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MuScleFitUtils Class Reference

#include <MuScleFitUtils.h>

Classes

struct  byPt
 
struct  massResolComponentsStruct
 

Public Member Functions

 MuScleFitUtils ()
 
virtual ~MuScleFitUtils ()
 

Static Public Member Functions

static lorentzVector applyBias (const lorentzVector &muon, const int charge)
 
static lorentzVector applyScale (const lorentzVector &muon, const std::vector< double > &parval, const int charge)
 
static lorentzVector applyScale (const lorentzVector &muon, double *parval, const int charge)
 
static lorentzVector applySmearing (const lorentzVector &muon)
 
static bool checkMassWindow (const double &mass, const double &leftBorder, const double &rightBorder)
 Method to check if the mass value is within the mass window of the i-th resonance. More...
 
static double computeWeight (const double &mass, const int iev, const bool doUseBkgrWindow=false)
 
static double deltaPhi (const double &phi1, const double &phi2)
 
static double deltaPhiNoFabs (const double &phi1, const double &phi2)
 Without fabs at the end, used to have a symmetric distribution for the resolution fits and variance computations. More...
 
static double deltaR (const double &eta1, const double &eta2, const double &phi1, const double &phi2)
 
static std::pair
< MuScleFitMuon, MuScleFitMuon
findBestRecoRes (const std::vector< MuScleFitMuon > &muons)
 
static std::pair< SimTrack,
SimTrack
findBestSimuRes (const std::vector< SimTrack > &simMuons)
 
static std::pair
< lorentzVector, lorentzVector
findGenMuFromRes (const reco::GenParticleCollection *genParticles)
 
static std::pair
< lorentzVector, lorentzVector
findGenMuFromRes (const edm::HepMCProduct *evtMC)
 
static std::pair
< lorentzVector, lorentzVector
findSimMuFromRes (const edm::Handle< edm::HepMCProduct > &evtMC, const edm::Handle< edm::SimTrackContainer > &simTracks)
 
static std::vector
< TGraphErrors * > 
fitMass (TH2F *histo)
 
static std::vector
< TGraphErrors * > 
fitReso (TH2F *histo)
 
static lorentzVector fromPtEtaPhiToPxPyPz (const double *ptEtaPhiE)
 
static double invDimuonMass (const lorentzVector &mu1, const lorentzVector &mu2)
 
static double massProb (const double &mass, const double &rapidity, const int ires, const double &massResol)
 
static double massProb (const double &mass, const double &resEta, const double &rapidity, const double &massResol, const std::vector< double > &parval, const bool doUseBkgrWindow, const double &eta1, const double &eta2)
 
static double massProb (const double &mass, const double &resEta, const double &rapidity, const double &massResol, double *parval, const bool doUseBkgrWindow, const double &eta1, const double &eta2)
 
static double massResolution (const lorentzVector &mu1, const lorentzVector &mu2)
 
static double massResolution (const lorentzVector &mu1, const lorentzVector &mu2, const std::vector< double > &parval)
 
static double massResolution (const lorentzVector &mu1, const lorentzVector &mu2, std::auto_ptr< double > parval)
 
static double massResolution (const lorentzVector &mu1, const lorentzVector &mu2, double *parval)
 
static double massResolution (const lorentzVector &mu1, const lorentzVector &mu2, const ResolutionFunction &resolFunc)
 
static void minimizeLikelihood ()
 
static double probability (const double &mass, const double &massResol, const double GLvalue[][1001][1001], const double GLnorm[][1001], const int iRes, const int iY)
 Computes the probability given the mass, mass resolution and the arrays with the probabilities and the normalizations. More...
 

Static Public Attributes

static const int backgroundFunctionsRegions
 
static BackgroundHandlerbackgroundHandler
 
static TH1D * backgroundProb_ = 0
 
static int BgrFitType = 0
 
static scaleFunctionBase
< std::vector< double > > * 
biasFunction = 0
 
static int BiasType = 0
 
static bool computeMinosErrors_
 
static int counter_resprob = 0
 
static double crossSection [6]
 
static CrossSectionHandlercrossSectionHandler
 
static int debug = 0
 
static bool debugMassResol_
 
static double deltaPhiMaxCut_ = 100.
 
static double deltaPhiMinCut_ = -100.
 
static std::vector< int > doBackgroundFit
 
static std::vector< int > doCrossSectionFit
 
static std::vector< int > doResolFit
 
static std::vector< int > doScaleFit
 
static bool duringMinos_ = false
 
static int FitStrategy = 1
 
static std::vector< std::pair
< lorentzVector, lorentzVector > > 
genPair
 
static double GLNorm [6][1001]
 
static double GLValue [6][1001][1001]
 
static double GLZNorm [40][1001]
 
static double GLZValue [40][1001][1001]
 
static int goodmuon = 0
 
static int iev_ = 0
 
static TH1D * likelihoodInLoop_ = 0
 
static unsigned int loopCounter = 5
 
static struct
MuScleFitUtils::massResolComponentsStruct 
massResolComponents
 
static double massWindowHalfWidth [3][6]
 
static double maxMuonEtaFirstRange_ = 6.
 
static double maxMuonEtaSecondRange_ = 100.
 
static double maxMuonPt_ = 100000000.
 
static bool minimumShapePlots_
 
static double minMuonEtaFirstRange_ = -6.
 
static double minMuonEtaSecondRange_ = -100.
 
static double minMuonPt_ = 0.
 
static int minuitLoop_ = 0
 
static const double mMu2 = 0.011163612
 
static const unsigned int motherPdgIdArray [6] = {23, 100553, 100553, 553, 100443, 443}
 
static const double muMass = 0.105658
 
static int MuonType
 
static int MuonTypeForCheckMassWindow
 
static int nbins = 1000
 
static unsigned int normalizationChanged_ = 0
 
static bool normalizeLikelihoodByEventNumber_ = true
 
static double oldNormalization_ = 0.
 
static std::vector< double > parBgr
 
static std::vector< int > parBgrFix
 
static std::vector< int > parBgrOrder
 
static std::vector< double > parBias
 
static std::vector< double > parCrossSection
 
static std::vector< int > parCrossSectionFix
 
static std::vector< int > parCrossSectionOrder
 
static std::vector< int > parfix
 
static std::vector< int > parorder
 
static std::vector< double > parResol
 
static std::vector< int > parResolFix
 
static std::vector< double > parResolMax
 
static std::vector< double > parResolMin
 
static std::vector< int > parResolOrder
 
static std::vector< double > parResolStep
 
static std::vector< double > parScale
 
static std::vector< int > parScaleFix
 
static std::vector< double > parScaleMax
 
static std::vector< double > parScaleMin
 
static std::vector< int > parScaleOrder
 
static std::vector< double > parScaleStep
 
static std::vector< double > parSmear
 
static std::vector
< std::vector< double > > 
parvalue
 
static bool rapidityBinsForZ_ = true
 
static std::vector< std::pair
< lorentzVector, lorentzVector > > 
ReducedSavedPair
 
static std::vector< int > resfind
 
static bool ResFound = false
 
static double ResGamma [6] = {2.4952, 0.000020, 0.000032, 0.000054, 0.000317, 0.0000932 }
 
static double ResHalfWidth [6]
 
static double ResMass [6] = {91.1876, 10.3552, 10.0233, 9.4603, 3.68609, 3.0969}
 
static double ResMaxSigma [6]
 
static double ResMinMass [6] = {-99, -99, -99, -99, -99, -99}
 
static int ResolFitType = 0
 
static resolutionFunctionBase
< double * > * 
resolutionFunction = 0
 
static resolutionFunctionBase
< std::vector< double > > * 
resolutionFunctionForVec = 0
 
static TMinuit * rminPtr_ = 0
 
static std::vector< std::pair
< lorentzVector, lorentzVector > > 
SavedPair
 
static std::vector< std::pair
< MuScleFitMuon, MuScleFitMuon > > 
SavedPairMuScleFitMuons
 
static bool scaleFitNotDone_ = true
 
static int ScaleFitType = 0
 
static scaleFunctionBase
< double * > * 
scaleFunction = 0
 
static scaleFunctionBase
< std::vector< double > > * 
scaleFunctionForVec = 0
 
static bool separateRanges_ = true
 
static bool sherpa_ = false
 
static TH1D * signalProb_ = 0
 
static std::vector< std::pair
< lorentzVector, lorentzVector > > 
simPair
 
static smearFunctionBasesmearFunction = 0
 
static int SmearType = 0
 
static bool speedup = false
 
static bool startWithSimplex_
 
static const int totalResNum = 6
 
static bool useProbsFile_ = true
 
static double x [7][10000]
 

Detailed Description

Definition at line 48 of file MuScleFitUtils.h.

Constructor & Destructor Documentation

MuScleFitUtils::MuScleFitUtils ( )
inline

Definition at line 53 of file MuScleFitUtils.h.

53 {};
virtual MuScleFitUtils::~MuScleFitUtils ( )
inlinevirtual

Definition at line 57 of file MuScleFitUtils.h.

57 {};

Member Function Documentation

lorentzVector MuScleFitUtils::applyBias ( const lorentzVector muon,
const int  charge 
)
static

Definition at line 432 of file MuScleFitUtils.cc.

References biasFunction, gather_cfg::cout, debug, fromPtEtaPhiToPxPyPz(), parBias, and scaleFunctionBase< T >::scale().

Referenced by MuScleFit::applyBias().

433 {
434  double ptEtaPhiE[4] = {muon.Pt(),muon.Eta(),muon.Phi(),muon.E()};
435 
436  if (MuScleFitUtils::debug>1) std::cout << "pt before bias = " << ptEtaPhiE[0] << std::endl;
437 
438  // Use functors (although not with the () operator)
439  // Note that we always pass pt, eta and phi, but internally only the needed
440  // values are used.
441  // The functors used are takend from the same group used for the scaling
442  // thus the name of the method used is "scale".
443  ptEtaPhiE[0] = biasFunction->scale(ptEtaPhiE[0], ptEtaPhiE[1], ptEtaPhiE[2], chg, MuScleFitUtils::parBias);
444 
445  if (MuScleFitUtils::debug>1) std::cout << "pt after bias = " << ptEtaPhiE[0] << std::endl;
446 
447  return( fromPtEtaPhiToPxPyPz(ptEtaPhiE) );
448 }
static std::vector< double > parBias
static int debug
static scaleFunctionBase< std::vector< double > > * biasFunction
static lorentzVector fromPtEtaPhiToPxPyPz(const double *ptEtaPhiE)
virtual double scale(const double &pt, const double &eta, const double &phi, const int chg, const T &parScale) const =0
tuple cout
Definition: gather_cfg.py:121
lorentzVector MuScleFitUtils::applyScale ( const lorentzVector muon,
const std::vector< double > &  parval,
const int  charge 
)
static

Definition at line 452 of file MuScleFitUtils.cc.

References AlCaHLTBitMon_ParallelJobs::p.

Referenced by MuScleFit::duringFastLoop(), and likelihood().

454 {
455  double * p = new double[(int)(parval.size())];
456  // Replaced by auto_ptr, which handles delete at the end
457  // std::auto_ptr<double> p(new double[(int)(parval.size())]);
458  // Removed auto_ptr, check massResolution for an explanation.
459  int id = 0;
460  for (std::vector<double>::const_iterator it=parval.begin(); it!=parval.end(); ++it, ++id) {
461  //(&*p)[id] = *it;
462  // Also ok would be (p.get())[id] = *it;
463  p[id] = *it;
464  }
465  lorentzVector tempScaleVec( applyScale (muon, p, chg) );
466  delete[] p;
467  return tempScaleVec;
468 }
reco::Particle::LorentzVector lorentzVector
Definition: GenMuonPair.h:9
static lorentzVector applyScale(const lorentzVector &muon, const std::vector< double > &parval, const int charge)
lorentzVector MuScleFitUtils::applyScale ( const lorentzVector muon,
double *  parval,
const int  charge 
)
static

Definition at line 472 of file MuScleFitUtils.cc.

References gather_cfg::cout, debug, fromPtEtaPhiToPxPyPz(), parResol, scaleFunctionBase< T >::scale(), scaleFunction, and edm::shift.

474 {
475  double ptEtaPhiE[4] = {muon.Pt(),muon.Eta(),muon.Phi(),muon.E()};
476  int shift = parResol.size();
477 
478  if (MuScleFitUtils::debug>1) std::cout << "pt before scale = " << ptEtaPhiE[0] << std::endl;
479 
480  // the address of parval[shift] is passed as pointer to double. Internally it is used as a normal array, thus:
481  // array[0] = parval[shift], array[1] = parval[shift+1], ...
482  ptEtaPhiE[0] = scaleFunction->scale(ptEtaPhiE[0], ptEtaPhiE[1], ptEtaPhiE[2], chg, &(parval[shift]));
483 
484  if (MuScleFitUtils::debug>1) std::cout << "pt after scale = " << ptEtaPhiE[0] << std::endl;
485 
486  return( fromPtEtaPhiToPxPyPz(ptEtaPhiE) );
487 }
static std::vector< double > parResol
static int debug
static lorentzVector fromPtEtaPhiToPxPyPz(const double *ptEtaPhiE)
virtual double scale(const double &pt, const double &eta, const double &phi, const int chg, const T &parScale) const =0
static unsigned int const shift
tuple cout
Definition: gather_cfg.py:121
static scaleFunctionBase< double * > * scaleFunction
lorentzVector MuScleFitUtils::applySmearing ( const lorentzVector muon)
static

Definition at line 402 of file MuScleFitUtils.cc.

References gather_cfg::cout, debug, eta(), fromPtEtaPhiToPxPyPz(), goodmuon, i, parSmear, phi, RecoTauCleanerPlugins::pt, smearFunctionBase::smear(), smearFunction, SmearType, x, and detailsBasic3DVector::y.

Referenced by MuScleFit::applySmearing().

403 {
404  double pt = muon.Pt();
405  double eta = muon.Eta();
406  double phi = muon.Phi();
407  double E = muon.E();
408 
409  double y[7] = {};
410  for (int i=0; i<SmearType+3; i++) {
411  y[i] = x[i][goodmuon%10000];
412  }
413 
414  // Use the smear function selected in the constructor
415  smearFunction->smear( pt, eta, phi, y, parSmear );
416 
417  if (debug>9) {
418  std::cout << "Smearing Pt,eta,phi = " << pt << " " << eta << " "
419  << phi << "; x = ";
420  for (int i=0; i<SmearType+3; i++) {
421  std::cout << y[i];
422  }
423  std::cout << std::endl;
424  }
425 
426  double ptEtaPhiE[4] = {pt, eta, phi, E};
427  return( fromPtEtaPhiToPxPyPz(ptEtaPhiE) );
428 }
int i
Definition: DBlmapReader.cc:9
static smearFunctionBase * smearFunction
virtual void smear(double &pt, double &eta, double &phi, const double *y, const std::vector< double > &parSmear)=0
static double x[7][10000]
static int debug
T eta() const
static int SmearType
static lorentzVector fromPtEtaPhiToPxPyPz(const double *ptEtaPhiE)
static std::vector< double > parSmear
static int goodmuon
tuple cout
Definition: gather_cfg.py:121
Definition: DDAxes.h:10
bool MuScleFitUtils::checkMassWindow ( const double &  mass,
const double &  leftBorder,
const double &  rightBorder 
)
inlinestatic

Method to check if the mass value is within the mass window of the i-th resonance.

Definition at line 1090 of file MuScleFitUtils.cc.

Referenced by computeWeight(), massProb(), and minimizeLikelihood().

1091 {
1092  return( (mass > leftBorder) && (mass < rightBorder) );
1093 }
double MuScleFitUtils::computeWeight ( const double &  mass,
const int  iev,
const bool  doUseBkgrWindow = false 
)
static

Definition at line 1097 of file MuScleFitUtils.cc.

References backgroundHandler, checkMassWindow(), gather_cfg::cout, debug, doBackgroundFit, ires, loopCounter, resfind, histoStyle::weight, and BackgroundHandler::windowBorders().

Referenced by MuScleFit::duringFastLoop(), and likelihood().

1098 {
1099  // Compute weight for this event
1100  // -----------------------------
1101  double weight = 0.;
1102 
1103  // Take the highest-mass resonance within bounds
1104  // NB this must be revised once credible estimates of the relative xs of Y(1S), (2S), and (3S)
1105  // are made. Those are priors in the decision of which resonance to assign to an in-between event.
1106  // -----------------------------------------------------------------------------------------------
1107 
1108  if( doUseBkgrWindow && (debug > 0) ) std::cout << "using backgrond window for mass = " << mass << std::endl;
1109  // bool useBackgroundWindow = (doBackgroundFit[loopCounter] || doUseBkgrWindow);
1110  bool useBackgroundWindow = (doBackgroundFit[loopCounter]);
1111 
1112  for (int ires=0; ires<6; ires++) {
1113  if (resfind[ires]>0 && weight==0.) {
1114  // std::pair<double, double> windowFactor = backgroundHandler->windowFactors( useBackgroundWindow, ires );
1115  std::pair<double, double> windowBorder = backgroundHandler->windowBorders( useBackgroundWindow, ires );
1116  // if( checkMassWindow(mass, ires, backgroundHandler->resMass( useBackgroundWindow, ires ),
1117  // windowFactor.first, windowFactor.second) ) {
1118  if( checkMassWindow(mass, windowBorder.first, windowBorder.second) ) {
1119  weight = 1.0;
1120  if( doUseBkgrWindow && (debug > 0) ) std::cout << "setting weight to = " << weight << std::endl;
1121  }
1122  }
1123  }
1124 
1125  return weight;
1126 }
static unsigned int loopCounter
static std::vector< int > doBackgroundFit
int ires[2]
static BackgroundHandler * backgroundHandler
static int debug
static bool checkMassWindow(const double &mass, const double &leftBorder, const double &rightBorder)
Method to check if the mass value is within the mass window of the i-th resonance.
std::pair< double, double > windowBorders(const bool doBackgroundFit, const int ires)
Returns the appropriate window borders depending on whether the background is being fitted and on the...
tuple cout
Definition: gather_cfg.py:121
int weight
Definition: histoStyle.py:50
static std::vector< int > resfind
static double MuScleFitUtils::deltaPhi ( const double &  phi1,
const double &  phi2 
)
inlinestatic

Definition at line 93 of file MuScleFitUtils.h.

References Pi.

Referenced by ResolutionAnalyzer::checkDeltaR(), MuScleFit::checkDeltaR(), deltaPhiNoFabs(), deltaR(), HDelta::Fill(), HMassResolutionVSPart::Fill(), and MuScleFit::selectMuons().

94  {
95  double deltaPhi = phi1 - phi2;
96  while(deltaPhi >= TMath::Pi()) deltaPhi -= 2*TMath::Pi();
97  while(deltaPhi < -TMath::Pi()) deltaPhi += 2*TMath::Pi();
98  return fabs(deltaPhi);
99  }
const double Pi
static double deltaPhi(const double &phi1, const double &phi2)
static double MuScleFitUtils::deltaPhiNoFabs ( const double &  phi1,
const double &  phi2 
)
inlinestatic

Without fabs at the end, used to have a symmetric distribution for the resolution fits and variance computations.

Definition at line 101 of file MuScleFitUtils.h.

References deltaPhi(), and Pi.

Referenced by ResolutionAnalyzer::analyze(), HCovarianceVSParts::Fill(), and MuScleFit::fillComparisonHistograms().

102  {
103  double deltaPhi = phi1 - phi2;
104  while(deltaPhi >= TMath::Pi()) deltaPhi -= 2*TMath::Pi();
105  while(deltaPhi < -TMath::Pi()) deltaPhi += 2*TMath::Pi();
106  return deltaPhi;
107  }
const double Pi
static double deltaPhi(const double &phi1, const double &phi2)
static double MuScleFitUtils::deltaR ( const double &  eta1,
const double &  eta2,
const double &  phi1,
const double &  phi2 
)
inlinestatic

Definition at line 108 of file MuScleFitUtils.h.

References deltaPhi(), funct::pow(), and mathSSE::sqrt().

109  {
110  return sqrt( std::pow( eta1-eta2, 2 ) + std::pow( deltaPhi(phi1, phi2), 2 ) );
111  }
T sqrt(T t)
Definition: SSEVec.h:48
static double deltaPhi(const double &phi1, const double &phi2)
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:40
std::pair< MuScleFitMuon, MuScleFitMuon > MuScleFitUtils::findBestRecoRes ( const std::vector< MuScleFitMuon > &  muons)
static

Definition at line 307 of file MuScleFitUtils.cc.

References gather_cfg::cout, debug, ires, massProb(), massResolution(), maxMuonEtaFirstRange_, maxMuonEtaSecondRange_, maxMuonPt_, minMuonEtaFirstRange_, minMuonEtaSecondRange_, minMuonPt_, parResol, mix_2012_Summer_inTimeOnly_cff::prob, resfind, ResFound, ResMass, and useProbsFile_.

Referenced by TestCorrection::analyze(), and MuScleFit::selectMuons().

307  {
308  // NB this routine returns the resonance, but it also sets the ResFound flag, which
309  // is used in MuScleFit to decide whether to use the event or not.
310  // --------------------------------------------------------------------------------
311  if (debug>0) std::cout << "In findBestRecoRes" << std::endl;
312  ResFound = false;
313  std::pair<MuScleFitMuon, MuScleFitMuon> recMuFromBestRes;
314 
315  // Choose the best resonance using its mass probability
316  // ----------------------------------------------------
317  double maxprob = -0.1;
318  double minDeltaMass = 999999;
319  std::pair<MuScleFitMuon,MuScleFitMuon> bestMassMuons;
320  for (std::vector<MuScleFitMuon>::const_iterator Muon1=muons.begin(); Muon1!=muons.end(); ++Muon1) {
321  //rc2010
322  if (debug>0) std::cout << "muon_1_charge:"<<(*Muon1).charge() << std::endl;
323  for (std::vector<MuScleFitMuon>::const_iterator Muon2=Muon1+1; Muon2!=muons.end(); ++Muon2) {
324  //rc2010
325  if (debug>0) std::cout << "after_2" << std::endl;
326  if ((((*Muon1).charge())*((*Muon2).charge()))>0) {
327  continue; // This also gets rid of Muon1==Muon2...
328  }
329  // To allow the selection of ranges at negative and positive eta independently we define two
330  // ranges of eta: (minMuonEtaFirstRange_, maxMuonEtaFirstRange_) and (minMuonEtaSecondRange_, maxMuonEtaSecondRange_).
331  // If the interval selected is simmetric, one only needs to specify the first range. The second has
332  // default values that accept all muons (minMuonEtaSecondRange_ = -100., maxMuonEtaSecondRange_ = 100.).
333  double pt1 = (*Muon1).Pt();
334  double pt2 = (*Muon2).Pt();
335  double eta1 = (*Muon1).Eta();
336  double eta2 = (*Muon2).Eta();
337  if( pt1 >= minMuonPt_ && pt1 < maxMuonPt_ &&
338  pt2 >= minMuonPt_ && pt2 < maxMuonPt_ &&
339  ( (eta1 >= minMuonEtaFirstRange_ && eta1 < maxMuonEtaFirstRange_ &&
340  eta2 >= minMuonEtaFirstRange_ && eta2 < maxMuonEtaFirstRange_) ||
341  (eta1 >= minMuonEtaSecondRange_ && eta1 < maxMuonEtaSecondRange_ &&
342  eta2 >= minMuonEtaSecondRange_ && eta2 < maxMuonEtaSecondRange_) ) ) {
343  double mcomb = ((*Muon1).p4()+(*Muon2).p4()).mass();
344  double Y = ((*Muon1).p4()+(*Muon2).p4()).Rapidity();
345  if (debug>1) {
346  std::cout<<"muon1 "<<(*Muon1).p4().Px()<<", "<<(*Muon1).p4().Py()<<", "<<(*Muon1).p4().Pz()<<", "<<(*Muon1).p4().E()<<", "<<(*Muon1).charge()<<std::endl;
347  std::cout<<"muon2 "<<(*Muon2).p4().Px()<<", "<<(*Muon2).p4().Py()<<", "<<(*Muon2).p4().Pz()<<", "<<(*Muon2).p4().E()<<", "<<(*Muon2).charge()<<std::endl;
348  std::cout<<"mcomb "<<mcomb<<std::endl;}
349  double massResol = 0.;
350  if( useProbsFile_ ) {
351  massResol = massResolution ((*Muon1).p4(), (*Muon2).p4(), parResol);
352  }
353  double prob = 0;
354  for( int ires=0; ires<6; ires++ ) {
355  if( resfind[ires]>0 ) {
356  if( useProbsFile_ ) {
357  prob = massProb( mcomb, Y, ires, massResol );
358  }
359  if( prob>maxprob ) {
360  if( (*Muon1).charge()<0 ) { // store first the mu minus and then the mu plus
361  recMuFromBestRes.first = (*Muon1);
362  recMuFromBestRes.second = (*Muon2);
363  } else {
364  recMuFromBestRes.first = (*Muon2);
365  recMuFromBestRes.second = (*Muon1);
366  }
367  if (debug>0) std::cout << "muon_1_charge (after swapping):"<<recMuFromBestRes.first.charge() << std::endl;
368  ResFound = true; // NNBB we accept "resonances" even outside mass bounds
369  maxprob = prob;
370  }
371  // if( ResMass[ires] == 0 ) {
372  // std::cout << "Error: ResMass["<<ires<<"] = " << ResMass[ires] << std::endl;
373  // exit(1);
374  // }
375  double deltaMass = fabs(mcomb-ResMass[ires])/ResMass[ires];
376  if( deltaMass<minDeltaMass ){
377  bestMassMuons = std::make_pair((*Muon1),(*Muon2));
378  minDeltaMass = deltaMass;
379  }
380  }
381  }
382  }
383  }
384  }
385  //If outside mass window (maxprob==0) then take the two muons with best invariant mass
386  //(anyway they will not be used in the likelihood calculation, only to fill plots)
387  if(!maxprob){
388  if(bestMassMuons.first.charge()<0){
389  recMuFromBestRes.first = bestMassMuons.first;
390  recMuFromBestRes.second = bestMassMuons.second;
391  }
392  else{
393  recMuFromBestRes.second = bestMassMuons.first;
394  recMuFromBestRes.first = bestMassMuons.second;
395  }
396  }
397  return recMuFromBestRes;
398 }
static double maxMuonEtaSecondRange_
static std::vector< double > parResol
int ires[2]
static int debug
static double ResMass[6]
static bool ResFound
static double minMuonEtaFirstRange_
static double massProb(const double &mass, const double &rapidity, const int ires, const double &massResol)
static double maxMuonPt_
static double massResolution(const lorentzVector &mu1, const lorentzVector &mu2)
static double minMuonEtaSecondRange_
tuple muons
Definition: patZpeak.py:38
tuple cout
Definition: gather_cfg.py:121
static double minMuonPt_
static bool useProbsFile_
static std::vector< int > resfind
static double maxMuonEtaFirstRange_
std::pair< SimTrack, SimTrack > MuScleFitUtils::findBestSimuRes ( const std::vector< SimTrack > &  simMuons)
static

Definition at line 270 of file MuScleFitUtils.cc.

References ires, massProb(), mix_2012_Summer_inTimeOnly_cff::prob, and resfind.

Referenced by MuScleFitPlotter::fillSim().

270  {
271 
272  std::pair<SimTrack, SimTrack> simMuFromBestRes;
273  double maxprob = -0.1;
274 
275  // Double loop on muons
276  // --------------------
277  for (std::vector<SimTrack>::const_iterator simMu1=simMuons.begin(); simMu1!=simMuons.end(); simMu1++) {
278  for (std::vector<SimTrack>::const_iterator simMu2=simMu1+1; simMu2!=simMuons.end(); simMu2++) {
279  if (((*simMu1).charge()*(*simMu2).charge())>0) {
280  continue; // this also gets rid of simMu1==simMu2...
281  }
282  // Choose the best resonance using its mass. Check Z, Y(3S,2S,1S), Psi(2S), J/Psi in order
283  // ---------------------------------------------------------------------------------------
284  double mcomb = ((*simMu1).momentum()+(*simMu2).momentum()).mass();
285  double Y = ((*simMu1).momentum()+(*simMu2).momentum()).Rapidity();
286  for (int ires=0; ires<6; ires++) {
287  if (resfind[ires]>0) {
288  double prob = massProb( mcomb, Y, ires, 0. );
289  if (prob>maxprob) {
290  simMuFromBestRes.first = (*simMu1);
291  simMuFromBestRes.second = (*simMu2);
292  maxprob = prob;
293  }
294  }
295  }
296  }
297  }
298 
299  // Return most likely combination of muons making a resonance
300  // ----------------------------------------------------------
301  return simMuFromBestRes;
302 }
int ires[2]
static double massProb(const double &mass, const double &rapidity, const int ires, const double &massResol)
static std::vector< int > resfind
std::pair< lorentzVector, lorentzVector > MuScleFitUtils::findGenMuFromRes ( const reco::GenParticleCollection genParticles)
static

Definition at line 2258 of file MuScleFitUtils.cc.

References gather_cfg::cout, debug, ires, motherPdgIdArray, and resfind.

Referenced by MuScleFitGenFilter::filter().

2259 {
2260  std::pair<lorentzVector,lorentzVector> muFromRes;
2261 
2262  //Loop on generated particles
2263  if( debug>0 ) std::cout << "Starting loop on " << genParticles->size() << " genParticles" << std::endl;
2264  for( reco::GenParticleCollection::const_iterator part=genParticles->begin(); part!=genParticles->end(); ++part ) {
2265  if (fabs(part->pdgId())==13 && part->status()==1) {
2266  bool fromRes = false;
2267  unsigned int motherPdgId = part->mother()->pdgId();
2268  if( debug>0 ) {
2269  std::cout << "Found a muon with mother: " << motherPdgId << std::endl;
2270  }
2271  for( int ires = 0; ires < 6; ++ires ) {
2272  if( motherPdgId == motherPdgIdArray[ires] && resfind[ires] ) fromRes = true;
2273  }
2274  if(fromRes){
2275  if(part->pdgId()==13) {
2276  muFromRes.first = part->p4();
2277  if( debug>0 ) std::cout << "Found a genMuon + : " << muFromRes.first << std::endl;
2278  // muFromRes.first = (lorentzVector(part->p4().px(),part->p4().py(),
2279  // part->p4().pz(),part->p4().e()));
2280  }
2281  else {
2282  muFromRes.second = part->p4();
2283  if( debug>0 ) std::cout << "Found a genMuon - : " << muFromRes.second << std::endl;
2284  // muFromRes.second = (lorentzVector(part->p4().px(),part->p4().py(),
2285  // part->p4().pz(),part->p4().e()));
2286  }
2287  }
2288  }
2289  }
2290  return muFromRes;
2291 }
int ires[2]
static int debug
static const unsigned int motherPdgIdArray[6]
part
Definition: HCALResponse.h:20
tuple cout
Definition: gather_cfg.py:121
static std::vector< int > resfind
std::pair< lorentzVector, lorentzVector > MuScleFitUtils::findGenMuFromRes ( const edm::HepMCProduct evtMC)
static

Definition at line 2220 of file MuScleFitUtils.cc.

References edm::HepMCProduct::GetEvent(), ires, motherPdgIdArray, resfind, and sherpa_.

2221 {
2222  const HepMC::GenEvent* Evt = evtMC->GetEvent();
2223  std::pair<lorentzVector,lorentzVector> muFromRes;
2224  //Loop on generated particles
2225  for (HepMC::GenEvent::particle_const_iterator part=Evt->particles_begin();
2226  part!=Evt->particles_end(); part++) {
2227  if (fabs((*part)->pdg_id())==13 && (*part)->status()==1) {
2228  bool fromRes = false;
2229  for (HepMC::GenVertex::particle_iterator mother = (*part)->production_vertex()->particles_begin(HepMC::ancestors);
2230  mother != (*part)->production_vertex()->particles_end(HepMC::ancestors); ++mother) {
2231  unsigned int motherPdgId = (*mother)->pdg_id();
2232 
2233  // For sherpa the resonance is not saved. The muons from the resonance can be identified
2234  // by having as mother a muon of status 3.
2235  if( sherpa_ ) {
2236  if( motherPdgId == 13 && (*mother)->status() == 3 ) fromRes = true;
2237  }
2238  else {
2239  for( int ires = 0; ires < 6; ++ires ) {
2240  if( motherPdgId == motherPdgIdArray[ires] && resfind[ires] ) fromRes = true;
2241  }
2242  }
2243  }
2244  if(fromRes){
2245  if((*part)->pdg_id()==13)
2246  // muFromRes.first = (*part)->momentum();
2247  muFromRes.first = (lorentzVector((*part)->momentum().px(),(*part)->momentum().py(),
2248  (*part)->momentum().pz(),(*part)->momentum().e()));
2249  else
2250  muFromRes.second = (lorentzVector((*part)->momentum().px(),(*part)->momentum().py(),
2251  (*part)->momentum().pz(),(*part)->momentum().e()));
2252  }
2253  }
2254  }
2255  return muFromRes;
2256 }
int ires[2]
reco::Particle::LorentzVector lorentzVector
Definition: GenMuonPair.h:9
static const unsigned int motherPdgIdArray[6]
static bool sherpa_
const HepMC::GenEvent * GetEvent() const
Definition: HepMCProduct.h:35
part
Definition: HCALResponse.h:20
static std::vector< int > resfind
std::pair< lorentzVector, lorentzVector > MuScleFitUtils::findSimMuFromRes ( const edm::Handle< edm::HepMCProduct > &  evtMC,
const edm::Handle< edm::SimTrackContainer > &  simTracks 
)
static

Definition at line 2182 of file MuScleFitUtils.cc.

References configurableAnalysis::GenParticle, ires, motherPdgIdArray, and resfind.

Referenced by MuScleFitPlotter::fillGenSim().

2184 {
2185  //Loop on simulated tracks
2186  std::pair<lorentzVector, lorentzVector> simMuFromRes;
2187  for( edm::SimTrackContainer::const_iterator simTrack=simTracks->begin(); simTrack!=simTracks->end(); ++simTrack ) {
2188  //Chose muons
2189  if (fabs((*simTrack).type())==13) {
2190  //If tracks from IP than find mother
2191  if ((*simTrack).genpartIndex()>0) {
2192  HepMC::GenParticle* gp = evtMC->GetEvent()->barcode_to_particle ((*simTrack).genpartIndex());
2193  if( gp != 0 ) {
2194 
2195  for (HepMC::GenVertex::particle_iterator mother = gp->production_vertex()->particles_begin(HepMC::ancestors);
2196  mother!=gp->production_vertex()->particles_end(HepMC::ancestors); ++mother) {
2197 
2198  bool fromRes = false;
2199  unsigned int motherPdgId = (*mother)->pdg_id();
2200  for( int ires = 0; ires < 6; ++ires ) {
2201  if( motherPdgId == motherPdgIdArray[ires] && resfind[ires] ) fromRes = true;
2202  }
2203  if( fromRes ) {
2204  if(gp->pdg_id() == 13)
2205  simMuFromRes.first = lorentzVector(simTrack->momentum().px(),simTrack->momentum().py(),
2206  simTrack->momentum().pz(),simTrack->momentum().e());
2207  else
2208  simMuFromRes.second = lorentzVector(simTrack->momentum().px(),simTrack->momentum().py(),
2209  simTrack->momentum().pz(),simTrack->momentum().e());
2210  }
2211  }
2212  }
2213  // else LogDebug("MuScleFitUtils") << "WARNING: no matching genParticle found for simTrack" << std::endl;
2214  }
2215  }
2216  }
2217  return simMuFromRes;
2218 }
int ires[2]
reco::Particle::LorentzVector lorentzVector
Definition: GenMuonPair.h:9
static const unsigned int motherPdgIdArray[6]
static std::vector< int > resfind
std::vector< TGraphErrors * > MuScleFitUtils::fitMass ( TH2F *  histo)
static

Definition at line 1901 of file MuScleFitUtils.cc.

References cont, gather_cfg::cout, debug, alignCSCRings::e, i, j, lorentzianPeak(), mergeVDriftHistosByStation::name, python.entryComment::results, and x.

1901  {
1902 
1903  if (MuScleFitUtils::debug>0) std::cout << "Fitting " << histo->GetName() << std::endl;
1904 
1905  std::vector<TGraphErrors *> results;
1906 
1907  // Results of the fit
1908  // ------------------
1909  std::vector<double> Ftop;
1910  std::vector<double> Fwidth;
1911  std::vector<double> Fmass;
1912  std::vector<double> Etop;
1913  std::vector<double> Ewidth;
1914  std::vector<double> Emass;
1915  std::vector<double> Fchi2;
1916  // X bin center and width
1917  // ----------------------
1918  std::vector<double> Xcenter;
1919  std::vector<double> Ex;
1920 
1921  // Fit with lorentzian peak
1922  // ------------------------
1923  TF1 *fitFcn = new TF1 ("fitFcn", lorentzianPeak, 70, 110, 3);
1924  fitFcn->SetParameters (100, 3, 91);
1925  fitFcn->SetParNames ("Ftop", "Fwidth", "Fmass");
1926  fitFcn->SetLineWidth (2);
1927 
1928  // Fit slices projected along Y from bins in X
1929  // -------------------------------------------
1930  double cont_min = 20; // Minimum number of entries
1931  Int_t binx = histo->GetXaxis()->GetNbins();
1932  // TFile *f= new TFile("prova.root", "recreate");
1933  // histo->Write();
1934  for (int i=1; i<=binx; i++) {
1935  TH1 * histoY = histo->ProjectionY ("", i, i);
1936  // histoY->Write();
1937  double cont = histoY->GetEntries();
1938  if (cont>cont_min) {
1939  histoY->Fit ("fitFcn", "0", "", 70, 110);
1940  double *par = fitFcn->GetParameters();
1941  double *err = fitFcn->GetParErrors();
1942 
1943  Ftop.push_back(par[0]);
1944  Fwidth.push_back(par[1]);
1945  Fmass.push_back(par[2]);
1946  Etop.push_back(err[0]);
1947  Ewidth.push_back(err[1]);
1948  Emass.push_back(err[2]);
1949 
1950  double chi2 = fitFcn->GetChisquare();
1951  Fchi2.push_back(chi2);
1952 
1953  double xx = histo->GetXaxis()->GetBinCenter(i);
1954  Xcenter.push_back(xx);
1955  double ex = 0; // FIXME: you can use the bin width
1956  Ex.push_back(ex);
1957  }
1958  }
1959  // f->Close();
1960 
1961  // Put the fit results in arrays for TGraphErrors
1962  // ----------------------------------------------
1963  const int nn = Fmass.size();
1964  double *x = new double[nn];
1965  double *ym = new double[nn];
1966  double *e = new double[nn];
1967  double *eym = new double[nn];
1968  double *yw = new double[nn];
1969  double *eyw = new double[nn];
1970  double *yc = new double[nn];
1971 
1972  for (int j=0; j<nn; j++) {
1973  x[j] = Xcenter[j];
1974  ym[j] = Fmass[j];
1975  eym[j] = Emass[j];
1976  yw[j] = Fwidth[j];
1977  eyw[j] = Ewidth[j];
1978  yc[j] = Fchi2[j];
1979  e[j] = Ex[j];
1980  }
1981 
1982  // Create TGraphErrors
1983  // -------------------
1984  TString name = histo->GetName();
1985  TGraphErrors *grM = new TGraphErrors (nn, x, ym, e, eym);
1986  grM->SetTitle (name+"_M");
1987  grM->SetName (name+"_M");
1988  TGraphErrors *grW = new TGraphErrors (nn, x, yw, e, eyw);
1989  grW->SetTitle (name+"_W");
1990  grW->SetName (name+"_W");
1991  TGraphErrors *grC = new TGraphErrors (nn, x, yc, e, e);
1992  grC->SetTitle (name+"_chi2");
1993  grC->SetName (name+"_chi2");
1994 
1995  // Cleanup
1996  // -------
1997  delete[] x;
1998  delete[] ym;
1999  delete[] eym;
2000  delete[] yw;
2001  delete[] eyw;
2002  delete[] yc;
2003  delete[] e;
2004  delete fitFcn;
2005 
2006  results.push_back(grM);
2007  results.push_back(grW);
2008  results.push_back(grC);
2009  return results;
2010 }
int i
Definition: DBlmapReader.cc:9
static double x[7][10000]
static int debug
int j
Definition: DBlmapReader.cc:9
Double_t lorentzianPeak(Double_t *x, Double_t *par)
int cont
tuple cout
Definition: gather_cfg.py:121
std::vector< TGraphErrors * > MuScleFitUtils::fitReso ( TH2F *  histo)
static

Definition at line 2014 of file MuScleFitUtils.cc.

References cont, gather_cfg::cout, alignCSCRings::e, Gaussian(), i, j, mergeVDriftHistosByStation::name, python.entryComment::results, and x.

2014  {
2015  std::cout << "Fitting " << histo->GetName() << std::endl;
2016  std::vector<TGraphErrors *> results;
2017 
2018  // Results from fit
2019  // ----------------
2020  std::vector<double> maxs;
2021  std::vector<double> means;
2022  std::vector<double> sigmas;
2023  std::vector<double> chi2s;
2024  std::vector<double> Emaxs;
2025  std::vector<double> Emeans;
2026  std::vector<double> Esigmas;
2027 
2028  // X bin center and width
2029  // ----------------------
2030  std::vector<double> Xcenter;
2031  std::vector<double> Ex;
2032 
2033  // Fit with a gaussian
2034  // -------------------
2035  TF1 *fitFcn = new TF1 ("fitFunc", Gaussian, -0.2, 0.2, 3);
2036  fitFcn->SetParameters (100, 0, 0.02);
2037  fitFcn->SetParNames ("max", "mean", "sigma");
2038  fitFcn->SetLineWidth (2);
2039 
2040  // Fit slices projected along Y from bins in X
2041  // -------------------------------------------
2042  double cont_min = 20; // Minimum number of entries
2043  Int_t binx = histo->GetXaxis()->GetNbins();
2044  for (int i=1; i<=binx; i++) {
2045  TH1 * histoY = histo->ProjectionY ("", i, i);
2046  double cont = histoY->GetEntries();
2047  if (cont>cont_min) {
2048  histoY->Fit ("fitFunc", "0", "", -0.2, 0.2);
2049  double *par = fitFcn->GetParameters();
2050  double *err = fitFcn->GetParErrors();
2051 
2052  maxs.push_back (par[0]);
2053  means.push_back (par[1]);
2054  sigmas.push_back (par[2]);
2055  Emaxs.push_back (err[0]);
2056  Emeans.push_back (err[1]);
2057  Esigmas.push_back (err[2]);
2058 
2059  double chi2 = fitFcn->GetChisquare();
2060  chi2s.push_back (chi2);
2061 
2062  double xx = histo->GetXaxis()->GetBinCenter(i);
2063  Xcenter.push_back (xx);
2064  double ex = 0; // FIXME: you can use the bin width
2065  Ex.push_back (ex);
2066  }
2067  }
2068 
2069  // Put the fit results in arrays for TGraphErrors
2070  // ----------------------------------------------
2071  const int nn = means.size();
2072  double *x = new double[nn];
2073  double *ym = new double[nn];
2074  double *e = new double[nn];
2075  double *eym = new double[nn];
2076  double *yw = new double[nn];
2077  double *eyw = new double[nn];
2078  double *yc = new double[nn];
2079 
2080  for (int j=0; j<nn; j++) {
2081  x[j] = Xcenter[j];
2082  ym[j] = means[j];
2083  eym[j] = Emeans[j];
2084  // yw[j] = maxs[j];
2085  // eyw[j] = Emaxs[j];
2086  yw[j] = sigmas[j];
2087  eyw[j] = Esigmas[j];
2088  yc[j] = chi2s[j];
2089  e[j] = Ex[j];
2090  }
2091 
2092  // Create TGraphErrors
2093  // -------------------
2094  TString name = histo->GetName();
2095  TGraphErrors *grM = new TGraphErrors (nn, x, ym, e, eym);
2096  grM->SetTitle (name+"_mean");
2097  grM->SetName (name+"_mean");
2098  TGraphErrors *grW = new TGraphErrors (nn, x, yw, e, eyw);
2099  grW->SetTitle (name+"_sigma");
2100  grW->SetName (name+"_sigma");
2101  TGraphErrors *grC = new TGraphErrors (nn, x, yc, e, e);
2102  grC->SetTitle (name+"_chi2");
2103  grC->SetName (name+"_chi2");
2104 
2105  // Cleanup
2106  // -------
2107  delete[] x;
2108  delete[] ym;
2109  delete[] eym;
2110  delete[] yw;
2111  delete[] eyw;
2112  delete[] yc;
2113  delete[] e;
2114  delete fitFcn;
2115 
2116  results.push_back (grM);
2117  results.push_back (grW);
2118  results.push_back (grC);
2119  return results;
2120 }
int i
Definition: DBlmapReader.cc:9
Double_t Gaussian(Double_t *x, Double_t *par)
static double x[7][10000]
int j
Definition: DBlmapReader.cc:9
int cont
tuple cout
Definition: gather_cfg.py:121
lorentzVector MuScleFitUtils::fromPtEtaPhiToPxPyPz ( const double *  ptEtaPhiE)
static

Definition at line 491 of file MuScleFitUtils.cc.

References funct::cos(), create_public_lumi_plots::exp, muMass, funct::sin(), mathSSE::sqrt(), and tmp.

Referenced by applyBias(), applyScale(), applySmearing(), and TestCorrection::correctMuon().

492 {
493  double px = ptEtaPhiE[0]*cos(ptEtaPhiE[2]);
494  double py = ptEtaPhiE[0]*sin(ptEtaPhiE[2]);
495  double tmp = 2*atan(exp(-ptEtaPhiE[1]));
496  double pz = ptEtaPhiE[0]*cos(tmp)/sin(tmp);
497  double E = sqrt(px*px+py*py+pz*pz+muMass*muMass);
498 
499  // lorentzVector corrMu(px,py,pz,E);
500  // To fix memory leaks, this is to be substituted with
501  // std::auto_ptr<lorentzVector> corrMu(new lorentzVector(px, py, pz, E));
502 
503  return lorentzVector(px,py,pz,E);
504 }
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
reco::Particle::LorentzVector lorentzVector
Definition: GenMuonPair.h:9
static const double muMass
T sqrt(T t)
Definition: SSEVec.h:48
Cos< T >::type cos(const T &t)
Definition: Cos.h:22
std::vector< std::vector< double > > tmp
Definition: MVATrainer.cc:100
double MuScleFitUtils::invDimuonMass ( const lorentzVector mu1,
const lorentzVector mu2 
)
inlinestatic

Definition at line 508 of file MuScleFitUtils.cc.

Referenced by likelihood(), and minimizeLikelihood().

510 {
511  return (mu1+mu2).mass();
512 }
double MuScleFitUtils::massProb ( const double &  mass,
const double &  rapidity,
const int  ires,
const double &  massResol 
)
static

Definition at line 2124 of file MuScleFitUtils.cc.

References gather_cfg::cout, debug, alignCSCRings::e, GL, ires, np, P, Pi, ResGamma, ResMass, w(), and x.

Referenced by MuScleFit::duringFastLoop(), findBestRecoRes(), findBestSimuRes(), likelihood(), and massProb().

2125 {
2126  // This routine computes the likelihood that a given measured mass "measMass" is
2127  // the result of resonance #ires if the resolution expected for the two muons is massResol
2128  // ---------------------------------------------------------------------------------------
2129 
2130  double P = 0.;
2131 
2132  // Return Lorentz value for zero resolution cases (like MC)
2133  // --------------------------------------------------------
2134  if (massResol==0.) {
2135  if (debug>9) std::cout << "Mass, gamma , mref, width, P: " << mass
2136  << " " << ResGamma[ires] << " " << ResMass[ires]<< " " << massResol
2137  << " : used Lorentz P-value" << std::endl;
2138  return (0.5*ResGamma[ires]/TMath::Pi())/((mass-ResMass[ires])*(mass-ResMass[ires])+
2139  .25*ResGamma[ires]*ResGamma[ires]);
2140  }
2141 
2142  // NB defined as below, P is not a "probability" but a likelihood that we observe
2143  // a dimuon mass "mass", given mRef, gamma, and massResol. It is what we need for the
2144  // fit which finds the best resolution parameters, though. A definition which is
2145  // more properly a probability is given below (in massProb2()), where the result
2146  // cannot be used to fit resolution parameters because the fit would always prefer
2147  // to set the res parameters to the minimum possible value (best resolution),
2148  // to have a probability close to one of observing any mass.
2149  // -------------------------------------------------------------------------------
2150  // NNBB the following two lines have been replaced with the six following them,
2151  // which provide an improvement of a factor 9 in speed of execution at a
2152  // negligible price in precision.
2153  // ----------------------------------------------------------------------------
2154  // GL->SetParameters(gamma,mRef,mass,massResol);
2155  // P = GL->Integral(mass-5*massResol, mass+5*massResol);
2156 
2157  Int_t np = 100;
2158  double * x = new double[np];
2159  double * w = new double[np];
2160  GL->SetParameters (ResGamma[ires], ResMass[ires], mass, massResol);
2161  GL->CalcGaussLegendreSamplingPoints (np, x, w, 0.1e-15);
2162  P = GL->IntegralFast (np, x, w, ResMass[ires]-10*ResGamma[ires], ResMass[ires]+10*ResGamma[ires]);
2163  delete[] x;
2164  delete[] w;
2165 
2166  // If we are too far away we set P to epsilon and forget about this event
2167  // ----------------------------------------------------------------------
2168  if (P<1.0e-12) {
2169  P = 1.0e-12;
2170  if (debug>9) std::cout << "Mass, gamma , mref, width, P: " << mass
2171  << " " << ResGamma[ires] << " " << ResMass[ires] << " " << massResol
2172  << ": used epsilon" << std::endl;
2173  return P;
2174  }
2175 
2176  if (debug>9) std::cout << "Mass, gamma , mref, width, P: " << mass
2177  << " " << ResGamma[ires] << " " << ResMass[ires] << " " << massResol
2178  << " " << P << std::endl;
2179  return P;
2180 }
const double Pi
int ires[2]
static double x[7][10000]
static int debug
static double ResMass[6]
TF1 * GL
#define P
int np
Definition: AMPTWrapper.h:33
static double ResGamma[6]
tuple cout
Definition: gather_cfg.py:121
T w() const
double MuScleFitUtils::massProb ( const double &  mass,
const double &  resEta,
const double &  rapidity,
const double &  massResol,
const std::vector< double > &  parval,
const bool  doUseBkgrWindow,
const double &  eta1,
const double &  eta2 
)
static

Definition at line 697 of file MuScleFitUtils.cc.

References massProb(), and AlCaHLTBitMon_ParallelJobs::p.

698 {
699 #ifdef USE_CALLGRIND
700  CALLGRIND_START_INSTRUMENTATION;
701 #endif
702 
703  double * p = new double[(int)(parval.size())];
704  // Replaced by auto_ptr, which handles delete at the end
705  // Removed auto_ptr, check massResolution for an explanation.
706  // std::auto_ptr<double> p(new double[(int)(parval.size())]);
707 
708  std::vector<double>::const_iterator it = parval.begin();
709  int id = 0;
710  for ( ; it!=parval.end(); ++it, ++id) {
711  // (&*p)[id] = *it;
712  p[id] = *it;
713  }
714  // p must be passed by value as below:
715  double massProbability = massProb( mass, resEta, rapidity, massResol, p, doUseBkgrWindow, eta1, eta2 );
716  delete[] p;
717 
718 #ifdef USE_CALLGRIND
719  CALLGRIND_STOP_INSTRUMENTATION;
720  CALLGRIND_DUMP_STATS;
721 #endif
722 
723  return massProbability;
724 }
static double massProb(const double &mass, const double &rapidity, const int ires, const double &massResol)
double MuScleFitUtils::massProb ( const double &  mass,
const double &  resEta,
const double &  rapidity,
const double &  massResol,
double *  parval,
const bool  doUseBkgrWindow,
const double &  eta1,
const double &  eta2 
)
static

Definition at line 862 of file MuScleFitUtils.cc.

References BackgroundHandler::backgroundFunction(), backgroundHandler, backgroundProb_, checkMassWindow(), gather_cfg::cout, crossSectionHandler, debug, doBackgroundFit, GLNorm, GLValue, GLZNorm, GLZValue, i, ires, j, loopCounter, minuitLoop_, MuonType, P, parBgr, CrossSectionHandler::parNum(), parResol, parScale, probability(), rapidityBinsForZ_, CrossSectionHandler::relativeCrossSections(), resfind, ResHalfWidth, BackgroundHandler::resMass(), ResMass, signalProb_, totalResNum, and BackgroundHandler::windowBorders().

862  {
863 
864  // This routine computes the likelihood that a given measured mass "measMass" is
865  // the result of a reference mass ResMass[] if the resolution
866  // expected for the two muons is massResol.
867  // This version includes two parameters (the last two in parval, by default)
868  // to size up the background fraction and its relative normalization with respect
869  // to the signal shape.
870  //
871  // We model the signal probability with a Lorentz L(M,H) of resonance mass M and natural width H
872  // convoluted with a gaussian G(m,s) of measured mass m and expected mass resolution s,
873  // by integrating over the intersection of the supports of L and G (which can be made to coincide with
874  // the region where L is non-zero, given that H<<s in most cases) the product L(M,H)*G(m,s) dx as follows:
875  //
876  // GL(m,s) = Int(M-10H,M+10H) [ L(x-M,H) * G(x-m,s) ] dx
877  //
878  // The above convolution is computed numerically by an independent root macro, Probs.C, which outputs
879  // the values in six 1001x1001 grids, one per resonance.
880  //
881  // NB THe following block of explanations for background models is outdated, see detailed
882  // explanations where the code computes PB.
883  // +++++++++++++++++++++++
884  // For the background, instead, we have two choices: a linear and an exponential model.
885  // * For the linear model, we choose a one-parameter form whereby the line is automatically normalized
886  // in the support [x1,x2] where we defined our "signal region", as follows:
887  //
888  // B(x;b) = 1/(x2-x1) + {x - (x2+x1)/2} * b
889  //
890  // Defined as above, B(x) is a line passing for the point of coordinates (x1+x2)/2, 1/(x2-x1),
891  // whose slope b has as support the interval ( -2/[(x1-x2)*(x1+x2)], 2/[(x1-x2)*(x1+x2)] )
892  // so that B(x) is always positive-definite in [x1,x2].
893  //
894  // * For the exponential model, we define B(x;b) as
895  //
896  // B(x;b) = b * { exp(-b*x) / [exp(-b*x1)-exp(-b*x2)] }
897  //
898  // This one-parameter definition is automatically normalized to unity in [x1,x2], with a parameter
899  // b which has to be positive in order for the slope to be negative.
900  // Please note that this model is not useful in most circumstances; a more useful form would be one
901  // which included a linear component.
902  // ++++++++++++++++++++++
903  //
904  // Once GL(m,s) and B(x;b) are defined, we introduce a further parameter a, such that we can have the
905  // likelihood control the relative fraction of signal and background. We first normalize GL(m,s) for
906  // any given s by taking the integral
907  //
908  // Int(x1,x2) GL(m,s) dm = K_s
909  //
910  // We then define the probability as
911  //
912  // P(m,s,a,b) = GL(m,s)/K_s * a + B(x,b) * (1-a)
913  //
914  // with a taking on values in the interval [0,1].
915  // Defined as above, the probability is well-behaved, in the sense that it has a value between 0 and 1,
916  // and the four parameters m,s,a,b fully control its shape.
917  //
918  // It is to be noted that the formulation above requires the computation of two rather time-consuming
919  // integrals. The one defining GL(m,s) can be stored in a TH2D and loaded by the constructor from a
920  // file suitably prepared, and this will save loads of computing time.
921  // ----------------------------------------------------------------------------------------------------
922 
923  double P = 0.;
924  int crossSectionParShift = parResol.size() + parScale.size();
925  // Take the relative cross sections
926  std::vector<double> relativeCrossSections = crossSectionHandler->relativeCrossSections(&(parval[crossSectionParShift]), resfind);
927  // for( unsigned int i=0; i<relativeCrossSections.size(); ++i ) {
928  // std::cout << "relativeCrossSections["<<i<<"] = " << relativeCrossSections[i] << std::endl;
929  // std::cout << "parval["<<crossSectionParShift+i<<"] = " << parval[crossSectionParShift+i] << std::endl;
930  // }
931 
932  // int bgrParShift = crossSectionParShift + parCrossSection.size();
933  int bgrParShift = crossSectionParShift + crossSectionHandler->parNum();
934  double Bgrp1 = 0.;
935  // double Bgrp2 = 0.;
936  // double Bgrp3 = 0.;
937 
938  // NB defined as below, P is a non-rigorous "probability" that we observe
939  // a dimuon mass "mass", given ResMass[], gamma, and massResol. It is what we need for the
940  // fit which finds the best resolution parameters, though. A definition which is
941  // more properly a probability is given below (in massProb2()), where the result
942  // cannot be used to fit resolution parameters because the fit would always prefer
943  // to set the res parameters to the minimum possible value (best resolution),
944  // to have a probability close to one of observing any mass.
945  // -------------------------------------------------------------------------------
946 
947  // Determine what resonance(s) we have to deal with
948  // NB for now we assume equal xs for each resonance
949  // so we do not assign them different weights
950  // ------------------------------------------------
951  double PS[6] = {0.};
952  double PB = 0.;
953  double PStot[6] = {0.};
954 
955  // Should be removed because it is not used
956  bool resConsidered[6] = {false};
957 
958  bool useBackgroundWindow = (doBackgroundFit[loopCounter] || doUseBkgrWindow);
959  // bool useBackgroundWindow = (doBackgroundFit[loopCounter]);
960 
961  // First check the Z, which is divided in 24 rapidity bins
962  // NB max value of Z rapidity to be considered is 2.4 here
963  // -------------------------------------------------------
964 
965  // Do this only if we want to use the rapidity bins for the Z
967  // ATTENTION: cut on Z rapidity at 2.4 since we only have histograms up to that value
968  // std::pair<double, double> windowFactors = backgroundHandler->windowFactors( useBackgroundWindow, 0 );
969  std::pair<double, double> windowBorders = backgroundHandler->windowBorders( useBackgroundWindow, 0 );
970  if( resfind[0]>0
971  // && checkMassWindow( mass, 0,
972  // backgroundHandler->resMass( useBackgroundWindow, 0 ),
973  // windowFactors.first, windowFactors.second )
974  && checkMassWindow( mass, windowBorders.first, windowBorders.second )
975  // && fabs(rapidity)<2.4
976  ) {
977 
978  int iY = (int)(fabs(rapidity)*10.);
979  if( iY > 23 ) iY = 23;
980 
981  if (MuScleFitUtils::debug>1) std::cout << "massProb:resFound = 0, rapidity bin =" << iY << std::endl;
982 
983  // In this case the last value is the rapidity bin
984  PS[0] = probability(mass, massResol, GLZValue, GLZNorm, 0, iY);
985 
986  if( PS[0] != PS[0] ) {
987  std::cout << "ERROR: PS[0] = nan, setting it to 0" << std::endl;
988  PS[0] = 0;
989  }
990 
991  // std::pair<double, double> bgrResult = backgroundHandler->backgroundFunction( doBackgroundFit[loopCounter],
992  // &(parval[bgrParShift]), MuScleFitUtils::totalResNum, 0,
993  // resConsidered, ResMass, ResHalfWidth, MuonType, mass, resEta );
994 
995  std::pair<double, double> bgrResult = backgroundHandler->backgroundFunction( doBackgroundFit[loopCounter],
996  &(parval[bgrParShift]), MuScleFitUtils::totalResNum, 0,
997  resConsidered, ResMass, ResHalfWidth, MuonType, mass, eta1, eta2 );
998 
999  Bgrp1 = bgrResult.first;
1000  // When fitting the background we have only one Bgrp1
1001  // When not fitting the background we have many only in a superposition region and this case is treated
1002  // separately after this loop
1003  PB = bgrResult.second;
1004  if( PB != PB ) PB = 0;
1005  PStot[0] = (1-Bgrp1)*PS[0] + Bgrp1*PB;
1006 
1007 
1008  // PStot[0] *= crossSectionHandler->crossSection(0);
1009  // PStot[0] *= parval[crossSectionParShift];
1010  PStot[0] *= relativeCrossSections[0];
1011  if ( MuScleFitUtils::debug > 0 ) std::cout << "PStot["<<0<<"] = " << "(1-"<<Bgrp1<<")*"<<PS[0]<<" + "<<Bgrp1<<"*"<<PB<<" = " << PStot[0] << " (reletiveXS = )" << relativeCrossSections[0] << std::endl;
1012  }
1013  else {
1014  if( debug > 0 ) {
1015  std::cout << "Mass = " << mass << " outside range with rapidity = " << rapidity << std::endl;
1016  std::cout << "with resMass = " << backgroundHandler->resMass( useBackgroundWindow, 0 ) << " and left border = " << windowBorders.first << " right border = " << windowBorders.second << std::endl;
1017  }
1018  }
1019  }
1020  // Next check the other resonances
1021  // -------------------------------
1022  int firstRes = 1;
1023  if( !MuScleFitUtils::rapidityBinsForZ_ ) firstRes = 0;
1024  for( int ires=firstRes; ires<6; ++ires ) {
1025  if( resfind[ires] > 0 ) {
1026  // First is left, second is right (returns (1,1) in the case of resonances, it could be improved avoiding the call in this case)
1027  // std::pair<double, double> windowFactor = backgroundHandler->windowFactors( useBackgroundWindow, ires );
1028  std::pair<double, double> windowBorder = backgroundHandler->windowBorders( useBackgroundWindow, ires );
1029  if( checkMassWindow(mass, windowBorder.first, windowBorder.second) ) {
1030  if (MuScleFitUtils::debug>1) std::cout << "massProb:resFound = " << ires << std::endl;
1031 
1032  // In this case the rapidity value is instead the resonance index again.
1033  PS[ires] = probability(mass, massResol, GLValue, GLNorm, ires, ires);
1034 
1035  std::pair<double, double> bgrResult = backgroundHandler->backgroundFunction( doBackgroundFit[loopCounter],
1036  &(parval[bgrParShift]), MuScleFitUtils::totalResNum, ires,
1037  // resConsidered, ResMass, ResHalfWidth, MuonType, mass, resEta );
1038  resConsidered, ResMass, ResHalfWidth, MuonType, mass, eta1, eta2 );
1039  Bgrp1 = bgrResult.first;
1040  PB = bgrResult.second;
1041 
1042  if( PB != PB ) PB = 0;
1043  PStot[ires] = (1-Bgrp1)*PS[ires] + Bgrp1*PB;
1044  if( MuScleFitUtils::debug>0 ) std::cout << "PStot["<<ires<<"] = " << "(1-"<<Bgrp1<<")*"<<PS[ires]<<" + "<<Bgrp1<<"*"<<PB<<" = " << PStot[ires] << std::endl;
1045 
1046  PStot[ires] *= relativeCrossSections[ires];
1047  }
1048  }
1049  }
1050 
1051  for( int i=0; i<6; ++i ) {
1052  P += PStot[i];
1053  }
1054 
1056  double PStotTemp = 0.;
1057  for( int i=0; i<6; ++i ) {
1058  PStotTemp += PS[i]*relativeCrossSections[i];
1059  }
1060  if( PStotTemp != PStotTemp ) {
1061  std::cout << "ERROR: PStotTemp = nan!!!!!!!!!" << std::endl;
1062  int parnumber = (int)(parResol.size()+parScale.size()+crossSectionHandler->parNum()+parBgr.size());
1063  for( int i=0; i<6; ++i ) {
1064  std::cout << "PS[i] = " << PS[i] << std::endl;
1065  if( PS[i] != PS[i] ) {
1066  std::cout << "mass = " << mass << std::endl;
1067  std::cout << "massResol = " << massResol << std::endl;
1068  for( int j=0; j<parnumber; ++j ) {
1069  std::cout << "parval["<<j<<"] = " << parval[j] << std::endl;
1070  }
1071  }
1072  }
1073  }
1074  if( PStotTemp == PStotTemp ) {
1076  }
1077  if (debug>0) std::cout << "mass = " << mass << ", P = " << P << ", PStot = " << PStotTemp << ", PB = " << PB << ", bgrp1 = " << Bgrp1 << std::endl;
1078 
1080  }
1081  return P;
1082 }
static double GLValue[6][1001][1001]
int i
Definition: DBlmapReader.cc:9
static unsigned int loopCounter
static std::vector< int > doBackgroundFit
static std::vector< double > parResol
int ires[2]
static TH1D * backgroundProb_
static BackgroundHandler * backgroundHandler
std::pair< double, double > backgroundFunction(const bool doBackgroundFit, const double *parval, const int resTotNum, const int ires, const bool *resConsidered, const double *ResMass, const double ResHalfWidth[], const int MuonType, const double &mass, const double &eta1, const double &eta2)
static int debug
static double ResMass[6]
#define P
static bool checkMassWindow(const double &mass, const double &leftBorder, const double &rightBorder)
Method to check if the mass value is within the mass window of the i-th resonance.
static const int totalResNum
static int minuitLoop_
static double GLZNorm[40][1001]
static std::vector< double > parBgr
int j
Definition: DBlmapReader.cc:9
static TH1D * signalProb_
static double GLZValue[40][1001][1001]
double resMass(const bool doBackgroundFit, const int ires)
static std::vector< double > parScale
std::vector< double > relativeCrossSections(const double *variables, const std::vector< int > &resfind)
Perform a variable transformation from N-1 to relative cross sections.
static bool rapidityBinsForZ_
static double GLNorm[6][1001]
std::pair< double, double > windowBorders(const bool doBackgroundFit, const int ires)
Returns the appropriate window borders depending on whether the background is being fitted and on the...
static int MuonType
tuple cout
Definition: gather_cfg.py:121
static double probability(const double &mass, const double &massResol, const double GLvalue[][1001][1001], const double GLnorm[][1001], const int iRes, const int iY)
Computes the probability given the mass, mass resolution and the arrays with the probabilities and th...
static std::vector< int > resfind
static double ResHalfWidth[6]
static CrossSectionHandler * crossSectionHandler
static double MuScleFitUtils::massResolution ( const lorentzVector mu1,
const lorentzVector mu2 
)
static
double MuScleFitUtils::massResolution ( const lorentzVector mu1,
const lorentzVector mu2,
const std::vector< double > &  parval 
)
static

Definition at line 516 of file MuScleFitUtils.cc.

References massResolution(), and AlCaHLTBitMon_ParallelJobs::p.

519 {
520  // double * p = new double[(int)(parval.size())];
521  // Replaced by auto_ptr, which handles delete at the end
522  // --------- //
523  // ATTENTION //
524  // --------- //
525  // auto_ptr calls delete, not delete[] and thus it must
526  // not be used with arrays. There are alternatives see
527  // e.g.: http://www.gotw.ca/gotw/042.htm. The best
528  // alternative seems to be to switch to vector though.
529  // std::auto_ptr<double> p(new double[(int)(parval.size())]);
530 
531  double * p = new double[(int)(parval.size())];
532  std::vector<double>::const_iterator it = parval.begin();
533  int id = 0;
534  for ( ; it!=parval.end(); ++it, ++id) {
535  // (&*p)[id] = *it;
536  p[id] = *it;
537  }
538  double massRes = massResolution (mu1, mu2, p);
539  delete[] p;
540  return massRes;
541 }
static double massResolution(const lorentzVector &mu1, const lorentzVector &mu2)
static double MuScleFitUtils::massResolution ( const lorentzVector mu1,
const lorentzVector mu2,
std::auto_ptr< double >  parval 
)
static
double MuScleFitUtils::massResolution ( const lorentzVector mu1,
const lorentzVector mu2,
double *  parval 
)
static

We use the following formula:

M = sqrt ( (E1+E2)^2 - (P1+P2)^2 )

where we express E and P as a function of Pt, phi, and theta:

E = sqrt ( Pt^2*(1+cotg(theta)^2) + M_mu^2 )
Px = Pt*cos(phi), Py = Pt*sin(phi), Pz = Pt*cotg(theta)

from which we find

M = sqrt( 2*M_mu^2 + 2*sqrt(Pt1^2/sin(theta1)^2 + M_mu^2)*sqrt(Pt2^2/sin(theta2)^2 + M_mu^2) - 2*Pt1*Pt2* ( cos(phi1-phi2) + cotg(theta1)*cotg(theta2) ) )

and derive WRT Pt1, Pt2, phi1, phi2, theta1, theta2 to get the resolution.

Definition at line 560 of file MuScleFitUtils.cc.

References funct::cos(), counter_resprob, gather_cfg::cout, resolutionFunctionBase< T >::covPt1Pt2(), debug, debugMassResol_, MuScleFitUtils::massResolComponentsStruct::dmdcotgth1, MuScleFitUtils::massResolComponentsStruct::dmdcotgth2, MuScleFitUtils::massResolComponentsStruct::dmdphi1, MuScleFitUtils::massResolComponentsStruct::dmdphi2, MuScleFitUtils::massResolComponentsStruct::dmdpt1, MuScleFitUtils::massResolComponentsStruct::dmdpt2, create_public_lumi_plots::exp, ires, LogDebug, massResolComponents, mMu2, funct::pow(), resfind, ResHalfWidth, ResMass, ResMaxSigma, resolutionFunction, resolutionFunctionBase< T >::sigmaCotgTh(), resolutionFunctionBase< T >::sigmaPhi(), resolutionFunctionBase< T >::sigmaPt(), funct::sin(), and mathSSE::sqrt().

563 {
564  double mass = (mu1+mu2).mass();
565  double pt1 = mu1.Pt();
566  double phi1 = mu1.Phi();
567  double eta1 = mu1.Eta();
568  double theta1 = 2*atan(exp(-eta1));
569  double pt2 = mu2.Pt();
570  double phi2 = mu2.Phi();
571  double eta2 = mu2.Eta();
572  double theta2 = 2*atan(exp(-eta2));
573 
574  double dmdpt1 = (pt1/std::pow(sin(theta1),2)*sqrt((std::pow(pt2/sin(theta2),2)+mMu2)/(std::pow(pt1/sin(theta1),2)+mMu2))-
575  pt2*(cos(phi1-phi2)+cos(theta1)*cos(theta2)/(sin(theta1)*sin(theta2))))/mass;
576  double dmdpt2 = (pt2/std::pow(sin(theta2),2)*sqrt((std::pow(pt1/sin(theta1),2)+mMu2)/(std::pow(pt2/sin(theta2),2)+mMu2))-
577  pt1*(cos(phi2-phi1)+cos(theta2)*cos(theta1)/(sin(theta2)*sin(theta1))))/mass;
578  double dmdphi1 = pt1*pt2/mass*sin(phi1-phi2);
579  double dmdphi2 = pt2*pt1/mass*sin(phi2-phi1);
580  double dmdcotgth1 = (pt1*pt1*cos(theta1)/sin(theta1)*
581  sqrt((std::pow(pt2/sin(theta2),2)+mMu2)/(std::pow(pt1/sin(theta1),2)+mMu2)) -
582  pt1*pt2*cos(theta2)/sin(theta2))/mass;
583  double dmdcotgth2 = (pt2*pt2*cos(theta2)/sin(theta2)*
584  sqrt((std::pow(pt1/sin(theta1),2)+mMu2)/(std::pow(pt2/sin(theta2),2)+mMu2)) -
585  pt2*pt1*cos(theta1)/sin(theta1))/mass;
586 
587  if( debugMassResol_ ) {
588  massResolComponents.dmdpt1 = dmdpt1;
589  massResolComponents.dmdpt2 = dmdpt2;
590  massResolComponents.dmdphi1 = dmdphi1;
591  massResolComponents.dmdphi2 = dmdphi2;
592  massResolComponents.dmdcotgth1 = dmdcotgth1;
593  massResolComponents.dmdcotgth2 = dmdcotgth2;
594  }
595 
596  // Resolution parameters:
597  // ----------------------
598  double sigma_pt1 = resolutionFunction->sigmaPt( pt1,eta1,parval );
599  double sigma_pt2 = resolutionFunction->sigmaPt( pt2,eta2,parval );
600  double sigma_phi1 = resolutionFunction->sigmaPhi( pt1,eta1,parval );
601  double sigma_phi2 = resolutionFunction->sigmaPhi( pt2,eta2,parval );
602  double sigma_cotgth1 = resolutionFunction->sigmaCotgTh( pt1,eta1,parval );
603  double sigma_cotgth2 = resolutionFunction->sigmaCotgTh( pt2,eta2,parval );
604  double cov_pt1pt2 = resolutionFunction->covPt1Pt2( pt1, eta1, pt2, eta2, parval );
605 
606  // Sigma_Pt is defined as a relative sigmaPt/Pt for this reason we need to
607  // multiply it by pt.
608  double mass_res = sqrt(std::pow(dmdpt1*sigma_pt1*pt1,2)+std::pow(dmdpt2*sigma_pt2*pt2,2)+
609  std::pow(dmdphi1*sigma_phi1,2)+std::pow(dmdphi2*sigma_phi2,2)+
610  std::pow(dmdcotgth1*sigma_cotgth1,2)+std::pow(dmdcotgth2*sigma_cotgth2,2)+
611  2*dmdpt1*dmdpt2*cov_pt1pt2*sigma_pt1*sigma_pt2);
612 
613  if (debug>19) {
614  std::cout << " Pt1=" << pt1 << " phi1=" << phi1 << " cotgth1=" << cos(theta1)/sin(theta1) << " - Pt2=" << pt2
615  << " phi2=" << phi2 << " cotgth2=" << cos(theta2)/sin(theta2) << std::endl;
616  std::cout << " P[0]="
617  << parval[0] << " P[1]=" << parval[1] << "P[2]=" << parval[2] << " P[3]=" << parval[3] << std::endl;
618  std::cout << " Dmdpt1= " << dmdpt1 << " dmdpt2= " << dmdpt2 << " sigma_pt1="
619  << sigma_pt1 << " sigma_pt2=" << sigma_pt2 << std::endl;
620  std::cout << " Dmdphi1= " << dmdphi1 << " dmdphi2= " << dmdphi2 << " sigma_phi1="
621  << sigma_phi1 << " sigma_phi2=" << sigma_phi2 << std::endl;
622  std::cout << " Dmdcotgth1= " << dmdcotgth1 << " dmdcotgth2= " << dmdcotgth2
623  << " sigma_cotgth1="
624  << sigma_cotgth1 << " sigma_cotgth2=" << sigma_cotgth2 << std::endl;
625  std::cout << " Mass resolution (pval) for muons of Pt = " << pt1 << " " << pt2
626  << " : " << mass << " +- " << mass_res << std::endl;
627  }
628 
629  // Debug std::cout
630  // ----------
631  bool didit = false;
632  for (int ires=0; ires<6; ires++) {
633  if (!didit && resfind[ires]>0 && fabs(mass-ResMass[ires])<ResHalfWidth[ires]) {
634  if (mass_res>ResMaxSigma[ires] && counter_resprob<100) {
635  counter_resprob++;
636  LogDebug("MuScleFitUtils") << "RESOLUTION PROBLEM: ires=" << ires << std::endl;
637  didit = true;
638  }
639  }
640  }
641 
642  return mass_res;
643 }
#define LogDebug(id)
static bool debugMassResol_
int ires[2]
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
static int debug
static double ResMass[6]
static struct MuScleFitUtils::massResolComponentsStruct massResolComponents
virtual double sigmaPt(const double &pt, const double &eta, const T &parval)=0
T sqrt(T t)
Definition: SSEVec.h:48
Cos< T >::type cos(const T &t)
Definition: Cos.h:22
virtual double covPt1Pt2(const double &pt1, const double &eta1, const double &pt2, const double &eta2, const T &parval)
Definition: Functions.h:3031
static double ResMaxSigma[6]
virtual double sigmaCotgTh(const double &pt, const double &eta, const T &parval)=0
static const double mMu2
tuple cout
Definition: gather_cfg.py:121
virtual double sigmaPhi(const double &pt, const double &eta, const T &parval)=0
static std::vector< int > resfind
static double ResHalfWidth[6]
static int counter_resprob
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:40
static resolutionFunctionBase< double * > * resolutionFunction
double MuScleFitUtils::massResolution ( const lorentzVector mu1,
const lorentzVector mu2,
const ResolutionFunction resolFunc 
)
static

This method can be used outside MuScleFit. It gets the ResolutionFunction that must have been built with the parameters.
TO-DO: this method duplicates the code in the previous method. It should be changed to avoid the duplication.

Definition at line 649 of file MuScleFitUtils.cc.

References funct::cos(), create_public_lumi_plots::exp, mMu2, funct::pow(), ResolutionFunction::sigmaCotgTh(), ResolutionFunction::sigmaPhi(), ResolutionFunction::sigmaPt(), funct::sin(), and mathSSE::sqrt().

652 {
653  double mass = (mu1+mu2).mass();
654  double pt1 = mu1.Pt();
655  double phi1 = mu1.Phi();
656  double eta1 = mu1.Eta();
657  double theta1 = 2*atan(exp(-eta1));
658  double pt2 = mu2.Pt();
659  double phi2 = mu2.Phi();
660  double eta2 = mu2.Eta();
661  double theta2 = 2*atan(exp(-eta2));
662 
663  double dmdpt1 = (pt1/std::pow(sin(theta1),2)*sqrt((std::pow(pt2/sin(theta2),2)+mMu2)/(std::pow(pt1/sin(theta1),2)+mMu2))-
664  pt2*(cos(phi1-phi2)+cos(theta1)*cos(theta2)/(sin(theta1)*sin(theta2))))/mass;
665  double dmdpt2 = (pt2/std::pow(sin(theta2),2)*sqrt((std::pow(pt1/sin(theta1),2)+mMu2)/(std::pow(pt2/sin(theta2),2)+mMu2))-
666  pt1*(cos(phi2-phi1)+cos(theta2)*cos(theta1)/(sin(theta2)*sin(theta1))))/mass;
667  double dmdphi1 = pt1*pt2/mass*sin(phi1-phi2);
668  double dmdphi2 = pt2*pt1/mass*sin(phi2-phi1);
669  double dmdcotgth1 = (pt1*pt1*cos(theta1)/sin(theta1)*
670  sqrt((std::pow(pt2/sin(theta2),2)+mMu2)/(std::pow(pt1/sin(theta1),2)+mMu2)) -
671  pt1*pt2*cos(theta2)/sin(theta2))/mass;
672  double dmdcotgth2 = (pt2*pt2*cos(theta2)/sin(theta2)*
673  sqrt((std::pow(pt1/sin(theta1),2)+mMu2)/(std::pow(pt2/sin(theta2),2)+mMu2)) -
674  pt2*pt1*cos(theta1)/sin(theta1))/mass;
675 
676  // Resolution parameters:
677  // ----------------------
678  double sigma_pt1 = resolFunc.sigmaPt( mu1 );
679  double sigma_pt2 = resolFunc.sigmaPt( mu2 );
680  double sigma_phi1 = resolFunc.sigmaPhi( mu1 );
681  double sigma_phi2 = resolFunc.sigmaPhi( mu2 );
682  double sigma_cotgth1 = resolFunc.sigmaCotgTh( mu1 );
683  double sigma_cotgth2 = resolFunc.sigmaCotgTh( mu2 );
684 
685  // Sigma_Pt is defined as a relative sigmaPt/Pt for this reason we need to
686  // multiply it by pt.
687  double mass_res = sqrt(std::pow(dmdpt1*sigma_pt1*pt1,2)+std::pow(dmdpt2*sigma_pt2*pt2,2)+
688  std::pow(dmdphi1*sigma_phi1,2)+std::pow(dmdphi2*sigma_phi2,2)+
689  std::pow(dmdcotgth1*sigma_cotgth1,2)+std::pow(dmdcotgth2*sigma_cotgth2,2));
690 
691  return mass_res;
692 }
double sigmaPt(const U &track, const int i=0) const
The second, optional, parameter is the iteration number.
double sigmaCotgTh(const U &track, const int i=0) const
The second, optional, parameter is the iteration number.
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
T sqrt(T t)
Definition: SSEVec.h:48
Cos< T >::type cos(const T &t)
Definition: Cos.h:22
double sigmaPhi(const U &track, const int i=0) const
The second, optional, parameter is the iteration number.
static const double mMu2
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:40
void MuScleFitUtils::minimizeLikelihood ( )
static

Definition at line 1130 of file MuScleFitUtils.cc.

References backgroundHandler, backgroundProb_, BgrFitType, svgfig::canvas(), CastorDataFrameFilter_impl::check(), checkMassWindow(), computeMinosErrors_, gather_cfg::cout, crossSectionHandler, debug, doBackgroundFit, doCrossSectionFit, doResolFit, doScaleFit, duringMinos_, FitStrategy, i, invDimuonMass(), iorder, ires, likelihood(), likelihoodInLoop_, loopCounter, massWindowHalfWidth, minimumShapePlots_, minuitLoop_, MuonType, mergeVDriftHistosByStation::name, normalizationChanged_, parBgr, parBgrFix, parBgrOrder, parCrossSection, parCrossSectionOrder, parfix, scaleFunctionBase< T >::parNum(), CrossSectionHandler::parNum(), resolutionFunctionBase< T >::parNum(), parorder, parResol, parResolFix, parResolMax, parResolMin, parResolOrder, parResolStep, parScale, parScaleFix, parScaleMax, parScaleMin, parScaleOrder, parScaleStep, parvalue, ReducedSavedPair, BackgroundHandler::regionsParNum(), CrossSectionHandler::relativeCrossSections(), CrossSectionHandler::releaseParameters(), BackgroundHandler::rescale(), scaleFunctionBase< T >::resetParameters(), resfind, ResMass, ResolFitType, rminPtr_, SavedPair, scaleFitNotDone_, ScaleFitType, scaleFunction, CrossSectionHandler::setParameters(), scaleFunctionBase< T >::setParameters(), BackgroundHandler::setParameters(), resolutionFunctionBase< T >::setParameters(), signalProb_, startWithSimplex_, cmsPerfCommons::Step, BackgroundHandler::unlockParameter(), and BackgroundHandler::windowBorders().

Referenced by MuScleFit::endOfFastLoop().

1131 {
1132  // Output file with fit parameters resulting from minimization
1133  // -----------------------------------------------------------
1134  ofstream FitParametersFile;
1135  FitParametersFile.open ("FitParameters.txt", std::ios::app);
1136  FitParametersFile << "Fitting with resolution, scale, bgr function # "
1137  << ResolFitType << " " << ScaleFitType << " " << BgrFitType
1138  << " - Iteration " << loopCounter << std::endl;
1139 
1140  // Fill parvalue and other vectors needed for the fitting
1141  // ------------------------------------------------------
1142 
1143 
1144 
1145 
1146 
1147  // ----- //
1148  // FIXME //
1149  // ----- //
1150  // this was changed to verify the possibility that fixed parameters influence the errors.
1151  // It must be 0 otherwise the parameters for resonances will not be passed by minuit (will be always 0).
1152  // Should be removed.
1153  int parForResonanceWindows = 0;
1154  // int parnumber = (int)(parResol.size()+parScale.size()+parCrossSection.size()+parBgr.size() - parForResonanceWindows);
1155  int parnumber = (int)(parResol.size()+parScale.size()+crossSectionHandler->parNum()+parBgr.size() - parForResonanceWindows);
1156 
1157 
1158 
1159 
1160 
1161 
1162  int parnumberAll = (int)(parResol.size()+parScale.size()+crossSectionHandler->parNum()+parBgr.size());
1163 
1164  // parvalue is a std::vector<std::vector<double> > storing all the parameters from all the loops
1165  parvalue.push_back(parResol);
1166  std::vector<double> *tmpVec = &(parvalue.back());
1167 
1168  // If this is not the first loop we want to start from neutral values
1169  // Otherwise the scale will start with values correcting again a bias
1170  // that is already corrected.
1171  if( scaleFitNotDone_ ) {
1172  tmpVec->insert( tmpVec->end(), parScale.begin(), parScale.end() );
1173  std::cout << "scaleFitNotDone: tmpVec->size() = " << tmpVec->size() << std::endl;
1174  }
1175  else {
1176  scaleFunction->resetParameters(tmpVec);
1177  std::cout << "scaleFitDone: tmpVec->size() = " << tmpVec->size() << std::endl;
1178  }
1179  tmpVec->insert( tmpVec->end(), parCrossSection.begin(), parCrossSection.end() );
1180  tmpVec->insert( tmpVec->end(), parBgr.begin(), parBgr.end() );
1181  int i = 0;
1182  std::vector<double>::const_iterator it = tmpVec->begin();
1183  for( ; it != tmpVec->end(); ++it, ++i ) {
1184  std::cout << "tmpVec["<<i<<"] = " << *it << std::endl;
1185  }
1186 
1187  // Empty vector of size = number of cross section fitted parameters. Note that the cross section
1188  // fit works in a different way than the others and it uses ratios of the paramters passed via cfg.
1189  // We use this empty vector for compatibility with the rest of the structure.
1190  std::vector<int> crossSectionParNumSizeVec( MuScleFitUtils::crossSectionHandler->parNum(), 0 );
1191 
1192  std::vector<int> parfix(parResolFix);
1193  parfix.insert( parfix.end(), parScaleFix.begin(), parScaleFix.end() );
1194  parfix.insert( parfix.end(), crossSectionParNumSizeVec.begin(), crossSectionParNumSizeVec.end() );
1195  parfix.insert( parfix.end(), parBgrFix.begin(), parBgrFix.end() );
1196 
1197  std::vector<int> parorder(parResolOrder);
1198  parorder.insert( parorder.end(), parScaleOrder.begin(), parScaleOrder.end() );
1199  parorder.insert( parorder.end(), crossSectionParNumSizeVec.begin(), crossSectionParNumSizeVec.end() );
1200  parorder.insert( parorder.end(), parBgrOrder.begin(), parBgrOrder.end() );
1201 
1202  // This is filled later
1203  std::vector<double> parerr(3*parnumberAll,0.);
1204 
1205  if (debug>19) {
1206  std::cout << "[MuScleFitUtils-minimizeLikelihood]: Parameters before likelihood " << std::endl;
1207  for (unsigned int i=0; i<(unsigned int)parnumberAll; i++) {
1208  std::cout << " Par # " << i << " = " << parvalue[loopCounter][i] << " : free = " << parfix[i] << "; order = "
1209  << parorder[i] << std::endl;
1210  }
1211  }
1212 
1213 // // Background rescaling from regions to resonances
1214 // // -----------------------------------------------
1215 // // If we are in a loop > 0 and we are not fitting the background, but we have fitted it in the previous iteration
1216 // if( loopCounter > 0 && !(doBackgroundFit[loopCounter]) && doBackgroundFit[loopCounter-1] ) {
1217 // // This rescales from regions to resonances
1218 // int localMuonType = MuonType;
1219 // if( MuonType > 2 ) localMuonType = 2;
1220 // backgroundHandler->rescale( parBgr, ResMass, massWindowHalfWidth[localMuonType],
1221 // MuScleFitUtils::SavedPair);
1222 // }
1223 
1224  // Init Minuit
1225  // -----------
1226  TMinuit rmin (parnumber);
1227  rminPtr_ = &rmin;
1228  rmin.SetFCN (likelihood); // Unbinned likelihood
1229  // Standard initialization of minuit parameters:
1230  // sets input to be $stdin, output to be $stdout
1231  // and saving to a file.
1232  rmin.mninit (5, 6, 7);
1233  int ierror = 0;
1234  int istat;
1235  double arglis[4];
1236  arglis[0] = FitStrategy; // Strategy 1 or 2
1237  // 1 standard
1238  // 2 try to improve minimum (slower)
1239  rmin.mnexcm ("SET STR", arglis, 1, ierror);
1240 
1241  arglis[0] = 10001;
1242  // Set the random seed for the generator used in SEEk to a fixed value for reproducibility
1243  rmin.mnexcm("SET RAN", arglis, 1, ierror);
1244 
1245  // Set fit parameters
1246  // ------------------
1247  double * Start = new double[parnumberAll];
1248  double * Step = new double[parnumberAll];
1249  double * Mini = new double[parnumberAll];
1250  double * Maxi = new double[parnumberAll];
1251  int * ind = new int[parnumberAll]; // Order of release of parameters
1252  TString * parname = new TString[parnumberAll];
1253 
1254  if( !parResolStep.empty() && !parResolMin.empty() && !parResolMax.empty() ) {
1256  }
1257  else {
1258  MuScleFitUtils::resolutionFunctionForVec->setParameters( Start, Step, Mini, Maxi, ind, parname, parResol, parResolOrder, MuonType );
1259  }
1260 
1261  // Take the number of parameters in the resolutionFunction and displace the arrays passed to the scaleFunction
1263 
1264  if( !parScaleStep.empty() && !parScaleMin.empty() && !parScaleMax.empty() ) {
1265  MuScleFitUtils::scaleFunctionForVec->setParameters( &(Start[resParNum]), &(Step[resParNum]),
1266  &(Mini[resParNum]), &(Maxi[resParNum]),
1267  &(ind[resParNum]), &(parname[resParNum]),
1270  }
1271  else {
1272  MuScleFitUtils::scaleFunctionForVec->setParameters( &(Start[resParNum]), &(Step[resParNum]),
1273  &(Mini[resParNum]), &(Maxi[resParNum]),
1274  &(ind[resParNum]), &(parname[resParNum]),
1276  }
1277 
1278  // Initialize cross section parameters
1279  int crossSectionParShift = resParNum + MuScleFitUtils::scaleFunctionForVec->parNum();
1280  MuScleFitUtils::crossSectionHandler->setParameters( &(Start[crossSectionParShift]), &(Step[crossSectionParShift]), &(Mini[crossSectionParShift]),
1281  &(Maxi[crossSectionParShift]), &(ind[crossSectionParShift]), &(parname[crossSectionParShift]),
1283 
1284  // Initialize background parameters
1285  int bgrParShift = crossSectionParShift + crossSectionHandler->parNum();
1286  MuScleFitUtils::backgroundHandler->setParameters( &(Start[bgrParShift]), &(Step[bgrParShift]), &(Mini[bgrParShift]), &(Maxi[bgrParShift]),
1287  &(ind[bgrParShift]), &(parname[bgrParShift]), parBgr, parBgrOrder, MuonType );
1288 
1289  for( int ipar=0; ipar<parnumber; ++ipar ) {
1290  std::cout << "parname["<<ipar<<"] = " << parname[ipar] << std::endl;
1291  std::cout << "Start["<<ipar<<"] = " << Start[ipar] << std::endl;
1292  std::cout << "Step["<<ipar<<"] = " << Step[ipar] << std::endl;
1293  std::cout << "Mini["<<ipar<<"] = " << Mini[ipar] << std::endl;
1294  std::cout << "Maxi["<<ipar<<"] = " << Maxi[ipar] << std::endl;
1295 
1296 
1297  rmin.mnparm( ipar, parname[ipar], Start[ipar], Step[ipar], Mini[ipar], Maxi[ipar], ierror );
1298 
1299 
1300  // Testing without limits
1301  // rmin.mnparm( ipar, parname[ipar], Start[ipar], Step[ipar], 0, 0, ierror );
1302 
1303 
1304  }
1305 
1306  // Do minimization
1307  // ---------------
1308  if (debug>19)
1309  std::cout << "[MuScleFitUtils-minimizeLikelihood]: Starting minimization" << std::endl;
1310  double fmin;
1311  double fdem;
1312  double errdef;
1313  int npari;
1314  int nparx;
1315  rmin.mnexcm ("CALL FCN", arglis, 1, ierror);
1316 
1317  // First, fix all parameters
1318  // -------------------------
1319  if (debug>19)
1320  std::cout << "[MuScleFitUtils-minimizeLikelihood]: First fix all parameters ...";
1321  for (int ipar=0; ipar<parnumber; ipar++) {
1322  rmin.FixParameter (ipar);
1323  }
1324 
1325  // Then release them in the specified order and refit
1326  // --------------------------------------------------
1327  if (debug>19) std::cout << " Then release them in order..." << std::endl;
1328 
1329  TString name;
1330  double pval;
1331  double pmin;
1332  double pmax;
1333  double errp;
1334  double errl;
1335  double errh;
1336  int ivar;
1337  double erro;
1338  double cglo;
1339  int n_times = 0;
1340  // n_times = number of loops required to unlock all parameters.
1341 
1342  if (debug>19) std::cout << "Before scale parNum" << std::endl;
1343  int scaleParNum = scaleFunction->parNum();
1344  if (debug>19) std::cout << "After scale parNum" << std::endl;
1345  // edm::LogInfo("minimizeLikelihood") << "number of parameters for scaleFunction = " << scaleParNum << std::endl;
1346  // edm::LogInfo("minimizeLikelihood") << "number of parameters for resolutionFunction = " << resParNum << std::endl;
1347  // edm::LogInfo("minimizeLikelihood") << "number of parameters for cross section = " << crossSectionHandler->parNum() << std::endl;
1348  // edm::LogInfo("minimizeLikelihood") << "number of parameters for backgroundFunction = " << parBgr.size() << std::endl;
1349  std::cout << "number of parameters for scaleFunction = " << scaleParNum << std::endl;
1350  std::cout << "number of parameters for resolutionFunction = " << resParNum << std::endl;
1351  std::cout << "number of parameters for cross section = " << crossSectionHandler->parNum() << std::endl;
1352  std::cout << "number of parameters for backgroundFunction = " << parBgr.size() << std::endl;
1353  // edm::LogInfo("minimizeLikelihood") << "number of parameters for backgroundFunction = " << backgroundFunction->parNum() << std::endl;
1354 
1355  for (int i=0; i<parnumber; i++) {
1356  // NB ind[] has been set as parorder[] previously
1357  if (n_times<ind[i]) {
1358  edm::LogInfo("minimizeLikelihood") << "n_times = " << n_times << ", ind["<<i<<"] = " << ind[i] << ", scaleParNum = " << scaleParNum << ", doScaleFit["<<loopCounter<<"] = " << doScaleFit[loopCounter] << std::endl;
1359  // Set the n_times only if we will do the fit
1360  if ( i<resParNum ) {
1361  if( doResolFit[loopCounter] ) n_times = ind[i];
1362  }
1363  else if( i<resParNum+scaleParNum ) {
1364  if( doScaleFit[loopCounter] ) n_times = ind[i];
1365  }
1366  else if( doBackgroundFit[loopCounter] ) n_times = ind[i];
1367  }
1368  }
1369  for (int iorder=0; iorder<n_times+1; iorder++) { // Repeat fit n_times times
1370  std::cout << "Starting minimization " << iorder << " of " << n_times << std::endl;
1371 
1372  bool somethingtodo = false;
1373 
1374  // Use parameters from cfg to select which fit to do
1375  // -------------------------------------------------
1376  if( doResolFit[loopCounter] ) {
1377  // Release resolution parameters and fit them
1378  // ------------------------------------------
1379  for( unsigned int ipar=0; ipar<parResol.size(); ++ipar ) {
1380  if( parfix[ipar]==0 && ind[ipar]==iorder ) {
1381  rmin.Release( ipar );
1382  somethingtodo = true;
1383  }
1384  }
1385  }
1386  if( doScaleFit[loopCounter] ) {
1387  // Release scale parameters and fit them
1388  // -------------------------------------
1389  for( unsigned int ipar=parResol.size(); ipar<parResol.size()+parScale.size(); ++ipar ) {
1390  if( parfix[ipar]==0 && ind[ipar]==iorder ) { // parfix=0 means parameter is free
1391  rmin.Release( ipar );
1392  somethingtodo = true;
1393  }
1394  }
1395  scaleFitNotDone_ = false;
1396  }
1397  unsigned int crossSectionParShift = parResol.size()+parScale.size();
1398  if( doCrossSectionFit[loopCounter] ) {
1399  // Release cross section parameters and fit them
1400  // ---------------------------------------------
1401  // Note that only cross sections of resonances that are being fitted are released
1402  bool doCrossSection = crossSectionHandler->releaseParameters( rmin, resfind, parfix, ind, iorder, crossSectionParShift );
1403  if( doCrossSection ) somethingtodo = true;
1404  }
1405  if( doBackgroundFit[loopCounter] ) {
1406  // Release background parameters and fit them
1407  // ------------------------------------------
1408  // for( int ipar=parResol.size()+parScale.size(); ipar<parnumber; ++ipar ) {
1409  // Free only the parameters for the regions, as the resonances intervals are never used to fit the background
1410  unsigned int bgrParShift = crossSectionParShift+crossSectionHandler->parNum();
1411  for( unsigned int ipar = bgrParShift; ipar < bgrParShift+backgroundHandler->regionsParNum(); ++ipar ) {
1412  // Release only those parameters for the resonances we are fitting
1413  if( parfix[ipar]==0 && ind[ipar]==iorder && backgroundHandler->unlockParameter(resfind, ipar - bgrParShift) ) {
1414  rmin.Release( ipar );
1415  somethingtodo = true;
1416  }
1417  }
1418  }
1419 
1420  // OK, now do minimization if some parameter has been released
1421  // -----------------------------------------------------------
1422  if( somethingtodo ) {
1423 // #ifdef DEBUG
1424 
1425  std::stringstream fileNum;
1426  fileNum << loopCounter;
1427 
1428  minuitLoop_ = 0;
1429  char name[50];
1430  sprintf(name, "likelihoodInLoop_%d_%d", loopCounter, iorder);
1431  TH1D * tempLikelihoodInLoop = new TH1D(name, "likelihood value in minuit loop", 10000, 0, 10000);
1432  likelihoodInLoop_ = tempLikelihoodInLoop;
1433  char signalProbName[50];
1434  sprintf(signalProbName, "signalProb_%d_%d", loopCounter, iorder);
1435  TH1D * tempSignalProb = new TH1D(signalProbName, "signal probability", 10000, 0, 10000);
1436  signalProb_ = tempSignalProb;
1437  char backgroundProbName[50];
1438  sprintf(backgroundProbName, "backgroundProb_%d_%d", loopCounter, iorder);
1439  TH1D * tempBackgroundProb = new TH1D(backgroundProbName, "background probability", 10000, 0, 10000);
1440  backgroundProb_ = tempBackgroundProb;
1441 // #endif
1442 
1443 
1444 
1445  // Before we start the minimization we create a list of events with only the events inside a smaller
1446  // window than the one in which the probability is != 0. We will compute the probability for all those
1447  // events and hopefully the margin will avoid them to get a probability = 0 (which causes a discontinuity
1448  // in the likelihood function). The width of this smaller window must be optimized, but we can start using
1449  // an 90% of the normalization window.
1450  double protectionFactor = 0.9;
1451 
1453  for( unsigned int nev=0; nev<MuScleFitUtils::SavedPair.size(); ++nev ) {
1454  const lorentzVector * recMu1 = &(MuScleFitUtils::SavedPair[nev].first);
1455  const lorentzVector * recMu2 = &(MuScleFitUtils::SavedPair[nev].second);
1456  double mass = MuScleFitUtils::invDimuonMass( *recMu1, *recMu2 );
1457  // Test all resonances to see if the mass is inside at least one of the windows
1458  bool check = false;
1459  for( int ires = 0; ires < 6; ++ires ) {
1460  // std::pair<double, double> windowFactor = backgroundHandler->windowFactors( doBackgroundFit[loopCounter], ires );
1461  std::pair<double, double> windowBorder = backgroundHandler->windowBorders( doBackgroundFit[loopCounter], ires );
1462  // if( resfind[ires] && checkMassWindow( mass, ires, backgroundHandler->resMass( doBackgroundFit[loopCounter], ires ),
1463  // 0.9*windowFactor.first, 0.9*windowFactor.second ) ) {
1464  // double resMassValue = backgroundHandler->resMass( doBackgroundFit[loopCounter], ires );
1465  // double windowBorderLeft = resMassValue - protectionFactor*(resMassValue - windowBorder.first);
1466  // double windowBorderRight = resMassValue + protectionFactor*(windowBorder.second - resMassValue);
1467  double windowBorderShift = (windowBorder.second - windowBorder.first)*(1-protectionFactor)/2.;
1468  double windowBorderLeft = windowBorder.first + windowBorderShift;
1469  double windowBorderRight = windowBorder.second - windowBorderShift;
1470  if( resfind[ires] && checkMassWindow( mass, windowBorderLeft, windowBorderRight ) ) {
1471  check = true;
1472  }
1473  }
1474  if( check ) {
1475  MuScleFitUtils::ReducedSavedPair.push_back(std::make_pair(*recMu1, *recMu2));
1476  }
1477  }
1478  std::cout << "Fitting with " << MuScleFitUtils::ReducedSavedPair.size() << " events" << std::endl;
1479 
1480 
1481  // rmin.SetMaxIterations(500*parnumber);
1482 
1483  //Print some informations
1484  std::cout<<"MINUIT is starting the minimization for the iteration number "<<loopCounter<<std::endl;
1485 
1486  //Try to set iterations
1487  // rmin.SetMaxIterations(100000);
1488 
1489  std::cout<<"maxNumberOfIterations (just set) = "<<rmin.GetMaxIterations()<<std::endl;
1490 
1492 
1493  // Maximum number of iterations
1494  arglis[0] = 100000;
1495  // tolerance
1496  arglis[1] = 0.1;
1497 
1498  // Run simplex first to get an initial estimate of the minimum
1499  if( startWithSimplex_ ) {
1500  rmin.mnexcm( "SIMPLEX", arglis, 0, ierror );
1501  }
1502 
1503  rmin.mnexcm( "MIGRAD", arglis, 2, ierror );
1504 
1505 
1506 
1507 
1508 // #ifdef DEBUG
1509  likelihoodInLoop_->Write();
1510  signalProb_->Write();
1511  backgroundProb_->Write();
1512  delete tempLikelihoodInLoop;
1513  delete tempSignalProb;
1514  delete tempBackgroundProb;
1515  likelihoodInLoop_ = 0;
1516  signalProb_ = 0;
1517  backgroundProb_ = 0;
1518 // #endif
1519 
1520 
1521  // Compute again the error matrix
1522  rmin.mnexcm( "HESSE", arglis, 0, ierror );
1523 
1524  // Peform minos error analysis.
1525  if( computeMinosErrors_ ) {
1526  duringMinos_ = true;
1527  rmin.mnexcm( "MINOS", arglis, 0, ierror );
1528  duringMinos_ = false;
1529  }
1530 
1531  if( normalizationChanged_ > 1 ) {
1532  std::cout << "WARNING: normalization changed during fit meaning that events exited from the mass window. This causes a discontinuity in the likelihood function. Please check the scan of the likelihood as a function of the parameters to see if there are discontinuities around the minimum." << std::endl;
1533  }
1534  }
1535 
1536  // bool notWritten = true;
1537  for (int ipar=0; ipar<parnumber; ipar++) {
1538 
1539  rmin.mnpout (ipar, name, pval, erro, pmin, pmax, ivar);
1540  // Save parameters in parvalue[] vector
1541  // ------------------------------------
1542  if (ierror!=0 && debug>0) {
1543  std::cout << "[MuScleFitUtils-minimizeLikelihood]: ierror!=0, bogus pars" << std::endl;
1544  }
1545  // for (int ipar=0; ipar<parnumber; ipar++) {
1546  // rmin.mnpout (ipar, name, pval, erro, pmin, pmax, ivar);
1547  parvalue[loopCounter][ipar] = pval;
1548  // }
1549 
1550 
1551  // int ilax2 = 0;
1552  // Double_t val2pl, val2mi;
1553  // rmin.mnmnot (ipar+1, ilax2, val2pl, val2mi);
1554  rmin.mnerrs (ipar, errh, errl, errp, cglo);
1555 
1556 
1557  // Set error on params
1558  // -------------------
1559  if (errp!=0) {
1560  parerr[3*ipar] = errp;
1561  } else {
1562  parerr[3*ipar] = (((errh)>(fabs(errl)))?(errh):(fabs(errl)));
1563  }
1564  parerr[3*ipar+1] = errl;
1565  parerr[3*ipar+2] = errh;
1566 
1567  if( ipar == 0 ) {
1568  FitParametersFile << " Resolution fit parameters:" << std::endl;
1569  }
1570  if( ipar == int(parResol.size()) ) {
1571  FitParametersFile << " Scale fit parameters:" << std::endl;
1572  }
1573  if( ipar == int(parResol.size()+parScale.size()) ) {
1574  FitParametersFile << " Cross section fit parameters:" << std::endl;
1575  }
1576  if( ipar == int(parResol.size()+parScale.size()+crossSectionHandler->parNum()) ) {
1577  FitParametersFile << " Background fit parameters:" << std::endl;
1578  }
1579 // if( ipar >= int(parResol.size()+parScale.size()) && ipar < int(parResol.size()+parScale.size()+crossSectionHandler->parNum()) && notWritted ) {
1580 
1581 // std::vector<double> relativeCrossSections = crossSectionHandler->relativeCrossSections(&(parvalue[loopCounter][parResol.size()+parScale.size()]));
1582 // std::vector<double>::const_iterator it = relativeCrossSections.begin();
1583 // for( ; it != relativeCrossSections.end(); ++it ) {
1584 // FitParametersFile << " Results of the fit: parameter " << ipar << " has value "
1585 // << *it << "+-" << 0
1586 // << " + " << 0 << " - " << 0
1587 // << " /t/t (" << 0 << ")" << std::endl;
1588 // }
1589 
1590 // notWritten = false;
1591 // }
1592 // else {
1593  FitParametersFile << " Results of the fit: parameter " << ipar << " has value "
1594  << pval << "+-" << parerr[3*ipar]
1595  << " + " << parerr[3*ipar+1] << " - " << parerr[3*ipar+2]
1596  // << " \t\t (" << parname[ipar] << ")"
1597  << std::endl;
1598 
1599 
1600 
1601  }
1602  rmin.mnstat (fmin, fdem, errdef, npari, nparx, istat); // NNBB Commented for a check!
1603  FitParametersFile << std::endl;
1604 
1605  if( minimumShapePlots_ ) {
1606  // Create plots of the minimum vs parameters
1607  // -----------------------------------------
1608  // Keep this after the parameters filling because it recomputes the values and it can compromise the fit results.
1609  if( somethingtodo ) {
1610  std::stringstream iorderString;
1611  iorderString << iorder;
1612  std::stringstream iLoopString;
1613  iLoopString << loopCounter;
1614 
1615  for (int ipar=0; ipar<parnumber; ipar++) {
1616  if( parfix[ipar] == 1 ) continue;
1617  std::cout << "plotting parameter = " << ipar+1 << std::endl;
1618  std::stringstream iparString;
1619  iparString << ipar+1;
1620  std::stringstream iparStringName;
1621  iparStringName << ipar;
1622  rmin.mncomd( ("scan "+iparString.str()).c_str(), ierror );
1623  if( ierror == 0 ) {
1624  TCanvas * canvas = new TCanvas(("likelihoodCanvas_loop_"+iLoopString.str()+"_oder_"+iorderString.str()+"_par_"+iparStringName.str()).c_str(), ("likelihood_"+iparStringName.str()).c_str(), 1000, 800);
1625  canvas->cd();
1626  // arglis[0] = ipar;
1627  // rmin.mnexcm( "SCA", arglis, 0, ierror );
1628  TGraph * graph = (TGraph*)rmin.GetPlot();
1629  graph->Draw("AP");
1630  // graph->SetTitle(("parvalue["+iparStringName.str()+"]").c_str());
1631  graph->SetTitle(parname[ipar]);
1632  // graph->Write();
1633 
1634  canvas->Write();
1635  }
1636  }
1637 
1638  // // Draw contours of the fit
1639  // TCanvas * canvas = new TCanvas(("contourCanvas_oder_"+iorderString.str()).c_str(), "contour", 1000, 800);
1640  // canvas->cd();
1641  // TGraph * contourGraph = (TGraph*)rmin.Contour(4, 2, 4);
1642  // if( (rmin.GetStatus() == 0) || (rmin.GetStatus() >= 3) ) {
1643  // contourGraph->Draw("AP");
1644  // }
1645  // else {
1646  // std::cout << "Contour graph error: status = " << rmin.GetStatus() << std::endl;
1647  // }
1648  // canvas->Write();
1649  }
1650  }
1651 
1652  } // end loop on iorder
1653  FitParametersFile.close();
1654 
1655  std::cout << "[MuScleFitUtils-minimizeLikelihood]: Parameters after likelihood " << std::endl;
1656  for (unsigned int ipar=0; ipar<(unsigned int)parnumber; ipar++) {
1657  std::cout << ipar << " " << parvalue[loopCounter][ipar] << " : free = "
1658  << parfix[ipar] << "; order = " << parorder[ipar] << std::endl;
1659  }
1660 
1661  // Put back parvalue into parResol, parScale, parCrossSection, parBgr
1662  // ------------------------------------------------------------------
1663  for( int i=0; i<(int)(parResol.size()); ++i ) {
1665  }
1666  for( int i=0; i<(int)(parScale.size()); ++i ) {
1667  parScale[i] = parvalue[loopCounter][i+parResol.size()];
1668  }
1670  for( unsigned int i=0; i<parCrossSection.size(); ++i ) {
1671  // parCrossSection[i] = parvalue[loopCounter][i+parResol.size()+parScale.size()];
1672  std::cout << "relative cross section["<<i<<"] = " << parCrossSection[i] << std::endl;
1673  }
1674  // Save only the fitted background parameters
1675  for( unsigned int i = 0; i<(parBgr.size() - parForResonanceWindows); ++i ) {
1677  }
1678 
1679  // Background rescaling from regions to resonances
1680  // -----------------------------------------------
1681  // Only if we fitted the background
1682  if( doBackgroundFit[loopCounter] ) {
1683  // This rescales from regions to resonances
1684  int localMuonType = MuonType;
1685  if( MuonType > 2 ) localMuonType = 2;
1688  }
1689 
1690  // Delete the arrays used to set some parameters
1691  delete[] Start;
1692  delete[] Step;
1693  delete[] Mini;
1694  delete[] Maxi;
1695  delete[] ind;
1696  delete[] parname;
1697 }
static std::vector< int > doScaleFit
static std::vector< int > doResolFit
int i
Definition: DBlmapReader.cc:9
static std::vector< int > parCrossSectionOrder
static std::vector< int > parScaleOrder
static std::vector< int > doCrossSectionFit
int regionsParNum()
Returns the total number of parameters used for the regions.
static std::vector< int > parBgrOrder
static std::vector< int > parfix
static unsigned int loopCounter
static std::vector< double > parResolMax
void likelihood(int &npar, double *grad, double &fval, double *xval, int flag)
static bool startWithSimplex_
static std::vector< int > doBackgroundFit
static std::vector< double > parResol
void setParameters(double *Start, double *Step, double *Mini, double *Maxi, int *ind, TString *parname, const std::vector< double > &parCrossSection, const std::vector< int > &parCrossSectionOrder, const std::vector< int > &resfind)
Initializes the arrays needed by Minuit.
int ires[2]
static TH1D * backgroundProb_
static BackgroundHandler * backgroundHandler
static int debug
static double ResMass[6]
static double massWindowHalfWidth[3][6]
static bool scaleFitNotDone_
static unsigned int normalizationChanged_
static bool checkMassWindow(const double &mass, const double &leftBorder, const double &rightBorder)
Method to check if the mass value is within the mass window of the i-th resonance.
static std::vector< int > parBgrFix
static std::vector< double > parResolMin
static bool minimumShapePlots_
static std::vector< int > parScaleFix
static bool computeMinosErrors_
reco::Particle::LorentzVector lorentzVector
Definition: GenMuonPair.h:9
static scaleFunctionBase< std::vector< double > > * scaleFunctionForVec
def canvas
Definition: svgfig.py:481
static std::vector< std::vector< double > > parvalue
static int ScaleFitType
static std::vector< std::pair< lorentzVector, lorentzVector > > ReducedSavedPair
static int minuitLoop_
virtual int parNum() const
Definition: Functions.h:3050
static std::vector< double > parScaleMin
void rescale(std::vector< double > &parBgr, const double *ResMass, const double *massWindowHalfWidth, const std::vector< std::pair< reco::Particle::LorentzVector, reco::Particle::LorentzVector > > &muonPairs, const double &weight=1.)
static std::vector< double > parBgr
bool check(const DataFrame &df, bool capcheck, bool dvercheck)
virtual void setParameters(double *Start, double *Step, double *Mini, double *Maxi, int *ind, TString *parname, const T &parScale, const std::vector< int > &parScaleOrder, const int muonType)=0
This method is used to differentiate parameters among the different functions.
bool releaseParameters(TMinuit &rmin, const std::vector< int > &resfind, const std::vector< int > &parfix, const int *ind, const int iorder, const unsigned int shift)
Use the information in resfind, parorder and parfix to release the N-1 variables. ...
static std::vector< double > parScaleStep
static std::vector< std::pair< lorentzVector, lorentzVector > > SavedPair
static double invDimuonMass(const lorentzVector &mu1, const lorentzVector &mu2)
static TH1D * signalProb_
static std::vector< int > parResolFix
static TMinuit * rminPtr_
static std::vector< int > parResolOrder
static int BgrFitType
static TH1D * likelihoodInLoop_
static std::vector< double > parScaleMax
Definition: adjgraph.h:12
static std::vector< double > parScale
std::vector< double > relativeCrossSections(const double *variables, const std::vector< int > &resfind)
Perform a variable transformation from N-1 to relative cross sections.
void setParameters(double *Start, double *Step, double *Mini, double *Maxi, int *ind, TString *parname, const std::vector< double > &parBgr, const std::vector< int > &parBgrOrder, const int muonType)
Sets initial parameters for all the functions.
static bool duringMinos_
int iorder
static int ResolFitType
static std::vector< double > parCrossSection
std::pair< double, double > windowBorders(const bool doBackgroundFit, const int ires)
Returns the appropriate window borders depending on whether the background is being fitted and on the...
bool unlockParameter(const std::vector< int > &resfind, const unsigned int ipar)
returns true if the parameter is to be unlocked
virtual void setParameters(double *Start, double *Step, double *Mini, double *Maxi, int *ind, TString *parname, const T &parResol, const std::vector< int > &parResolOrder, const int muonType)
This method is used to differentiate parameters among the different functions.
Definition: Functions.h:3038
static int MuonType
tuple cout
Definition: gather_cfg.py:121
static scaleFunctionBase< double * > * scaleFunction
static std::vector< int > resfind
virtual void resetParameters(std::vector< double > *scaleVec) const
This method is used to reset the scale parameters to neutral values (useful for iterations &gt; 0) ...
Definition: Functions.h:49
static resolutionFunctionBase< std::vector< double > > * resolutionFunctionForVec
static std::vector< int > parorder
virtual int parNum() const
Definition: Functions.h:66
static int FitStrategy
static CrossSectionHandler * crossSectionHandler
static std::vector< double > parResolStep
double MuScleFitUtils::probability ( const double &  mass,
const double &  massResol,
const double  GLvalue[][1001][1001],
const double  GLnorm[][1001],
const int  iRes,
const int  iY 
)
static

Computes the probability given the mass, mass resolution and the arrays with the probabilities and the normalizations.

After the introduction of the rapidity bins for the Z the probability method works in the following way:

  • if passing iRes == 0, iY is used to select the rapidity bin
  • if passing iRes != 0, iY is used to select the resonance

Definition at line 731 of file MuScleFitUtils.cc.

References counter_resprob, gather_cfg::cout, debug, LogDebug, nbins, ResHalfWidth, ResMass, ResMaxSigma, and ResMinMass.

Referenced by massProb(), and MuScleFitBase::ProbForIntegral::operator()().

734 {
735  if( iRes == 0 && iY > 23 ) {
736  std::cout << "WARNING: rapidity bin selected = " << iY << " but there are only histograms for the first 24 bins" << std::endl;
737  }
738 
739  double PS = 0.;
740  bool insideProbMassWindow = true;
741  // Interpolate the four values of GLZValue[] in the
742  // grid square within which the (mass,sigma) values lay
743  // ----------------------------------------------------
744  // This must be done with respect to the width used in the computation of the probability distribution,
745  // so that the bin 0 really matches the bin 0 of that distribution.
746  // double fracMass = (mass-(ResMass[iRes]-ResHalfWidth[iRes]))/(2*ResHalfWidth[iRes]);
747  double fracMass = (mass - ResMinMass[iRes])/(2*ResHalfWidth[iRes]);
748  if (debug>1) std::cout << std::setprecision(9)<<"mass ResMinMass[iRes] ResHalfWidth[iRes] ResHalfWidth[iRes]"
749  << mass << " "<<ResMinMass[iRes]<<" "<<ResHalfWidth[iRes]<<" "<<ResHalfWidth[iRes]<<std::endl;
750  int iMassLeft = (int)(fracMass*(double)nbins);
751  int iMassRight = iMassLeft+1;
752  double fracMassStep = (double)nbins*(fracMass - (double)iMassLeft/(double)nbins);
753  if (debug>1) std::cout<<"nbins iMassLeft fracMass "<<nbins<<" "<<iMassLeft<<" "<<fracMass<<std::endl;
754 
755  // Simple protections for the time being: the region where we fit should not include
756  // values outside the boundaries set by ResMass-ResHalfWidth : ResMass+ResHalfWidth
757  // ---------------------------------------------------------------------------------
758  if (iMassLeft<0) {
759  edm::LogInfo("probability") << "WARNING: fracMass=" << fracMass << ", iMassLeft="
760  << iMassLeft << "; mass = " << mass << " and bounds are " << ResMinMass[iRes]
761  << ":" << ResMinMass[iRes]+2*ResHalfWidth[iRes] << " - iMassLeft set to 0" << std::endl;
762  iMassLeft = 0;
763  iMassRight = 1;
764  insideProbMassWindow = false;
765  }
766  if (iMassRight>nbins) {
767  edm::LogInfo("probability") << "WARNING: fracMass=" << fracMass << ", iMassRight="
768  << iMassRight << "; mass = " << mass << " and bounds are " << ResMinMass[iRes]
769  << ":" << ResMass[iRes]+2*ResHalfWidth[iRes] << " - iMassRight set to " << nbins-1 << std::endl;
770  iMassLeft = nbins-1;
771  iMassRight = nbins;
772  insideProbMassWindow = false;
773  }
774  double fracSigma = (massResol/ResMaxSigma[iRes]);
775  int iSigmaLeft = (int)(fracSigma*(double)nbins);
776  int iSigmaRight = iSigmaLeft+1;
777  double fracSigmaStep = (double)nbins * (fracSigma - (double)iSigmaLeft/(double)nbins);
778  // std::cout << "massResol = " << massResol << std::endl;
779  // std::cout << "ResMaxSigma["<<iRes<<"] = " << ResMaxSigma[iRes] << std::endl;
780  // std::cout << "fracSigma = " << fracSigma << std::endl;
781  // std::cout << "nbins = " << nbins << std::endl;
782  // std::cout << "ISIGMALEFT = " << iSigmaLeft << std::endl;
783  // std::cout << "ISIGMARIGHT = " << iSigmaRight << std::endl;
784  // std::cout << "fracSigmaStep = " << fracSigmaStep << std::endl;
785 
786  // Simple protections for the time being: they should not affect convergence, since
787  // ResMaxSigma is set to very large values, and if massResol exceeds them the fit
788  // should not get any prize for that (for large sigma, the prob. distr. becomes flat)
789  // ----------------------------------------------------------------------------------
790  if (iSigmaLeft<0) {
791  edm::LogInfo("probability") << "WARNING: fracSigma = " << fracSigma << ", iSigmaLeft="
792  << iSigmaLeft << ", with massResol = " << massResol << " and ResMaxSigma[iRes] = "
793  << ResMaxSigma[iRes] << " - iSigmaLeft set to 0" << std::endl;
794  iSigmaLeft = 0;
795  iSigmaRight = 1;
796  }
797  if (iSigmaRight>nbins ) {
798  if (counter_resprob<100)
799  edm::LogInfo("probability") << "WARNING: fracSigma = " << fracSigma << ", iSigmaRight="
800  << iSigmaRight << ", with massResol = " << massResol << " and ResMaxSigma[iRes] = "
801  << ResMaxSigma[iRes] << " - iSigmaRight set to " << nbins-1 << std::endl;
802  iSigmaLeft = nbins-1;
803  iSigmaRight = nbins;
804  }
805 
806  // If f11,f12,f21,f22 are the values at the four corners, one finds by linear interpolation the
807  // formula below for PS
808  // --------------------------------------------------------------------------------------------
809  if( insideProbMassWindow ) {
810  double f11 = 0.;
811  if (GLnorm[iY][iSigmaLeft]>0)
812  f11 = GLvalue[iY][iMassLeft][iSigmaLeft] / GLnorm[iY][iSigmaLeft];
813  double f12 = 0.;
814  if (GLnorm[iY][iSigmaRight]>0)
815  f12 = GLvalue[iY][iMassLeft][iSigmaRight] / GLnorm[iY][iSigmaRight];
816  double f21 = 0.;
817  if (GLnorm[iY][iSigmaLeft]>0)
818  f21 = GLvalue[iY][iMassRight][iSigmaLeft] / GLnorm[iY][iSigmaLeft];
819  double f22 = 0.;
820  if (GLnorm[iY][iSigmaRight]>0)
821  f22 = GLvalue[iY][iMassRight][iSigmaRight] / GLnorm[iY][iSigmaRight];
822  PS = f11 + (f12-f11)*fracSigmaStep + (f21-f11)*fracMassStep +
823  (f22-f21-f12+f11)*fracMassStep*fracSigmaStep;
824  if (PS>0.1 || debug>1) LogDebug("MuScleFitUtils") << "iRes = " << iRes << " PS=" << PS << " f11,f12,f21,f22="
825  << f11 << " " << f12 << " " << f21 << " " << f22 << " "
826  << " fSS=" << fracSigmaStep << " fMS=" << fracMassStep << " iSL, iSR="
827  << iSigmaLeft << " " << iSigmaRight
828  << " GLvalue["<<iY<<"]["<<iMassLeft<<"] = " << GLvalue[iY][iMassLeft][iSigmaLeft]
829  << " GLnorm["<<iY<<"]["<<iSigmaLeft<<"] = " << GLnorm[iY][iSigmaLeft] << std::endl;
830 
831 // if (PS>0.1) std::cout << "iRes = " << iRes << " PS=" << PS << " f11,f12,f21,f22="
832 // << f11 << " " << f12 << " " << f21 << " " << f22 << " "
833 // << " fSS=" << fracSigmaStep << " fMS=" << fracMassStep << " iSL, iSR="
834 // << iSigmaLeft << " " << iSigmaRight << " GLV,GLN="
835 // << GLvalue[iY][iMassLeft][iSigmaLeft]
836 // << " " << GLnorm[iY][iSigmaLeft] << std::endl;
837 
838  }
839  else {
840  edm::LogInfo("probability") << "outside mass probability window. Setting PS["<<iRes<<"] = 0" << std::endl;
841  }
842 
843 // if( PS != PS ) {
844 // std::cout << "ERROR: PS = " << PS << " for iRes = " << iRes << std::endl;
845 
846 // std::cout << "mass = " << mass << ", massResol = " << massResol << std::endl;
847 // std::cout << "fracMass = " << fracMass << ", iMassLeft = " << iMassLeft
848 // << ", iMassRight = " << iMassRight << ", fracMassStep = " << fracMassStep << std::endl;
849 // std::cout << "fracSigma = " << fracSigma << ", iSigmaLeft = " << iSigmaLeft
850 // << ", iSigmaRight = " << iSigmaRight << ", fracSigmaStep = " << fracSigmaStep << std::endl;
851 // std::cout << "ResMaxSigma["<<iRes<<"] = " << ResMaxSigma[iRes] << std::endl;
852 
853 // std::cout << "GLvalue["<<iY<<"]["<<iMassLeft<<"] = " << GLvalue[iY][iMassLeft][iSigmaLeft]
854 // << " GLnorm["<<iY<<"]["<<iSigmaLeft<<"] = " << GLnorm[iY][iSigmaLeft] << std::endl;
855 // }
856 
857  return PS;
858 }
#define LogDebug(id)
static int nbins
static double ResMinMass[6]
static int debug
static double ResMass[6]
static double ResMaxSigma[6]
tuple cout
Definition: gather_cfg.py:121
static double ResHalfWidth[6]
static int counter_resprob

Member Data Documentation

const int MuScleFitUtils::backgroundFunctionsRegions
static

Definition at line 146 of file MuScleFitUtils.h.

BackgroundHandler * MuScleFitUtils::backgroundHandler
static
TH1D * MuScleFitUtils::backgroundProb_ = 0
static

Definition at line 169 of file MuScleFitUtils.h.

Referenced by massProb(), and minimizeLikelihood().

int MuScleFitUtils::BgrFitType = 0
static

Definition at line 141 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood().

scaleFunctionBase< std::vector< double > > * MuScleFitUtils::biasFunction = 0
static

Definition at line 134 of file MuScleFitUtils.h.

Referenced by applyBias(), and MuScleFit::MuScleFit().

int MuScleFitUtils::BiasType = 0
static
bool MuScleFitUtils::computeMinosErrors_
static

Definition at line 263 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood(), and MuScleFit::MuScleFit().

int MuScleFitUtils::counter_resprob = 0
static

Definition at line 198 of file MuScleFitUtils.h.

Referenced by massResolution(), probability(), and MuScleFit::startingNewLoop().

double MuScleFitUtils::crossSection[6]
static

Definition at line 121 of file MuScleFitUtils.h.

CrossSectionHandler * MuScleFitUtils::crossSectionHandler
static
int MuScleFitUtils::debug = 0
static
bool MuScleFitUtils::debugMassResol_
static
double MuScleFitUtils::deltaPhiMaxCut_ = 100.
static

Definition at line 248 of file MuScleFitUtils.h.

Referenced by MuScleFit::MuScleFit(), and MuScleFit::selectMuons().

double MuScleFitUtils::deltaPhiMinCut_ = -100.
static

Definition at line 247 of file MuScleFitUtils.h.

Referenced by MuScleFit::MuScleFit(), and MuScleFit::selectMuons().

std::vector< int > MuScleFitUtils::doBackgroundFit
static
std::vector< int > MuScleFitUtils::doCrossSectionFit
static
std::vector< int > MuScleFitUtils::doResolFit
static
std::vector< int > MuScleFitUtils::doScaleFit
static
bool MuScleFitUtils::duringMinos_ = false
static

Definition at line 171 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood().

int MuScleFitUtils::FitStrategy = 1
static

Definition at line 194 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood(), and MuScleFit::MuScleFit().

std::vector< std::pair< lorentzVector, lorentzVector > > MuScleFitUtils::genPair
static

Definition at line 217 of file MuScleFitUtils.h.

Referenced by MuScleFit::duringFastLoop(), and MuScleFit::selectMuons().

double MuScleFitUtils::GLNorm
static
double MuScleFitUtils::GLValue
static
double MuScleFitUtils::GLZNorm
static
double MuScleFitUtils::GLZValue
static
int MuScleFitUtils::goodmuon = 0
static
int MuScleFitUtils::iev_ = 0
static
TH1D * MuScleFitUtils::likelihoodInLoop_ = 0
static

Definition at line 167 of file MuScleFitUtils.h.

Referenced by likelihood(), and minimizeLikelihood().

unsigned int MuScleFitUtils::loopCounter = 5
static
MuScleFitUtils::massResolComponentsStruct MuScleFitUtils::massResolComponents
static

Definition at line 253 of file MuScleFitUtils.cc.

Referenced by MuScleFit::duringFastLoop(), and massResolution().

double MuScleFitUtils::massWindowHalfWidth
static

Definition at line 117 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood(), and MuScleFit::MuScleFit().

double MuScleFitUtils::maxMuonEtaFirstRange_ = 6.
static

Definition at line 244 of file MuScleFitUtils.h.

Referenced by findBestRecoRes(), MuScleFit::MuScleFit(), and MuScleFit::selectMuons().

double MuScleFitUtils::maxMuonEtaSecondRange_ = 100.
static

Definition at line 246 of file MuScleFitUtils.h.

Referenced by findBestRecoRes(), MuScleFit::MuScleFit(), and MuScleFit::selectMuons().

double MuScleFitUtils::maxMuonPt_ = 100000000.
static

Definition at line 242 of file MuScleFitUtils.h.

Referenced by findBestRecoRes(), MuScleFit::MuScleFit(), and MuScleFit::selectMuons().

bool MuScleFitUtils::minimumShapePlots_
static

Definition at line 264 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood(), and MuScleFit::MuScleFit().

double MuScleFitUtils::minMuonEtaFirstRange_ = -6.
static

Definition at line 243 of file MuScleFitUtils.h.

Referenced by findBestRecoRes(), MuScleFit::MuScleFit(), and MuScleFit::selectMuons().

double MuScleFitUtils::minMuonEtaSecondRange_ = -100.
static

Definition at line 245 of file MuScleFitUtils.h.

Referenced by findBestRecoRes(), MuScleFit::MuScleFit(), and MuScleFit::selectMuons().

double MuScleFitUtils::minMuonPt_ = 0.
static

Definition at line 241 of file MuScleFitUtils.h.

Referenced by findBestRecoRes(), MuScleFit::MuScleFit(), and MuScleFit::selectMuons().

int MuScleFitUtils::minuitLoop_ = 0
static

Definition at line 166 of file MuScleFitUtils.h.

Referenced by likelihood(), massProb(), and minimizeLikelihood().

const double MuScleFitUtils::mMu2 = 0.011163612
static
const unsigned int MuScleFitUtils::motherPdgIdArray = {23, 100553, 100553, 553, 100443, 443}
static

Definition at line 126 of file MuScleFitUtils.h.

Referenced by findGenMuFromRes(), and findSimMuFromRes().

const double MuScleFitUtils::muMass = 0.105658
static

Definition at line 123 of file MuScleFitUtils.h.

Referenced by fromPtEtaPhiToPxPyPz().

int MuScleFitUtils::MuonType
static

Definition at line 206 of file MuScleFitUtils.h.

Referenced by massProb(), minimizeLikelihood(), and MuScleFit::MuScleFit().

int MuScleFitUtils::MuonTypeForCheckMassWindow
static

Definition at line 207 of file MuScleFitUtils.h.

Referenced by MuScleFit::MuScleFit().

int MuScleFitUtils::nbins = 1000
static
unsigned int MuScleFitUtils::normalizationChanged_ = 0
static

Definition at line 227 of file MuScleFitUtils.h.

Referenced by likelihood(), and minimizeLikelihood().

bool MuScleFitUtils::normalizeLikelihoodByEventNumber_ = true
static

Definition at line 222 of file MuScleFitUtils.h.

Referenced by likelihood(), and MuScleFit::MuScleFit().

double MuScleFitUtils::oldNormalization_ = 0.
static

Definition at line 226 of file MuScleFitUtils.h.

Referenced by likelihood(), and MuScleFit::startingNewLoop().

std::vector< double > MuScleFitUtils::parBgr
static
std::vector< int > MuScleFitUtils::parBgrFix
static
std::vector< int > MuScleFitUtils::parBgrOrder
static
std::vector< double > MuScleFitUtils::parBias
static

Definition at line 174 of file MuScleFitUtils.h.

Referenced by applyBias(), MuScleFit::checkParameters(), and MuScleFit::MuScleFit().

std::vector< double > MuScleFitUtils::parCrossSection
static
std::vector< int > MuScleFitUtils::parCrossSectionFix
static

Definition at line 187 of file MuScleFitUtils.h.

Referenced by MuScleFit::checkParameters(), and MuScleFit::MuScleFit().

std::vector< int > MuScleFitUtils::parCrossSectionOrder
static
std::vector<int> MuScleFitUtils::parfix
static

Definition at line 211 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood().

std::vector<int> MuScleFitUtils::parorder
static

Definition at line 212 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood().

std::vector< double > MuScleFitUtils::parResol
static
std::vector< int > MuScleFitUtils::parResolFix
static
std::vector< double > MuScleFitUtils::parResolMax
static

Definition at line 178 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood(), and MuScleFit::MuScleFit().

std::vector< double > MuScleFitUtils::parResolMin
static

Definition at line 177 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood(), and MuScleFit::MuScleFit().

std::vector< int > MuScleFitUtils::parResolOrder
static
std::vector< double > MuScleFitUtils::parResolStep
static

Definition at line 176 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood(), and MuScleFit::MuScleFit().

std::vector< double > MuScleFitUtils::parScale
static
std::vector< int > MuScleFitUtils::parScaleFix
static
std::vector< double > MuScleFitUtils::parScaleMax
static

Definition at line 182 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood(), and MuScleFit::MuScleFit().

std::vector< double > MuScleFitUtils::parScaleMin
static

Definition at line 181 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood(), and MuScleFit::MuScleFit().

std::vector< int > MuScleFitUtils::parScaleOrder
static
std::vector< double > MuScleFitUtils::parScaleStep
static

Definition at line 180 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood(), and MuScleFit::MuScleFit().

std::vector< double > MuScleFitUtils::parSmear
static
std::vector< std::vector< double > > MuScleFitUtils::parvalue
static

Definition at line 209 of file MuScleFitUtils.h.

Referenced by MuScleFit::duringFastLoop(), and minimizeLikelihood().

bool MuScleFitUtils::rapidityBinsForZ_ = true
static
std::vector< std::pair< lorentzVector, lorentzVector > > MuScleFitUtils::ReducedSavedPair
static

Definition at line 216 of file MuScleFitUtils.h.

Referenced by likelihood(), and minimizeLikelihood().

std::vector< int > MuScleFitUtils::resfind
static
bool MuScleFitUtils::ResFound = false
static
double MuScleFitUtils::ResGamma = {2.4952, 0.000020, 0.000032, 0.000054, 0.000317, 0.0000932 }
static

Definition at line 118 of file MuScleFitUtils.h.

Referenced by massProb().

double MuScleFitUtils::ResHalfWidth
static
double MuScleFitUtils::ResMass = {91.1876, 10.3552, 10.0233, 9.4603, 3.68609, 3.0969}
static
double MuScleFitUtils::ResMaxSigma
static
double MuScleFitUtils::ResMinMass = {-99, -99, -99, -99, -99, -99}
static
int MuScleFitUtils::ResolFitType = 0
static
resolutionFunctionBase< double * > * MuScleFitUtils::resolutionFunction = 0
static
resolutionFunctionBase< std::vector< double > > * MuScleFitUtils::resolutionFunctionForVec = 0
static
TMinuit * MuScleFitUtils::rminPtr_ = 0
static

Definition at line 224 of file MuScleFitUtils.h.

Referenced by likelihood(), and minimizeLikelihood().

std::vector< std::pair< lorentzVector, lorentzVector > > MuScleFitUtils::SavedPair
static
std::vector< std::pair< MuScleFitMuon, MuScleFitMuon > > MuScleFitUtils::SavedPairMuScleFitMuons
static

Definition at line 215 of file MuScleFitUtils.h.

Referenced by MuScleFit::selectMuons().

bool MuScleFitUtils::scaleFitNotDone_ = true
static

Definition at line 220 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood().

int MuScleFitUtils::ScaleFitType = 0
static

Definition at line 138 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood(), and MuScleFit::MuScleFit().

scaleFunctionBase< double * > * MuScleFitUtils::scaleFunction = 0
static

Definition at line 139 of file MuScleFitUtils.h.

Referenced by applyScale(), minimizeLikelihood(), and MuScleFit::MuScleFit().

scaleFunctionBase< std::vector< double > > * MuScleFitUtils::scaleFunctionForVec = 0
static

Definition at line 140 of file MuScleFitUtils.h.

Referenced by MuScleFit::MuScleFit().

bool MuScleFitUtils::separateRanges_ = true
static

Definition at line 240 of file MuScleFitUtils.h.

Referenced by MuScleFit::MuScleFit(), and MuScleFit::selectMuons().

bool MuScleFitUtils::sherpa_ = false
static

Definition at line 230 of file MuScleFitUtils.h.

Referenced by findGenMuFromRes(), and MuScleFit::MuScleFit().

TH1D * MuScleFitUtils::signalProb_ = 0
static

Definition at line 168 of file MuScleFitUtils.h.

Referenced by massProb(), and minimizeLikelihood().

std::vector< std::pair< lorentzVector, lorentzVector > > MuScleFitUtils::simPair
static

Definition at line 218 of file MuScleFitUtils.h.

Referenced by MuScleFit::duringFastLoop(), and MuScleFit::selectMuons().

smearFunctionBase * MuScleFitUtils::smearFunction = 0
static

Definition at line 131 of file MuScleFitUtils.h.

Referenced by applySmearing(), and MuScleFit::MuScleFit().

int MuScleFitUtils::SmearType = 0
static
bool MuScleFitUtils::speedup = false
static
bool MuScleFitUtils::startWithSimplex_
static

Definition at line 262 of file MuScleFitUtils.h.

Referenced by minimizeLikelihood(), and MuScleFit::MuScleFit().

const int MuScleFitUtils::totalResNum = 6
static

Definition at line 116 of file MuScleFitUtils.h.

Referenced by massProb().

bool MuScleFitUtils::useProbsFile_ = true
static
double MuScleFitUtils::x
static