CalibrationSummaryFactory Class Reference

#include <CalibrationSummaryFactory.h>

Inheritance diagram for CalibrationSummaryFactory:

Protected Member Functions
void	extract (Iterator) override
void	format () override
Protected Member Functions inherited from SummaryPlotFactoryBase
void	fill (TH1 &summary_histo)
void	init (const sistrip::Monitorable &, const sistrip::Presentation &, const sistrip::View &, const std::string &top_level_dir, const sistrip::Granularity &)
	SummaryPlotFactoryBase ()
	~SummaryPlotFactoryBase ()

Additional Inherited Members
Public Types inherited from SummaryPlotFactory< CommissioningAnalysis * >
typedef std::map< uint32_t, CommissioningAnalysis * >::const_iterator	Iterator
Public Member Functions inherited from SummaryPlotFactory< CommissioningAnalysis * >
void	fill (TH1 &summary_histo)
uint32_t	init (const sistrip::Monitorable &, const sistrip::Presentation &, const sistrip::View &, const std::string &top_level_dir, const sistrip::Granularity &, const std::map< uint32_t, CommissioningAnalysis * > &data)
	SummaryPlotFactory ()
virtual	~SummaryPlotFactory ()
Protected Attributes inherited from SummaryPlotFactoryBase
SummaryGenerator *	generator_
sistrip::Granularity	gran_
std::string	level_
sistrip::Monitorable	mon_
sistrip::Presentation	pres_
sistrip::View	view_

Detailed Description

Definition at line 6 of file CalibrationSummaryFactory.h.

Member Function Documentation

void CalibrationSummaryFactory::extract ( Iterator  iter )

overrideprotectedvirtual

Reimplemented from SummaryPlotFactory< CommissioningAnalysis * >.

Definition at line 12 of file CalibrationSummaryFactory.cc.

References CustomPhysics_cfi::amplitude, CalibrationAnalysis::amplitude(), CalibrationAnalysis::amplitudeMax(), CalibrationAnalysis::amplitudeMean(), CalibrationAnalysis::amplitudeMin(), CalibrationAnalysis::amplitudeSpread(), CalibrationAnalysis::baseline(), CalibrationAnalysis::baselineMax(), CalibrationAnalysis::baselineMean(), CalibrationAnalysis::baselineMin(), CalibrationAnalysis::baselineSpread(), create_public_pileup_plots::bins, sistrip::CALIBRATION_AMPLITUDE, sistrip::CALIBRATION_AMPLITUDE_ALLSTRIPS, sistrip::CALIBRATION_AMPLITUDE_MAX, sistrip::CALIBRATION_AMPLITUDE_MIN, sistrip::CALIBRATION_BASELINE, sistrip::CALIBRATION_BASELINE_ALLSTRIPS, sistrip::CALIBRATION_BASELINE_MAX, sistrip::CALIBRATION_BASELINE_MIN, sistrip::CALIBRATION_CHI2, sistrip::CALIBRATION_CHI2_ALLSTRIPS, sistrip::CALIBRATION_CHI2_MAX, sistrip::CALIBRATION_CHI2_MIN, sistrip::CALIBRATION_MAXIMUM, sistrip::CALIBRATION_MAXIMUM_ALLSTRIPS, sistrip::CALIBRATION_MAXIMUM_MAX, sistrip::CALIBRATION_MAXIMUM_MIN, sistrip::CALIBRATION_RISETIME, sistrip::CALIBRATION_RISETIME_ALLSTRIPS, sistrip::CALIBRATION_RISETIME_MAX, sistrip::CALIBRATION_RISETIME_MIN, sistrip::CALIBRATION_SMEARING, sistrip::CALIBRATION_SMEARING_ALLSTRIPS, sistrip::CALIBRATION_SMEARING_MAX, sistrip::CALIBRATION_SMEARING_MIN, sistrip::CALIBRATION_TAIL, sistrip::CALIBRATION_TAIL_ALLSTRIPS, sistrip::CALIBRATION_TAIL_MAX, sistrip::CALIBRATION_TAIL_MIN, sistrip::CALIBRATION_TIMECONSTANT, sistrip::CALIBRATION_TIMECONSTANT_ALLSTRIPS, sistrip::CALIBRATION_TIMECONSTANT_MAX, sistrip::CALIBRATION_TIMECONSTANT_MIN, sistrip::CALIBRATION_TURNON, sistrip::CALIBRATION_TURNON_ALLSTRIPS, sistrip::CALIBRATION_TURNON_MAX, sistrip::CALIBRATION_TURNON_MIN, sistrip::CALIBRATION_UNDERSHOOT, sistrip::CALIBRATION_UNDERSHOOT_ALLSTRIPS, sistrip::CALIBRATION_UNDERSHOOT_MAX, sistrip::CALIBRATION_UNDERSHOOT_MIN, SiStripFecKey::ccuAddr(), SiStripFecKey::ccuChan(), vertices_cff::chi2, CalibrationAnalysis::chi2(), CalibrationAnalysis::chi2Max(), CalibrationAnalysis::chi2Mean(), CalibrationAnalysis::chi2Min(), CalibrationAnalysis::chi2Spread(), relativeConstraints::error, SiStripFecKey::fecCrate(), SiStripFecKey::fecRing(), SiStripFecKey::fecSlot(), SummaryGenerator::fillMap(), SummaryPlotFactoryBase::generator_, SummaryPlotFactoryBase::gran_, mps_fire::i, SiStripFecKey::i2cAddr(), sistrip::invalid_, SiStripKey::key(), SummaryPlotFactoryBase::level_, SiStripFecKey::lldChan(), CalibrationAnalysis::maximum(), CalibrationAnalysis::maximumMax(), CalibrationAnalysis::maximumMean(), CalibrationAnalysis::maximumMin(), CalibrationAnalysis::maximumSpread(), sistrip::mlSummaryPlots_, SummaryPlotFactoryBase::mon_, SiStripEnumsAndStrings::monitorable(), CalibrationAnalysis::riseTime(), CalibrationAnalysis::riseTimeMax(), CalibrationAnalysis::riseTimeMean(), CalibrationAnalysis::riseTimeMin(), CalibrationAnalysis::riseTimeSpread(), CalibrationAnalysis::smearing(), CalibrationAnalysis::smearingMax(), CalibrationAnalysis::smearingMean(), CalibrationAnalysis::smearingMin(), CalibrationAnalysis::smearingSpread(), CalibrationAnalysis::tail(), CalibrationAnalysis::tailMax(), CalibrationAnalysis::tailMean(), CalibrationAnalysis::tailMin(), CalibrationAnalysis::tailSpread(), groupFilesInBlocks::temp, CalibrationAnalysis::timeConstant(), CalibrationAnalysis::timeConstantMax(), CalibrationAnalysis::timeConstantMean(), CalibrationAnalysis::timeConstantMin(), CalibrationAnalysis::timeConstantSpread(), CalibrationAnalysis::turnOn(), CalibrationAnalysis::turnOnMax(), CalibrationAnalysis::turnOnMean(), CalibrationAnalysis::turnOnMin(), CalibrationAnalysis::turnOnSpread(), CalibrationAnalysis::undershoot(), CalibrationAnalysis::undershootMax(), CalibrationAnalysis::undershootMean(), CalibrationAnalysis::undershootMin(), CalibrationAnalysis::undershootSpread(), and relativeConstraints::value.

                                                       {

  CalibrationAnalysis* anal = dynamic_cast<CalibrationAnalysis*>( iter->second );
  if ( !anal ) { return; }

  std::vector<float> temp(128, 1. * sistrip::invalid_ );
  std::vector< std::vector<float> > value( 2, temp );
  std::vector< std::vector<float> > error( 2, temp );
  std::vector< std::vector<float> > amplitude( 2, temp );
  std::vector< std::vector<float> > tail( 2, temp );
  std::vector< std::vector<float> > riseTime( 2, temp );
  std::vector< std::vector<float> > timeConstant( 2, temp );
  std::vector< std::vector<float> > turnOn( 2, temp );
  std::vector< std::vector<float> > maximum( 2, temp );
  std::vector< std::vector<float> > undershoot( 2, temp );
  std::vector< std::vector<float> > baseline( 2, temp );
  std::vector< std::vector<float> > smearing( 2, temp );
  std::vector< std::vector<float> > chi2( 2, temp );
  amplitude[0] = anal->amplitude()[0];
  amplitude[1] = anal->amplitude()[1];
  tail[0] = anal->tail()[0];
  tail[1] = anal->tail()[1];
  riseTime[0] = anal->riseTime()[0];
  riseTime[1] = anal->riseTime()[1];
  timeConstant[0] = anal->timeConstant()[0];
  timeConstant[1] = anal->timeConstant()[1];
  turnOn[0] = anal->turnOn()[0];
  turnOn[1] = anal->turnOn()[1];
  maximum[0] = anal->maximum()[0];
  maximum[1] = anal->maximum()[1];
  undershoot[0] = anal->undershoot()[0];
  undershoot[1] = anal->undershoot()[1];
  baseline[0] = anal->baseline()[0];
  baseline[1] = anal->baseline()[1];
  smearing[0] = anal->smearing()[0];
  smearing[1] = anal->smearing()[1];
  chi2[0] = anal->chi2()[0];
  chi2[1] = anal->chi2()[1];
  
  SiStripFecKey lldKey = SiStripFecKey(iter->first);
  uint32_t key1 = SiStripFecKey(lldKey.fecCrate(),
                                lldKey.fecSlot(),
                                lldKey.fecRing(),
                                lldKey.ccuAddr(),
                                lldKey.ccuChan(),
                                lldKey.lldChan(),
                                lldKey.i2cAddr(lldKey.lldChan(),true)).key();
  uint32_t key2 = SiStripFecKey(lldKey.fecCrate(),
                                lldKey.fecSlot(),
                                lldKey.fecRing(),
                                lldKey.ccuAddr(),
                                lldKey.ccuChan(),
                                lldKey.lldChan(),
                                lldKey.i2cAddr(lldKey.lldChan(),false)).key();
  
  bool all_strips = false;
  bool with_error = false;

  // Amplitude
  if ( mon_ == sistrip::CALIBRATION_AMPLITUDE_ALLSTRIPS) {
    all_strips = true;
    uint16_t bins = amplitude[amplitude[0].size() < amplitude[1].size() ? 1 : 0].size();
    for ( uint16_t i = 0; i < bins; i++ ) {
      value[0][i] = amplitude[0][i]/10.;
      value[1][i] = amplitude[1][i]/10.;
    }
  } else if ( mon_ == sistrip::CALIBRATION_AMPLITUDE) {
    with_error = true;
    value[0][0] = anal->amplitudeMean()[0]/10.;
    value[1][0] = anal->amplitudeMean()[1]/10.;
    error[0][0] = anal->amplitudeSpread()[0]/10.;
    error[1][0] = anal->amplitudeSpread()[1]/10.;
  } else if ( mon_ == sistrip::CALIBRATION_AMPLITUDE_MIN) {
    value[0][0] = anal->amplitudeMin()[0]/10.;
    value[1][0] = anal->amplitudeMin()[1]/10.;
  } else if ( mon_ == sistrip::CALIBRATION_AMPLITUDE_MAX) {
    value[0][0] = anal->amplitudeMax()[0]/10.;
    value[1][0] = anal->amplitudeMax()[1]/10.;
  } 
  // Tail parameter
  else if ( mon_ == sistrip::CALIBRATION_TAIL_ALLSTRIPS) {
    all_strips = true;
    uint16_t bins = tail[tail[0].size() < tail[1].size() ? 1 : 0].size();
    for ( uint16_t i = 0; i < bins; i++ ) {
      value[0][i] = tail[0][i];
      value[1][i] = tail[1][i];
    }
  } else if ( mon_ == sistrip::CALIBRATION_TAIL) {
    with_error = true;
    value[0][0] = anal->tailMean()[0];
    value[1][0] = anal->tailMean()[1];
    error[0][0] = anal->tailSpread()[0];
    error[1][0] = anal->tailSpread()[1];
  } else if ( mon_ == sistrip::CALIBRATION_TAIL_MIN) {
    value[0][0] = anal->tailMin()[0];
    value[1][0] = anal->tailMin()[1];
  } else if ( mon_ == sistrip::CALIBRATION_TAIL_MAX) {
    value[0][0] = anal->tailMax()[0];
    value[1][0] = anal->tailMax()[1];
  } 
  // Risetime parameter
  else if ( mon_ == sistrip::CALIBRATION_RISETIME_ALLSTRIPS) {
    all_strips = true;
    uint16_t bins = riseTime[riseTime[0].size() < riseTime[1].size() ? 1 : 0].size();
    for ( uint16_t i = 0; i < bins; i++ ) {
      value[0][i] = riseTime[0][i];
      value[1][i] = riseTime[1][i];
    }
  } else if ( mon_ == sistrip::CALIBRATION_RISETIME) {
    with_error = true;
    value[0][0] = anal->riseTimeMean()[0];
    value[1][0] = anal->riseTimeMean()[1];
    error[0][0] = anal->riseTimeSpread()[0];
    error[1][0] = anal->riseTimeSpread()[1];
  } else if ( mon_ == sistrip::CALIBRATION_RISETIME_MIN) {
    value[0][0] = anal->riseTimeMin()[0];
    value[1][0] = anal->riseTimeMin()[1];
  } else if ( mon_ == sistrip::CALIBRATION_RISETIME_MAX) {
    value[0][0] = anal->riseTimeMax()[0];
    value[1][0] = anal->riseTimeMax()[1];
  } 
  // TimeConstant
  else if ( mon_ == sistrip::CALIBRATION_TIMECONSTANT_ALLSTRIPS) {
    all_strips = true;
    uint16_t bins = timeConstant[timeConstant[0].size() < timeConstant[1].size() ? 1 : 0].size();
    for ( uint16_t i = 0; i < bins; i++ ) {
      value[0][i] = timeConstant[0][i];
      value[1][i] = timeConstant[1][i];
    }
  } else if ( mon_ == sistrip::CALIBRATION_TIMECONSTANT) {
    with_error = true;
    value[0][0] = anal->timeConstantMean()[0];
    value[1][0] = anal->timeConstantMean()[1];
    error[0][0] = anal->timeConstantSpread()[0];
    error[1][0] = anal->timeConstantSpread()[1];
  } else if ( mon_ == sistrip::CALIBRATION_TIMECONSTANT_MIN) {
    value[0][0] = anal->timeConstantMin()[0];
    value[1][0] = anal->timeConstantMin()[1];
  } else if ( mon_ == sistrip::CALIBRATION_TIMECONSTANT_MAX) {
    value[0][0] = anal->timeConstantMax()[0];
    value[1][0] = anal->timeConstantMax()[1];
  } 
  // Turn-on
  else if ( mon_ == sistrip::CALIBRATION_TURNON_ALLSTRIPS) {
    all_strips = true;
    uint16_t bins = turnOn[turnOn[0].size() < turnOn[1].size() ? 1 : 0].size();
    for ( uint16_t i = 0; i < bins; i++ ) {
      value[0][i] = turnOn[0][i];
      value[1][i] = turnOn[1][i];
    }
  } else if ( mon_ == sistrip::CALIBRATION_TURNON) {
    with_error = true;
    value[0][0] = anal->turnOnMean()[0];
    value[1][0] = anal->turnOnMean()[1];
    error[0][0] = anal->turnOnSpread()[0];
    error[1][0] = anal->turnOnSpread()[1];
  } else if ( mon_ == sistrip::CALIBRATION_TURNON_MIN) {
    value[0][0] = anal->turnOnMin()[0];
    value[1][0] = anal->turnOnMin()[1];
  } else if ( mon_ == sistrip::CALIBRATION_TURNON_MAX) {
    value[0][0] = anal->turnOnMax()[0];
    value[1][0] = anal->turnOnMax()[1];

  } 
  // Maximum
  else if ( mon_ == sistrip::CALIBRATION_MAXIMUM_ALLSTRIPS) {
    all_strips = true;
    uint16_t bins = maximum[maximum[0].size() < maximum[1].size() ? 1 : 0].size();
    for ( uint16_t i = 0; i < bins; i++ ) {
      value[0][i] = maximum[0][i];
      value[1][i] = maximum[1][i];
    }
  } else if ( mon_ == sistrip::CALIBRATION_MAXIMUM) {
    with_error = true;
    value[0][0] = anal->maximumMean()[0];
    value[1][0] = anal->maximumMean()[1];
    error[0][0] = anal->maximumSpread()[0];
    error[1][0] = anal->maximumSpread()[1];
  } else if ( mon_ == sistrip::CALIBRATION_MAXIMUM_MIN) {
    value[0][0] = anal->maximumMin()[0];
    value[1][0] = anal->maximumMin()[1];
  } else if ( mon_ == sistrip::CALIBRATION_MAXIMUM_MAX) {
    value[0][0] = anal->maximumMax()[0];
    value[1][0] = anal->maximumMax()[1];

  }
  // Undershoot
  else if ( mon_ == sistrip::CALIBRATION_UNDERSHOOT_ALLSTRIPS) {
    all_strips = true;
    uint16_t bins = undershoot[undershoot[0].size() < undershoot[1].size() ? 1 : 0].size();
    for ( uint16_t i = 0; i < bins; i++ ) {
      value[0][i] = undershoot[0][i];
      value[1][i] = undershoot[1][i];
    }
  } else if ( mon_ == sistrip::CALIBRATION_UNDERSHOOT) {
    with_error = true;
    value[0][0] = anal->undershootMean()[0];
    value[1][0] = anal->undershootMean()[1];
    error[0][0] = anal->undershootSpread()[0];
    error[1][0] = anal->undershootSpread()[1];
  } else if ( mon_ == sistrip::CALIBRATION_UNDERSHOOT_MIN) {
    value[0][0] = anal->undershootMin()[0];
    value[1][0] = anal->undershootMin()[1];
  } else if ( mon_ == sistrip::CALIBRATION_UNDERSHOOT_MAX) {
    value[0][0] = anal->undershootMax()[0];
    value[1][0] = anal->undershootMax()[1];
    
  } 
  // Baseline
  else if ( mon_ == sistrip::CALIBRATION_BASELINE_ALLSTRIPS) {
    all_strips = true;
    uint16_t bins = baseline[baseline[0].size() < baseline[1].size() ? 1 : 0].size();
    for ( uint16_t i = 0; i < bins; i++ ) {
      value[0][i] = baseline[0][i];
      value[1][i] = baseline[1][i];
    }
  } else if ( mon_ == sistrip::CALIBRATION_BASELINE) {
    with_error = true;
    value[0][0] = anal->baselineMean()[0];
    value[1][0] = anal->baselineMean()[1];
    error[0][0] = anal->baselineSpread()[0];
    error[1][0] = anal->baselineSpread()[1];
  } else if ( mon_ == sistrip::CALIBRATION_BASELINE_MIN) {
    value[0][0] = anal->baselineMin()[0];
    value[1][0] = anal->baselineMin()[1];
  } else if ( mon_ == sistrip::CALIBRATION_BASELINE_MAX) {
    value[0][0] = anal->baselineMax()[0];
    value[1][0] = anal->baselineMax()[1];
  }
  
  // Smearing
  else if ( mon_ == sistrip::CALIBRATION_SMEARING_ALLSTRIPS) {
    all_strips = true;
    uint16_t bins = smearing[smearing[0].size() < smearing[1].size() ? 1 : 0].size();
    for ( uint16_t i = 0; i < bins; i++ ) {
      value[0][i] = smearing[0][i];
      value[1][i] = smearing[1][i];
    }
  }  
  else if ( mon_ == sistrip::CALIBRATION_SMEARING) {
    with_error = true;
    value[0][0] = anal->smearingMean()[0];
    value[1][0] = anal->smearingMean()[1];
    error[0][0] = anal->smearingSpread()[0];
    error[1][0] = anal->smearingSpread()[1];
  } else if ( mon_ == sistrip::CALIBRATION_SMEARING_MIN) {
    value[0][0] = anal->smearingMin()[0];
    value[1][0] = anal->smearingMin()[1];
  } else if ( mon_ == sistrip::CALIBRATION_SMEARING_MAX) {
    value[0][0] = anal->smearingMax()[0];
    value[1][0] = anal->smearingMax()[1];
  }   
  // Fit chi2
  else if ( mon_ == sistrip::CALIBRATION_CHI2_ALLSTRIPS) {
    all_strips = true;
    uint16_t bins = chi2[chi2[0].size() < chi2[1].size() ? 1 : 0].size();
    for ( uint16_t i = 0; i < bins; i++ ) {
      value[0][i] = chi2[0][i];
      value[1][i] = chi2[1][i];
    }
  }   
  else if ( mon_ == sistrip::CALIBRATION_CHI2) {
    with_error = true;
    value[0][0] = anal->chi2Mean()[0]/100.;
    value[1][0] = anal->chi2Mean()[1]/100.;
    error[0][0] = anal->chi2Spread()[0]/100.;
    error[1][0] = anal->chi2Spread()[1]/100.;
  } else if ( mon_ == sistrip::CALIBRATION_CHI2_MIN) {
    value[0][0] = anal->chi2Min()[0]/100.;
    value[1][0] = anal->chi2Min()[1]/100.;
  } else if ( mon_ == sistrip::CALIBRATION_CHI2_MAX) {
    value[0][0] = anal->chi2Max()[0]/100.;
    value[1][0] = anal->chi2Max()[1]/100.;
  } else { 
    edm::LogWarning(mlSummaryPlots_)
        << "[SummaryPlotFactory::" << __func__ << "]"
        << " Unexpected monitorable: "
        << SiStripEnumsAndStrings::monitorable( SummaryPlotFactoryBase::mon_ );
    return; 
  }

  if ( !all_strips ) {
    if( !with_error) {
      SummaryPlotFactoryBase::generator_->fillMap( SummaryPlotFactoryBase::level_,
                                                   SummaryPlotFactoryBase::gran_,
                           key1,
                           value[0][0] );
                         
      SummaryPlotFactoryBase::generator_->fillMap( SummaryPlotFactoryBase::level_,
                                                   SummaryPlotFactoryBase::gran_,
                           key2,
                           value[1][0] );
    } else {
      SummaryPlotFactoryBase::generator_->fillMap( SummaryPlotFactoryBase::level_,
                                                   SummaryPlotFactoryBase::gran_,
                           key1,
                           value[0][0],
                           error[0][0]);
                         
      SummaryPlotFactoryBase::generator_->fillMap( SummaryPlotFactoryBase::level_,
                                                   SummaryPlotFactoryBase::gran_,
                           key2,
                           value[1][0],
                           error[1][0]);
    }
  } else {
    
    for ( uint16_t istr = 0; istr < value[0].size(); istr++ ) {
      SummaryPlotFactoryBase::generator_->fillMap( SummaryPlotFactoryBase::level_,
                                                   SummaryPlotFactoryBase::gran_,
                           key1,
                           value[0][istr] );
    }
    
    for ( uint16_t istr = 0; istr < value[1].size(); istr++ ) {
      SummaryPlotFactoryBase::generator_->fillMap( SummaryPlotFactoryBase::level_,
                                                   SummaryPlotFactoryBase::gran_,
                           key2,
                           value[1][istr] );
    }
  }
}

void CalibrationSummaryFactory::format ( )

overrideprotectedvirtual

Reimplemented from SummaryPlotFactory< CommissioningAnalysis * >.

Definition at line 337 of file CalibrationSummaryFactory.cc.

References sistrip::CALIBRATION_AMPLITUDE, sistrip::CALIBRATION_BASELINE, sistrip::CALIBRATION_CHI2, sistrip::CALIBRATION_MAXIMUM, sistrip::CALIBRATION_RISETIME, sistrip::CALIBRATION_SMEARING, sistrip::CALIBRATION_TAIL, sistrip::CALIBRATION_TIMECONSTANT, sistrip::CALIBRATION_TURNON, sistrip::CALIBRATION_UNDERSHOOT, sistrip::mlSummaryPlots_, SummaryPlotFactoryBase::mon_, and SiStripEnumsAndStrings::monitorable().

                                       {

  // Histogram formatting
  // Histogram formatting
  if ( mon_ == sistrip::CALIBRATION_AMPLITUDE ) {
    generator_->axisLabel( "Amplitude (ADC*Nevt/10.)" );
  } else if ( mon_ == sistrip::CALIBRATION_TAIL ) { 
    generator_->axisLabel( "Tail (%)" );
  } else if ( mon_ == sistrip::CALIBRATION_RISETIME ) { 
    generator_->axisLabel( "Rise time (ns)" );
  } else if ( mon_ == sistrip::CALIBRATION_TIMECONSTANT ) { 
    generator_->axisLabel( "Time constant (ns)" );
  } else if ( mon_ == sistrip::CALIBRATION_TURNON ) { 
    generator_->axisLabel( "TrunOn (ns)" );
  } else if ( mon_ == sistrip::CALIBRATION_MAXIMUM ) { 
    generator_->axisLabel( "Maximum time (ns)" );
  } else if ( mon_ == sistrip::CALIBRATION_UNDERSHOOT ) { 
    generator_->axisLabel( "Undershoot (ADC*Nevt/10.)" );
  } else if ( mon_ == sistrip::CALIBRATION_BASELINE ) { 
    generator_->axisLabel( "Baseline Amplitude (ADC*Nevt/10.)" );
  } else if ( mon_ == sistrip::CALIBRATION_SMEARING ) { 
    generator_->axisLabel( "Smearing (ns)" );
  } else if ( mon_ == sistrip::CALIBRATION_CHI2 ) { 
    generator_->axisLabel( "Chi2/100." );
  } else { 
    edm::LogWarning(mlSummaryPlots_) 
      << "[SummaryPlotFactory::" << __func__ << "]"
      <<  " Unexpected SummaryHisto value:"
      << SiStripEnumsAndStrings::monitorable( SummaryPlotFactoryBase::mon_ ) ;
  }   
}