#include <MuonResidualsAngleFitter.h>

Inheritance diagram for MuonResidualsAngleFitter:

Public Types
enum	{ kAngle = 0, kXControl, kYControl, kSigma, kGamma, kNPar }

enum	{ kResidual = 0, kXAngle, kYAngle, kNData }

Public Types inherited from MuonResidualsFitter
enum	{ kPureGaussian, kPowerLawTails, kROOTVoigt, kGaussPowerTails, kPureGaussian2D }

enum	{ k1DOF, k5DOF, k6DOF, k6DOFrphi, kPositionFitter, kAngleFitter, kAngleBfieldFitter }

enum	{ k1111, k1110, k1100, k1010, k0010 }

Public Member Functions
bool	fit (Alignable *ali)

	MuonResidualsAngleFitter (int residualsModel, int minHitsPerRegion, int useResiduals, bool weightAlignment=true)

int	ndata ()

int	npar ()

double	plot (std::string name, TFileDirectory dir, Alignable ali)

double	sumofweights ()

int	type () const

Public Member Functions inherited from MuonResidualsFitter
void	computeHistogramRangeAndBinning (int which, int &nbins, double &a, double &b)

virtual void	correctBField ()=0

virtual void	correctBField (int idx_momentum, int idx_q)

TMatrixDSym	correlationMatrix ()

double	covarianceElement (int parNum1, int parNum2)

TMatrixDSym	covarianceMatrix ()

void	eraseNotSelectedResiduals ()

double	errorerror (int parNum)

void	fill (double *residual)

void	fix (int parNum, bool val=true)

bool	fixed (int parNum)

void	histogramChi2GaussianFit (int which, double &fit_mean, double &fit_sigma)

double	loglikelihood ()

	MuonResidualsFitter (int residualsModel, int minHits, int useResiduals, bool weightAlignment=true)

int	nfixed ()

long	numResiduals () const

long	numsegments ()

int	parNum2parIdx (int parNum)

void	plotsimple (std::string name, TFileDirectory *dir, int which, double multiplier)

void	plotweighted (std::string name, TFileDirectory *dir, int which, int whichredchi2, double multiplier)

void	read (FILE *file, int which=0)

std::vector< double * > ::const_iterator	residuals_begin () const

std::vector< double * > ::const_iterator	residuals_end () const

int	residualsModel () const

std::vector< bool > &	selectedResidualsFlags ()

void	selectPeakResiduals (double nsigma, int nvar, int *vars)

void	selectPeakResiduals_simple (double nsigma, int nvar, int *vars)

void	setPrintLevel (int printLevel)

void	setStrategy (int strategy)

int	useRes () const

double	value (int parNum)

void	write (FILE *file, int which=0)

virtual	~MuonResidualsFitter ()

Protected Member Functions
void	inform (TMinuit *tMinuit)

Protected Member Functions inherited from MuonResidualsFitter
bool	dofit (void(fcn)(int &, double , double &, double *, int), std::vector< int > &parNum, std::vector< std::string > &parName, std::vector< double > &start, std::vector< double > &step, std::vector< double > &low, std::vector< double > &high)

void	initialize_table ()

Additional Inherited Members
Protected Attributes inherited from MuonResidualsFitter
double	m_center [20]

TMatrixDSym	m_cov

std::vector< double >	m_error

std::vector< bool >	m_fixed

double	m_loglikelihood

int	m_minHits

std::map< int, int >	m_parNum2parIdx

int	m_printLevel

double	m_radii [20]

std::vector< double * >	m_residuals

std::vector< bool >	m_residuals_ok

int	m_residualsModel

int	m_strategy

int	m_useResiduals

std::vector< double >	m_value

bool	m_weightAlignment

Detailed Description

Date:: 2010/03/12 22:23:18

Revision:: 1.10

Author: J. Pivarski - Texas A&M University pivar.nosp@m.ski@.nosp@m.physi.nosp@m.cs.t.nosp@m.amu.e.nosp@m.du

Definition at line 12 of file MuonResidualsAngleFitter.h.

Member Enumeration Documentation

anonymous enum

Enumerator
kAngle
kXControl
kYControl
kSigma
kGamma
kNPar

Definition at line 14 of file MuonResidualsAngleFitter.h.

        {
     kAngle = 0,
     kXControl,
     kYControl,
     kSigma,
     kGamma,
     kNPar
   };

anonymous enum

Enumerator
kResidual
kXAngle
kYAngle
kNData

Definition at line 23 of file MuonResidualsAngleFitter.h.

        {
     kResidual = 0,
     kXAngle,
     kYAngle,
     kNData
   };

Constructor & Destructor Documentation

MuonResidualsAngleFitter::MuonResidualsAngleFitter	(	int	residualsModel,
		int	minHitsPerRegion,
		int	useResiduals,
		bool	weightAlignment = `true`
	)

inline

Definition at line 30 of file MuonResidualsAngleFitter.h.

30 : MuonResidualsFitter(residualsModel, minHitsPerRegion, useResiduals, weightAlignment) {}

align_cfg.weightAlignment

tuple weightAlignment

Definition: align_cfg.py:30

MuonResidualsFitter::residualsModel

int residualsModel() const

Definition: MuonResidualsFitter.h:150

MuonResidualsFitter::MuonResidualsFitter

MuonResidualsFitter(int residualsModel, int minHits, int useResiduals, bool weightAlignment=true)

Definition: MuonResidualsFitter.h:130

align_cfg.useResiduals

list useResiduals

Definition: align_cfg.py:36

Member Function Documentation

bool MuonResidualsAngleFitter::fit ( Alignable * ali )

virtual

Implements MuonResidualsFitter.

Definition at line 40 of file MuonResidualsAngleFitter.cc.

References MuonResidualsFitter::dofit(), MuonResidualsFitter::initialize_table(), kAngle, kGamma, MuonResidualsFitter::kGaussPowerTails, MuonResidualsFitter::kPureGaussian, kResidual, kSigma, kXControl, kYControl, MuonResidualsFitter::m_minHits, timingPdfMaker::mean, MuonResidualsAngleFitter_FCN(), N, funct::pow(), MuonResidualsFitter::residuals_begin(), MuonResidualsFitter::residuals_end(), MuonResidualsFitter::residualsModel(), mathSSE::sqrt(), dqm_diff::start, plotscripts::stdev(), relval_parameters_module::step, AlCaHLTBitMon_QueryRunRegistry::string, makeMuonMisalignmentScenario::sum_x, and makeMuonMisalignmentScenario::sum_xx.

                                                  {
   initialize_table();  // if not already initialized
 
   double sum_x = 0.;
   double sum_xx = 0.;
   int N = 0;
 
   for (std::vector<double*>::const_iterator resiter = residuals_begin();  resiter != residuals_end();  ++resiter) {
     const double residual = (*resiter)[kResidual];
 //     const double xangle = (*resiter)[kXAngle];
 //     const double yangle = (*resiter)[kYAngle];
 
     if (fabs(residual) < 0.1) {  // truncate at 100 mrad
       sum_x += residual;
       sum_xx += residual*residual;
       N++;
     }
   }
 
   if (N < m_minHits) return false;
 
   // truncated mean and stdev to seed the fit
   double mean = sum_x/double(N);
   double stdev = sqrt(sum_xx/double(N) - pow(sum_x/double(N), 2));
 
   // refine the standard deviation calculation
   sum_x = 0.;
   sum_xx = 0.;
   N = 0;
   for (std::vector<double*>::const_iterator resiter = residuals_begin();  resiter != residuals_end();  ++resiter) {
     const double residual = (*resiter)[kResidual];
     if (mean - 1.5*stdev < residual  &&  residual < mean + 1.5*stdev) {
       sum_x += residual;
       sum_xx += residual*residual;
       N++;
     }
   }
   mean = sum_x/double(N);
   stdev = sqrt(sum_xx/double(N) - pow(sum_x/double(N), 2));
 
   sum_x = 0.;
   sum_xx = 0.;
   N = 0;
   for (std::vector<double*>::const_iterator resiter = residuals_begin();  resiter != residuals_end();  ++resiter) {
     const double residual = (*resiter)[kResidual];
     if (mean - 1.5*stdev < residual  &&  residual < mean + 1.5*stdev) {
       sum_x += residual;
       sum_xx += residual*residual;
       N++;
     }
   }
   mean = sum_x/double(N);
   stdev = sqrt(sum_xx/double(N) - pow(sum_x/double(N), 2));
 
   std::vector<int> parNum;
   std::vector<std::string> parName;
   std::vector<double> start;
   std::vector<double> step;
   std::vector<double> low;
   std::vector<double> high;
 
   parNum.push_back(kAngle);     parName.push_back(std::string("angle"));     start.push_back(mean);     step.push_back(0.1);               low.push_back(0.);    high.push_back(0.);
   parNum.push_back(kXControl);  parName.push_back(std::string("xcontrol"));  start.push_back(0.);       step.push_back(0.1);               low.push_back(0.);    high.push_back(0.);
   parNum.push_back(kYControl);  parName.push_back(std::string("ycontrol"));  start.push_back(0.);       step.push_back(0.1);               low.push_back(0.);    high.push_back(0.);
   parNum.push_back(kSigma);     parName.push_back(std::string("sigma"));     start.push_back(stdev);  step.push_back(0.1*stdev);       low.push_back(0.);    high.push_back(0.);
   if (residualsModel() != kPureGaussian && residualsModel() != kGaussPowerTails) {
   parNum.push_back(kGamma);     parName.push_back(std::string("gamma"));     start.push_back(stdev);  step.push_back(0.1*stdev);         low.push_back(0.);    high.push_back(0.);
   }
 
   return dofit(&MuonResidualsAngleFitter_FCN, parNum, parName, start, step, low, high);
 }

void MuonResidualsAngleFitter::inform ( TMinuit * tMinuit )

protectedvirtual

Implements MuonResidualsFitter.

Definition at line 5 of file MuonResidualsAngleFitter.cc.

References MuonResidualsAngleFitter_TMinuit.

                                                       {
   MuonResidualsAngleFitter_TMinuit = tMinuit;
 }

int MuonResidualsAngleFitter::ndata ( )

inlinevirtual

Implements MuonResidualsFitter.

Definition at line 40 of file MuonResidualsAngleFitter.h.

References kNData.

40 { return kNData; }

MuonResidualsAngleFitter::kNData

Definition: MuonResidualsAngleFitter.h:27

int MuonResidualsAngleFitter::npar ( )

inlinevirtual

Implements MuonResidualsFitter.

Definition at line 34 of file MuonResidualsAngleFitter.h.

References assert(), MuonResidualsFitter::kGaussPowerTails, kNPar, MuonResidualsFitter::kPowerLawTails, MuonResidualsFitter::kPureGaussian, MuonResidualsFitter::kROOTVoigt, and MuonResidualsFitter::residualsModel().

              {
     if (residualsModel() == kPureGaussian || residualsModel() == kGaussPowerTails) return kNPar - 1;
     else if (residualsModel() == kPowerLawTails) return kNPar;
     else if (residualsModel() == kROOTVoigt) return kNPar;
     else assert(false);
   }

double MuonResidualsAngleFitter::plot	(	std::string	name,
		TFileDirectory *	dir,
		Alignable *	ali
	)

virtual

Implements MuonResidualsFitter.

Definition at line 112 of file MuonResidualsAngleFitter.cc.

References kAngle, kGamma, MuonResidualsFitter::kGaussPowerTails, MuonResidualsFitter::kPowerLawTails, MuonResidualsFitter::kPureGaussian, kResidual, MuonResidualsFitter::kROOTVoigt, kSigma, kXAngle, kXControl, kYAngle, kYControl, TFileDirectory::make(), MuonResidualsFitter_GaussPowerTails_TF1(), MuonResidualsFitter_powerLawTails_TF1(), MuonResidualsFitter_pureGaussian_TF1(), MuonResidualsFitter_ROOTVoigt_TF1(), NULL, MuonResidualsFitter::numResiduals(), MuonResidualsFitter::residuals_begin(), MuonResidualsFitter::residuals_end(), MuonResidualsFitter::residualsModel(), AlCaHLTBitMon_QueryRunRegistry::string, and MuonResidualsFitter::value().

Referenced by cuy.FindIssue::__init__().

                                                                                          {
   std::stringstream raw_name, narrowed_name, xcontrol_name, ycontrol_name;
   raw_name << name << "_raw";
   narrowed_name << name << "_narrowed";
   xcontrol_name << name << "_xcontrol";
   ycontrol_name << name << "_ycontrol";
 
   TH1F *raw_hist = dir->make<TH1F>(raw_name.str().c_str(), (raw_name.str() + std::string(" (mrad)")).c_str(), 100, -100., 100.);
   TH1F *narrowed_hist = dir->make<TH1F>(narrowed_name.str().c_str(), (narrowed_name.str() + std::string(" (mrad)")).c_str(), 100, -100., 100.);
   TProfile *xcontrol_hist = dir->make<TProfile>(xcontrol_name.str().c_str(), (xcontrol_name.str() + std::string(" (mrad)")).c_str(), 100, -1., 1.);
   TProfile *ycontrol_hist = dir->make<TProfile>(ycontrol_name.str().c_str(), (ycontrol_name.str() + std::string(" (mrad)")).c_str(), 100, -1., 1.);
 
   narrowed_name << "fit";
   xcontrol_name << "fit";
   ycontrol_name << "fit";
 
   double scale_factor = double(numResiduals()) * (100. - -100.)/100;   // (max - min)/nbins
 
   TF1 *narrowed_fit = NULL;
   if (residualsModel() == kPureGaussian) {
     narrowed_fit = new TF1(narrowed_name.str().c_str(), MuonResidualsFitter_pureGaussian_TF1, -100., 100., 3);
     narrowed_fit->SetParameters(scale_factor, value(kAngle) * 1000., value(kSigma) * 1000.);
     narrowed_fit->Write();
   }
   else if (residualsModel() == kPowerLawTails) {
     narrowed_fit = new TF1(narrowed_name.str().c_str(), MuonResidualsFitter_powerLawTails_TF1, -100., 100., 4);
     narrowed_fit->SetParameters(scale_factor, value(kAngle) * 1000., value(kSigma) * 1000., value(kGamma) * 1000.);
     narrowed_fit->Write();
   }
   else if (residualsModel() == kROOTVoigt) {
     narrowed_fit = new TF1(narrowed_name.str().c_str(), MuonResidualsFitter_ROOTVoigt_TF1, -100., 100., 4);
     narrowed_fit->SetParameters(scale_factor, value(kAngle) * 1000., value(kSigma) * 1000., value(kGamma) * 1000.);
     narrowed_fit->Write();
   }
   else if (residualsModel() == kGaussPowerTails) {
     narrowed_fit = new TF1(narrowed_name.str().c_str(), MuonResidualsFitter_GaussPowerTails_TF1, -100., 100., 3);
     narrowed_fit->SetParameters(scale_factor, value(kAngle) * 1000., value(kSigma) * 1000.);
     narrowed_fit->Write();
   }
 
   TF1 *xcontrol_fit = new TF1(xcontrol_name.str().c_str(), "[0]+x*[1]", -1., 1.);
   xcontrol_fit->SetParameters(value(kAngle) * 1000., value(kXControl) * 1000.);
   xcontrol_fit->Write();
 
   TF1 *ycontrol_fit = new TF1(ycontrol_name.str().c_str(), "[0]+x*[1]", -1., 1.);
   ycontrol_fit->SetParameters(value(kAngle) * 1000., value(kYControl) * 1000.);
   ycontrol_fit->Write();
 
   for (std::vector<double*>::const_iterator resiter = residuals_begin();  resiter != residuals_end();  ++resiter) {
     const double raw_residual = (*resiter)[kResidual];
     const double xangle = (*resiter)[kXAngle];
     const double yangle = (*resiter)[kYAngle];
 
     double xangle_correction = value(kXControl) * xangle;
     double yangle_correction = value(kYControl) * yangle;
     double corrected_residual = raw_residual - xangle_correction - yangle_correction;
 
     raw_hist->Fill(raw_residual * 1000.);
     narrowed_hist->Fill(corrected_residual * 1000.);
 
     xcontrol_hist->Fill(xangle, (raw_residual - yangle_correction) * 1000.);
     ycontrol_hist->Fill(yangle, (raw_residual - xangle_correction) * 1000.);
   }
 
   return 0.;
 }