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TtFullLepKinSolver Class Reference

#include <TtFullLepKinSolver.h>

List of all members.

Classes

struct  NeutrinoSolution

Public Member Functions

TtDilepEvtSolution addKinSolInfo (TtDilepEvtSolution *asol)
NeutrinoSolution getNuSolution (TLorentzVector LV_l, TLorentzVector LV_l_, TLorentzVector LV_b, TLorentzVector LV_b_)
void SetConstraints (const double xx=0, const double yy=0)
 TtFullLepKinSolver (const double, const double, const double, const std::vector< double >, const double=80.4, const double=4.8)
 constructor with parameters to configure the top-mass scan and the neutrino spectrum
 TtFullLepKinSolver ()
 default constructor
void useWeightFromMC (bool useMC)
 ~TtFullLepKinSolver ()
 destructor

Private Member Functions

int cubic (const double *c_coeff, double *c_sol) const
void FindCoeff (const TLorentzVector al, const TLorentzVector l, const TLorentzVector b_al, const TLorentzVector b_l, const double mt, const double mat, const double pxboost, const double pyboost, double *q_coeff)
int quartic (double *q_coeff, double *q_sol) const
double sqr (const double x) const
void SWAP (double &realone, double &realtwo) const
void TopRec (const TLorentzVector al, const TLorentzVector l, const TLorentzVector b_al, const TLorentzVector b_l, const double sol)
double WeightSolfromMC () const
double WeightSolfromShape () const
 use the parametrized event shape to obtain the solution weight.

Private Attributes

double C
double D
TF2 * EventShape_
 Event shape.
double F
TLorentzVector genLV_n
 provisional
TLorentzVector genLV_n_
double k16
double k26
double k36
double k46
double k51
double k56
double k61
TLorentzVector LV_n
TLorentzVector LV_n_
TLorentzVector LV_t
TLorentzVector LV_t_
TLorentzVector LV_tt_t
TLorentzVector LV_tt_t_
double m1
double m2
double m3
const double mb
const double mw
double n1
double n2
double n3
double pom
double pxmiss_
double pymiss_
const double topmass_begin
const double topmass_end
const double topmass_step
bool useMCforBest_
 flag to swith from WeightSolfromMC() to WeightSolfromShape()

Detailed Description

Definition at line 25 of file TtFullLepKinSolver.h.


Constructor & Destructor Documentation

TtFullLepKinSolver::TtFullLepKinSolver ( )

default constructor

Definition at line 4 of file TtFullLepKinSolver.cc.

References EventShape_.

                                      :
  topmass_begin(0),
  topmass_end(0),
  topmass_step(0),
  mw(80.4),
  mb(4.8),
  pxmiss_(0),
  pymiss_(0)
{
  // That crude parametrisation has been obtained from a fit of O(1000) pythia events.
  // It is normalized to 1.
  EventShape_ = new TF2("landau2D","[0]*TMath::Landau(x,[1],[2],0)*TMath::Landau(y,[3],[4],0)",0,500,0,500);
  EventShape_->SetParameters(30.7137,56.2880,23.0744,59.1015,24.9145);
}
TtFullLepKinSolver::TtFullLepKinSolver ( const double  b,
const double  e,
const double  s,
const std::vector< double >  nupars,
const double  mW = 80.4,
const double  mB = 4.8 
)

constructor with parameters to configure the top-mass scan and the neutrino spectrum

Definition at line 19 of file TtFullLepKinSolver.cc.

References EventShape_.

                                                                                                                                                      :
  topmass_begin(b),
  topmass_end(e),
  topmass_step(s),
  mw(mW),
  mb(mB),
  pxmiss_(0),
  pymiss_(0)
{
  EventShape_ = new TF2("landau2D","[0]*TMath::Landau(x,[1],[2],0)*TMath::Landau(y,[3],[4],0)",0,500,0,500);
  EventShape_->SetParameters(nupars[0],nupars[1],nupars[2],nupars[3],nupars[4]);
}
TtFullLepKinSolver::~TtFullLepKinSolver ( )

destructor

Definition at line 35 of file TtFullLepKinSolver.cc.

References EventShape_.

{
  delete EventShape_;
}

Member Function Documentation

TtDilepEvtSolution TtFullLepKinSolver::addKinSolInfo ( TtDilepEvtSolution asol)

Definition at line 40 of file TtFullLepKinSolver.cc.

References reco::LeafCandidate::energy(), FindCoeff(), genLV_n, genLV_n_, TtDilepEvtSolution::getCalJetB(), TtDilepEvtSolution::getCalJetBbar(), TtDilepEvtSolution::getElectronm(), TtDilepEvtSolution::getElectronp(), TtDilepEvtSolution::getGenN(), TtDilepEvtSolution::getGenNbar(), TtDilepEvtSolution::getMuonm(), TtDilepEvtSolution::getMuonp(), TtDilepEvtSolution::getTaum(), TtDilepEvtSolution::getTaup(), TtDilepEvtSolution::getWmDecay(), TtDilepEvtSolution::getWpDecay(), reco::LeafCandidate::px(), pxmiss_, reco::LeafCandidate::py(), pymiss_, reco::LeafCandidate::pz(), quartic(), TtDilepEvtSolution::setRecTopMass(), TtDilepEvtSolution::setRecWeightMax(), topmass_begin, topmass_end, topmass_step, TopRec(), useMCforBest_, CommonMethods::weight(), WeightSolfromMC(), and WeightSolfromShape().

Referenced by TtDilepEvtSolutionMaker::produce().

{
  TtDilepEvtSolution fitsol(*asol);
  
  //antilepton and lepton
  TLorentzVector LV_e, LV_e_;
  //b and bbar quark
  TLorentzVector LV_b, LV_b_;
  
  bool hasMCinfo = true;
  if(fitsol.getGenN()) { // protect against non-dilept genevents
    genLV_n = TLorentzVector(fitsol.getGenN()->px(), fitsol.getGenN()->py(),
                             fitsol.getGenN()->pz(), fitsol.getGenN()->energy());
  } else hasMCinfo = false;

  if(fitsol.getGenNbar()) { // protect against non-dilept genevents
    genLV_n_ = TLorentzVector(fitsol.getGenNbar()->px(), fitsol.getGenNbar()->py(),
                              fitsol.getGenNbar()->pz(), fitsol.getGenNbar()->energy());
  } else hasMCinfo = false;
  // if MC is to be used to select the best top mass and is not available,
  // then nothing can be done. Stop here.
  if(useMCforBest_&&!hasMCinfo) return fitsol;

  // first lepton
  if (fitsol.getWpDecay() == "muon") {
    LV_e = TLorentzVector(fitsol.getMuonp().px(), fitsol.getMuonp().py(),
                          fitsol.getMuonp().pz(), fitsol.getMuonp().energy());
  } else if (fitsol.getWpDecay() == "electron") {
    LV_e = TLorentzVector(fitsol.getElectronp().px(), fitsol.getElectronp().py(),
                          fitsol.getElectronp().pz(), fitsol.getElectronp().energy());
  } else if (fitsol.getWpDecay() == "tau") {
    LV_e = TLorentzVector(fitsol.getTaup().px(), fitsol.getTaup().py(),
                          fitsol.getTaup().pz(), fitsol.getTaup().energy());
  }
    
  // second lepton
  if (fitsol.getWmDecay() == "muon") {
    LV_e_ = TLorentzVector(fitsol.getMuonm().px(), fitsol.getMuonm().py(),
                          fitsol.getMuonm().pz(), fitsol.getMuonm().energy());
  } else if (fitsol.getWmDecay() == "electron") {
    LV_e_ = TLorentzVector(fitsol.getElectronm().px(), fitsol.getElectronm().py(),
                           fitsol.getElectronm().pz(), fitsol.getElectronm().energy());
  } else if (fitsol.getWmDecay() == "tau") {
    LV_e_ = TLorentzVector(fitsol.getTaum().px(), fitsol.getTaum().py(),
                           fitsol.getTaum().pz(), fitsol.getTaum().energy());
  }

  // first jet
  LV_b = TLorentzVector(fitsol.getCalJetB().px(), fitsol.getCalJetB().py(),
                        fitsol.getCalJetB().pz(), fitsol.getCalJetB().energy());

  // second jet
  LV_b_ = TLorentzVector(fitsol.getCalJetBbar().px(), fitsol.getCalJetBbar().py(),
                         fitsol.getCalJetBbar().pz(), fitsol.getCalJetBbar().energy());
  
  //loop on top mass parameter
  double weightmax = -1e30;
  double mtmax = 0;
  for (double mt = topmass_begin; 
              mt < topmass_end + 0.5*topmass_step; 
              mt += topmass_step) {
    //cout << "mt = " << mt << endl;
    double q_coeff[5], q_sol[4];
    FindCoeff(LV_e, LV_e_, LV_b, LV_b_, mt, mt, pxmiss_, pymiss_, q_coeff);
    int NSol = quartic(q_coeff, q_sol);
    
    //loop on all solutions
    for (int isol = 0; isol < NSol; isol++) {
      TopRec(LV_e, LV_e_, LV_b, LV_b_, q_sol[isol]);
      double weight = useMCforBest_ ? WeightSolfromMC() : WeightSolfromShape();
      if (weight > weightmax) {
        weightmax =weight;
        mtmax = mt;
      }
    }
    
    //for (int i=0;i<5;i++) cout << " q_coeff["<<i<< "]= " << q_coeff[i];
    //cout << endl;
    
    //for (int i=0;i<4;i++) cout << " q_sol["<<i<< "]= " << q_sol[i];
    //cout << endl;
    //cout << "NSol_" << NSol << endl;
  }
  
  fitsol.setRecTopMass(mtmax);
  fitsol.setRecWeightMax(weightmax);
  
  return fitsol;
}
int TtFullLepKinSolver::cubic ( const double *  c_coeff,
double *  c_sol 
) const [private]

Definition at line 375 of file TtFullLepKinSolver.cc.

References funct::cos(), h, i, AlCaHLTBitMon_ParallelJobs::p, phi, Pi, lumiQueryAPI::q, sqr(), mathSSE::sqrt(), SWAP(), and w().

Referenced by quartic().

{
  unsigned nreal;
  double w, p, q, dis, h, phi;
  
  if (coeffs[3]!=0.0) {
    /* cubic problem? */
    w = coeffs[2]/(3*coeffs[3]);
    p = sqr(coeffs[1]/(3*coeffs[3])-sqr(w))*(coeffs[1]/(3*coeffs[3])-sqr(w));
    q = -0.5*(2*sqr(w)*w-(coeffs[1]*w-coeffs[0])/coeffs[3]);
    dis = sqr(q)+p;
    /* discriminant */
    if (dis<0.0) {
      /* 3 real solutions */
      h = q/sqrt(-p);
      if (h>1.0) h = 1.0;
      /* confine the argument of */
      if (h<-1.0) h = -1.0;
      /* acos to [-1;+1] */
      phi = acos(h);
      p = 2*TMath::Power(-p, 1.0/6.0);
      for(unsigned i=0; i<3; i++) 
        koreny[i] = p*cos((phi+2*i*TMath::Pi())/3.0) - w;
      if (koreny[1]<koreny[0]) SWAP(koreny[0], koreny[1]);
      /* sort results */
      if (koreny[2]<koreny[1]) SWAP(koreny[1], koreny[2]);
      if (koreny[1]<koreny[0]) SWAP(koreny[0], koreny[1]);
      nreal = 3;
    }
    else {
      /* only one real solution */
      dis = sqrt(dis);
      h = TMath::Power(fabs(q+dis), 1.0/3.0);
      p = TMath::Power(fabs(q-dis), 1.0/3.0);
      koreny[0] = ((q+dis>0.0)? h : -h) + ((q-dis>0.0)? p : -p) -  w;
      nreal = 1;
    }

    /* Perform one step of a Newton iteration in order to minimize
       round-off errors */
    for(unsigned i=0; i<nreal; i++) {
      h = coeffs[1] + koreny[i] * (2 * coeffs[2] + 3 * koreny[i] * coeffs[3]);
      if (h != 0.0)
        koreny[i] -= (coeffs[0] + koreny[i] * (coeffs[1] + koreny[i] * (coeffs[2] + koreny[i] * coeffs[3])))/h;
    }
  }

  else if (coeffs[2]!=0.0) {
    /* quadratic problem? */
    p = 0.5*coeffs[1]/coeffs[2];
    dis = sqr(p) - coeffs[0]/coeffs[2];
    if (dis>=0.0) {
      /* two real solutions */
      dis = sqrt(dis);
      koreny[0] = -p - dis;
      koreny[1] = -p + dis;
      nreal = 2;
    }
    else
      /* no real solution */
      nreal = 0;
  }

  else if (coeffs[1]!=0.0) {
    /* linear problem? */
    koreny[0] = -coeffs[0]/coeffs[1];
    nreal = 1;
  }

  else
    /* no equation */
    nreal = 0;
  
  return nreal;
}
void TtFullLepKinSolver::FindCoeff ( const TLorentzVector  al,
const TLorentzVector  l,
const TLorentzVector  b_al,
const TLorentzVector  b_l,
const double  mt,
const double  mat,
const double  pxboost,
const double  pyboost,
double *  q_coeff 
) [private]

Definition at line 174 of file TtFullLepKinSolver.cc.

References C, D, F, k16, k26, k36, k46, k51, k56, k61, m1, m2, m3, mb, mw, n1, n2, n3, pom, funct::pow(), and sqr().

Referenced by addKinSolInfo(), and getNuSolution().

{
  double E, apom1, apom2, apom3;
  double k11, k21, k31, k41,  cpom1, cpom2, cpom3, l11, l21, l31, l41, l51, l61, k1, k2, k3, k4, k5,k6;
  double l1, l2, l3, l4, l5, l6, k15, k25, k35, k45;

  C = -al.Px()-b_al.Px()-l.Px()-b_l.Px() + px_miss;
  D = -al.Py()-b_al.Py()-l.Py()-b_l.Py() + py_miss;

  // right side of first two linear equations - missing pT
  
  E = (sqr(mt)-sqr(mw)-sqr(mb))/(2*b_al.E())-sqr(mw)/(2*al.E())-al.E()+al.Px()*b_al.Px()/b_al.E()+al.Py()*b_al.Py()/b_al.E()+al.Pz()*b_al.Pz()/b_al.E();
  F = (sqr(mat)-sqr(mw)-sqr(mb))/(2*b_l.E())-sqr(mw)/(2*l.E())-l.E()+l.Px()*b_l.Px()/b_l.E()+l.Py()*b_l.Py()/b_l.E()+l.Pz()*b_l.Pz()/b_l.E();
  
  m1 = al.Px()/al.E()-b_al.Px()/b_al.E();
  m2 = al.Py()/al.E()-b_al.Py()/b_al.E();
  m3 = al.Pz()/al.E()-b_al.Pz()/b_al.E();
  
  n1 = l.Px()/l.E()-b_l.Px()/b_l.E();
  n2 = l.Py()/l.E()-b_l.Py()/b_l.E();
  n3 = l.Pz()/l.E()-b_l.Pz()/b_l.E();
  
  pom = E-m1*C-m2*D;
  apom1 = sqr(al.Px())-sqr(al.E());
  apom2 = sqr(al.Py())-sqr(al.E());
  apom3 = sqr(al.Pz())-sqr(al.E());
  
  k11 = 1/sqr(al.E())*(pow(mw,4)/4+sqr(C)*apom1+sqr(D)*apom2+apom3*sqr(pom)/sqr(m3)+sqr(mw)*(al.Px()*C+al.Py()*D+al.Pz()*pom/m3)+2*al.Px()*al.Py()*C*D+2*al.Px()*al.Pz()*C*pom/m3+2*al.Py()*al.Pz()*D*pom/m3);
  k21 = 1/sqr(al.E())*(-2*C*m3*n3*apom1+2*apom3*n3*m1*pom/m3-sqr(mw)*m3*n3*al.Px()+sqr(mw)*m1*n3*al.Pz()-2*al.Px()*al.Py()*D*m3*n3+2*al.Px()*al.Pz()*C*m1*n3-2*al.Px()*al.Pz()*n3*pom+2*al.Py()*al.Pz()*D*m1*n3);
  k31 = 1/sqr(al.E())*(-2*D*m3*n3*apom2+2*apom3*n3*m2*pom/m3-sqr(mw)*m3*n3*al.Py()+sqr(mw)*m2*n3*al.Pz()-2*al.Px()*al.Py()*C*m3*n3+2*al.Px()*al.Pz()*C*m2*n3-2*al.Py()*al.Pz()*n3*pom+2*al.Py()*al.Pz()*D*m2*n3);
  k41 = 1/sqr(al.E())*(2*apom3*m1*m2*sqr(n3)+2*al.Px()*al.Py()*sqr(m3)*sqr(n3)-2*al.Px()*al.Pz()*m2*m3*sqr(n3)-2*al.Py()*al.Pz()*m1*m3*sqr(n3));
  k51 = 1/sqr(al.E())*(apom1*sqr(m3)*sqr(n3)+apom3*sqr(m1)*sqr(n3)-2*al.Px()*al.Pz()*m1*m3*sqr(n3));
  k61 = 1/sqr(al.E())*(apom2*sqr(m3)*sqr(n3)+apom3*sqr(m2)*sqr(n3)-2*al.Py()*al.Pz()*m2*m3*sqr(n3));
  
  cpom1 = sqr(l.Px())-sqr(l.E());
  cpom2 = sqr(l.Py())-sqr(l.E());
  cpom3 = sqr(l.Pz())-sqr(l.E());
  
  l11 = 1/sqr(l.E())*(pow(mw,4)/4+cpom3*sqr(F)/sqr(n3)+sqr(mw)*l.Pz()*F/n3);
  l21 = 1/sqr(l.E())*(-2*cpom3*F*m3*n1/n3+sqr(mw)*(l.Px()*m3*n3-l.Pz()*n1*m3)+2*l.Px()*l.Pz()*F*m3);
  l31 = 1/sqr(l.E())*(-2*cpom3*F*m3*n2/n3+sqr(mw)*(l.Py()*m3*n3-l.Pz()*n2*m3)+2*l.Py()*l.Pz()*F*m3);
  l41 = 1/sqr(l.E())*(2*cpom3*n1*n2*sqr(m3)+2*l.Px()*l.Py()*sqr(m3)*sqr(n3)-2*l.Px()*l.Pz()*n2*n3*sqr(m3)-2*l.Py()*l.Pz()*n1*n3*sqr(m3));
  l51 = 1/sqr(l.E())*(cpom1*sqr(m3)*sqr(n3)+cpom3*sqr(n1)*sqr(m3)-2*l.Px()*l.Pz()*n1*n3*sqr(m3));
  l61 = 1/sqr(l.E())*(cpom2*sqr(m3)*sqr(n3)+cpom3*sqr(n2)*sqr(m3)-2*l.Py()*l.Pz()*n2*n3*sqr(m3));
  
  k1 = k11*k61;
  k2 = k61*k21/k51;
  k3 = k31;
  k4 = k41/k51;
  k5 = k61/k51;
  k6 = 1;
  
  l1 = l11*k61;
  l2 = l21*k61/k51;
  l3 = l31;
  l4 = l41/k51;
  l5 = l51*k61/(sqr(k51));
  l6 = l61/k61;
  
  k15 = k1*l5-l1*k5;
  k25 = k2*l5-l2*k5;
  k35 = k3*l5-l3*k5;
  k45 = k4*l5-l4*k5;
  
  k16 = k1*l6-l1*k6;
  k26 = k2*l6-l2*k6;
  k36 = k3*l6-l3*k6;
  k46 = k4*l6-l4*k6;
  k56 = k5*l6-l5*k6;

  koeficienty[0] = k15*sqr(k36)-k35*k36*k16-k56*sqr(k16);
  koeficienty[1] = 2*k15*k36*k46+k25*sqr(k36)+k35*(-k46*k16-k36*k26)-k45*k36*k16-2*k56*k26*k16;
  koeficienty[2] = k15*sqr(k46)+2*k25*k36*k46+k35*(-k46*k26-k36*k56)-k56*(sqr(k26)+2*k56*k16)-k45*(k46*k16+k36*k26);
  koeficienty[3] = k25*sqr(k46)-k35*k46*k56-k45*(k46*k26+k36*k56)-2*sqr(k56)*k26;
  koeficienty[4] = -k45*k46*k56-pow(k56,3);
  
  // normalization of coefficients
  int moc=(int(log10(fabs(koeficienty[0])))+int(log10(fabs(koeficienty[4]))))/2;
  
  koeficienty[0]=koeficienty[0]/TMath::Power(10,moc);
  koeficienty[1]=koeficienty[1]/TMath::Power(10,moc);
  koeficienty[2]=koeficienty[2]/TMath::Power(10,moc);
  koeficienty[3]=koeficienty[3]/TMath::Power(10,moc);
  koeficienty[4]=koeficienty[4]/TMath::Power(10,moc);
}
TtFullLepKinSolver::NeutrinoSolution TtFullLepKinSolver::getNuSolution ( TLorentzVector  LV_l,
TLorentzVector  LV_l_,
TLorentzVector  LV_b,
TLorentzVector  LV_b_ 
)

Definition at line 138 of file TtFullLepKinSolver.cc.

References FindCoeff(), LV_n, LV_n_, TtFullLepKinSolver::NeutrinoSolution::neutrino, TtFullLepKinSolver::NeutrinoSolution::neutrinoBar, pxmiss_, pymiss_, quartic(), topmass_begin, topmass_end, topmass_step, TopRec(), CommonMethods::weight(), TtFullLepKinSolver::NeutrinoSolution::weight, and WeightSolfromShape().

Referenced by TtFullLepKinSolutionProducer::produce().

{
  math::XYZTLorentzVector maxLV_n  = math::XYZTLorentzVector(0,0,0,0); 
  math::XYZTLorentzVector maxLV_n_ = math::XYZTLorentzVector(0,0,0,0);   

  //loop on top mass parameter
  double weightmax = -1;
  for(double mt = topmass_begin; 
             mt < topmass_end + 0.5*topmass_step; 
             mt += topmass_step) {
    double q_coeff[5], q_sol[4];
    FindCoeff(LV_l, LV_l_, LV_b, LV_b_, mt, mt, pxmiss_, pymiss_, q_coeff);
    int NSol = quartic(q_coeff, q_sol);
    
    //loop on all solutions
    for (int isol = 0; isol < NSol; isol++) {
      TopRec(LV_l, LV_l_, LV_b, LV_b_, q_sol[isol]);
      double weight = WeightSolfromShape();
      if (weight > weightmax) {
        weightmax =weight;
        maxLV_n.SetPxPyPzE(LV_n.Px(), LV_n.Py(), LV_n.Pz(), LV_n.E());
        maxLV_n_.SetPxPyPzE(LV_n_.Px(), LV_n_.Py(), LV_n_.Pz(), LV_n_.E());
      }
    }
  }
  TtFullLepKinSolver::NeutrinoSolution nuSol;
  nuSol.neutrino    = reco::LeafCandidate(0, maxLV_n  );
  nuSol.neutrinoBar = reco::LeafCandidate(0, maxLV_n_ ); 
  nuSol.weight = weightmax; 
  return nuSol;
}
int TtFullLepKinSolver::quartic ( double *  q_coeff,
double *  q_sol 
) const [private]

Definition at line 315 of file TtFullLepKinSolver.cc.

References trackerHits::c, cubic(), h, i, sqr(), mathSSE::sqrt(), lumiQTWidget::t, w(), and z.

Referenced by addKinSolInfo(), and getNuSolution().

{
  double w, b0, b1, b2;
  double c[4];
  double d0, d1, h, t, z;
  double *px;
 
  if (koeficienty[4]==0.0) 
    return cubic(koeficienty, koreny);
  /* quartic problem? */
  w = koeficienty[3]/(4*koeficienty[4]);
  /* offset */
  b2 = -6*sqr(w) + koeficienty[2]/koeficienty[4];
  /* koeficienty. of shifted polynomial */
  b1 = (8*sqr(w) - 2*koeficienty[2]/koeficienty[4])*w + koeficienty[1]/koeficienty[4];
  b0 = ((-3*sqr(w) + koeficienty[2]/koeficienty[4])*w - koeficienty[1]/koeficienty[4])*w + koeficienty[0]/koeficienty[4];

  c[3] = 1.0;
  /* cubic resolvent */
  c[2] = b2;
  c[1] = -4*b0;
  c[0] = sqr(b1) - 4*b0*b2;
  
  cubic(c, koreny);
  z = koreny[0];
  //double z1=1.0,z2=2.0,z3=3.0;
  //TMath::RootsCubic(c,z1,z2,z3);
  //if (z2 !=0) z = z2;
  //if (z1 !=0) z = z1;
  /* only lowermost root needed */

  int nreal = 0;
  px = koreny;
  t = sqrt(0.25*sqr(z) - b0);
  for(int i=-1; i<=1; i+=2) {
    d0 = -0.5*z + i*t;
    /* coeffs. of quadratic factor */
    d1 = (t!=0.0)? -i*0.5*b1/t : i*sqrt(-z - b2);
    h = 0.25*sqr(d1) - d0;
    if (h>=0.0) {
      h = sqrt(h);
      nreal += 2;
      *px++ = -0.5*d1 - h - w;
      *px++ = -0.5*d1 + h - w;
    }
  }

  //  if (nreal==4) {
    /* sort results */
//    if (koreny[2]<koreny[0]) SWAP(koreny[0], koreny[2]);
//    if (koreny[3]<koreny[1]) SWAP(koreny[1], koreny[3]);
//    if (koreny[1]<koreny[0]) SWAP(koreny[0], koreny[1]);
//    if (koreny[3]<koreny[2]) SWAP(koreny[2], koreny[3]);
//    if (koreny[2]<koreny[1]) SWAP(koreny[1], koreny[2]);
//  }
  return nreal;

}
void TtFullLepKinSolver::SetConstraints ( const double  xx = 0,
const double  yy = 0 
)

Definition at line 131 of file TtFullLepKinSolver.cc.

References pxmiss_, and pymiss_.

Referenced by TtDilepEvtSolutionMaker::produce(), and TtFullLepKinSolutionProducer::produce().

{
  pxmiss_ = xx;
  pymiss_ = yy;
}
double TtFullLepKinSolver::sqr ( const double  x) const [inline, private]

Definition at line 78 of file TtFullLepKinSolver.h.

Referenced by cubic(), FindCoeff(), and quartic().

{return (x*x);}
void TtFullLepKinSolver::SWAP ( double &  realone,
double &  realtwo 
) const [private]

Definition at line 453 of file TtFullLepKinSolver.cc.

References printConversionInfo::aux.

Referenced by cubic().

{
  if (realtwo < realone) {
    double aux = realtwo;
    realtwo = realone;
    realone = aux;
  }
}
void TtFullLepKinSolver::TopRec ( const TLorentzVector  al,
const TLorentzVector  l,
const TLorentzVector  b_al,
const TLorentzVector  b_l,
const double  sol 
) [private]

Definition at line 268 of file TtFullLepKinSolver.cc.

References printConversionInfo::aux, C, D, F, k16, k26, k36, k46, k51, k56, k61, LV_n, LV_n_, LV_t, LV_t_, LV_tt_t, LV_tt_t_, m1, m2, m3, n1, n2, n3, pom, and funct::pow().

Referenced by addKinSolInfo(), and getNuSolution().

{
  TVector3 t_ttboost;
  TLorentzVector aux;
  double pxp, pyp, pzp, pup, pvp, pwp;
    
  pxp = sol*(m3*n3/k51);   
  pyp = -(m3*n3/k61)*(k56*pow(sol,2) + k26*sol + k16)/(k36 + k46*sol);
  pzp = -1/n3*(n1*pxp + n2*pyp - F);
  pwp = 1/m3*(m1*pxp + m2*pyp + pom);
  pup = C - pxp;
  pvp = D - pyp;
     
  LV_n_.SetXYZM(pxp, pyp, pzp, 0.0);
  LV_n.SetXYZM(pup, pvp, pwp, 0.0);
  
  LV_t_ = b_l + l + LV_n_;
  LV_t = b_al + al + LV_n;  
 
  aux = (LV_t_ + LV_t);
  t_ttboost = -aux.BoostVector();
  LV_tt_t_ = LV_t_;
  LV_tt_t = LV_t;
  LV_tt_t_.Boost(t_ttboost);
  LV_tt_t.Boost(t_ttboost); 
}
void TtFullLepKinSolver::useWeightFromMC ( bool  useMC) [inline]

Definition at line 44 of file TtFullLepKinSolver.h.

References useMCforBest_.

Referenced by TtDilepEvtSolutionMaker::produce().

{ useMCforBest_ = useMC; }
double TtFullLepKinSolver::WeightSolfromMC ( ) const [private]

Definition at line 300 of file TtFullLepKinSolver.cc.

References genLV_n, genLV_n_, LV_n, LV_n_, and CommonMethods::weight().

Referenced by addKinSolInfo().

{
  double weight = 1;
  weight = ((LV_n.E() > genLV_n.E())? genLV_n.E()/LV_n.E(): LV_n.E()/genLV_n.E())
           *((LV_n_.E() > genLV_n_.E())? genLV_n_.E()/LV_n_.E(): LV_n_.E()/genLV_n_.E());
  return weight;
}
double TtFullLepKinSolver::WeightSolfromShape ( ) const [private]

use the parametrized event shape to obtain the solution weight.

Definition at line 309 of file TtFullLepKinSolver.cc.

References EventShape_, LV_n, and LV_n_.

Referenced by addKinSolInfo(), and getNuSolution().

{
  return EventShape_->Eval(LV_n.E(),LV_n_.E());
}

Member Data Documentation

double TtFullLepKinSolver::C [private]

Definition at line 96 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

double TtFullLepKinSolver::D [private]

Definition at line 97 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

Event shape.

Definition at line 122 of file TtFullLepKinSolver.h.

Referenced by TtFullLepKinSolver(), WeightSolfromShape(), and ~TtFullLepKinSolver().

double TtFullLepKinSolver::F [private]

Definition at line 98 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

TLorentzVector TtFullLepKinSolver::genLV_n [private]

provisional

Definition at line 117 of file TtFullLepKinSolver.h.

Referenced by addKinSolInfo(), and WeightSolfromMC().

TLorentzVector TtFullLepKinSolver::genLV_n_ [private]

Definition at line 117 of file TtFullLepKinSolver.h.

Referenced by addKinSolInfo(), and WeightSolfromMC().

double TtFullLepKinSolver::k16 [private]

Definition at line 100 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

double TtFullLepKinSolver::k26 [private]

Definition at line 101 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

double TtFullLepKinSolver::k36 [private]

Definition at line 102 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

double TtFullLepKinSolver::k46 [private]

Definition at line 103 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

double TtFullLepKinSolver::k51 [private]

Definition at line 105 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

double TtFullLepKinSolver::k56 [private]

Definition at line 104 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

double TtFullLepKinSolver::k61 [private]

Definition at line 106 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

TLorentzVector TtFullLepKinSolver::LV_n [private]

Definition at line 115 of file TtFullLepKinSolver.h.

Referenced by getNuSolution(), TopRec(), WeightSolfromMC(), and WeightSolfromShape().

TLorentzVector TtFullLepKinSolver::LV_n_ [private]

Definition at line 115 of file TtFullLepKinSolver.h.

Referenced by getNuSolution(), TopRec(), WeightSolfromMC(), and WeightSolfromShape().

TLorentzVector TtFullLepKinSolver::LV_t [private]

Definition at line 115 of file TtFullLepKinSolver.h.

Referenced by TopRec().

TLorentzVector TtFullLepKinSolver::LV_t_ [private]

Definition at line 115 of file TtFullLepKinSolver.h.

Referenced by TopRec().

TLorentzVector TtFullLepKinSolver::LV_tt_t [private]

Definition at line 115 of file TtFullLepKinSolver.h.

Referenced by TopRec().

TLorentzVector TtFullLepKinSolver::LV_tt_t_ [private]

Definition at line 115 of file TtFullLepKinSolver.h.

Referenced by TopRec().

double TtFullLepKinSolver::m1 [private]

Definition at line 107 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

double TtFullLepKinSolver::m2 [private]

Definition at line 108 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

double TtFullLepKinSolver::m3 [private]

Definition at line 109 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

const double TtFullLepKinSolver::mb [private]

Definition at line 92 of file TtFullLepKinSolver.h.

Referenced by FindCoeff().

const double TtFullLepKinSolver::mw [private]

Definition at line 90 of file TtFullLepKinSolver.h.

Referenced by FindCoeff().

double TtFullLepKinSolver::n1 [private]

Definition at line 110 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

double TtFullLepKinSolver::n2 [private]

Definition at line 111 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

double TtFullLepKinSolver::n3 [private]

Definition at line 112 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

double TtFullLepKinSolver::pom [private]

Definition at line 99 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

double TtFullLepKinSolver::pxmiss_ [private]

Definition at line 94 of file TtFullLepKinSolver.h.

Referenced by addKinSolInfo(), getNuSolution(), and SetConstraints().

double TtFullLepKinSolver::pymiss_ [private]

Definition at line 94 of file TtFullLepKinSolver.h.

Referenced by addKinSolInfo(), getNuSolution(), and SetConstraints().

const double TtFullLepKinSolver::topmass_begin [private]

Definition at line 84 of file TtFullLepKinSolver.h.

Referenced by addKinSolInfo(), and getNuSolution().

const double TtFullLepKinSolver::topmass_end [private]

Definition at line 86 of file TtFullLepKinSolver.h.

Referenced by addKinSolInfo(), and getNuSolution().

const double TtFullLepKinSolver::topmass_step [private]

Definition at line 88 of file TtFullLepKinSolver.h.

Referenced by addKinSolInfo(), and getNuSolution().

flag to swith from WeightSolfromMC() to WeightSolfromShape()

Definition at line 120 of file TtFullLepKinSolver.h.

Referenced by addKinSolInfo(), and useWeightFromMC().