
}
double ElectroWeakReweighter::reweightqgqg() const {
// momenta and invariants
Lorentz5Momentum p1 = subProcess()->incoming().first ->momentum();
Lorentz5Momentum p2 = subProcess()->incoming().second->momentum();
tcPDPtr q;
if(subProcess()->incoming().first->id()!=ParticleID::g) {
q = subProcess()->incoming().first ->dataPtr();
}
else {
q = subProcess()->incoming().second->dataPtr();
swap(p1,p2);
}
Lorentz5Momentum p3 = subProcess()->outgoing()[0]->momentum();
Lorentz5Momentum p4 = subProcess()->outgoing()[1]->momentum();
if(subProcess()->outgoing()[0]->id()!=ParticleID::g)
swap(p3,p4);
Energy2 s = (p1+p2).m2();
Energy2 t = (p1-p4).m2();
Energy2 u = (p1-p3).m2();
// boost to partonic rest frame
Lorentz5Momentum psum=p1+p2;
LorentzRotation boost(-psum.boostVector());
p1 *= boost;
p2 *= boost;
p3 *= boost;
p4 *= boost;
// LO and EW corrected matrix element coefficients
boost::numeric::ublas::matrix<complex<InvEnergy2> >
bornQQGGweights,bornRRGGweights,EWQQGGweights,EWRRGGweights;
// quark left doublet
if(q->id()!=5) {
bornQQGGweights = evaluateRunning(EWProcess::QQGG,s,t,u,true ,1);
EWQQGGweights = evaluateRunning(EWProcess::QQGG,s,t,u,false,1);
}
else {
bornQQGGweights = evaluateRunning(EWProcess::QtQtGG,s,t,u,true ,1);
EWQQGGweights = evaluateRunning(EWProcess::QtQtGG,s,t,u,false,1);
}
// quark right singlet
if(abs(q->id())%2==0) {
bornRRGGweights = evaluateRunning(EWProcess::UUGG,s,t,u,true ,1);
EWRRGGweights = evaluateRunning(EWProcess::UUGG,s,t,u,false,1);
}
else {
bornRRGGweights = evaluateRunning(EWProcess::DDGG,s,t,u,true ,1);
EWRRGGweights = evaluateRunning(EWProcess::DDGG,s,t,u,false,1);
}
SpinorWaveFunction qw(p1,q,incoming);
SpinorBarWaveFunction qbarw(p4,q,outgoing);
vector<LorentzVector<Complex> > eps2,eps3;
SackGluonPolarizations(p1,p2,p3,p4,s,t,u,ZERO,eps2,eps3,2);
// compute the matrix elements
boost::numeric::ublas::matrix<Complex>
bornME = boost::numeric::ublas::zero_matrix<Complex>(3,3),
EWME = boost::numeric::ublas::zero_matrix<Complex>(3,3),
testME = boost::numeric::ublas::zero_matrix<Complex>(3,3);
for(unsigned int iq=0;iq<2;++iq) {
if(iq==0) {
qw.reset (0);
qbarw.reset(0);
}
else {
qw.reset (1);
qbarw.reset(1);
}
LorentzVector<complex<Energy> > current = iq==0 ?
qw.dimensionedWave(). leftCurrent(qbarw.dimensionedWave()) :
qw.dimensionedWave().rightCurrent(qbarw.dimensionedWave());
for(unsigned int i1=0;i1<2;++i1) {
complex<Energy> d31 = eps3[i1].dot(p1);
for(unsigned int i2=0;i2<2;++i2) {
boost::numeric::ublas::vector<complex<Energy2> > M(5);
Complex d34 = eps3[i1].dot(eps2[i2]);
complex<Energy> d42 = eps2[i2].dot(p4);
// M0 in paper
M(0) = qw.dimensionedWave().slash(eps3[i1])
.slash(p2-p4).vectorCurrent(qbarw.dimensionedWave()).dot(eps2[i2]);
// M4 in paper
M(2) = current.dot(eps2[i2])*d31;
// M5 in paper
M(3) = -current.dot(eps3[i1])*d42;
// M1 in paper (missing factor)
M(1) = current.dot(p2);
// M6 in paper
M(4) = M(1)*d31*d42/GeV2;
// M1 final factor
M(1) *= d34;
// coefficient of different contributions
boost::numeric::ublas::vector<Complex> Cborn(3),CEW(3);
if(iq==0) {
axpy_prod_local(bornQQGGweights,M,Cborn);
axpy_prod_local(EWQQGGweights ,M,CEW );
}
else {
axpy_prod_local(bornRRGGweights,M,Cborn);
axpy_prod_local(EWRRGGweights ,M,CEW );
}
unsigned int ioff = (Cborn.size()==6 && q->id()%2!=0) ? 3 : 0;
for(unsigned int ix=0;ix<3;++ix) {
for(unsigned int iy=0;iy<3;++iy) {
bornME(ix,iy) += Cborn(ix+ioff)*conj(Cborn(iy+ioff));
EWME (ix,iy) += CEW (ix+ioff)*conj(CEW (iy+ioff));
}
}
}
}
}
double born = 24.*real(bornME(0,0))+20./3.*real(bornME(1,1))+12.*real(bornME(2,2));
double EW = 24.*real(EWME(0,0))+20./3.*real(EWME(1,1))+12.*real(EWME(2,2));
return EW/born;
}
double ElectroWeakReweighter::reweightqbargqbarg() const {
// momenta and invariants
Lorentz5Momentum p1 = subProcess()->incoming().first ->momentum();
Lorentz5Momentum p2 = subProcess()->incoming().second->momentum();
tcPDPtr qbar;
if(subProcess()->incoming().first->id()==ParticleID::g) {
qbar = subProcess()->incoming().second->dataPtr();
}
else {
qbar = subProcess()->incoming().first ->dataPtr();
swap(p1,p2);
}
Lorentz5Momentum p3 = subProcess()->outgoing()[0]->momentum();
Lorentz5Momentum p4 = subProcess()->outgoing()[1]->momentum();
if(subProcess()->outgoing()[0]->id()==ParticleID::g)
swap(p3,p4);
Energy2 s = (p1+p2).m2();
Energy2 t = (p1-p4).m2();
Energy2 u = (p1-p3).m2();
// boost to partonci rest frame
Lorentz5Momentum psum=p1+p2;
LorentzRotation boost(-psum.boostVector());
p1 *= boost;
p2 *= boost;
p3 *= boost;
p4 *= boost;
// LO and EW corrected matrix element coefficients
boost::numeric::ublas::matrix<complex<InvEnergy2> >
bornQQGGweights,bornRRGGweights,EWQQGGweights,EWRRGGweights;
// quark left doublet
if(qbar->id()!=-5) {
bornQQGGweights = evaluateRunning(EWProcess::QQGG,s,t,u,true ,1);
EWQQGGweights = evaluateRunning(EWProcess::QQGG,s,t,u,false,1);
}
else {
bornQQGGweights = evaluateRunning(EWProcess::QtQtGG,s,t,u,true ,1);
EWQQGGweights = evaluateRunning(EWProcess::QtQtGG,s,t,u,false,1);
}
// quark right singlet
if(abs(qbar->id())%2==0) {
bornRRGGweights = evaluateRunning(EWProcess::UUGG,s,t,u,true ,1);
EWRRGGweights = evaluateRunning(EWProcess::UUGG,s,t,u,false,1);
}
else {
bornRRGGweights = evaluateRunning(EWProcess::DDGG,s,t,u,true ,1);
EWRRGGweights = evaluateRunning(EWProcess::DDGG,s,t,u,false,1);
}
SpinorWaveFunction qw(p3,qbar,outgoing);
SpinorBarWaveFunction qbarw(p2,qbar,incoming);
vector<LorentzVector<Complex> > eps1,eps4;
SackGluonPolarizations(p1,p2,p3,p4,s,t,u,ZERO,eps1,eps4,3);
boost::numeric::ublas::matrix<Complex>
bornME = boost::numeric::ublas::zero_matrix<Complex>(3,3),
EWME = boost::numeric::ublas::zero_matrix<Complex>(3,3);
for(unsigned int iq=0;iq<2;++iq) {
if(iq==0) {
qw.reset (1);
qbarw.reset(1);
}
else {
qw.reset (0);
qbarw.reset(0);
}
LorentzVector<complex<Energy> > current = iq==0 ?
qw.dimensionedWave(). leftCurrent(qbarw.dimensionedWave()) :
qw.dimensionedWave().rightCurrent(qbarw.dimensionedWave());
for(unsigned int i1=0;i1<2;++i1) {
complex<Energy> d31 = eps1[i1].dot(p3);
for(unsigned int i2=0;i2<2;++i2) {
boost::numeric::ublas::vector<complex<Energy2> > M(5);
Complex d34 = eps1[i1].dot(eps4[i2]);
complex<Energy> d42 = eps4[i2].dot(p2);
// M0 in paper
M(0) = qw.dimensionedWave().slash(eps1[i1])
.slash(p4-p2).vectorCurrent(qbarw.dimensionedWave()).dot(eps4[i2]);
// M4 in paper
M(2) = current.dot(eps4[i2])*d31;
// M5 in paper
M(3) = -current.dot(eps1[i1])*d42;
// M1 in paper (missing factor)
M(1) = current.dot(p4);
// M6 in paper
M(4) = M(1)*d31*d42/GeV2;
// M1 final factor
M(1) *= d34;
// coefficient of different contributions
boost::numeric::ublas::vector<Complex> Cborn(3),CEW(3);
if(iq==0) {
axpy_prod_local(bornQQGGweights,M,Cborn);
axpy_prod_local(EWQQGGweights ,M,CEW );
}
else {
axpy_prod_local(bornRRGGweights,M,Cborn);
axpy_prod_local(EWRRGGweights ,M,CEW );
}
unsigned int ioff = (Cborn.size()==6 && abs(qbar->id())%2!=0) ? 3 : 0;
for(unsigned int ix=0;ix<3;++ix) {
for(unsigned int iy=0;iy<3;++iy) {
bornME(ix,iy) += Cborn(ix+ioff)*conj(Cborn(iy+ioff));
EWME (ix,iy) += CEW (ix+ioff)*conj(CEW (iy+ioff));
}
}
}
}
}
double born = 24.*real(bornME(0,0))+20./3.*real(bornME(1,1))+12.*real(bornME(2,2));
double EW = 24.*real(EWME(0,0))+20./3.*real(EWME(1,1))+12.*real(EWME(2,2));
return EW/born;
}
double ElectroWeakReweighter::reweightqqbarqqbarS() const {
// momenta and invariants
Lorentz5Momentum p1 = subProcess()->incoming().first ->momentum();
tcPDPtr q1 = subProcess()->incoming().first ->dataPtr();
Lorentz5Momentum p2 = subProcess()->incoming().second->momentum();
tcPDPtr q1bar = subProcess()->incoming().second->dataPtr();
if(q1->id()<0) {
swap(p1,p2 );
swap(q1 ,q1bar);
}
Lorentz5Momentum p3 = subProcess()->outgoing()[0]->momentum();
tcPDPtr q2bar = subProcess()->outgoing()[0]->dataPtr();
Lorentz5Momentum p4 = subProcess()->outgoing()[1]->momentum();
tcPDPtr q2 = subProcess()->outgoing()[1]->dataPtr();
if(q2bar->id()>0) {
swap(p3,p4 );
swap(q2 ,q2bar);
}
Energy2 s = (p1+p2).m2();
Energy2 t = (p1-p4).m2();
Energy2 u = (p1-p3).m2();
// boost to partonci rest frame
Lorentz5Momentum psum=p1+p2;
LorentzRotation boost(-psum.boostVector());
p1 *= boost;
p2 *= boost;
p3 *= boost;
p4 *= boost;
p3.setMass(ZERO);
p3.rescaleRho();
p4.setMass(ZERO);
p4.rescaleRho();
// LO and EW corrected matrix element coefficients
boost::numeric::ublas::matrix<complex<InvEnergy2> >
bornLLLLWeights,bornLLRRWeights,bornRRLLWeights,bornRRRRWeights,
EWLLLLWeights,EWLLRRWeights,EWRRLLWeights,EWRRRRWeights;
bool ident = q1->id()==q2->id();
// LL -> LL
if((q1->id()<=4&& q2->id()<=4)|| (q1->id()==5 && q2->id()==5)) {
if(!ident) {
bornLLLLWeights = evaluateRunning(EWProcess::QQQQ,s,t,u,true ,0);
EWLLLLWeights = evaluateRunning(EWProcess::QQQQ,s,t,u,false,0);
}
else {
bornLLLLWeights = evaluateRunning(EWProcess::QQQQiden,s,t,u,true ,0);
EWLLLLWeights = evaluateRunning(EWProcess::QQQQiden,s,t,u,false,0);
}
}
else if(q1->id()==5 || q2->id()>=5) {
bornLLLLWeights = evaluateRunning(EWProcess::QtQtQQ,s,t,u,true ,0);
EWLLLLWeights = evaluateRunning(EWProcess::QtQtQQ,s,t,u,false,0);
}
else
assert(false);
// RR -> LL
if(q1->id()%2==0) {
if(q2->id()<5) {
bornRRLLWeights = evaluateRunning(EWProcess::QQUU,s,t,u,true ,0);
EWRRLLWeights = evaluateRunning(EWProcess::QQUU,s,t,u,false,0);
}
else {
bornRRLLWeights = evaluateRunning(EWProcess::QtQtUU,s,t,u,true ,0);
EWRRLLWeights = evaluateRunning(EWProcess::QtQtUU,s,t,u,false,0);
}
}
else {
if(q2->id()<5) {
bornRRLLWeights = evaluateRunning(EWProcess::QQDD,s,t,u,true ,0);
EWRRLLWeights = evaluateRunning(EWProcess::QQDD,s,t,u,false,0);
}
else {
bornRRLLWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,true ,0);
EWRRLLWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,false,0);
}
}
// LL -> RR
if(q1->id()<=4) {
if(q2->id()%2!=0) {
bornLLRRWeights = evaluateRunning(EWProcess::QQDD,s,t,u,true ,0);
EWLLRRWeights = evaluateRunning(EWProcess::QQDD,s,t,u,false,0);
}
else if (q2->id()==6) {
bornLLRRWeights = evaluateRunning(EWProcess::QQtRtR,s,t,u,true ,0);
EWLLRRWeights = evaluateRunning(EWProcess::QQtRtR,s,t,u,false,0);
}
else {
bornLLRRWeights = evaluateRunning(EWProcess::QQUU,s,t,u,true ,0);
EWLLRRWeights = evaluateRunning(EWProcess::QQUU,s,t,u,false,0);
}
}
else {
if(q2->id()%2!=0) {
bornLLRRWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,true ,0);
EWLLRRWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,false,0);
}
else {
bornLLRRWeights = evaluateRunning(EWProcess::QtQtUU,s,t,u,true ,0);
EWLLRRWeights = evaluateRunning(EWProcess::QtQtUU,s,t,u,false,0);
}
}
// RR -> RR
if(q1->id()%2==0) {
if(q2->id()==6) {
bornRRRRWeights = evaluateRunning(EWProcess::tRtRUU,s,t,u,true ,0);
EWRRRRWeights = evaluateRunning(EWProcess::tRtRUU,s,t,u,false,0);
}
else if(q2->id()%2==0) {
if(ident) {
bornRRRRWeights = evaluateRunning(EWProcess::UUUUiden,s,t,u,true ,0);
EWRRRRWeights = evaluateRunning(EWProcess::UUUUiden,s,t,u,false,0);
}
else {
bornRRRRWeights = evaluateRunning(EWProcess::UUUU,s,t,u,true ,0);
EWRRRRWeights = evaluateRunning(EWProcess::UUUU,s,t,u,false,0);
}
}
else {
bornRRRRWeights = evaluateRunning(EWProcess::UUDD,s,t,u,true ,0);
EWRRRRWeights = evaluateRunning(EWProcess::UUDD,s,t,u,false,0);
}
}
else {
if(q2->id()==6) {
bornRRRRWeights = evaluateRunning(EWProcess::tRtRDD,s,t,u,true ,0);
EWRRRRWeights = evaluateRunning(EWProcess::tRtRDD,s,t,u,false,0);
}
else if(q2->id()%2==0) {
bornRRRRWeights = evaluateRunning(EWProcess::UUDD,s,t,u,true ,0);
EWRRRRWeights = evaluateRunning(EWProcess::UUDD,s,t,u,false,0);
}
else {
if(ident) {
bornRRRRWeights = evaluateRunning(EWProcess::DDDDiden,s,t,u,true ,0);
EWRRRRWeights = evaluateRunning(EWProcess::DDDDiden,s,t,u,false,0);
}
else {
bornRRRRWeights = evaluateRunning(EWProcess::DDDD,s,t,u,true ,0);
EWRRRRWeights = evaluateRunning(EWProcess::DDDD,s,t,u,false,0);
}
}
}
// extra terms for identical particles
boost::numeric::ublas::matrix<complex<InvEnergy2> >
borntChannelWeights,EWtChannelWeights;
if(ident) {
if(q1->id()%2==0) {
borntChannelWeights = evaluateRunning(EWProcess::QQUU,s,t,u,true ,1);
EWtChannelWeights = evaluateRunning(EWProcess::QQUU,s,t,u,false,1);
}
else if(q1->id()==5) {
borntChannelWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,true ,1);
EWtChannelWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,false,1);
}
else {
borntChannelWeights = evaluateRunning(EWProcess::QQDD,s,t,u,true ,1);
EWtChannelWeights = evaluateRunning(EWProcess::QQDD,s,t,u,false,1);
}
}
SpinorWaveFunction q1w(p1,q1 ,incoming);
SpinorBarWaveFunction q1barw(p2,q1bar,incoming);
SpinorWaveFunction q2barw(p3,q2bar,outgoing);
SpinorBarWaveFunction q2w(p4,q2 ,outgoing);
boost::numeric::ublas::matrix<Complex>
bornME = boost::numeric::ublas::zero_matrix<Complex>(2,2),
EWME = boost::numeric::ublas::zero_matrix<Complex>(2,2);
for(unsigned int iq1=0;iq1<2;++iq1) {
if(iq1==0) {
q1w.reset (0);
q1barw.reset(1);
}
else {
q1w.reset (1);
q1barw.reset(0);
}
LorentzVector<complex<Energy> > current1 =
q1w.dimensionedWave().vectorCurrent(q1barw.dimensionedWave());
for(unsigned int iq2=0;iq2<2;++iq2) {
if(iq2==0) {
q2w.reset (0);
q2barw.reset(1);
}
else {
q2w.reset (1);
q2barw.reset(0);
}
LorentzVector<complex<Energy> > current2 =
q2barw.dimensionedWave().vectorCurrent(q2w.dimensionedWave());
complex<Energy2> amp = current1.dot(current2);
vector<Complex> Cborn(2),CEW(2);
// amplitudes
if(iq1==0) {
// LL
if(iq2==0) {
unsigned int ioff;
if(q1->id()%2==0) {
ioff = q2->id()%2==0 ? 0 : 2;
}
else {
ioff = q2->id()%2==0 ? 1 : 3;
}
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*bornLLLLWeights(6*ix+ioff,0);
CEW [ix] = amp* EWLLLLWeights(6*ix+ioff,0);
}
}
// LR
else {
unsigned int ioff = q1->id()%2==0 ? 0 : 1;
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*bornLLRRWeights(2*ix+ioff,0);
CEW [ix] = amp* EWLLRRWeights(2*ix+ioff,0);
}
}
}
else {
if(iq2==0) {
unsigned int ioff=q2->id()%2==0 ? 0 : 1;
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*bornRRLLWeights(2*ix+ioff,0);
CEW [ix] = amp* EWRRLLWeights(2*ix+ioff,0);
}
}
else {
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*bornRRRRWeights(ix,0);
CEW [ix] = amp* EWRRRRWeights(ix,0);
}
}
}
// square
for(unsigned int ix=0;ix<2;++ix) {
for(unsigned int iy=0;iy<2;++iy) {
bornME(ix,iy) += Cborn[ix]*conj(Cborn[iy]);
EWME (ix,iy) += CEW [ix]*conj(CEW [iy]);
}
}
}
}
// extra t-channel pieces if identical flavours
if(ident) {
for(unsigned int iq1=0;iq1<2;++iq1) {
q1w.reset(iq1);
q2w.reset(iq1);
LorentzVector<complex<Energy> > current1 =
q1w.dimensionedWave().vectorCurrent(q2w.dimensionedWave());
q1barw.reset(iq1);
q2barw.reset(iq1);
LorentzVector<complex<Energy> > current2 =
q2barw.dimensionedWave().vectorCurrent(q1barw.dimensionedWave());
complex<Energy2> amp = current1.dot(current2);
vector<Complex> Cborn(2),CEW(2);
unsigned int ioff = q1->id()%2==0 ? 0 : 1;
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*borntChannelWeights(2*ix+ioff,0);
CEW [ix] = amp* EWtChannelWeights(2*ix+ioff,0);
}
// square
for(unsigned int ix=0;ix<2;++ix) {
for(unsigned int iy=0;iy<2;++iy) {
bornME(ix,iy) += Cborn[ix]*conj(Cborn[iy]);
EWME (ix,iy) += CEW [ix]*conj(CEW [iy]);
}
}
}
}
// colour factors
double born = 2.*real(bornME(0,0))+9.*real(bornME(1,1));
double EW = 2.*real( EWME(0,0))+9.*real( EWME(1,1));
return EW/born;
}
double ElectroWeakReweighter::reweightqqbarqqbarT() const {
// momenta and invariants
Lorentz5Momentum p1 = subProcess()->incoming().first ->momentum();
tcPDPtr q1 = subProcess()->incoming().first ->dataPtr();
Lorentz5Momentum p2 = subProcess()->incoming().second->momentum();
tcPDPtr q1bar = subProcess()->incoming().second->dataPtr();
if(q1->id()<0) {
swap(p1,p2 );
swap(q1 ,q1bar);
}
Lorentz5Momentum p3 = subProcess()->outgoing()[0]->momentum();
tcPDPtr q2bar = subProcess()->outgoing()[0]->dataPtr();
Lorentz5Momentum p4 = subProcess()->outgoing()[1]->momentum();
tcPDPtr q2 = subProcess()->outgoing()[1]->dataPtr();
if(q2bar->id()>0) {
swap(p3,p4 );
swap(q2 ,q2bar);
}
Energy2 s = (p1+p2).m2();
Energy2 t = (p1-p4).m2();
Energy2 u = (p1-p3).m2();
// boost to partonci rest frame
Lorentz5Momentum psum=p1+p2;
LorentzRotation boost(-psum.boostVector());
p1 *= boost;
p2 *= boost;
p3 *= boost;
p4 *= boost;
p3.setMass(ZERO);
p3.rescaleRho();
p4.setMass(ZERO);
p4.rescaleRho();
assert(q1==q2 && q1bar==q2bar);
assert( q1->id() != -q1bar->id() && q2->id() != -q2bar->id() );
// LO and EW corrected matrix element coefficients
boost::numeric::ublas::matrix<complex<InvEnergy2> >
bornLLLLWeights,bornLLRRWeights,bornRRLLWeights,bornRRRRWeights,
EWLLLLWeights,EWLLRRWeights,EWRRLLWeights,EWRRRRWeights;
// LL
if( q1->id() == ParticleID::b ||
q1bar->id() == ParticleID::bbar ) {
bornLLLLWeights = evaluateRunning(EWProcess::QtQtQQ,s,t,u,true ,1);
EWLLLLWeights = evaluateRunning(EWProcess::QtQtQQ,s,t,u,false,1);
}
else {
bornLLLLWeights = evaluateRunning(EWProcess::QQQQ,s,t,u,true ,1);
EWLLLLWeights = evaluateRunning(EWProcess::QQQQ,s,t,u,false,1);
}
// RR -> LL
if(q1->id()%2==0) {
if(q1bar->id()==ParticleID::bbar) {
bornRRLLWeights = evaluateRunning(EWProcess::QtQtUU,s,t,u,true ,1);
EWRRLLWeights = evaluateRunning(EWProcess::QtQtUU,s,t,u,false,1);
}
else {
bornRRLLWeights = evaluateRunning(EWProcess::QQUU,s,t,u,true ,1);
EWRRLLWeights = evaluateRunning(EWProcess::QQUU,s,t,u,false,1);
}
}
else {
if(q1bar->id()==ParticleID::bbar) {
bornRRLLWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,true ,1);
EWRRLLWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,false,1);
}
else {
bornRRLLWeights = evaluateRunning(EWProcess::QQDD,s,t,u,true ,1);
EWRRLLWeights = evaluateRunning(EWProcess::QQDD,s,t,u,false,1);
}
}
// LL -> RR
if(abs(q1bar->id())%2==0) {
if(q1->id()==ParticleID::b) {
bornLLRRWeights = evaluateRunning(EWProcess::QtQtUU,s,t,u,true ,1);
EWLLRRWeights = evaluateRunning(EWProcess::QtQtUU,s,t,u,false,1);
}
else {
bornLLRRWeights = evaluateRunning(EWProcess::QQUU,s,t,u,true ,1);
EWLLRRWeights = evaluateRunning(EWProcess::QQUU,s,t,u,false,1);
}
}
else {
if(q1->id()==ParticleID::b) {
bornLLRRWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,true ,1);
EWLLRRWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,false,1);
}
else {
bornLLRRWeights = evaluateRunning(EWProcess::QQDD,s,t,u,true ,1);
EWLLRRWeights = evaluateRunning(EWProcess::QQDD,s,t,u,false,1);
}
}
// RR -> RR
if(q1->id()%2==0) {
if(abs(q1bar->id())%2==0) {
bornRRRRWeights = evaluateRunning(EWProcess::UUUU,s,t,u,true ,1);
EWRRRRWeights = evaluateRunning(EWProcess::UUUU,s,t,u,false,1);
}
else {
bornRRRRWeights = evaluateRunning(EWProcess::UUDD,s,t,u,true ,1);
EWRRRRWeights = evaluateRunning(EWProcess::UUDD,s,t,u,false,1);
}
}
else {
if(abs(q1bar->id())%2==0) {
bornRRRRWeights = evaluateRunning(EWProcess::UUDD,s,t,u,true ,1);
EWRRRRWeights = evaluateRunning(EWProcess::UUDD,s,t,u,false,1);
}
else {
bornRRRRWeights = evaluateRunning(EWProcess::DDDD,s,t,u,true ,1);
EWRRRRWeights = evaluateRunning(EWProcess::DDDD,s,t,u,false,1);
}
}
// calculate the spinors
SpinorWaveFunction q1w(p1,q1 ,incoming);
SpinorBarWaveFunction q1barw(p2,q1bar,incoming);
SpinorWaveFunction q2barw(p3,q2bar,outgoing);
SpinorBarWaveFunction q2w(p4,q2 ,outgoing);
boost::numeric::ublas::matrix<Complex>
bornME = boost::numeric::ublas::zero_matrix<Complex>(2,2),
EWME = boost::numeric::ublas::zero_matrix<Complex>(2,2);
for(unsigned int iq1=0;iq1<2;++iq1) {
q1w.reset(iq1);
q2w.reset(iq1);
LorentzVector<complex<Energy> > current1 =
q1w.dimensionedWave().vectorCurrent(q2w.dimensionedWave());
for(unsigned int iq2=0;iq2<2;++iq2) {
q1barw.reset(iq2);
q2barw.reset(iq2);
LorentzVector<complex<Energy> > current2 =
q2barw.dimensionedWave().vectorCurrent(q1barw.dimensionedWave());
// calculate the amplitude
complex<Energy2> amp = current1.dot(current2);
vector<Complex> Cborn(2),CEW(2);
if(iq1==0) {
// LL RR
if(iq2==0) {
unsigned int ioff = q1->id()%2==0 ? 0 : 1;
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*bornLLRRWeights(2*ix+ioff,0);
CEW [ix] = amp* EWLLRRWeights(2*ix+ioff,0);
}
}
// LL LL
else {
unsigned int ioff;
if(q1->id()%2==0) {
ioff = abs(q1bar->id())%2==0 ? 0 : 2;
}
else {
ioff = abs(q1bar->id())%2==0 ? 1 : 3;
}
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*bornLLLLWeights(6*ix+ioff,0);
CEW [ix] = amp* EWLLLLWeights(6*ix+ioff,0);
}
}
}
else {
// RR RR
if(iq2==0) {
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*bornRRRRWeights(ix,0);
CEW [ix] = amp* EWRRRRWeights(ix,0);
}
}
// RR LL
else {
unsigned int ioff=abs(q1bar->id())%2==0 ? 0 : 1;
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*bornRRLLWeights(2*ix+ioff,0);
CEW [ix] = amp* EWRRLLWeights(2*ix+ioff,0);
}
}
}
// square
for(unsigned int ix=0;ix<2;++ix) {
for(unsigned int iy=0;iy<2;++iy) {
bornME(ix,iy) += Cborn[ix]*conj(Cborn[iy]);
EWME (ix,iy) += CEW [ix]*conj(CEW [iy]);
}
}
}
}
// colour factors
double born = 2.*real(bornME(0,0))+9.*real(bornME(1,1));
double EW = 2.*real( EWME(0,0))+9.*real( EWME(1,1));
return EW/born;
}
double ElectroWeakReweighter::reweightqqqq() const {
// momenta and invariants
Lorentz5Momentum p1 = subProcess()->incoming().first ->momentum();
tcPDPtr q1 = subProcess()->incoming().first ->dataPtr();
Lorentz5Momentum p2 = subProcess()->incoming().second->momentum();
tcPDPtr q2 = subProcess()->incoming().second->dataPtr();
Lorentz5Momentum p3 = subProcess()->outgoing()[0] ->momentum();
tcPDPtr q3 = subProcess()->outgoing()[0] ->dataPtr();
Lorentz5Momentum p4 = subProcess()->outgoing()[1] ->momentum();
tcPDPtr q4 = subProcess()->outgoing()[1] ->dataPtr();
if(q1->id()!=q3->id()) {
swap(q3,q4);
swap(p3,p4);
}
assert(q1->id()==q3->id());
assert(q2->id()==q4->id());
Energy2 s = (p1+p2).m2();
Energy2 t = (p1-p4).m2();
Energy2 u = (p1-p3).m2();
// boost to partonci rest frame
Lorentz5Momentum psum=p1+p2;
LorentzRotation boost(-psum.boostVector());
p1 *= boost;
p2 *= boost;
p3 *= boost;
p4 *= boost;
p3.setMass(ZERO);
p3.rescaleRho();
p4.setMass(ZERO);
p4.rescaleRho();
// LO and EW corrected matrix element coefficients
boost::numeric::ublas::matrix<complex<InvEnergy2> >
bornLLLLWeights,bornLLRRWeights,bornRRLLWeights,bornRRRRWeights,
EWLLLLWeights,EWLLRRWeights,EWRRLLWeights,EWRRRRWeights;
bool ident = q1->id()==q2->id();
// LL -> LL
if((q1->id()<=4&& q2->id()<=4)|| (q1->id()==5 && q2->id()==5)) {
if(!ident) {
bornLLLLWeights = evaluateRunning(EWProcess::QQQQ,s,t,u,true ,2);
EWLLLLWeights = evaluateRunning(EWProcess::QQQQ,s,t,u,false,2);
}
else {
bornLLLLWeights = evaluateRunning(EWProcess::QQQQiden,s,t,u,true ,2);
EWLLLLWeights = evaluateRunning(EWProcess::QQQQiden,s,t,u,false,2);
}
}
else if(q1->id()==5 || q2->id()==5) {
bornLLLLWeights = evaluateRunning(EWProcess::QtQtQQ,s,t,u,true ,2);
EWLLLLWeights = evaluateRunning(EWProcess::QtQtQQ,s,t,u,false,2);
}
else
assert(false);
// RR -> LL
if(q1->id()%2==0) {
if(q2->id()<5) {
bornRRLLWeights = evaluateRunning(EWProcess::QQUU,s,t,u,true ,2);
EWRRLLWeights = evaluateRunning(EWProcess::QQUU,s,t,u,false,2);
}
else {
bornRRLLWeights = evaluateRunning(EWProcess::QtQtUU,s,t,u,true ,2);
EWRRLLWeights = evaluateRunning(EWProcess::QtQtUU,s,t,u,false,2);
}
}
else {
if(q2->id()<5) {
bornRRLLWeights = evaluateRunning(EWProcess::QQDD,s,t,u,true ,2);
EWRRLLWeights = evaluateRunning(EWProcess::QQDD,s,t,u,false,2);
}
else {
bornRRLLWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,true ,2);
EWRRLLWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,false,2);
}
}
// LL -> RR
if(q1->id()<=4) {
if(q2->id()%2!=0) {
bornLLRRWeights = evaluateRunning(EWProcess::QQDD,s,t,u,true ,2);
EWLLRRWeights = evaluateRunning(EWProcess::QQDD,s,t,u,false,2);
}
else {
bornLLRRWeights = evaluateRunning(EWProcess::QQUU,s,t,u,true ,2);
EWLLRRWeights = evaluateRunning(EWProcess::QQUU,s,t,u,false,2);
}
}
else {
if(q2->id()%2!=0) {
bornLLRRWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,true ,2);
EWLLRRWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,false,2);
}
else {
bornLLRRWeights = evaluateRunning(EWProcess::QtQtUU,s,t,u,true ,2);
EWLLRRWeights = evaluateRunning(EWProcess::QtQtUU,s,t,u,false,2);
}
}
// RR -> RR
if(q1->id()%2==0) {
if(q2->id()%2==0) {
if(ident) {
bornRRRRWeights = evaluateRunning(EWProcess::UUUUiden,s,t,u,true ,2);
EWRRRRWeights = evaluateRunning(EWProcess::UUUUiden,s,t,u,false,2);
}
else {
bornRRRRWeights = evaluateRunning(EWProcess::UUUU,s,t,u,true ,2);
EWRRRRWeights = evaluateRunning(EWProcess::UUUU,s,t,u,false,2);
}
}
else {
bornRRRRWeights = evaluateRunning(EWProcess::UUDD,s,t,u,true ,2);
EWRRRRWeights = evaluateRunning(EWProcess::UUDD,s,t,u,false,2);
}
}
else {
if(q2->id()%2==0) {
bornRRRRWeights = evaluateRunning(EWProcess::UUDD,s,t,u,true ,2);
EWRRRRWeights = evaluateRunning(EWProcess::UUDD,s,t,u,false,2);
}
else {
if(ident) {
bornRRRRWeights = evaluateRunning(EWProcess::DDDDiden,s,t,u,true ,2);
EWRRRRWeights = evaluateRunning(EWProcess::DDDDiden,s,t,u,false,2);
}
else {
bornRRRRWeights = evaluateRunning(EWProcess::DDDD,s,t,u,true ,2);
EWRRRRWeights = evaluateRunning(EWProcess::DDDD,s,t,u,false,2);
}
}
}
// extra terms for identical particles
boost::numeric::ublas::matrix<complex<InvEnergy2> >
borntChannelWeights,EWtChannelWeights;
if(ident) {
if(q1->id()%2==0) {
borntChannelWeights = evaluateRunning(EWProcess::QQUU,s,u,t,true ,2);
EWtChannelWeights = evaluateRunning(EWProcess::QQUU,s,u,t,false,2);
}
else if(q1->id()==5) {
borntChannelWeights = evaluateRunning(EWProcess::QtQtDD,s,u,t,true ,2);
EWtChannelWeights = evaluateRunning(EWProcess::QtQtDD,s,u,t,false,2);
}
else {
borntChannelWeights = evaluateRunning(EWProcess::QQDD,s,u,t,true ,2);
EWtChannelWeights = evaluateRunning(EWProcess::QQDD,s,u,t,false,2);
}
}
SpinorWaveFunction q1w(p1,q1,incoming);
SpinorWaveFunction q2w(p2,q2,incoming);
SpinorBarWaveFunction q3w(p3,q3,outgoing);
SpinorBarWaveFunction q4w(p4,q4,outgoing);
boost::numeric::ublas::matrix<Complex>
bornME = boost::numeric::ublas::zero_matrix<Complex>(2,2),
EWME = boost::numeric::ublas::zero_matrix<Complex>(2,2);
for(unsigned int iq1=0;iq1<2;++iq1) {
q1w.reset(iq1);
q3w.reset(iq1);
LorentzVector<complex<Energy> > current1 =
q1w.dimensionedWave().vectorCurrent(q3w.dimensionedWave());
for(unsigned int iq2=0;iq2<2;++iq2) {
q2w.reset(iq2);
q4w.reset(iq2);
LorentzVector<complex<Energy> > current2 =
q2w.dimensionedWave().vectorCurrent(q4w.dimensionedWave());
complex<Energy2> amp = current1.dot(current2);
vector<Complex> Cborn(2),CEW(2);
// amplitudes
if(iq1==0) {
// LL
if(iq2==0) {
unsigned int ioff;
if(q1->id()%2==0) {
ioff = q2->id()%2==0 ? 0 : 2;
}
else {
ioff = q2->id()%2==0 ? 1 : 3;
}
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*bornLLLLWeights(6*ix+ioff,0);
CEW [ix] = amp* EWLLLLWeights(6*ix+ioff,0);
}
}
// LR
else {
unsigned int ioff = q1->id()%2==0 ? 0 : 1;
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*bornLLRRWeights(2*ix+ioff,0);
CEW [ix] = amp* EWLLRRWeights(2*ix+ioff,0);
}
}
}
else {
if(iq2==0) {
unsigned int ioff=q2->id()%2==0 ? 0 : 1;
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*bornRRLLWeights(2*ix+ioff,0);
CEW [ix] = amp* EWRRLLWeights(2*ix+ioff,0);
}
}
else {
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*bornRRRRWeights(ix,0);
CEW [ix] = amp* EWRRRRWeights(ix,0);
}
}
}
// square
for(unsigned int ix=0;ix<2;++ix) {
for(unsigned int iy=0;iy<2;++iy) {
bornME(ix,iy) += Cborn[ix]*conj(Cborn[iy]);
EWME (ix,iy) += CEW [ix]*conj(CEW [iy]);
}
}
}
}
// extra u-channel pieces if identical flavours
if(ident) {
for(unsigned int iq1=0;iq1<2;++iq1) {
q1w.reset(iq1);
q4w.reset(iq1);
LorentzVector<complex<Energy> > current1 =
q1w.dimensionedWave().vectorCurrent(q4w.dimensionedWave());
if(iq1==0) {
q2w.reset(1);
q3w.reset(1);
}
else {
q2w.reset(0);
q3w.reset(0);
}
LorentzVector<complex<Energy> > current2 =
q2w.dimensionedWave().vectorCurrent(q3w.dimensionedWave());
complex<Energy2> amp = current1.dot(current2);
vector<Complex> Cborn(2),CEW(2);
unsigned int ioff = q1->id()%2==0 ? 0 : 1;
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*borntChannelWeights(2*ix+ioff,0);
CEW [ix] = amp* EWtChannelWeights(2*ix+ioff,0);
}
// square
for(unsigned int ix=0;ix<2;++ix) {
for(unsigned int iy=0;iy<2;++iy) {
bornME(ix,iy) += Cborn[ix]*conj(Cborn[iy]);
EWME (ix,iy) += CEW [ix]*conj(CEW [iy]);
}
}
}
}
// colour factors
double born = 2.*real(bornME(0,0))+9.*real(bornME(1,1));
double EW = 2.*real( EWME(0,0))+9.*real( EWME(1,1));
return EW/born;
}
double ElectroWeakReweighter::reweightqbarqbarqbarqbar() const {
// momenta and invariants
Lorentz5Momentum p1 = subProcess()->incoming().first ->momentum();
tcPDPtr qbar1 = subProcess()->incoming().first ->dataPtr();
Lorentz5Momentum p2 = subProcess()->incoming().second->momentum();
tcPDPtr qbar2 = subProcess()->incoming().second->dataPtr();
Lorentz5Momentum p3 = subProcess()->outgoing()[0] ->momentum();
tcPDPtr qbar3 = subProcess()->outgoing()[0] ->dataPtr();
Lorentz5Momentum p4 = subProcess()->outgoing()[1] ->momentum();
tcPDPtr qbar4 = subProcess()->outgoing()[1] ->dataPtr();
if(qbar1->id()!=qbar3->id()) {
swap(qbar3,qbar4);
swap(p3,p4);
}
assert(qbar1->id()==qbar3->id());
assert(qbar2->id()==qbar4->id());
Energy2 s = (p1+p2).m2();
Energy2 t = (p1-p4).m2();
Energy2 u = (p1-p3).m2();
// boost to partonic rest frame
Lorentz5Momentum psum=p1+p2;
LorentzRotation boost(-psum.boostVector());
p1 *= boost;
p2 *= boost;
p3 *= boost;
p4 *= boost;
p3.setMass(ZERO);
p3.rescaleRho();
p4.setMass(ZERO);
p4.rescaleRho();
// LO and EW corrected matrix element coefficients
boost::numeric::ublas::matrix<complex<InvEnergy2> >
bornLLLLWeights,bornLLRRWeights,bornRRLLWeights,bornRRRRWeights,
EWLLLLWeights,EWLLRRWeights,EWRRLLWeights,EWRRRRWeights;
bool ident = qbar1->id()==qbar2->id();
// LL -> LL
if((abs(qbar1->id())<=4 && abs(qbar2->id())<=4) ||
(abs(qbar1->id())==5 && abs(qbar2->id())==5)) {
if(!ident) {
bornLLLLWeights = evaluateRunning(EWProcess::QQQQ,s,t,u,true ,2);
EWLLLLWeights = evaluateRunning(EWProcess::QQQQ,s,t,u,false,2);
}
else {
bornLLLLWeights = evaluateRunning(EWProcess::QQQQiden,s,t,u,true ,2);
EWLLLLWeights = evaluateRunning(EWProcess::QQQQiden,s,t,u,false,2);
}
}
else if(abs(qbar1->id())==5 || abs(qbar2->id())==5) {
bornLLLLWeights = evaluateRunning(EWProcess::QtQtQQ,s,t,u,true ,2);
EWLLLLWeights = evaluateRunning(EWProcess::QtQtQQ,s,t,u,false,2);
}
else
assert(false);
// RR -> LL
if(abs(qbar1->id())%2==0) {
if(abs(qbar2->id())<5) {
bornRRLLWeights = evaluateRunning(EWProcess::QQUU,s,t,u,true ,2);
EWRRLLWeights = evaluateRunning(EWProcess::QQUU,s,t,u,false,2);
}
else {
bornRRLLWeights = evaluateRunning(EWProcess::QtQtUU,s,t,u,true ,2);
EWRRLLWeights = evaluateRunning(EWProcess::QtQtUU,s,t,u,false,2);
}
}
else {
if(abs(qbar2->id())<5) {
bornRRLLWeights = evaluateRunning(EWProcess::QQDD,s,t,u,true ,2);
EWRRLLWeights = evaluateRunning(EWProcess::QQDD,s,t,u,false,2);
}
else {
bornRRLLWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,true ,2);
EWRRLLWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,false,2);
}
}
// LL -> RR
if(abs(qbar1->id())<=4) {
if(abs(qbar2->id())%2!=0) {
bornLLRRWeights = evaluateRunning(EWProcess::QQDD,s,t,u,true ,2);
EWLLRRWeights = evaluateRunning(EWProcess::QQDD,s,t,u,false,2);
}
else {
bornLLRRWeights = evaluateRunning(EWProcess::QQUU,s,t,u,true ,2);
EWLLRRWeights = evaluateRunning(EWProcess::QQUU,s,t,u,false,2);
}
}
else {
if(abs(qbar2->id())%2!=0) {
bornLLRRWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,true ,2);
EWLLRRWeights = evaluateRunning(EWProcess::QtQtDD,s,t,u,false,2);
}
else {
bornLLRRWeights = evaluateRunning(EWProcess::QtQtUU,s,t,u,true ,2);
EWLLRRWeights = evaluateRunning(EWProcess::QtQtUU,s,t,u,false,2);
}
}
// RR -> RR
if(abs(qbar1->id())%2==0) {
if(abs(qbar2->id())%2==0) {
if(ident) {
bornRRRRWeights = evaluateRunning(EWProcess::UUUUiden,s,t,u,true ,2);
EWRRRRWeights = evaluateRunning(EWProcess::UUUUiden,s,t,u,false,2);
}
else {
bornRRRRWeights = evaluateRunning(EWProcess::UUUU,s,t,u,true ,2);
EWRRRRWeights = evaluateRunning(EWProcess::UUUU,s,t,u,false,2);
}
}
else {
bornRRRRWeights = evaluateRunning(EWProcess::UUDD,s,t,u,true ,2);
EWRRRRWeights = evaluateRunning(EWProcess::UUDD,s,t,u,false,2);
}
}
else {
if(abs(qbar2->id())%2==0) {
bornRRRRWeights = evaluateRunning(EWProcess::UUDD,s,t,u,true ,2);
EWRRRRWeights = evaluateRunning(EWProcess::UUDD,s,t,u,false,2);
}
else {
if(ident) {
bornRRRRWeights = evaluateRunning(EWProcess::DDDDiden,s,t,u,true ,2);
EWRRRRWeights = evaluateRunning(EWProcess::DDDDiden,s,t,u,false,2);
}
else {
bornRRRRWeights = evaluateRunning(EWProcess::DDDD,s,t,u,true ,2);
EWRRRRWeights = evaluateRunning(EWProcess::DDDD,s,t,u,false,2);
}
}
}
// extra terms for identical particles
boost::numeric::ublas::matrix<complex<InvEnergy2> >
borntChannelWeights,EWtChannelWeights;
if(ident) {
if(abs(qbar1->id())%2==0) {
borntChannelWeights = evaluateRunning(EWProcess::QQUU,s,u,t,true ,2);
EWtChannelWeights = evaluateRunning(EWProcess::QQUU,s,u,t,false,2);
}
else if(abs(qbar1->id())==5) {
borntChannelWeights = evaluateRunning(EWProcess::QtQtDD,s,u,t,true ,2);
EWtChannelWeights = evaluateRunning(EWProcess::QtQtDD,s,u,t,false,2);
}
else {
borntChannelWeights = evaluateRunning(EWProcess::QQDD,s,u,t,true ,2);
EWtChannelWeights = evaluateRunning(EWProcess::QQDD,s,u,t,false,2);
}
}
SpinorBarWaveFunction qbar1w(p1,qbar1,incoming);
SpinorBarWaveFunction qbar2w(p2,qbar2,incoming);
SpinorWaveFunction qbar3w(p3,qbar3,outgoing);
SpinorWaveFunction qbar4w(p4,qbar4,outgoing);
boost::numeric::ublas::matrix<Complex>
bornME = boost::numeric::ublas::zero_matrix<Complex>(2,2),
EWME = boost::numeric::ublas::zero_matrix<Complex>(2,2);
for(unsigned int iq1=0;iq1<2;++iq1) {
qbar1w.reset(iq1);
qbar3w.reset(iq1);
LorentzVector<complex<Energy> > current1 =
qbar3w.dimensionedWave().vectorCurrent(qbar1w.dimensionedWave());
for(unsigned int iq2=0;iq2<2;++iq2) {
qbar2w.reset(iq2);
qbar4w.reset(iq2);
LorentzVector<complex<Energy> > current2 =
qbar4w.dimensionedWave().vectorCurrent(qbar2w.dimensionedWave());
complex<Energy2> amp = current1.dot(current2);
vector<Complex> Cborn(2),CEW(2);
// amplitudes
if(iq1==1) {
// LL
if(iq2==1) {
unsigned int ioff;
if(abs(qbar1->id())%2==0) {
ioff = abs(qbar2->id())%2==0 ? 0 : 2;
}
else {
ioff = abs(qbar2->id())%2==0 ? 1 : 3;
}
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*bornLLLLWeights(6*ix+ioff,0);
CEW [ix] = amp* EWLLLLWeights(6*ix+ioff,0);
}
}
// LR
else {
unsigned int ioff = abs(qbar1->id())%2==0 ? 0 : 1;
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*bornLLRRWeights(2*ix+ioff,0);
CEW [ix] = amp* EWLLRRWeights(2*ix+ioff,0);
}
}
}
else {
if(iq2==1) {
unsigned int ioff=abs(qbar2->id())%2==0 ? 0 : 1;
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*bornRRLLWeights(2*ix+ioff,0);
CEW [ix] = amp* EWRRLLWeights(2*ix+ioff,0);
}
}
else {
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*bornRRRRWeights(ix,0);
CEW [ix] = amp* EWRRRRWeights(ix,0);
}
}
}
// square
for(unsigned int ix=0;ix<2;++ix) {
for(unsigned int iy=0;iy<2;++iy) {
bornME(ix,iy) += Cborn[ix]*conj(Cborn[iy]);
EWME (ix,iy) += CEW [ix]*conj(CEW [iy]);
}
}
}
}
// extra u-channel pieces if identical flavours
if(ident) {
for(unsigned int iq1=0;iq1<2;++iq1) {
qbar1w.reset(iq1);
qbar4w.reset(iq1);
LorentzVector<complex<Energy> > current1 =
qbar4w.dimensionedWave().vectorCurrent(qbar1w.dimensionedWave());
if(iq1==0) {
qbar2w.reset(1);
qbar3w.reset(1);
}
else {
qbar2w.reset(0);
qbar3w.reset(0);
}
LorentzVector<complex<Energy> > current2 =
qbar3w.dimensionedWave().vectorCurrent(qbar2w.dimensionedWave());
complex<Energy2> amp = current1.dot(current2);
vector<Complex> Cborn(2),CEW(2);
unsigned int ioff = abs(qbar1->id())%2==0 ? 0 : 1;
for(unsigned int ix=0;ix<2;++ix) {
Cborn[ix] = amp*borntChannelWeights(2*ix+ioff,0);
CEW [ix] = amp* EWtChannelWeights(2*ix+ioff,0);
}
// square
for(unsigned int ix=0;ix<2;++ix) {
for(unsigned int iy=0;iy<2;++iy) {
bornME(ix,iy) += Cborn[ix]*conj(Cborn[iy]);
EWME (ix,iy) += CEW [ix]*conj(CEW [iy]);
}
}
}
}
// colour factors
double born = 2.*real(bornME(0,0))+9.*real(bornME(1,1));
double EW = 2.*real( EWME(0,0))+9.*real( EWME(1,1));
return EW/born;
}
diff --git a/MatrixElement/EW/HighEnergyMatching.cc b/MatrixElement/EW/HighEnergyMatching.cc
--- a/MatrixElement/EW/HighEnergyMatching.cc
+++ b/MatrixElement/EW/HighEnergyMatching.cc
@@ -1,1179 +1,1181 @@
// -*- C++ -*-
//
// HighEnergyMatching.cc is a part of Herwig - A multi-purpose Monte Carlo event generator
//
// Herwig is licenced under version 2 of the GPL, see COPYING for details.
// Please respect the MCnet academic guidelines, see GUIDELINES for details.
//
//
//
#include "HighEnergyMatching.h"
#include "ElectroWeakReweighter.h"
#include "GroupInvariants.h"
#include <boost/numeric/ublas/operation.hpp>
#include <boost/numeric/ublas/vector.hpp>
using namespace Herwig;
using namespace HighEnergyMatching;
using namespace GroupInvariants;
using namespace EWProcess;
namespace {
/**
* \f$M_N\f$, this matrix is used for identical particle scattering
*/
boost::numeric::ublas::matrix<Complex> M_N(unsigned int suN) {
double N(suN);
boost::numeric::ublas::matrix<Complex> M(2,2);
M(0,0) = -1.0/N;
M(0,1) = 2.0;
M(1,0) = 0.5 - 1.0/(2.0*N*N);
M(1,1) = 1.0/N;
return M;
}
#ifdef ThePEG_HAS_UNITS_CHECKING
void axpy_prod_local(const boost::numeric::ublas::matrix<Complex> & A,
const boost::numeric::ublas::matrix<complex<InvEnergy2> > & B,
boost::numeric::ublas::matrix<complex<InvEnergy2> > & C) {
assert(A.size2()==B.size1());
C.resize(A.size1(),B.size2());
for(unsigned int ix=0;ix<A.size1();++ix) {
for(unsigned int iy=0;iy<B.size2();++iy) {
C(ix,iy) = ZERO;
for(unsigned int iz=0;iz<A.size2();++iz) {
C(ix,iy) += A(ix,iz)*B(iz,iy);
}
}
}
}
void axpy_prod_local(const boost::numeric::ublas::matrix<complex<InvEnergy2> > & A,
const boost::numeric::ublas::matrix<Complex> & B,
boost::numeric::ublas::matrix<complex<InvEnergy2> > & C) {
assert(A.size2()==B.size1());
C.resize(A.size1(),B.size2());
for(unsigned int ix=0;ix<A.size1();++ix) {
for(unsigned int iy=0;iy<B.size2();++iy) {
C(ix,iy) = ZERO;
for(unsigned int iz=0;iz<A.size2();++iz) {
C(ix,iy) += A(ix,iz)*B(iz,iy);
}
}
}
}
#else
void axpy_prod_local(const boost::numeric::ublas::matrix<Complex> & A,
const boost::numeric::ublas::matrix<Complex> & B,
boost::numeric::ublas::matrix<Complex> & C) {
+ assert(A.size2()==B.size1());
+ C.resize(A.size1(),B.size2());
axpy_prod(A,B,C);
}
#endif
}
boost::numeric::ublas::matrix<complex<InvEnergy2> >
HighEnergyMatching::highEnergyMatching(Energy highScale,
Energy2 s, Energy2 t, Energy2 u,
EWProcess::Process process,
bool oneLoop, bool includeAlphaS2) {
switch (process) {
case QQQQ: case QQQQiden:
case QtQtQQ: case QQUU:
case QtQtUU: case QQtRtR:
case QQDD: case QtQtDD:
case QQLL: case QQEE:
case UUUU: case UUUUiden:
case tRtRUU: case UUDD:
case tRtRDD: case UULL:
case UUEE: case DDDD:
case DDDDiden: case DDLL:
case DDEE: case LLLL:
case LLLLiden: case LLEE:
case EEEE: case EEEEiden:
return SpinHalfMatching(highScale,s,t,u,process,oneLoop,includeAlphaS2);
break;
case QQWW:
case QQWG:
case QQBG:
case QQGG:
case QtQtGG:
case LLWW:
case UUBB:
case UUBG:
case UUGG:
case tRtRGG:
case DDBB:
case DDBG:
case DDGG:
case EEBB:
return Spin1HighMatching(highScale,s,t,u,process,oneLoop,includeAlphaS2);
break;
case QQPhiPhi:
case LLPhiPhi:
case UUPhiPhi:
case DDPhiPhi:
case EEPhiPhi:
return Spin0HighMatching(highScale,s,t,u,process,oneLoop,includeAlphaS2);
break;
default:
assert(false);
break;
}
}
boost::numeric::ublas::matrix<complex<InvEnergy2> >
HighEnergyMatching::SpinHalfMatching(Energy highScale,
Energy2 s, Energy2 t, Energy2 u,
EWProcess::Process process,
bool oneLoop, bool includeAlphaS2) {
using Constants::pi;
boost::numeric::ublas::matrix<complex<InvEnergy2> > highC;
Energy Q = highScale;
double a1 = ElectroWeakReweighter::coupling()->a1(Q);
double a2 = ElectroWeakReweighter::coupling()->a2(Q);
double a3 = ElectroWeakReweighter::coupling()->a3(Q);
double y_t = ElectroWeakReweighter::coupling()->y_t(Q);
unsigned int order = !oneLoop ? 0 : 1;
double Yi(0.),Yf(0.);
Complex Ls = MinusLog(-s/(Q*Q));
double C_A_2 = C_A(2);
double C_A_3 = C_A(3);
double C_F_2 = C_F(2);
double C_F_3 = C_F(3);
double C_d_2 = C_d(2);
double C_d_3 = C_d(3);
double C_1_2 = C_1(2);
double C_1_3 = C_1(3);
Complex W = WFunction(Q,s);
Complex X_2_st = XNFunction(2,Q,s,t);
//Complex X_2_su = XNFunction(2,Q,s,u);
Complex X_3_st = XNFunction(3,Q,s,t);
Complex X_3_su = XNFunction(3,Q,s,u);
Complex PI1 = PI1_function(Q,s);
Complex fTilde_st = fTildeFunction(Q,s,t);
Complex fTilde_su = fTildeFunction(Q,s,u);
switch (process) {
case QQQQ:
// NOTE this 4x1 column vector highC is given by (C_11,C_21,C_12,C_22),
// where C_12 is the coeff. for the term that transforms under SU(2) but not SU(3)
Yi = Yf = 1./6.;
highC.resize(4,1);
highC(0,0) = ZERO;
highC(2,0) = 4.0*pi*a2 / s;
highC(1,0) = 4.0*pi*a3 / s;
highC(3,0) = 4.0*pi*a1*Yi*Yf / s;
if (order >= 1) {
highC(0,0) += (1.0/s)*(-2.0*a2*a3*fTilde_st);
highC(2,0) += (1.0/s)*(a2*a2*(X_2_st-(C_d_2+C_A_2)/4.0*fTilde_st) +
2.0*(a1*a2*Yi*Yf+a2*a3*C_F_3)*W -
2.0*a1*a2*Yi*Yf*fTilde_st);
highC(1,0) += (1.0/s)*(2.0*(a1*a3*Yi*Yf+a2*a3*C_F_2)*W -
2.0*a1*a3*Yi*Yf*fTilde_st);
highC(3,0) += (1.0/s)*(-1.0*(a2*a2*C_1_2+a1*a1*Yi*Yi*Yf*Yf)*fTilde_st +
a1*a1*Yi*Yf*PI1 +
2.0*(a1*a3*Yi*Yf*C_F_3+a1*a2*Yi*Yf*C_F_2+a1*a1*Yi*Yi*Yf*Yf)*W);
if (includeAlphaS2) {
highC(1,0) += (1.0/s)*(a3*a3*(X_3_st-(C_d_3+C_A_3)/4.0*fTilde_st));
highC(3,0) += (1.0/s)*(-1.0*(a3*a3*C_1_3)*fTilde_st);
}
}
break;
case QQQQiden:
{
Process parentCase = QQQQ;
boost::numeric::ublas::matrix<complex<InvEnergy2> >
highCs_st = highEnergyMatching(Q,s,t,u,parentCase,oneLoop,includeAlphaS2);
boost::numeric::ublas::matrix<complex<InvEnergy2> >
highCs_ts = highEnergyMatching(Q,t,s,u,parentCase,oneLoop,includeAlphaS2);
boost::numeric::ublas::matrix<complex<InvEnergy2> > highCt_st(4,1);
boost::numeric::ublas::matrix<complex<InvEnergy2> > highCs_ts_2x2(2,2);
highCs_ts_2x2(0,0) = highCs_ts(0,0);
highCs_ts_2x2(1,0) = highCs_ts(1,0);
highCs_ts_2x2(0,1) = highCs_ts(2,0);
highCs_ts_2x2(1,1) = highCs_ts(3,0);
boost::numeric::ublas::matrix<Complex> temp(2,2);
temp = boost::numeric::ublas::trans(M_N(3));
boost::numeric::ublas::matrix<complex<InvEnergy2> > highCt_st_2x2(2,2),temp2(2,2);
axpy_prod_local(highCs_ts_2x2,temp,temp2);
axpy_prod_local(M_N(2),temp2,highCt_st_2x2);
highCt_st(0,0) = highCt_st_2x2(0,0);
highCt_st(1,0) = highCt_st_2x2(1,0);
highCt_st(2,0) = highCt_st_2x2(0,1);
highCt_st(3,0) = highCt_st_2x2(1,1);
highC = highCs_st + highCt_st;
}
break;
case QtQtQQ:
{
highC.resize(4,1);
Process parentCase = QQQQ;
highC = highEnergyMatching(Q,s,t,u,parentCase,oneLoop,includeAlphaS2);
double Y = 1.0/6.0; // Hypercharge of the non-3rd-gen doublet (still a quark doublet).
if (order >= 1) {
highC(2,0) += y_t*y_t*a2/(4.0*pi*s)*(3.0/2.0-0.5*Ls);
highC(1,0) += y_t*y_t*a3/(4.0*pi*s)*(1.0/2.0-0.5*Ls);
highC(3,0) += y_t*y_t*a1*Y/(4.0*pi*s)*(-5.0/12.0-1.0/12.0*Ls);
}
}
break;
case QQUU:
Yi = 1./6.; Yf = 2./3.;
highC.resize(2,1);
highC(0,0) = 4.0*pi*a3 / s;
highC(1,0) = 4.0*pi*a1*Yi*Yf / s;
if (order >= 1) {
highC(0,0) += (1.0/s)*((a1*a3*(Yi*Yi+Yf*Yf)+a2*a3*C_F_2)*W +
2.0*a1*a3*Yi*Yf*fTilde_su);
highC(1,0) += (1.0/s)*(a1*a1*Yi*Yf*PI1 +
(a1*a2*Yi*Yf*C_F_2+2.0*a1*a3*Yi*Yf*C_F_3+
a1*a1*(Yi*Yi*Yi*Yf+Yf*Yf*Yf*Yi))*W);
if (includeAlphaS2) {
highC(0,0) += (1.0/s)*(a3*a3*(X_3_su+(C_d_3-C_A_3)/4.0*fTilde_su));
highC(1,0) += (1.0/s)*((a3*a3*C_1_3+a1*a1*Yi*Yi*Yf*Yf)*fTilde_su);
}
}
break;
case QtQtUU:
{
highC.resize(2,1);
Process parentCase = QQUU;
highC = highEnergyMatching(Q,s,t,u,parentCase,oneLoop,includeAlphaS2);
double Y = 2./3.;
if (order >= 1) {
highC(0,0) += y_t*y_t*a3/(4.0*pi*s)*(1.0/2.0-0.5*Ls);
highC(1,0) += y_t*y_t*a1*Y/(4.0*pi*s)*(-5.0/12.0-1.0/12.0*Ls);
}
}
break;
case QQtRtR:
{
highC.resize(2,1);
Process parentCase = QQUU;
highC = highEnergyMatching(Q,s,t,u,parentCase,oneLoop,includeAlphaS2);
double Y = 1.0/6.0;
if (order >= 1) {
highC(0,0) += y_t*y_t*a3/(4.0*pi*s)*(1.0-Ls);
highC(1,0) += y_t*y_t*a1*Y/(4.0*pi*s)*(5.0/3.0-2.0/3.0*Ls);
}
}
break;
case QQDD:
Yi = 1./6.; Yf = -1./3.;
highC.resize(2,1);
highC(0,0) = 4.0*pi*a3 / s;
highC(1,0) = 4.0*pi*a1*Yi*Yf / s;
if (order >= 1) {
highC(0,0) += (1.0/s)*((a1*a3*(Yi*Yi+Yf*Yf)+a2*a3*C_F_2)*W +
2.0*a1*a3*Yi*Yf*fTilde_su);
highC(1,0) += (1.0/s)*(a1*a1*Yi*Yf*PI1 +
(a1*a2*Yi*Yf*C_F_2+2.0*a1*a3*Yi*Yf*C_F_3+
a1*a1*(Yi*Yi*Yi*Yf+Yf*Yf*Yf*Yi))*W);
if (includeAlphaS2) {
highC(0,0) += (1.0/s)*(a3*a3*(X_3_su+(C_d_3-C_A_3)/4.0*fTilde_su));
highC(1,0) += (1.0/s)*((a3*a3*C_1_3+a1*a1*Yi*Yi*Yf*Yf)*fTilde_su);
}
}
break;
case QtQtDD:
{
highC.resize(2,1);
Process parentCase = QQDD;
highC = highEnergyMatching(Q,s,t,u,parentCase,oneLoop,includeAlphaS2);
double Y = -1./3.;
if (order >= 1) {
highC(0,0) += y_t*y_t*a3/(4.0*pi*s)*(1.0/2.0-0.5*Ls);
highC(1,0) += y_t*y_t*a1*Y/(4.0*pi*s)*(-5.0/12.0-1.0/12.0*Ls);
}
}
break;
case QQLL:
Yi = 1./6.; Yf = -1./2.;
highC.resize(2,1);
highC(0,0) = 4.0*pi*a2 / s;
highC(1,0) = 4.0*pi*a1*Yi*Yf / s;
if (order >= 1) {
highC(0,0) += (1.0/s)*(a2*a2*(X_2_st-(C_d_2+C_A_2)/4.0*fTilde_st) +
(a2*a3*C_F_3 + a1*a2*(Yi*Yi+Yf*Yf))*W -
2.0*a1*a2*Yi*Yf*fTilde_st);
highC(1,0) += (1.0/s)*(-1.0*(a2*a2*C_1_2+a1*a1*Yi*Yi*Yf*Yf)*fTilde_st +
a1*a1*Yi*Yf*PI1 +
(a1*a3*Yi*Yf*C_F_3+2.0*a1*a2*Yi*Yf*C_F_2+
a1*a1*(Yi*Yi*Yi*Yf+Yf*Yf*Yf*Yi))*W);
}
break;
case QQEE:
Yi = 1./6.; Yf = -1.;
highC.resize(1,1);
highC(0,0) = 4.0*pi*a1*Yi*Yf / s;
if (order >= 1) {
highC(0,0) += (1.0/s)*(a1*a1*Yi*Yi*Yf*Yf*fTilde_su + a1*a1*Yi*Yf*PI1 +
(a1*a3*Yi*Yf*C_F_3 + a1*a2*Yi*Yf*C_F_2 +
a1*a1*(Yi*Yi*Yi*Yf+Yf*Yf*Yf*Yi))*W);
}
break;
case UUUU:
Yi = Yf = 2./3.;
highC.resize(2,1);
highC(0,0) = 4.0*pi*a3 / s;
highC(1,0) = 4.0*pi*a1*Yi*Yf / s;
if (order >= 1) {
highC(0,0) += (1.0/s)*(-2.0*a1*a3*Yi*Yf*fTilde_st +
a1*a3*(Yi*Yi+Yf*Yf)*W);
highC(1,0) += (1.0/s)*(-1.0*(a1*a1*Yi*Yi*Yf*Yf)*fTilde_st +
a1*a1*Yi*Yf*PI1 +
(2.0*a1*a3*Yi*Yf*C_F_3+a1*a1*(Yi*Yi*Yi*Yf+Yf*Yf*Yf*Yi))*W);
if (includeAlphaS2) {
highC(0,0) += (1.0/s)*(a3*a3*(X_3_st-(C_d_3+C_A_3)/4.0*fTilde_st));
highC(1,0) += (1.0/s)*(-1.0*(a3*a3*C_1_3)*fTilde_st);
}
}
break;
case UUUUiden:
{
Process parentCase = UUUU;
boost::numeric::ublas::matrix<complex<InvEnergy2> >
highCs_st = highEnergyMatching(Q,s,t,u,parentCase,oneLoop,includeAlphaS2);
boost::numeric::ublas::matrix<complex<InvEnergy2> >
highCs_ts = highEnergyMatching(Q,t,s,u,parentCase,oneLoop,includeAlphaS2);
boost::numeric::ublas::matrix<complex<InvEnergy2> > highCt_st;
axpy_prod_local(M_N(3),highCs_ts,highCt_st);
highC = highCs_st + highCt_st;
}
break;
case tRtRUU:
{
highC.resize(2,1);
Process parentCase = UUUU;
highC = highEnergyMatching(Q,s,t,u,parentCase,oneLoop,includeAlphaS2);
double Y = 2./3.;
if (order >= 1) {
highC(0,0) += y_t*y_t*a3/(4.0*pi*s)*(1.0-Ls);
highC(1,0) += y_t*y_t*a1*Y/(4.0*pi*s)*(5.0/3.0-2.0/3.0*Ls);
}
}
break;
case UUDD:
Yi = 2./3.; Yf = -1./3.;
highC.resize(2,1);
highC(0,0) = 4.0*pi*a3 / s;
highC(1,0) = 4.0*pi*a1*Yi*Yf / s;
if (order >= 1) {
highC(0,0) += (1.0/s)*(-2.0*a1*a3*Yi*Yf*fTilde_st +
a1*a3*(Yi*Yi+Yf*Yf)*W);
highC(1,0) += (1.0/s)*(-1.0*(a1*a1*Yi*Yi*Yf*Yf)*fTilde_st +
a1*a1*Yi*Yf*PI1 +
(2.0*a1*a3*Yi*Yf*C_F_3+a1*a1*(Yi*Yi*Yi*Yf+Yf*Yf*Yf*Yi))*W);
if (includeAlphaS2) {
highC(0,0) += (1.0/s)*(a3*a3*(X_3_st-(C_d_3+C_A_3)/4.0*fTilde_st));
highC(1,0) += (1.0/s)*(-1.0*(a3*a3*C_1_3)*fTilde_st);
}
}
break;
case tRtRDD:
{
highC.resize(2,1);
Process parentCase = UUDD;
highC = highEnergyMatching(Q,s,t,u,parentCase,oneLoop,includeAlphaS2);
double Y = -1./3.;
if (order >= 1) {
highC(0,0) += y_t*y_t*a3/(4.0*pi*s)*(1.0-Ls);
highC(1,0) += y_t*y_t*a1*Y/(4.0*pi*s)*(5.0/3.0-2.0/3.0*Ls);
}
}
break;
case UULL:
Yi = 2./3.; Yf = -0.5;
highC.resize(1,1);
highC(0,0) = 4.0*pi*a1*Yi*Yf / s;
if (order >= 1) {
highC(0,0) += (1.0/s)*(a1*a1*Yi*Yi*Yf*Yf*fTilde_su + a1*a1*Yi*Yf*PI1 +
(a1*a3*Yi*Yf*C_F_3 + a1*a2*Yi*Yf*C_F_2 +
a1*a1*(Yi*Yi*Yi*Yf+Yf*Yf*Yf*Yi))*W);
}
break;
case UUEE:
Yi = 2./3.; Yf = -1.;
highC.resize(1,1);
highC(0,0) = 4.0*pi*a1*Yi*Yf / s;
if (order >= 1) {
highC(0,0) += (1.0/s)*(-1.0*a1*a1*Yi*Yi*Yf*Yf*fTilde_st + a1*a1*Yi*Yf*PI1 +
(a1*a3*Yi*Yf*C_F_3 +
a1*a1*(Yi*Yi*Yi*Yf+Yf*Yf*Yf*Yi))*W);
}
break;
case DDDD:
Yi = Yf = -1./3.;
highC.resize(2,1);
highC(0,0) = 4.0*pi*a3 / s;
highC(1,0) = 4.0*pi*a1*Yi*Yf / s;
if (order >= 1) {
highC(0,0) += (1.0/s)*(-2.0*a1*a3*Yi*Yf*fTilde_st +
a1*a3*(Yi*Yi+Yf*Yf)*W);
highC(1,0) += (1.0/s)*(-1.0*(a1*a1*Yi*Yi*Yf*Yf)*fTilde_st +
a1*a1*Yi*Yf*PI1 +
(2.0*a1*a3*Yi*Yf*C_F_3+a1*a1*(Yi*Yi*Yi*Yf+Yf*Yf*Yf*Yi))*W);
if (includeAlphaS2) {
highC(0,0) += (1.0/s)*(a3*a3*(X_3_st-(C_d_3+C_A_3)/4.0*fTilde_st));
highC(1,0) += (1.0/s)*(-1.0*(a3*a3*C_1_3)*fTilde_st);
}
}
break;
case DDDDiden:
{
Process parentCase = DDDD;
boost::numeric::ublas::matrix<complex<InvEnergy2> >
highCs_st = highEnergyMatching(Q,s,t,u,parentCase,oneLoop,includeAlphaS2);
boost::numeric::ublas::matrix<complex<InvEnergy2> >
highCs_ts = highEnergyMatching(Q,t,s,u,parentCase,oneLoop,includeAlphaS2);
boost::numeric::ublas::matrix<complex<InvEnergy2> > highCt_st;
axpy_prod_local(M_N(3),highCs_ts,highCt_st);
highC = highCs_st + highCt_st;
}
break;
case DDLL:
Yi = -1./3.; Yf = -0.5;
highC.resize(1,1);
highC(0,0) = 4.0*pi*a1*Yi*Yf / s;
if (order >= 1) {
highC(0,0) += (1.0/s)*(a1*a1*Yi*Yi*Yf*Yf*fTilde_su + a1*a1*Yi*Yf*PI1 +
(a1*a3*Yi*Yf*C_F_3 + a1*a2*Yi*Yf*C_F_2 +
a1*a1*(Yi*Yi*Yi*Yf+Yf*Yf*Yf*Yi))*W);
}
break;
case DDEE:
Yi = -1./3.; Yf = -1.;
highC.resize(1,1);
highC(0,0) = 4.0*pi*a1*Yi*Yf / s;
if (order >= 1) {
highC(0,0) += (1.0/s)*(-1.0*a1*a1*Yi*Yi*Yf*Yf*fTilde_st + a1*a1*Yi*Yf*PI1 +
(a1*a3*Yi*Yf*C_F_3 +
a1*a1*(Yi*Yi*Yi*Yf+Yf*Yf*Yf*Yi))*W);
}
break;
case LLLL:
Yi = Yf = -0.5;
highC.resize(2,1);
highC(0,0) = 4.0*pi*a2 / s;
highC(1,0) = 4.0*pi*a1*Yi*Yf / s;
if (order >= 1) {
highC(0,0) += (1.0/s)*(a2*a2*(X_2_st-(C_d_2+C_A_2)/4.0*fTilde_st) +
2.0*a1*a2*Yi*Yf*W -
2.0*a1*a2*Yi*Yf*fTilde_st);
highC(1,0) += (1.0/s)*(-1.0*(a2*a2*C_1_2+a1*a1*Yi*Yi*Yf*Yf)*fTilde_st +
a1*a1*Yi*Yf*PI1 +
2.0*(a1*a2*Yi*Yf*C_F_2+a1*a1*Yi*Yi*Yf*Yf)*W);
}
break;
case LLLLiden:
{
Process parentCase = LLLL;
boost::numeric::ublas::matrix<complex<InvEnergy2> >
highCs_st = highEnergyMatching(Q,s,t,u,parentCase,oneLoop,includeAlphaS2);
boost::numeric::ublas::matrix<complex<InvEnergy2> >
highCs_ts = highEnergyMatching(Q,t,s,u,parentCase,oneLoop,includeAlphaS2);
boost::numeric::ublas::matrix<complex<InvEnergy2> > highCt_st;
axpy_prod_local(M_N(2), highCs_ts, highCt_st);
highC = highCs_st + highCt_st;
}
break;
case LLEE:
Yi = -0.5; Yf = -1.;
highC.resize(1,1);
highC(0,0) = 4.0*pi*a1*Yi*Yf / s;
if (order >= 1) {
highC(0,0) += (1.0/s)*(a1*a1*Yi*Yi*Yf*Yf*fTilde_su + a1*a1*Yi*Yf*PI1 +
(a1*a2*Yi*Yf*C_F_2 +
a1*a1*(Yi*Yi*Yi*Yf+Yf*Yf*Yf*Yi))*W);
}
break;
case EEEE:
Yi = Yf = -1.;
highC.resize(1,1);
highC(0,0) = 4.0*pi*a1*Yi*Yf / s;
if (order >= 1) {
highC(0,0) += (1.0/s)*(-1.0*a1*a1*Yi*Yi*Yf*Yf*fTilde_st + a1*a1*Yi*Yf*PI1 +
2.0*a1*a1*Yi*Yi*Yf*Yf*W);
}
break;
case EEEEiden:
{
Process parentCase = EEEE;
boost::numeric::ublas::matrix<complex<InvEnergy2> >
highCs_st = highEnergyMatching(Q,s,t,u,parentCase,oneLoop,includeAlphaS2);
boost::numeric::ublas::matrix<complex<InvEnergy2> >
highCs_ts = highEnergyMatching(Q,t,s,u,parentCase,oneLoop,includeAlphaS2);
boost::numeric::ublas::matrix<complex<InvEnergy2> >
highCt_st = highCs_ts;
highC = highCs_st + highCt_st;
}
break;
default:
assert(false);
}
return highC;
}
boost::numeric::ublas::matrix<complex<InvEnergy2> >
HighEnergyMatching::Spin1HighMatching(Energy highScale,
Energy2 s, Energy2 t, Energy2 u,
EWProcess::Process process,
bool oneLoop, bool includeAlphaS2) {
using Constants::pi;
unsigned int order = !oneLoop ? 0 : 1;
// (If crossed graphs, swap s and t here)
Complex L_s = MinusLog(-s/(highScale*highScale));
Complex L_t = MinusLog(-t/(highScale*highScale));
Complex L_u = MinusLog(-u/(highScale*highScale));
Complex L_s2 = L_s*L_s;
Complex L_t2 = L_t*L_t;
Complex L_u2 = L_u*L_u;
// Tree-Level:
// Topology types defined. Note each of these is a vector of 5 entries. They are the coefficients
// for the dirac structures M_0, M_1, M_4, M_5, and M_6 for vector boson production.
boost::numeric::ublas::vector<complex<InvEnergy2> > R1(5);
for(unsigned int ix=0;ix<5;++ix) R1[ix] = ZERO;
R1[0] = -1.0/t;
R1[1] = -2.0/t;
R1[2] = ZERO;
R1[3] = ZERO;
R1[4] = ZERO;
boost::numeric::ublas::vector<complex<InvEnergy2> > R1_bar(5);
for(unsigned int ix=0;ix<5;++ix) R1_bar[ix] = ZERO;
R1_bar[0] = -1.0/u;
boost::numeric::ublas::vector<complex<InvEnergy2> > R2(5);
for(unsigned int ix=0;ix<5;++ix) R2[ix] = ZERO;
R2[1] = -1.0/s*2.0;
// Topologies T1:
boost::numeric::ublas::vector<complex<InvEnergy2> > T1a(5);
for(unsigned int ix=0;ix<5;++ix) T1a[ix] = ZERO;
T1a[0] = 1.0/(t*u)*(-3.0*t*L_s2-(s+4.0*t)*L_t2+2.0*(s+4.0*t)*L_s*L_t+2.0*u*L_t-
pi*pi*(7.0/6.0*s+25.0/6.0*t)-4.0*u);
T1a[1] = 1.0/(u*u*t*s)*(0.5*t*(9.0*s*s+14.0*s*t+7.0*t*t)*L_s2+s*(2.0*s+t)*(s+2.0*t)*L_t2-
2.0*(2.0*s*s*s+9.0*s*s*t+10.0*s*t*t+4.0*t*t*t)*L_s*L_t-
2.0*t*t*u*L_s-2.0*u*s*(2.0*s+3.0*t)*L_t+
pi*pi*(7.0/3.0*s*s*s+125.0/12.0*s*s*t+71.0/6.0*s*t*t+
19.0/4.0*t*t*t)-
8.0*s*s*s-20.0*s*s*t-16.0*s*t*t-4.0*t*t*t);
T1a[2] = 1.0/(t*u*u)*(-t*(3.0*s+4.0*t)*L_s2-(s*s+5.0*s*t+5.0*t*t)*L_t2+
2.0*t*(3.0*s+4.0*t)*L_s*L_t+2.0*u*t*(2.0*s+t)*L_s/s-
2.0*u*t*L_t+pi*pi*(s*s/6.0-8.0/3.0*s*t-23.0/6.0*t*t)+
4.0*t*t*t/s+4.0*s*t+8.0*t*t);
T1a[3] = T1a[2];
T1a[4] = GeV2/(t*u*u*u)*(-4.0*t*(s+2.0*t)*(L_s-L_t)*(L_s-L_t)+
4.0*u*(3.0*s+5.0*t)*(L_s-L_t)-4.0*pi*pi*t*(s+2.0*t)-4.0*u*u);
boost::numeric::ublas::vector<complex<InvEnergy2> > T1b(5);
for(unsigned int ix=0;ix<5;++ix) T1b[ix] = ZERO;
T1b[0] = 1.0/(t*u*s*s)*(-s*t*(2.0*s+3.0*t)*L_u2+s*u*(s+3.0*t)*L_t2+
2.0*s*(s*s+3.0*s*t+3.0*t*t)*L_u*L_t+s*s*t*L_u+s*s*u*L_t-
pi*pi*(7.0/6.0*s*s*s+3.0*s*s*t+3.0*s*t*t)+2.0*s*s*s);
T1b[1] = 1.0/(t*s*s*u)*(3.0*s*t*u*L_u2+s*u*(2.0*s+3.0*t)*L_t2-
2.0*s*u*(2.0*s+3.0*t)*L_u*L_t+2.0*s*s*u*L_t-
pi*pi*(7.0/3.0*s*s*s+16.0/3.0*s*s*t+3.0*s*t*t)+
4.0*s*s*s+4.0*s*s*t);
T1b[2] = 1.0/(t*u*s*s)*(-3.0*s*t*u*(L_u-L_t)*(L_u-L_t)+4.0*s*s*t*L_u+4.0*s*s*u*L_t+
pi*pi*(3.0*s*s*t+3.0*s*t*t)+8.0*s*s*s);
T1b[3] = 1.0/(t*u*s*s)*(s*t*(2.0*s+3.0*t)*L_u2-s*u*(s+3.0*t)*L_t2+6.0*s*t*u*L_u*L_t+
pi*pi*(-1.0/6.0*s*s*s+3.0*s*s*t+3.0*s*t*t));
T1b[4] = 12.0*GeV2/(t*u)*(L_t-L_u);
boost::numeric::ublas::vector<complex<InvEnergy2> > T1c(5);
for(unsigned int ix=0;ix<5;++ix) T1c[ix] = ZERO;
T1c[0] = 1.0/t*(2.0*L_s*L_t-7.0*pi*pi/6.0-L_t2);
T1c[1] = 1.0/(t*u*u)*(s*t*L_s2-(2.0*s*s+3.0*s*t+2.0*t*t)*L_t2+
2.0*(2.0*s*s+3.0*s*t+2.0*t*t)*L_s*L_t+2.0*t*u*(L_s-L_t)-
pi*pi*(7.0/3.0*s*s+11.0/3.0*s*t+7.0/3.0*t*t));
T1c[2] = 1.0/(t*u*u)*(t*(3.0*s+2.0*t)*(L_s-L_t)*(L_s-L_t)+2.0*u*t*L_s+
2.0*u*(2.0*s+t)*L_t+pi*pi*t*(3.0*s+2.0*t)+8.0*u*u);
T1c[3] = T1c[2];
T1c[4] = GeV2/(t*u*u*u)*(4.0*t*(2.0*s+t)*(L_s-L_t)*(L_s-L_t)-4.0*u*(3.0*s+t)*(L_s-L_t)+
4.0*pi*pi*t*(2.0*s+t)-4.0*u*u);
boost::numeric::ublas::vector<complex<InvEnergy2> > T1d(5);
for(unsigned int ix=0;ix<5;++ix) T1d[ix] = ZERO;
T1d[2] = 1.0/s*(-2.0*L_s+4.0);
T1d[3] = T1d[2];
boost::numeric::ublas::vector<complex<InvEnergy2> > T1a_bar(5);
for(unsigned int ix=0;ix<5;++ix) T1a_bar[ix] = ZERO;
T1a_bar[0] = 1.0/(u*t)*(-3.0*u*L_s2-(s+4.0*u)*L_u2+2.0*(s+4.0*u)*L_s*L_u+2.0*t*L_u-
pi*pi*(7.0/6.0*s+25.0/6.0*u)-4.0*t);
T1a_bar[1] = 2.0*T1a_bar[0] -
1.0/(t*t*u*s)*(0.5*u*(9.0*s*s+14.0*s*u+7.0*u*u)*L_s2+s*(2.0*s+u)*(s+2.0*u)*L_u2-
2.0*(2.0*s*s*s+9.0*s*s*u+10.0*s*u*u+4.0*u*u*u)*L_s*L_u-
2.0*u*u*t*L_s-2.0*t*s*(2.0*s+3.0*u)*L_u+
pi*pi*(7.0/3.0*s*s*s+125.0/12.0*s*s*u+71.0/6.0*s*u*u+
19.0/4.0*u*u*u)-
8.0*s*s*s-20.0*s*s*u-16.0*s*u*u-4.0*u*u*u);
T1a_bar[2] = 1.0/(u*t*t)*(-u*(3.0*s+4.0*u)*L_s2-(s*s+5.0*s*u+5.0*u*u)*L_u2+
2.0*u*(3.0*s+4.0*u)*L_s*L_u+2.0*t*u*(2.0*s+u)*L_s/s-
2.0*t*u*L_u+pi*pi*(s*s/6.0-8.0/3.0*s*u-23.0/6.0*u*u)+
4.0*u*u*u/s+4.0*s*u+8.0*u*u);
T1a_bar[3] = T1a_bar[2];
T1a_bar[4] = -GeV2/(u*t*t*t)*(-4.0*u*(s+2.0*u)*(L_s-L_u)*(L_s-L_u)+
4.0*t*(3.0*s+5.0*u)*(L_s-L_u)-4.0*pi*pi*u*(s+2.0*u)-4.0*t*t);
boost::numeric::ublas::vector<complex<InvEnergy2> > T1b_bar(5);
for(unsigned int ix=0;ix<5;++ix) T1b_bar[ix] = ZERO;
T1b_bar[0] = 1.0/(u*t*s*s)*(-s*u*(2.0*s+3.0*u)*L_t2+s*t*(s+3.0*u)*L_u2+
2.0*s*(s*s+3.0*s*u+3.0*u*u)*L_t*L_u+
s*s*u*L_t+s*s*t*L_u-
pi*pi*(7.0/6.0*s*s*s+3.0*s*s*u+3.0*s*u*u)+2.0*s*s*s);
T1b_bar[1] = 2.0*T1b_bar[0] -
1.0/(u*s*s*t)*(3.0*s*u*t*L_t2+s*t*(2.0*s+3.0*u)*L_u2-
2.0*s*t*(2.0*s+3.0*u)*L_t*L_u+2.0*s*s*t*L_u-
pi*pi*(7.0/3.0*s*s*s+16.0/3.0*s*s*u+3.0*s*u*u)+
4.0*s*s*s+4.0*s*s*u);
T1b_bar[3] = 1.0/(u*t*s*s)*(-3.0*s*u*t*(L_t-L_u)*(L_t-L_u)+4.0*s*s*u*L_t+4.0*s*s*t*L_u+
pi*pi*(3.0*s*s*u+3.0*s*u*u)+8.0*s*s*s);
T1b_bar[2] = 1.0/(u*t*s*s)*(s*u*(2.0*s+3.0*u)*L_t2-s*t*(s+3.0*u)*L_u2+6.0*s*u*t*L_t*L_u+
pi*pi*(-1.0/6.0*s*s*s+3.0*s*s*u+3.0*s*u*u));
T1b_bar[4] = -12.0*GeV2/(u*t)*(L_u-L_t);
boost::numeric::ublas::vector<complex<InvEnergy2> > T1c_bar(5);
for(unsigned int ix=0;ix<5;++ix) T1c_bar[ix] = ZERO;
T1c_bar[0] = 1.0/u*(2.0*L_s*L_u-7.0*pi*pi/6.0-L_u2);
T1c_bar[1] = 2.0*T1c_bar[0] -
1.0/(u*t*t)*(s*u*L_s2-(2.0*s*s+3.0*s*u+2.0*u*u)*L_u2+
2.0*(2.0*s*s+3.0*s*u+2.0*u*u)*L_s*L_u+2.0*u*t*(L_s-L_u)-
pi*pi*(7.0/3.0*s*s+11.0/3.0*s*u+7.0/3.0*u*u));
T1c_bar[2] = 1.0/(u*t*t)*(u*(3.0*s+2.0*u)*(L_s-L_u)*(L_s-L_u)+2.0*t*u*L_s+
2.0*t*(2.0*s+u)*L_u+pi*pi*u*(3.0*s+2.0*u)+8.0*t*t);
T1c_bar[3] = T1c_bar[2];
T1c_bar[4] = -GeV2/(u*t*t*t)*(4.0*u*(2.0*s+u)*(L_s-L_u)*(L_s-L_u)-4.0*t*(3.0*s+u)*(L_s-L_u)+
4.0*pi*pi*u*(2.0*s+u)-4.0*t*t);
// Topologies T2:
boost::numeric::ublas::vector<complex<InvEnergy2> > T2a(5);
for(unsigned int ix=0;ix<5;++ix) T2a[ix] = ZERO;
T2a[1] = 1.0/s*(L_s/6.0-11.0/18.0);
boost::numeric::ublas::vector<complex<InvEnergy2> > T2b(5);
for(unsigned int ix=0;ix<5;++ix) T2b[ix] = ZERO;
T2b[1] = 1.0/s*(-2.0/3.0*L_s+22.0/9.0);
boost::numeric::ublas::vector<complex<InvEnergy2> > T2c(5);
for(unsigned int ix=0;ix<5;++ix) T2c[ix] = ZERO;
T2c[1] = 1.0/s*(3.0/2.0*L_s2-17.0/2.0*L_s-pi*pi/4.0+95.0/6.0);
boost::numeric::ublas::vector<complex<InvEnergy2> > T2d(5);
for(unsigned int ix=0;ix<5;++ix) T2d[ix] = ZERO;
T2d[1] = 1.0/s*(-4.0/3.0*L_s+14.0/9.0);
// Topologies T3:
boost::numeric::ublas::vector<complex<InvEnergy2> > T3a(5);
for(unsigned int ix=0;ix<5;++ix) T3a[ix] = ZERO;
T3a[0] = 1.0/t*(L_t2-pi*pi/6.0);
T3a[1] = 2.0*T3a[0];
T3a[3] = 1.0/t*(-L_t2+pi*pi/6.0+2.0);
boost::numeric::ublas::vector<complex<InvEnergy2> > T3b(5);
for(unsigned int ix=0;ix<5;++ix) T3b[ix] = ZERO;
T3b[0] = 1.0/t*(-L_t+4.0);
T3b[1] = 2.0*T3b[0];
T3b[3] = 1.0/t*(4.0*L_t-10.0);
boost::numeric::ublas::vector<complex<InvEnergy2> > T3a_bar(5);
for(unsigned int ix=0;ix<5;++ix) T3a_bar[ix] = ZERO;
T3a_bar[0] = 1.0/u*(L_u2-pi*pi/6.0);
T3a_bar[2] = 1.0/u*(-L_u2+pi*pi/6.0+2.0);
boost::numeric::ublas::vector<complex<InvEnergy2> > T3b_bar(5);
for(unsigned int ix=0;ix<5;++ix) T3b_bar[ix] = ZERO;
T3b_bar[0] = 1.0/u*(-L_u+4.0);
T3b_bar[2] = 1.0/u*(4.0*L_u-10.0);
// Topologies T4:
boost::numeric::ublas::vector<complex<InvEnergy2> > T4a(5);
for(unsigned int ix=0;ix<5;++ix) T4a[ix] = ZERO;
T4a[0] = 1.0/t*(L_t2-pi*pi/6.0);
T4a[1] = 2.0*T4a[0];
T4a[2] = 1.0/t*(-L_t2+pi*pi/6.0+2.0);
boost::numeric::ublas::vector<complex<InvEnergy2> > T4b(5);
for(unsigned int ix=0;ix<5;++ix) T4b[ix] = ZERO;
T4b[0] = 1.0/t*(-L_t+4.0);
T4b[1] = 2.0*T4b[0];
T4b[2] = 1.0/t*(4.0*L_t-10.0);
boost::numeric::ublas::vector<complex<InvEnergy2> > T4a_bar(5);
for(unsigned int ix=0;ix<5;++ix) T4a_bar[ix] = ZERO;
T4a_bar[0] = 1.0/u*(L_u2-pi*pi/6.0);
T4a_bar[3] = 1.0/u*(-L_u2+pi*pi/6.0+2.0);
boost::numeric::ublas::vector<complex<InvEnergy2> > T4b_bar(5);
for(unsigned int ix=0;ix<5;++ix) T4b_bar[ix] = ZERO;
T4b_bar[0] = 1.0/u*(-L_u+4.0);
T4b_bar[3] = 1.0/u*(4.0*L_u-10.0);
// Topologies T5:
boost::numeric::ublas::vector<complex<InvEnergy2> > T5a(5);
for(unsigned int ix=0;ix<5;++ix) T5a[ix] = ZERO;
T5a[1] = 1.0/s*(2.0*L_s-4.0);
boost::numeric::ublas::vector<complex<InvEnergy2> > T5b(5);
for(unsigned int ix=0;ix<5;++ix) T5b[ix] = ZERO;
T5b[1] = 1.0/s*(-2.0*L_s2+6.0*L_s-16.0+pi*pi/3.0);
// Topologies T6:
boost::numeric::ublas::vector<complex<InvEnergy2> > T6a(5);
for(unsigned int ix=0;ix<5;++ix) T6a[ix] = ZERO;
T6a[1] = 1.0/s*(-19.0/6.0*L_s+58.0/9.0);
boost::numeric::ublas::vector<complex<InvEnergy2> > T6b(5);
for(unsigned int ix=0;ix<5;++ix) T6b[ix] = ZERO;
T6b[1] = 1.0/s*(-1.0/6.0*L_s+4.0/9.0);
boost::numeric::ublas::vector<complex<InvEnergy2> > T6c(5);
for(unsigned int ix=0;ix<5;++ix) T6c[ix] = ZERO;
T6c[1] = 1.0/s*(2.0/3.0*L_s-16.0/9.0);
boost::numeric::ublas::vector<complex<InvEnergy2> > T6d(5);
for(unsigned int ix=0;ix<5;++ix) T6d[ix] = ZERO;
T6d[1] = 1.0/s*(4.0/3.0*L_s-20.0/9.0);
// Topology T7:
boost::numeric::ublas::vector<complex<InvEnergy2> > T7(5);
for(unsigned int ix=0;ix<5;++ix) T7[ix] = ZERO;
T7[0] = 1.0/t*(-L_t+1.0);
T7[1] = 2.0*T7[0];
boost::numeric::ublas::vector<complex<InvEnergy2> > T7_bar(5);
for(unsigned int ix=0;ix<5;++ix) T7_bar[ix] = ZERO;
T7_bar[0] = 1.0/u*(-L_u+1.0);
// Group Theory Factors / SM parameters needed for matrix elements:
double a1 = ElectroWeakReweighter::coupling()->a1(highScale);
double a2 = ElectroWeakReweighter::coupling()->a2(highScale);
double a3 = ElectroWeakReweighter::coupling()->a3(highScale);
double y_t = ElectroWeakReweighter::coupling()->y_t(highScale);
// Traces over complex scalars and weyl fermions.
double T_CS_3 = 0.0;
double T_CS_2 = 0.5;
//double T_CS_1 = 0.5;
double T_WF_3 = 2.0*3.0;
double T_WF_2 = 2.0*3.0;
//double T_WF_1 = 10.0/3.0*3.0;
double C_A_3 = 3.0;
double C_A_2 = 2.0;
double C_A_1 = 0.0;
double C_F_3 = 4.0/3.0;
double C_F_2 = 3.0/4.0;
double C_F_1 = 1.0;
// This is the coefficient of the delta term in G_TT
double G_TT = 0.5;
// This is the coeffidient of d^ABC in G_TT (non-zero for SU(3))
double G_TT_3_D = 0.25*C_A_3;
double G_f = 1.0;
// Factors TBD after fermion helicity is specified:
double Y_Q(0.), G_Plus_U1(0.);
double G_Plus_SU2 = 0.25;
double G_Plus_SU3 = 1./6.;
double G_Plus_SU3_D = 0.5;
double Lambda_Q(0.);
// the _s and _ew are the alpha3 and alpha1/2 parts of Lambda_Q
double Lambda_Q_s(0.);
double Lambda_Q_ew(0.);
double rho12(0.), rho13(0.);
double rho23 = sqrt(a2*a3);
double tRorQ = 1.0;
boost::numeric::ublas::matrix<complex<InvEnergy2> > highC(1,1);
switch (process) {
case QQWW: case LLWW:
{
// Finish Group Theory Factors:
if (process==QQWW) {
Y_Q = 1.0/6.0;
G_Plus_U1 = Y_Q*Y_Q;
Lambda_Q = C_F_3*a3 + C_F_2*a2 + Y_Q*Y_Q*C_F_1*a1;
rho12 = Y_Q*sqrt(a1*a2);
}
else if (process==LLWW) {
Y_Q = -1.0/2.0;
G_Plus_U1 = Y_Q*Y_Q;
Lambda_Q = C_F_2*a2 + Y_Q*Y_Q*C_F_1*a1;
rho12 = Y_Q*sqrt(a1*a2);
}
highC.resize(5,5);
for (int i=0; i<5; i++) {
highC(0,i) = G_Plus_SU2*(4.0*pi*a2)*(R1[i]+R1_bar[i]);
highC(1,i) = G_f*4.0*pi*a2*(-0.5*R1[i]+0.5*R1_bar[i]-R2[i]);
highC(2,i) = rho12*4.0*pi*(R1[i]+R1_bar[i]);
highC(3,i) = rho12*4.0*pi*(R1[i]+R1_bar[i]);
highC(4,i) = G_Plus_U1*(4.0*pi*a1)*(R1[i]+R1_bar[i]);
if (order>=1) {
highC(0,i) += G_Plus_SU2*((-0.5*a2*a2*C_A_2)*(T1b[i]+T1b_bar[i])+
a2*(Lambda_Q-a2*C_A_2)*(T1c[i]+T1c_bar[i])+
0.5*a2*a2*C_A_2*(T3a[i]+T3a_bar[i])+
a2*(Lambda_Q-0.5*a2*C_A_2)*(T3b[i]+T3b_bar[i])+
0.5*a2*a2*C_A_2*(T4a[i]+T4a_bar[i])+
a2*(Lambda_Q-0.5*a2*C_A_2)*(T4b[i]+T4b_bar[i])+
a2*Lambda_Q*(T7[i]+T7_bar[i])) +
G_TT*(-a2*a2*(T1a[i]+T1a_bar[i])+a2*a2*(T1b[i]+T1b_bar[i])+
a2*a2*(T1c[i]+T1c_bar[i])+2.0*a2*a2*T1d[i]);
highC(1,i) += G_f*(0.25*a2*a2*C_A_2*(T1a[i]-T1a_bar[i])+
a2*(0.25*a2*C_A_2-0.5*Lambda_Q)*(T1c[i]-T1c_bar[i])+
0.5*a2*a2*C_A_2*T2a[i]+a2*a2*T_CS_2*T2b[i]-
0.5*a2*a2*C_A_2*T2c[i]+a2*a2*T_WF_2*T2d[i]-
0.25*a2*a2*C_A_2*(T3a[i]-T3a_bar[i])-
0.5*a2*(Lambda_Q-0.5*a2*C_A_2)*(T3b[i]-T3b_bar[i])-
0.25*a2*a2*C_A_2*(T4a[i]-T4a_bar[i])-
0.5*a2*(Lambda_Q-0.5*a2*C_A_2)*(T4b[i]-T4b_bar[i])+
0.5*a2*a2*C_A_2*T5a[i]+a2*(Lambda_Q-0.5*a2*C_A_2)*T5b[i]+
a2*a2*C_A_2*T6a[i]+a2*a2*C_A_2*T6b[i]+
a2*a2*T_CS_2*T6c[i]+a2*a2*T_WF_2*T6d[i]-
0.5*a2*Lambda_Q*(T7[i]-T7_bar[i]));
highC(2,i) += rho12*(-0.5*a1*C_A_1*T1b[i]-0.5*a2*C_A_2*T1b_bar[i]+
(Lambda_Q-0.5*a1*C_A_1-0.5*a2*C_A_2)*(T1c[i]+T1c_bar[i])+
0.5*a1*C_A_1*T3a[i]+0.5*a2*C_A_2*T3a_bar[i]+
(Lambda_Q-0.5*a1*C_A_1)*T3b[i]+(Lambda_Q-0.5*a2*C_A_2)*T3b_bar[i]+
0.5*a2*C_A_2*T4a[i]+0.5*a1*C_A_1*T4a_bar[i]+
(Lambda_Q-0.5*a2*C_A_2)*T4b[i]+(Lambda_Q-0.5*a1*C_A_1)*T4b_bar[i]+
Lambda_Q*(T7[i]+T7_bar[i]));
highC(3,i) += rho12*(-0.5*a2*C_A_2*T1b[i]-0.5*a1*C_A_1*T1b_bar[i]+
(Lambda_Q-0.5*a2*C_A_2-0.5*a1*C_A_1)*(T1c[i]+T1c_bar[i])+
0.5*a2*C_A_2*T3a[i]+0.5*a1*C_A_1*T3a_bar[i]+
(Lambda_Q-0.5*a2*C_A_2)*T3b[i]+(Lambda_Q-0.5*a1*C_A_1)*T3b_bar[i]+
0.5*a1*C_A_1*T4a[i]+0.5*a2*C_A_2*T4a_bar[i]+
(Lambda_Q-0.5*a1*C_A_1)*T4b[i]+(Lambda_Q-0.5*a2*C_A_2)*T4b_bar[i]+
Lambda_Q*(T7[i]+T7_bar[i]));
highC(4,i) += G_Plus_U1*((-0.5*a1*a1*C_A_1)*(T1b[i]+T1b_bar[i])+
a1*(Lambda_Q-a1*C_A_1)*(T1c[i]+T1c_bar[i])+
0.5*a1*a1*C_A_1*(T3a[i]+T3a_bar[i])+
a1*(Lambda_Q-0.5*a1*C_A_1)*(T3b[i]+T3b_bar[i])+
0.5*a1*a1*C_A_1*(T4a[i]+T4a_bar[i])+
a1*(Lambda_Q-0.5*a1*C_A_1)*(T4b[i]+T4b_bar[i])+
a1*Lambda_Q*(T7[i]+T7_bar[i]));
}
}
}
break;
case UUBB: case DDBB: case EEBB:
{
// Finish Group Theory Factors:
if (process==UUBB) {
Y_Q = 2.0/3.0;
G_Plus_U1 = Y_Q*Y_Q;
Lambda_Q = C_F_3*a3 + Y_Q*Y_Q*C_F_1*a1;
}
else if (process==DDBB) {
Y_Q = -1.0/3.0;
G_Plus_U1 = Y_Q*Y_Q;
Lambda_Q = C_F_3*a3 + Y_Q*Y_Q*C_F_1*a1;
}
else if (process==EEBB) {
Y_Q = -1.0;
G_Plus_U1 = Y_Q*Y_Q;
Lambda_Q = Y_Q*Y_Q*C_F_1*a1;
}
highC.resize(1,5);
for (int i=0; i<5; i++) {
highC(0,i) = G_Plus_U1*(4.0*pi*a1)*(R1[i]+R1_bar[i]);
if (order>=1) {
highC(0,i) += G_Plus_U1*((-0.5*a1*a1*C_A_1)*(T1b[i]+T1b_bar[i])+
a1*(Lambda_Q-a1*C_A_1)*(T1c[i]+T1c_bar[i])+
0.5*a1*a1*C_A_1*(T3a[i]+T3a_bar[i])+
a1*(Lambda_Q-0.5*a1*C_A_1)*(T3b[i]+T3b_bar[i])+
0.5*a1*a1*C_A_1*(T4a[i]+T4a_bar[i])+
a1*(Lambda_Q-0.5*a1*C_A_1)*(T4b[i]+T4b_bar[i])+
a1*Lambda_Q*(T7[i]+T7_bar[i]));
}
}
}
break;
case QQWG:
{
// Finish Group Theory Factors:
Y_Q = 1./6.;
Lambda_Q = C_F_3*a3 + C_F_2*a2 + Y_Q*Y_Q*C_F_1*a1;
highC.resize(1,5);
for (int i=0; i<5; i++) {
highC(0,i) = rho23*4.0*pi*(R1[i]+R1_bar[i]);
if (order>=1) {
highC(0,i) += rho23*(-0.5*a3*C_A_3*T1b[i]-0.5*a2*C_A_2*T1b_bar[i]+
(Lambda_Q-0.5*a3*C_A_3-0.5*a2*C_A_2)*(T1c[i]+T1c_bar[i])+
0.5*a3*C_A_3*T3a[i]+0.5*a2*C_A_2*T3a_bar[i]+
(Lambda_Q-0.5*a3*C_A_3)*T3b[i]+(Lambda_Q-0.5*a2*C_A_2)*T3b_bar[i]+
0.5*a2*C_A_2*T4a[i]+0.5*a3*C_A_3*T4a_bar[i]+
(Lambda_Q-0.5*a2*C_A_2)*T4b[i]+(Lambda_Q-0.5*a3*C_A_3)*T4b_bar[i]+
Lambda_Q*(T7[i]+T7_bar[i]));
}
}
}
break;
case QQBG:
{
// Finish Group Theory Factors:
Y_Q = 1.0/6.0;
Lambda_Q = C_F_3*a3 + C_F_2*a2 + Y_Q*Y_Q*C_F_1*a1;
rho13 = Y_Q*sqrt(a1*a3);
highC.resize(1,5);
for (int i=0; i<5; i++) {
highC(0,i) = rho13*4.0*pi*(R1[i]+R1_bar[i]);
if (order>=1) {
highC(0,i) += rho13*(-0.5*a3*C_A_3*T1b[i]-0.5*a1*C_A_1*T1b_bar[i]+
(Lambda_Q-0.5*a3*C_A_3-0.5*a1*C_A_1)*(T1c[i]+T1c_bar[i])+
0.5*a3*C_A_3*T3a[i]+0.5*a1*C_A_1*T3a_bar[i]+
(Lambda_Q-0.5*a3*C_A_3)*T3b[i]+(Lambda_Q-0.5*a1*C_A_1)*T3b_bar[i]+
0.5*a1*C_A_1*T4a[i]+0.5*a3*C_A_3*T4a_bar[i]+
(Lambda_Q-0.5*a1*C_A_1)*T4b[i]+(Lambda_Q-0.5*a3*C_A_3)*T4b_bar[i]+
Lambda_Q*(T7[i]+T7_bar[i]));
}
}
}
break;
case UUBG: case DDBG:
{
// Finish Group Theory Factors:
if (process==UUBG) {
Y_Q = 2.0/3.0;
Lambda_Q = C_F_3*a3 + Y_Q*Y_Q*C_F_1*a1;
rho13 = Y_Q*sqrt(a1*a3);
}
else if (process==DDBG) {
Y_Q = -1.0/3.0;
Lambda_Q = C_F_3*a3 + Y_Q*Y_Q*C_F_1*a1;
rho13 = Y_Q*sqrt(a1*a3);
}
highC.resize(1,5);
for (int i=0; i<5; i++) {
highC(0,i) = rho13*4.0*pi*(R1[i]+R1_bar[i]);
if (order>=1) {
highC(0,i) += rho13*(-0.5*a3*C_A_3*T1b[i]-0.5*a1*C_A_1*T1b_bar[i]+
(Lambda_Q-0.5*a3*C_A_3-0.5*a1*C_A_1)*(T1c[i]+T1c_bar[i])+
0.5*a3*C_A_3*T3a[i]+0.5*a1*C_A_1*T3a_bar[i]+
(Lambda_Q-0.5*a3*C_A_3)*T3b[i]+(Lambda_Q-0.5*a1*C_A_1)*T3b_bar[i]+
0.5*a1*C_A_1*T4a[i]+0.5*a3*C_A_3*T4a_bar[i]+
(Lambda_Q-0.5*a1*C_A_1)*T4b[i]+(Lambda_Q-0.5*a3*C_A_3)*T4b_bar[i]+
Lambda_Q*(T7[i]+T7_bar[i]));
}
}
}
break;
case QQGG: case QtQtGG: case UUGG:
case tRtRGG: case DDGG:
{
// Finish Group Theory Factors:
if (process==QQGG || process==QtQtGG) {
Y_Q = 1.0/6.0;
Lambda_Q = C_F_3*a3 + C_F_2*a2 + Y_Q*Y_Q*C_F_1*a1;
Lambda_Q_s = C_F_3*a3;
Lambda_Q_ew = C_F_2*a2 + Y_Q*Y_Q*C_F_1*a1;
}
else if (process==UUGG || process==tRtRGG) {
Y_Q = 2.0/3.0;
Lambda_Q = C_F_3*a3 + Y_Q*Y_Q*C_F_1*a1;
Lambda_Q_s = C_F_3*a3;
Lambda_Q_ew = Y_Q*Y_Q*C_F_1*a1;
}
else if (process==DDGG || process==tRtRGG) {
Y_Q = -1.0/3.0;
Lambda_Q = C_F_3*a3 + Y_Q*Y_Q*C_F_1*a1;
Lambda_Q_s = C_F_3*a3;
Lambda_Q_ew = Y_Q*Y_Q*C_F_1*a1;
}
highC.resize(3,5);
for (int i=0; i<5; i++) {
highC(0,i) = G_Plus_SU3*(4.0*pi*a3)*(R1[i]+R1_bar[i]);
highC(1,i) = G_Plus_SU3_D*(4.0*pi*a3)*(R1[i]+R1_bar[i]);
highC(2,i) = G_f*4.0*pi*a3*(-0.5*R1[i]+0.5*R1_bar[i]-R2[i]);
if (order>=1) {
highC(0,i) += G_Plus_SU3*(a3*(Lambda_Q_ew)*(T1c[i]+T1c_bar[i])+
a3*(Lambda_Q_ew)*(T3b[i]+T3b_bar[i])+
a3*(Lambda_Q_ew)*(T4b[i]+T4b_bar[i])+
a3*Lambda_Q_ew*(T7[i]+T7_bar[i]));
highC(1,i) += G_Plus_SU3_D*(a3*(Lambda_Q_ew)*(T1c[i]+T1c_bar[i])+
a3*(Lambda_Q_ew)*(T3b[i]+T3b_bar[i])+
a3*(Lambda_Q_ew)*(T4b[i]+T4b_bar[i])+
a3*Lambda_Q_ew*(T7[i]+T7_bar[i]));
highC(2,i) += G_f*(a3*(-0.5*Lambda_Q_ew)*(T1c[i]-T1c_bar[i])-
0.5*a3*(Lambda_Q_ew)*(T3b[i]-T3b_bar[i])-
0.5*a3*(Lambda_Q_ew)*(T4b[i]-T4b_bar[i])+
a3*(Lambda_Q_ew)*T5b[i]-
0.5*a3*Lambda_Q_ew*(T7[i]-T7_bar[i]));
if (includeAlphaS2) {
highC(0,i) += G_Plus_SU3*((-0.5*a3*a3*C_A_3)*(T1b[i]+T1b_bar[i])+
a3*(Lambda_Q_s-a3*C_A_3)*(T1c[i]+T1c_bar[i])+
0.5*a3*a3*C_A_3*(T3a[i]+T3a_bar[i])+
a3*(Lambda_Q_s-0.5*a3*C_A_3)*(T3b[i]+T3b_bar[i])+
0.5*a3*a3*C_A_3*(T4a[i]+T4a_bar[i])+
a3*(Lambda_Q_s-0.5*a3*C_A_3)*(T4b[i]+T4b_bar[i])+
a3*Lambda_Q_s*(T7[i]+T7_bar[i])) +
G_TT*(-a3*a3*(T1a[i]+T1a_bar[i])+a3*a3*(T1b[i]+T1b_bar[i])+
a3*a3*(T1c[i]+T1c_bar[i])+2.0*a3*a3*T1d[i]);
highC(1,i) += G_Plus_SU3_D*((-0.5*a3*a3*C_A_3)*(T1b[i]+T1b_bar[i])+
a3*(Lambda_Q_s-a3*C_A_3)*(T1c[i]+T1c_bar[i])+
0.5*a3*a3*C_A_3*(T3a[i]+T3a_bar[i])+
a3*(Lambda_Q_s-0.5*a3*C_A_3)*(T3b[i]+T3b_bar[i])+
0.5*a3*a3*C_A_3*(T4a[i]+T4a_bar[i])+
a3*(Lambda_Q_s-0.5*a3*C_A_3)*(T4b[i]+T4b_bar[i])+
a3*Lambda_Q_s*(T7[i]+T7_bar[i])) +
G_TT_3_D*(-a3*a3*(T1a[i]+T1a_bar[i])+a3*a3*(T1b[i]+T1b_bar[i])+
a3*a3*(T1c[i]+T1c_bar[i])+2.0*a3*a3*T1d[i]);
highC(2,i) += G_f*(0.25*a3*a3*C_A_3*(T1a[i]-T1a_bar[i])+
a3*(0.25*a3*C_A_3-0.5*Lambda_Q_s)*(T1c[i]-T1c_bar[i])+
0.5*a3*a3*C_A_3*T2a[i]+a3*a3*T_CS_3*T2b[i]-
0.5*a3*a3*C_A_3*T2c[i]+a3*a3*T_WF_3*T2d[i]-
0.25*a3*a3*C_A_3*(T3a[i]-T3a_bar[i])-
0.5*a3*(Lambda_Q_s-0.5*a3*C_A_3)*(T3b[i]-T3b_bar[i])-
0.25*a3*a3*C_A_3*(T4a[i]-T4a_bar[i])-
0.5*a3*(Lambda_Q_s-0.5*a3*C_A_3)*(T4b[i]-T4b_bar[i])+
0.5*a3*a3*C_A_3*T5a[i]+a3*(Lambda_Q_s-0.5*a3*C_A_3)*T5b[i]+
a3*a3*C_A_3*T6a[i]+a3*a3*C_A_3*T6b[i]+
a3*a3*T_CS_3*T6c[i]+a3*a3*T_WF_3*T6d[i]-
0.5*a3*Lambda_Q_s*(T7[i]-T7_bar[i]));
}
}
}
if ( (process==QtQtGG||process==tRtRGG) && order>=1) {
if (process==tRtRGG) {
tRorQ = 2.0;
}
else {
tRorQ = 1.0;
}
highC(0,0) += tRorQ*(-1.0*(s*((s+t)*L_t - t*L_u)*y_t*y_t*a3)/(48.*pi*t*u*s));
highC(0,1) += tRorQ*((s*L_t*y_t*y_t*a3)/(24.*pi*t*s));
highC(0,2) += tRorQ*(-(s*s*y_t*y_t*a3)/((24.*pi*s*t+24.*pi*t*t)*s));
highC(0,3) += tRorQ*(-(s*s*y_t*y_t*a3)/((24.*pi*s*t+24.*pi*t*t)*s));
highC(1,0) += tRorQ*(-1.0*(s*((s+t)*L_t - t*L_u)*y_t*y_t*a3)/(16.*pi*t*u*s));
highC(1,1) += tRorQ*((s*L_t*y_t*y_t*a3)/(8.*pi*t*s));
highC(1,2) += tRorQ*(-(s*s*y_t*y_t*a3)/((8.*pi*s*t+8.*pi*t*t)*s));
highC(1,3) += tRorQ*(-(s*s*y_t*y_t*a3)/((8.*pi*s*t+8.*pi*t*t)*s));
highC(2,0) += tRorQ*((s*((s+t)*L_t + t*L_u)*y_t*y_t*a3)/(16.*pi*t*u*s));
highC(2,1) += tRorQ*(((2.*t-2.*t*L_s-s*L_t)*y_t*y_t*a3)/(8.*pi*t*s));
highC(2,2) += tRorQ*(-1.0*(s*(s+2.*t)*y_t*y_t*a3)/(8.*pi*t*u*s));
highC(2,3) += tRorQ*(-1.0*(s*(s+2.*t)*y_t*y_t*a3)/(8.*pi*t*u*s));
}
}
break;
default:
assert(false);
}
return highC;
}
boost::numeric::ublas::matrix<complex<InvEnergy2> >
HighEnergyMatching::Spin0HighMatching(Energy highScale,
Energy2 s, Energy2 t, Energy2 u,
EWProcess::Process process,
bool oneLoop, bool ) {
using Constants::pi;
unsigned int order = !oneLoop? 0 : 1;
// (If crossed graphs, swap s and t here)
Complex L_s = MinusLog(-s/(highScale*highScale));
Complex L_t = MinusLog(-t/(highScale*highScale));
Complex L_u = MinusLog(-u/(highScale*highScale));
Complex L_s2 = L_s*L_s;
Complex L_t2 = L_t*L_t;
Complex L_u2 = L_u*L_u;
// Tree-Level:
complex<InvEnergy2> S1 = 2.0/s;
// Topology T1:
complex<InvEnergy2> T1b = (-L_s2/(2.0*u)*(7.0*t/s+3.0)+2.0/u*L_t2+L_s*L_t*4.0/u*(t-u)/s+
L_s*2.0/s-4.0/s-pi*pi/(4.0*u)*(11.0+19.0*t/s));
complex<InvEnergy2> T1b_bar = -1.0*(-L_s2/(2.0*t)*(7.0*u/s+3.0)+2.0/t*L_u2+L_s*L_u*4.0/t*(u-t)/s+
L_s*2.0/s-4.0/s-pi*pi/(4.0*t)*(11.0+19.0*u/s));
// Topologies T2:
complex<InvEnergy2> T2a = 1.0/s*(-2.0*L_s2+8.0*L_s-16.0+pi*pi/3.0);
complex<InvEnergy2> T2b = 1.0/s*(0.5*L_s2+2.0*L_s-4.0-pi*pi/12.0);
// Topologies T5:
complex<InvEnergy2> T5a = 1.0/s*(-2.0*L_s2+6.0*L_s+pi*pi/3.0-16.0);
complex<InvEnergy2> T5b = 1.0/s*(2.0*L_s-4.0);
// Topologies T6:
complex<InvEnergy2> T6a = 1.0/s*(-19.0/6.0*L_s+58.0/9.0);
complex<InvEnergy2> T6b = 1.0/s*(-1.0/6.0*L_s+4.0/9.0);
complex<InvEnergy2> T6c = 1.0/s*(2.0/3.0*L_s-16.0/9.0);
complex<InvEnergy2> T6d = 1.0/s*(4.0/3.0*L_s-20.0/9.0);
// Group Theory Factors / SM parameters needed for matrix elements:
double a1 = ElectroWeakReweighter::coupling()->a1(highScale);
double a2 = ElectroWeakReweighter::coupling()->a2(highScale);
double a3 = ElectroWeakReweighter::coupling()->a3(highScale);
double y_t = ElectroWeakReweighter::coupling()->y_t(highScale);
double Y_phi = 1.0/2.0;
double C_F_3 = 4.0/3.0;
double C_F_2 = 3.0/4.0;
double C_F_1 = 1.0;
double n_g = 3.0;
double n_S = 1.0;
// Factors TBD after fermion helicity is specified:
double Y_Q(0.), Lambda_Q(0.), Lambda_phi(0.);
boost::numeric::ublas::matrix<complex<InvEnergy2> > highC(1,1);
switch (process) {
case QQPhiPhi: case LLPhiPhi:
// Finish Group Theory Factors:
if (process==QQPhiPhi) {
Y_Q = 1.0/6.0;
Lambda_Q = C_F_3*a3 + C_F_2*a2 + Y_Q*Y_Q*C_F_1*a1;
Lambda_phi = C_F_2*a2+Y_phi*Y_phi*a1;
}
else if (process==LLPhiPhi) {
Y_Q = -1.0/2.0;
Lambda_Q = C_F_2*a2 + Y_Q*Y_Q*C_F_1*a1;
Lambda_phi = C_F_2*a2+Y_phi*Y_phi*a1;
}
highC.resize(2,1);
highC(0,0) = S1*(4.0*pi*a2);
highC(1,0) = S1*(4.0*pi*a1*Y_Q*Y_phi);
if (order>=1) {
highC(0,0) += T1b*(0.5*a2*a2+2.0*a1*a2*Y_Q*Y_phi) +
T1b_bar*(-0.5*a2*a2+2.0*a1*a2*Y_Q*Y_phi) +
T2a*(-a2*a2+Lambda_phi*a2) + T2b*a2*a2 +
T5a*(-a2*a2+Lambda_Q*a2) + T5b*a2*a2 +
T6a*2.0*a2*a2 + T6b*2.0*a2*a2 +
T6c*0.5*a2*a2*n_S + T6d*2.0*a2*a2*n_g;
highC(1,0) += T1b*(3.0/16.0*a2*a2+a1*a1*Y_Q*Y_Q*Y_phi*Y_phi) +
T1b_bar*(3.0/16.0*a2*a2+a1*a1*Y_Q*Y_Q*Y_phi*Y_phi) +
T2a*(Lambda_phi*a1*Y_Q*Y_phi) + T5a*(Lambda_Q*a1*Y_Q*Y_phi) +
T6c*(2.0*a1*a1*n_S*Y_Q*Y_phi*Y_phi*Y_phi) +
T6d*(10.0/3.0*a1*a1*n_g*Y_Q*Y_phi);
// Top Quark contributions:
highC(0,0) += -3.0*y_t*y_t*a2/(4.0*pi)/s*(2.0*L_s-4.0);
highC(1,0) += -3.0*y_t*y_t*a1/(4.0*pi)*(Y_Q*Y_phi)/s*(2.0*L_s-4.0);
}
break;
case UUPhiPhi: case DDPhiPhi: case EEPhiPhi:
// Finish Group Theory Factors:
if (process==UUPhiPhi) {
Y_Q = 2.0/3.0;
Lambda_Q = C_F_3*a3 + Y_Q*Y_Q*C_F_1*a1;
Lambda_phi = C_F_2*a2 + Y_phi*Y_phi*a1;
}
else if (process==DDPhiPhi) {
Y_Q = -1.0/3.0;
Lambda_Q = C_F_3*a3 + Y_Q*Y_Q*C_F_1*a1;
Lambda_phi = C_F_2*a2 + Y_phi*Y_phi*a1;
}
else if (process==EEPhiPhi) {
Y_Q = -1.0;
Lambda_Q = Y_Q*Y_Q*C_F_1*a1;
Lambda_phi = C_F_2*a2 + Y_phi*Y_phi*a1;
}
highC.resize(1,1);
highC(0,0) = ZERO;
highC(0,0) = S1*(4.0*pi*a1*Y_Q*Y_phi);
if (order>=1) {
highC(0,0) += T1b*(a1*a1*Y_Q*Y_Q*Y_phi*Y_phi) +
T1b_bar*(a1*a1*Y_Q*Y_Q*Y_phi*Y_phi) +
T2a*(Lambda_phi*a1*Y_Q*Y_phi) + T5a*(Lambda_Q*a1*Y_Q*Y_phi) +
T6c*(2.0*a1*a1*n_S*Y_Q*Y_phi*Y_phi*Y_phi) +
T6d*(10.0/3.0*a1*a1*n_g*Y_Q*Y_phi);
// Top Quark Contribution:
highC(0,0) += -3.0*y_t*y_t*a1/(4.0*pi)*(Y_Q*Y_phi)/s*(2.0*L_s-4.0);
}
break;
default:
assert(false);
}
return highC;
}
File Metadata
Details
Attached
Mime Type
text/x-diff
Expires
Tue, Nov 19, 7:16 PM (1 d, 9 h)
Storage Engine
blob
Storage Format
Raw Data
Storage Handle
3805792
Default Alt Text
(116 KB)
Attached To
rHERWIGHG herwighg
Event Timeline
Log In to Comment