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TtFullLepKinSolver Class Reference

#include <TtFullLepKinSolver.h>

Classes

struct  NeutrinoSolution
 

Public Member Functions

TtDilepEvtSolution addKinSolInfo (TtDilepEvtSolution *asol)
 
NeutrinoSolution getNuSolution (const TLorentzVector &LV_l, const TLorentzVector &LV_l_, const TLorentzVector &LV_b, const TLorentzVector &LV_b_)
 
void SetConstraints (const double xx=0, const double yy=0)
 
 TtFullLepKinSolver ()
 default constructor More...
 
 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 More...
 
void useWeightFromMC (bool useMC)
 
 ~TtFullLepKinSolver ()
 destructor More...
 

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. More...
 

Private Attributes

double C
 
double D
 
TF2 * EventShape_
 Event shape. More...
 
double F
 
TLorentzVector genLV_n
 provisional More...
 
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() More...
 

Detailed Description

Definition at line 25 of file TtFullLepKinSolver.h.

Constructor & Destructor Documentation

◆ TtFullLepKinSolver() [1/2]

TtFullLepKinSolver::TtFullLepKinSolver ( )

default constructor

Definition at line 4 of file TtFullLepKinSolver.cc.

References EventShape_.

5  : topmass_begin(0), topmass_end(0), topmass_step(0), mw(80.4), mb(4.8), pxmiss_(0), pymiss_(0) {
6  // That crude parametrisation has been obtained from a fit of O(1000) pythia events.
7  // It is normalized to 1.
8  EventShape_ = new TF2("landau2D", "[0]*TMath::Landau(x,[1],[2],0)*TMath::Landau(y,[3],[4],0)", 0, 500, 0, 500);
9  EventShape_->SetParameters(30.7137, 56.2880, 23.0744, 59.1015, 24.9145);
10 }
const double topmass_end
const double topmass_step
TF2 * EventShape_
Event shape.
const double topmass_begin

◆ TtFullLepKinSolver() [2/2]

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 12 of file TtFullLepKinSolver.cc.

References EventShape_.

14  : topmass_begin(b), topmass_end(e), topmass_step(s), mw(mW), mb(mB), pxmiss_(0), pymiss_(0) {
15  EventShape_ = new TF2("landau2D", "[0]*TMath::Landau(x,[1],[2],0)*TMath::Landau(y,[3],[4],0)", 0, 500, 0, 500);
16  EventShape_->SetParameters(nupars[0], nupars[1], nupars[2], nupars[3], nupars[4]);
17 }
const double topmass_end
const double topmass_step
TF2 * EventShape_
Event shape.
double b
Definition: hdecay.h:118
const double topmass_begin

◆ ~TtFullLepKinSolver()

TtFullLepKinSolver::~TtFullLepKinSolver ( )

destructor

Definition at line 22 of file TtFullLepKinSolver.cc.

References EventShape_.

22 { delete EventShape_; }
TF2 * EventShape_
Event shape.

Member Function Documentation

◆ addKinSolInfo()

TtDilepEvtSolution TtFullLepKinSolver::addKinSolInfo ( TtDilepEvtSolution asol)

Definition at line 24 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(), TtSemiLepEvtBuilder_cfi::mt, reco::LeafCandidate::px(), pxmiss_, reco::LeafCandidate::py(), pymiss_, reco::LeafCandidate::pz(), quartic(), TtDilepEvtSolution::setRecTopMass(), TtDilepEvtSolution::setRecWeightMax(), topmass_begin, topmass_end, topmass_step, TopRec(), useMCforBest_, mps_merge::weight, WeightSolfromMC(), and WeightSolfromShape().

Referenced by TtDilepEvtSolutionMaker::produce().

24  {
25  TtDilepEvtSolution fitsol(*asol);
26 
27  //antilepton and lepton
28  TLorentzVector LV_e, LV_e_;
29  //b and bbar quark
30  TLorentzVector LV_b, LV_b_;
31 
32  bool hasMCinfo = true;
33  if (fitsol.getGenN()) { // protect against non-dilept genevents
34  genLV_n = TLorentzVector(
35  fitsol.getGenN()->px(), fitsol.getGenN()->py(), fitsol.getGenN()->pz(), fitsol.getGenN()->energy());
36  } else
37  hasMCinfo = false;
38 
39  if (fitsol.getGenNbar()) { // protect against non-dilept genevents
40  genLV_n_ = TLorentzVector(
41  fitsol.getGenNbar()->px(), fitsol.getGenNbar()->py(), fitsol.getGenNbar()->pz(), fitsol.getGenNbar()->energy());
42  } else
43  hasMCinfo = false;
44  // if MC is to be used to select the best top mass and is not available,
45  // then nothing can be done. Stop here.
46  if (useMCforBest_ && !hasMCinfo)
47  return fitsol;
48 
49  // first lepton
50  if (fitsol.getWpDecay() == "muon") {
51  LV_e = TLorentzVector(
52  fitsol.getMuonp().px(), fitsol.getMuonp().py(), fitsol.getMuonp().pz(), fitsol.getMuonp().energy());
53  } else if (fitsol.getWpDecay() == "electron") {
54  LV_e = TLorentzVector(fitsol.getElectronp().px(),
55  fitsol.getElectronp().py(),
56  fitsol.getElectronp().pz(),
57  fitsol.getElectronp().energy());
58  } else if (fitsol.getWpDecay() == "tau") {
59  LV_e =
60  TLorentzVector(fitsol.getTaup().px(), fitsol.getTaup().py(), fitsol.getTaup().pz(), fitsol.getTaup().energy());
61  }
62 
63  // second lepton
64  if (fitsol.getWmDecay() == "muon") {
65  LV_e_ = TLorentzVector(
66  fitsol.getMuonm().px(), fitsol.getMuonm().py(), fitsol.getMuonm().pz(), fitsol.getMuonm().energy());
67  } else if (fitsol.getWmDecay() == "electron") {
68  LV_e_ = TLorentzVector(fitsol.getElectronm().px(),
69  fitsol.getElectronm().py(),
70  fitsol.getElectronm().pz(),
71  fitsol.getElectronm().energy());
72  } else if (fitsol.getWmDecay() == "tau") {
73  LV_e_ =
74  TLorentzVector(fitsol.getTaum().px(), fitsol.getTaum().py(), fitsol.getTaum().pz(), fitsol.getTaum().energy());
75  }
76 
77  // first jet
78  LV_b = TLorentzVector(
79  fitsol.getCalJetB().px(), fitsol.getCalJetB().py(), fitsol.getCalJetB().pz(), fitsol.getCalJetB().energy());
80 
81  // second jet
82  LV_b_ = TLorentzVector(fitsol.getCalJetBbar().px(),
83  fitsol.getCalJetBbar().py(),
84  fitsol.getCalJetBbar().pz(),
85  fitsol.getCalJetBbar().energy());
86 
87  //loop on top mass parameter
88  double weightmax = -1e30;
89  double mtmax = 0;
90  for (double mt = topmass_begin; mt < topmass_end + 0.5 * topmass_step; mt += topmass_step) {
91  //cout << "mt = " << mt << endl;
92  double q_coeff[5], q_sol[4];
93  FindCoeff(LV_e, LV_e_, LV_b, LV_b_, mt, mt, pxmiss_, pymiss_, q_coeff);
94  int NSol = quartic(q_coeff, q_sol);
95 
96  //loop on all solutions
97  for (int isol = 0; isol < NSol; isol++) {
98  TopRec(LV_e, LV_e_, LV_b, LV_b_, q_sol[isol]);
100  if (weight > weightmax) {
101  weightmax = weight;
102  mtmax = mt;
103  }
104  }
105 
106  //for (int i=0;i<5;i++) cout << " q_coeff["<<i<< "]= " << q_coeff[i];
107  //cout << endl;
108 
109  //for (int i=0;i<4;i++) cout << " q_sol["<<i<< "]= " << q_sol[i];
110  //cout << endl;
111  //cout << "NSol_" << NSol << endl;
112  }
113 
114  fitsol.setRecTopMass(mtmax);
115  fitsol.setRecWeightMax(weightmax);
116 
117  return fitsol;
118 }
double WeightSolfromMC() const
const double topmass_end
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)
Definition: weight.py:1
bool useMCforBest_
flag to swith from WeightSolfromMC() to WeightSolfromShape()
double WeightSolfromShape() const
use the parametrized event shape to obtain the solution weight.
TLorentzVector genLV_n
provisional
const double topmass_step
int quartic(double *q_coeff, double *q_sol) const
TLorentzVector genLV_n_
void TopRec(const TLorentzVector &al, const TLorentzVector &l, const TLorentzVector &b_al, const TLorentzVector &b_l, const double sol)
const double topmass_begin

◆ cubic()

int TtFullLepKinSolver::cubic ( const double *  c_coeff,
double *  c_sol 
) const
private

Definition at line 372 of file TtFullLepKinSolver.cc.

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

Referenced by quartic().

372  {
373  unsigned nreal;
374  double w, p, q, dis, h, phi;
375 
376  if (coeffs[3] != 0.0) {
377  /* cubic problem? */
378  w = coeffs[2] / (3 * coeffs[3]);
379  p = sqr(coeffs[1] / (3 * coeffs[3]) - sqr(w)) * (coeffs[1] / (3 * coeffs[3]) - sqr(w));
380  q = -0.5 * (2 * sqr(w) * w - (coeffs[1] * w - coeffs[0]) / coeffs[3]);
381  dis = sqr(q) + p;
382  /* discriminant */
383  if (dis < 0.0) {
384  /* 3 real solutions */
385  h = q / sqrt(-p);
386  if (h > 1.0)
387  h = 1.0;
388  /* confine the argument of */
389  if (h < -1.0)
390  h = -1.0;
391  /* acos to [-1;+1] */
392  phi = acos(h);
393  p = 2 * TMath::Power(-p, 1.0 / 6.0);
394  for (unsigned i = 0; i < 3; i++)
395  koreny[i] = p * cos((phi + 2 * i * TMath::Pi()) / 3.0) - w;
396  if (koreny[1] < koreny[0])
397  SWAP(koreny[0], koreny[1]);
398  /* sort results */
399  if (koreny[2] < koreny[1])
400  SWAP(koreny[1], koreny[2]);
401  if (koreny[1] < koreny[0])
402  SWAP(koreny[0], koreny[1]);
403  nreal = 3;
404  } else {
405  /* only one real solution */
406  dis = sqrt(dis);
407  h = TMath::Power(fabs(q + dis), 1.0 / 3.0);
408  p = TMath::Power(fabs(q - dis), 1.0 / 3.0);
409  koreny[0] = ((q + dis > 0.0) ? h : -h) + ((q - dis > 0.0) ? p : -p) - w;
410  nreal = 1;
411  }
412 
413  /* Perform one step of a Newton iteration in order to minimize
414  round-off errors */
415  for (unsigned i = 0; i < nreal; i++) {
416  h = coeffs[1] + koreny[i] * (2 * coeffs[2] + 3 * koreny[i] * coeffs[3]);
417  if (h != 0.0)
418  koreny[i] -= (coeffs[0] + koreny[i] * (coeffs[1] + koreny[i] * (coeffs[2] + koreny[i] * coeffs[3]))) / h;
419  }
420  }
421 
422  else if (coeffs[2] != 0.0) {
423  /* quadratic problem? */
424  p = 0.5 * coeffs[1] / coeffs[2];
425  dis = sqr(p) - coeffs[0] / coeffs[2];
426  if (dis >= 0.0) {
427  /* two real solutions */
428  dis = sqrt(dis);
429  koreny[0] = -p - dis;
430  koreny[1] = -p + dis;
431  nreal = 2;
432  } else
433  /* no real solution */
434  nreal = 0;
435  }
436 
437  else if (coeffs[1] != 0.0) {
438  /* linear problem? */
439  koreny[0] = -coeffs[0] / coeffs[1];
440  nreal = 1;
441  }
442 
443  else
444  /* no equation */
445  nreal = 0;
446 
447  return nreal;
448 }
const double Pi
T w() const
void SWAP(double &realone, double &realtwo) const
T sqrt(T t)
Definition: SSEVec.h:19
Cos< T >::type cos(const T &t)
Definition: Cos.h:22
double sqr(const double x) const
The Signals That Services Can Subscribe To This is based on ActivityRegistry h
Helper function to determine trigger accepts.
Definition: Activities.doc:4

◆ FindCoeff()

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 157 of file TtFullLepKinSolver.cc.

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

Referenced by addKinSolInfo(), and getNuSolution().

165  {
166  double E, apom1, apom2, apom3;
167  double k11, k21, k31, k41, cpom1, cpom2, cpom3, l11, l21, l31, l41, l51, l61, k1, k2, k3, k4, k5, k6;
168  double l1, l2, l3, l4, l5, l6, k15, k25, k35, k45;
169 
170  C = -al.Px() - b_al.Px() - l.Px() - b_l.Px() + px_miss;
171  D = -al.Py() - b_al.Py() - l.Py() - b_l.Py() + py_miss;
172 
173  // right side of first two linear equations - missing pT
174 
175  E = (sqr(mt) - sqr(mw) - sqr(mb)) / (2 * b_al.E()) - sqr(mw) / (2 * al.E()) - al.E() +
176  al.Px() * b_al.Px() / b_al.E() + al.Py() * b_al.Py() / b_al.E() + al.Pz() * b_al.Pz() / b_al.E();
177  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() +
178  l.Py() * b_l.Py() / b_l.E() + l.Pz() * b_l.Pz() / b_l.E();
179 
180  m1 = al.Px() / al.E() - b_al.Px() / b_al.E();
181  m2 = al.Py() / al.E() - b_al.Py() / b_al.E();
182  m3 = al.Pz() / al.E() - b_al.Pz() / b_al.E();
183 
184  n1 = l.Px() / l.E() - b_l.Px() / b_l.E();
185  n2 = l.Py() / l.E() - b_l.Py() / b_l.E();
186  n3 = l.Pz() / l.E() - b_l.Pz() / b_l.E();
187 
188  pom = E - m1 * C - m2 * D;
189  apom1 = sqr(al.Px()) - sqr(al.E());
190  apom2 = sqr(al.Py()) - sqr(al.E());
191  apom3 = sqr(al.Pz()) - sqr(al.E());
192 
193  k11 = 1 / sqr(al.E()) *
194  (pow(mw, 4) / 4 + sqr(C) * apom1 + sqr(D) * apom2 + apom3 * sqr(pom) / sqr(m3) +
195  sqr(mw) * (al.Px() * C + al.Py() * D + al.Pz() * pom / m3) + 2 * al.Px() * al.Py() * C * D +
196  2 * al.Px() * al.Pz() * C * pom / m3 + 2 * al.Py() * al.Pz() * D * pom / m3);
197  k21 = 1 / sqr(al.E()) *
198  (-2 * C * m3 * n3 * apom1 + 2 * apom3 * n3 * m1 * pom / m3 - sqr(mw) * m3 * n3 * al.Px() +
199  sqr(mw) * m1 * n3 * al.Pz() - 2 * al.Px() * al.Py() * D * m3 * n3 + 2 * al.Px() * al.Pz() * C * m1 * n3 -
200  2 * al.Px() * al.Pz() * n3 * pom + 2 * al.Py() * al.Pz() * D * m1 * n3);
201  k31 = 1 / sqr(al.E()) *
202  (-2 * D * m3 * n3 * apom2 + 2 * apom3 * n3 * m2 * pom / m3 - sqr(mw) * m3 * n3 * al.Py() +
203  sqr(mw) * m2 * n3 * al.Pz() - 2 * al.Px() * al.Py() * C * m3 * n3 + 2 * al.Px() * al.Pz() * C * m2 * n3 -
204  2 * al.Py() * al.Pz() * n3 * pom + 2 * al.Py() * al.Pz() * D * m2 * n3);
205  k41 = 1 / sqr(al.E()) *
206  (2 * apom3 * m1 * m2 * sqr(n3) + 2 * al.Px() * al.Py() * sqr(m3) * sqr(n3) -
207  2 * al.Px() * al.Pz() * m2 * m3 * sqr(n3) - 2 * al.Py() * al.Pz() * m1 * m3 * sqr(n3));
208  k51 = 1 / sqr(al.E()) *
209  (apom1 * sqr(m3) * sqr(n3) + apom3 * sqr(m1) * sqr(n3) - 2 * al.Px() * al.Pz() * m1 * m3 * sqr(n3));
210  k61 = 1 / sqr(al.E()) *
211  (apom2 * sqr(m3) * sqr(n3) + apom3 * sqr(m2) * sqr(n3) - 2 * al.Py() * al.Pz() * m2 * m3 * sqr(n3));
212 
213  cpom1 = sqr(l.Px()) - sqr(l.E());
214  cpom2 = sqr(l.Py()) - sqr(l.E());
215  cpom3 = sqr(l.Pz()) - sqr(l.E());
216 
217  l11 = 1 / sqr(l.E()) * (pow(mw, 4) / 4 + cpom3 * sqr(F) / sqr(n3) + sqr(mw) * l.Pz() * F / n3);
218  l21 =
219  1 / sqr(l.E()) *
220  (-2 * cpom3 * F * m3 * n1 / n3 + sqr(mw) * (l.Px() * m3 * n3 - l.Pz() * n1 * m3) + 2 * l.Px() * l.Pz() * F * m3);
221  l31 =
222  1 / sqr(l.E()) *
223  (-2 * cpom3 * F * m3 * n2 / n3 + sqr(mw) * (l.Py() * m3 * n3 - l.Pz() * n2 * m3) + 2 * l.Py() * l.Pz() * F * m3);
224  l41 = 1 / sqr(l.E()) *
225  (2 * cpom3 * n1 * n2 * sqr(m3) + 2 * l.Px() * l.Py() * sqr(m3) * sqr(n3) -
226  2 * l.Px() * l.Pz() * n2 * n3 * sqr(m3) - 2 * l.Py() * l.Pz() * n1 * n3 * sqr(m3));
227  l51 = 1 / sqr(l.E()) *
228  (cpom1 * sqr(m3) * sqr(n3) + cpom3 * sqr(n1) * sqr(m3) - 2 * l.Px() * l.Pz() * n1 * n3 * sqr(m3));
229  l61 = 1 / sqr(l.E()) *
230  (cpom2 * sqr(m3) * sqr(n3) + cpom3 * sqr(n2) * sqr(m3) - 2 * l.Py() * l.Pz() * n2 * n3 * sqr(m3));
231 
232  k1 = k11 * k61;
233  k2 = k61 * k21 / k51;
234  k3 = k31;
235  k4 = k41 / k51;
236  k5 = k61 / k51;
237  k6 = 1;
238 
239  l1 = l11 * k61;
240  l2 = l21 * k61 / k51;
241  l3 = l31;
242  l4 = l41 / k51;
243  l5 = l51 * k61 / (sqr(k51));
244  l6 = l61 / k61;
245 
246  k15 = k1 * l5 - l1 * k5;
247  k25 = k2 * l5 - l2 * k5;
248  k35 = k3 * l5 - l3 * k5;
249  k45 = k4 * l5 - l4 * k5;
250 
251  k16 = k1 * l6 - l1 * k6;
252  k26 = k2 * l6 - l2 * k6;
253  k36 = k3 * l6 - l3 * k6;
254  k46 = k4 * l6 - l4 * k6;
255  k56 = k5 * l6 - l5 * k6;
256 
257  koeficienty[0] = k15 * sqr(k36) - k35 * k36 * k16 - k56 * sqr(k16);
258  koeficienty[1] =
259  2 * k15 * k36 * k46 + k25 * sqr(k36) + k35 * (-k46 * k16 - k36 * k26) - k45 * k36 * k16 - 2 * k56 * k26 * k16;
260  koeficienty[2] = k15 * sqr(k46) + 2 * k25 * k36 * k46 + k35 * (-k46 * k26 - k36 * k56) -
261  k56 * (sqr(k26) + 2 * k56 * k16) - k45 * (k46 * k16 + k36 * k26);
262  koeficienty[3] = k25 * sqr(k46) - k35 * k46 * k56 - k45 * (k46 * k26 + k36 * k56) - 2 * sqr(k56) * k26;
263  koeficienty[4] = -k45 * k46 * k56 - pow(k56, 3);
264 
265  // normalization of coefficients
266  int moc = (int(log10(fabs(koeficienty[0]))) + int(log10(fabs(koeficienty[4])))) / 2;
267 
268  koeficienty[0] = koeficienty[0] / TMath::Power(10, moc);
269  koeficienty[1] = koeficienty[1] / TMath::Power(10, moc);
270  koeficienty[2] = koeficienty[2] / TMath::Power(10, moc);
271  koeficienty[3] = koeficienty[3] / TMath::Power(10, moc);
272  koeficienty[4] = koeficienty[4] / TMath::Power(10, moc);
273 }
double sqr(const double x) const
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:29

◆ getNuSolution()

TtFullLepKinSolver::NeutrinoSolution TtFullLepKinSolver::getNuSolution ( const TLorentzVector &  LV_l,
const TLorentzVector &  LV_l_,
const TLorentzVector &  LV_b,
const TLorentzVector &  LV_b_ 
)

Definition at line 125 of file TtFullLepKinSolver.cc.

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

128  {
129  math::XYZTLorentzVector maxLV_n = math::XYZTLorentzVector(0, 0, 0, 0);
130  math::XYZTLorentzVector maxLV_n_ = math::XYZTLorentzVector(0, 0, 0, 0);
131 
132  //loop on top mass parameter
133  double weightmax = -1;
134  for (double mt = topmass_begin; mt < topmass_end + 0.5 * topmass_step; mt += topmass_step) {
135  double q_coeff[5], q_sol[4];
136  FindCoeff(LV_l, LV_l_, LV_b, LV_b_, mt, mt, pxmiss_, pymiss_, q_coeff);
137  int NSol = quartic(q_coeff, q_sol);
138 
139  //loop on all solutions
140  for (int isol = 0; isol < NSol; isol++) {
141  TopRec(LV_l, LV_l_, LV_b, LV_b_, q_sol[isol]);
142  double weight = WeightSolfromShape();
143  if (weight > weightmax) {
144  weightmax = weight;
145  maxLV_n.SetPxPyPzE(LV_n.Px(), LV_n.Py(), LV_n.Pz(), LV_n.E());
146  maxLV_n_.SetPxPyPzE(LV_n_.Px(), LV_n_.Py(), LV_n_.Pz(), LV_n_.E());
147  }
148  }
149  }
151  nuSol.neutrino = reco::LeafCandidate(0, maxLV_n);
152  nuSol.neutrinoBar = reco::LeafCandidate(0, maxLV_n_);
153  nuSol.weight = weightmax;
154  return nuSol;
155 }
const double topmass_end
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)
Definition: weight.py:1
double WeightSolfromShape() const
use the parametrized event shape to obtain the solution weight.
const double topmass_step
XYZTLorentzVectorD XYZTLorentzVector
Lorentz vector with cylindrical internal representation using pseudorapidity.
Definition: LorentzVector.h:29
int quartic(double *q_coeff, double *q_sol) const
void TopRec(const TLorentzVector &al, const TLorentzVector &l, const TLorentzVector &b_al, const TLorentzVector &b_l, const double sol)
const double topmass_begin

◆ quartic()

int TtFullLepKinSolver::quartic ( double *  q_coeff,
double *  q_sol 
) const
private

Definition at line 314 of file TtFullLepKinSolver.cc.

References b0, b1, b2, c, cubic(), d0, d1, h, mps_fire::i, multPhiCorr_741_25nsDY_cfi::px, sqr(), mathSSE::sqrt(), submitPVValidationJobs::t, w(), and z.

Referenced by addKinSolInfo(), and getNuSolution().

314  {
315  double w, b0, b1, b2;
316  double c[4];
317  double d0, d1, h, t, z;
318  double* px;
319 
320  if (koeficienty[4] == 0.0)
321  return cubic(koeficienty, koreny);
322  /* quartic problem? */
323  w = koeficienty[3] / (4 * koeficienty[4]);
324  /* offset */
325  b2 = -6 * sqr(w) + koeficienty[2] / koeficienty[4];
326  /* koeficienty. of shifted polynomial */
327  b1 = (8 * sqr(w) - 2 * koeficienty[2] / koeficienty[4]) * w + koeficienty[1] / koeficienty[4];
328  b0 = ((-3 * sqr(w) + koeficienty[2] / koeficienty[4]) * w - koeficienty[1] / koeficienty[4]) * w +
329  koeficienty[0] / koeficienty[4];
330 
331  c[3] = 1.0;
332  /* cubic resolvent */
333  c[2] = b2;
334  c[1] = -4 * b0;
335  c[0] = sqr(b1) - 4 * b0 * b2;
336 
337  cubic(c, koreny);
338  z = koreny[0];
339  //double z1=1.0,z2=2.0,z3=3.0;
340  //TMath::RootsCubic(c,z1,z2,z3);
341  //if (z2 !=0) z = z2;
342  //if (z1 !=0) z = z1;
343  /* only lowermost root needed */
344 
345  int nreal = 0;
346  px = koreny;
347  t = sqrt(0.25 * sqr(z) - b0);
348  for (int i = -1; i <= 1; i += 2) {
349  d0 = -0.5 * z + i * t;
350  /* coeffs. of quadratic factor */
351  d1 = (t != 0.0) ? -i * 0.5 * b1 / t : i * sqrt(-z - b2);
352  h = 0.25 * sqr(d1) - d0;
353  if (h >= 0.0) {
354  h = sqrt(h);
355  nreal += 2;
356  *px++ = -0.5 * d1 - h - w;
357  *px++ = -0.5 * d1 + h - w;
358  }
359  }
360 
361  // if (nreal==4) {
362  /* sort results */
363  // if (koreny[2]<koreny[0]) SWAP(koreny[0], koreny[2]);
364  // if (koreny[3]<koreny[1]) SWAP(koreny[1], koreny[3]);
365  // if (koreny[1]<koreny[0]) SWAP(koreny[0], koreny[1]);
366  // if (koreny[3]<koreny[2]) SWAP(koreny[2], koreny[3]);
367  // if (koreny[2]<koreny[1]) SWAP(koreny[1], koreny[2]);
368  // }
369  return nreal;
370 }
weight_default_t b1[25]
Definition: b1.h:9
T w() const
int cubic(const double *c_coeff, double *c_sol) const
T sqrt(T t)
Definition: SSEVec.h:19
weight_default_t b2[10]
Definition: b2.h:9
static constexpr float d0
double sqr(const double x) const
static constexpr float b0
static constexpr float d1
The Signals That Services Can Subscribe To This is based on ActivityRegistry h
Helper function to determine trigger accepts.
Definition: Activities.doc:4

◆ SetConstraints()

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

◆ sqr()

double TtFullLepKinSolver::sqr ( const double  x) const
inlineprivate

Definition at line 80 of file TtFullLepKinSolver.h.

References x.

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

80 { return (x * x); }

◆ SWAP()

void TtFullLepKinSolver::SWAP ( double &  realone,
double &  realtwo 
) const
private

Definition at line 450 of file TtFullLepKinSolver.cc.

References printConversionInfo::aux.

Referenced by cubic().

450  {
451  if (realtwo < realone) {
452  double aux = realtwo;
453  realtwo = realone;
454  realone = aux;
455  }
456 }

◆ TopRec()

void TtFullLepKinSolver::TopRec ( const TLorentzVector &  al,
const TLorentzVector &  l,
const TLorentzVector &  b_al,
const TLorentzVector &  b_l,
const double  sol 
)
private

Definition at line 275 of file TtFullLepKinSolver.cc.

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

Referenced by addKinSolInfo(), and getNuSolution().

279  {
280  TVector3 t_ttboost;
281  TLorentzVector aux;
282  double pxp, pyp, pzp, pup, pvp, pwp;
283 
284  pxp = sol * (m3 * n3 / k51);
285  pyp = -(m3 * n3 / k61) * (k56 * pow(sol, 2) + k26 * sol + k16) / (k36 + k46 * sol);
286  pzp = -1 / n3 * (n1 * pxp + n2 * pyp - F);
287  pwp = 1 / m3 * (m1 * pxp + m2 * pyp + pom);
288  pup = C - pxp;
289  pvp = D - pyp;
290 
291  LV_n_.SetXYZM(pxp, pyp, pzp, 0.0);
292  LV_n.SetXYZM(pup, pvp, pwp, 0.0);
293 
294  LV_t_ = b_l + l + LV_n_;
295  LV_t = b_al + al + LV_n;
296 
297  aux = (LV_t_ + LV_t);
298  t_ttboost = -aux.BoostVector();
299  LV_tt_t_ = LV_t_;
300  LV_tt_t = LV_t;
301  LV_tt_t_.Boost(t_ttboost);
302  LV_tt_t.Boost(t_ttboost);
303 }
constexpr float sol
Definition: Config.h:48
TLorentzVector LV_tt_t
TLorentzVector LV_tt_t_
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:29

◆ useWeightFromMC()

void TtFullLepKinSolver::useWeightFromMC ( bool  useMC)
inline

Definition at line 43 of file TtFullLepKinSolver.h.

References JetHT_cfg::useMC, and useMCforBest_.

Referenced by TtDilepEvtSolutionMaker::produce().

43 { useMCforBest_ = useMC; }
bool useMCforBest_
flag to swith from WeightSolfromMC() to WeightSolfromShape()
dictionary useMC
Definition: JetHT_cfg.py:44

◆ WeightSolfromMC()

double TtFullLepKinSolver::WeightSolfromMC ( ) const
private

Definition at line 305 of file TtFullLepKinSolver.cc.

References genLV_n, genLV_n_, LV_n, LV_n_, and mps_merge::weight.

Referenced by addKinSolInfo().

305  {
306  double weight = 1;
307  weight = ((LV_n.E() > genLV_n.E()) ? genLV_n.E() / LV_n.E() : LV_n.E() / genLV_n.E()) *
308  ((LV_n_.E() > genLV_n_.E()) ? genLV_n_.E() / LV_n_.E() : LV_n_.E() / genLV_n_.E());
309  return weight;
310 }
Definition: weight.py:1
TLorentzVector genLV_n
provisional
TLorentzVector genLV_n_

◆ WeightSolfromShape()

double TtFullLepKinSolver::WeightSolfromShape ( ) const
private

use the parametrized event shape to obtain the solution weight.

Definition at line 312 of file TtFullLepKinSolver.cc.

References EventShape_, LV_n, and LV_n_.

Referenced by addKinSolInfo(), and getNuSolution().

312 { return EventShape_->Eval(LV_n.E(), LV_n_.E()); }
TF2 * EventShape_
Event shape.

Member Data Documentation

◆ C

double TtFullLepKinSolver::C
private

Definition at line 98 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ D

double TtFullLepKinSolver::D
private

Definition at line 99 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ EventShape_

TF2* TtFullLepKinSolver::EventShape_
private

Event shape.

Definition at line 124 of file TtFullLepKinSolver.h.

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

◆ F

double TtFullLepKinSolver::F
private

Definition at line 100 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ genLV_n

TLorentzVector TtFullLepKinSolver::genLV_n
private

provisional

Definition at line 119 of file TtFullLepKinSolver.h.

Referenced by addKinSolInfo(), and WeightSolfromMC().

◆ genLV_n_

TLorentzVector TtFullLepKinSolver::genLV_n_
private

Definition at line 119 of file TtFullLepKinSolver.h.

Referenced by addKinSolInfo(), and WeightSolfromMC().

◆ k16

double TtFullLepKinSolver::k16
private

Definition at line 102 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ k26

double TtFullLepKinSolver::k26
private

Definition at line 103 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ k36

double TtFullLepKinSolver::k36
private

Definition at line 104 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ k46

double TtFullLepKinSolver::k46
private

Definition at line 105 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ k51

double TtFullLepKinSolver::k51
private

Definition at line 107 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ k56

double TtFullLepKinSolver::k56
private

Definition at line 106 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ k61

double TtFullLepKinSolver::k61
private

Definition at line 108 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ LV_n

TLorentzVector TtFullLepKinSolver::LV_n
private

Definition at line 117 of file TtFullLepKinSolver.h.

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

◆ LV_n_

TLorentzVector TtFullLepKinSolver::LV_n_
private

Definition at line 117 of file TtFullLepKinSolver.h.

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

◆ LV_t

TLorentzVector TtFullLepKinSolver::LV_t
private

Definition at line 117 of file TtFullLepKinSolver.h.

Referenced by TopRec().

◆ LV_t_

TLorentzVector TtFullLepKinSolver::LV_t_
private

Definition at line 117 of file TtFullLepKinSolver.h.

Referenced by TopRec().

◆ LV_tt_t

TLorentzVector TtFullLepKinSolver::LV_tt_t
private

Definition at line 117 of file TtFullLepKinSolver.h.

Referenced by TopRec().

◆ LV_tt_t_

TLorentzVector TtFullLepKinSolver::LV_tt_t_
private

Definition at line 117 of file TtFullLepKinSolver.h.

Referenced by TopRec().

◆ m1

double TtFullLepKinSolver::m1
private

Definition at line 109 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ m2

double TtFullLepKinSolver::m2
private

Definition at line 110 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ m3

double TtFullLepKinSolver::m3
private

Definition at line 111 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ mb

const double TtFullLepKinSolver::mb
private

Definition at line 94 of file TtFullLepKinSolver.h.

Referenced by FindCoeff().

◆ mw

const double TtFullLepKinSolver::mw
private

Definition at line 92 of file TtFullLepKinSolver.h.

Referenced by FindCoeff().

◆ n1

double TtFullLepKinSolver::n1
private

Definition at line 112 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ n2

double TtFullLepKinSolver::n2
private

Definition at line 113 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ n3

double TtFullLepKinSolver::n3
private

Definition at line 114 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ pom

double TtFullLepKinSolver::pom
private

Definition at line 101 of file TtFullLepKinSolver.h.

Referenced by FindCoeff(), and TopRec().

◆ pxmiss_

double TtFullLepKinSolver::pxmiss_
private

Definition at line 96 of file TtFullLepKinSolver.h.

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

◆ pymiss_

double TtFullLepKinSolver::pymiss_
private

Definition at line 96 of file TtFullLepKinSolver.h.

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

◆ topmass_begin

const double TtFullLepKinSolver::topmass_begin
private

Definition at line 86 of file TtFullLepKinSolver.h.

Referenced by addKinSolInfo(), and getNuSolution().

◆ topmass_end

const double TtFullLepKinSolver::topmass_end
private

Definition at line 88 of file TtFullLepKinSolver.h.

Referenced by addKinSolInfo(), and getNuSolution().

◆ topmass_step

const double TtFullLepKinSolver::topmass_step
private

Definition at line 90 of file TtFullLepKinSolver.h.

Referenced by addKinSolInfo(), and getNuSolution().

◆ useMCforBest_

bool TtFullLepKinSolver::useMCforBest_
private

flag to swith from WeightSolfromMC() to WeightSolfromShape()

Definition at line 122 of file TtFullLepKinSolver.h.

Referenced by addKinSolInfo(), and useWeightFromMC().