d1/dd4/FedTimingAlgorithm_8cc_source.html

 #include "DQM/SiStripCommissioningAnalysis/interface/FedTimingAlgorithm.h"

 #include "CondFormats/SiStripObjects/interface/FedTimingAnalysis.h"

 #include "DataFormats/SiStripCommon/interface/SiStripHistoTitle.h"

 #include "DataFormats/SiStripCommon/interface/SiStripEnumsAndStrings.h"

 #include "FWCore/MessageLogger/interface/MessageLogger.h"

 #include "TProfile.h"

 #include "TH1.h"

 #include <iostream>

 #include <iomanip>

 #include <cmath>


 using namespace sistrip;


 // ----------------------------------------------------------------------------

 //

 FedTimingAlgorithm::FedTimingAlgorithm(const edm::ParameterSet& pset, FedTimingAnalysis* const anal)

     : CommissioningAlgorithm(anal), histo_(nullptr, "") {

   ;

 }


 // ----------------------------------------------------------------------------

 //

 void FedTimingAlgorithm::extract(const std::vector<TH1*>& histos) {

   if (!anal()) {

     edm::LogWarning(mlCommissioning_) << "[FedTimingAlgorithm::" << __func__ << "]"

                                       << " NULL pointer to Analysis object!";

     return;

   }


   // Check number of histograms

   if (histos.size() != 1) {

     anal()->addErrorCode(sistrip::numberOfHistos_);

   }


   // Extract FED key from histo title

   if (!histos.empty()) {

     anal()->fedKey(extractFedKey(histos.front()));

   }


   // Extract histograms

   std::vector<TH1*>::const_iterator ihis = histos.begin();

   for (; ihis != histos.end(); ihis++) {

     // Check for NULL pointer

     if (!(*ihis)) {

       continue;

     }


     // Check name

     SiStripHistoTitle title((*ihis)->GetName());

     if (title.runType() != sistrip::FED_TIMING) {

       anal()->addErrorCode(sistrip::unexpectedTask_);

       continue;

     }


     // Extract timing histo

     histo_.first = *ihis;

     histo_.second = (*ihis)->GetName();

   }

 }


 // ----------------------------------------------------------------------------

 //

 void FedTimingAlgorithm::analyse() {

   if (!anal()) {

     edm::LogWarning(mlCommissioning_) << "[FedTimingAlgorithm::" << __func__ << "]"

                                       << " NULL pointer to base Analysis object!";

     return;

   }


   CommissioningAnalysis* tmp = const_cast<CommissioningAnalysis*>(anal());

   FedTimingAnalysis* anal = dynamic_cast<FedTimingAnalysis*>(tmp);

   if (!anal) {

     edm::LogWarning(mlCommissioning_) << "[FedTimingAlgorithm::" << __func__ << "]"

                                       << " NULL pointer to derived Analysis object!";

     return;

   }


   if (!histo_.first) {

     anal->addErrorCode(sistrip::nullPtr_);

     return;

   }


   // Transfer histogram contents/errors/stats to containers

   uint16_t non_zero = 0;

   float max = -1.e9;

   float min = 1.e9;

   uint16_t nbins = static_cast<uint16_t>(histo_.first->GetNbinsX());

   std::vector<float> bin_contents;

   std::vector<float> bin_errors;

   std::vector<float> bin_entries;

   bin_contents.reserve(nbins);

   bin_errors.reserve(nbins);

   bin_entries.reserve(nbins);

   for (uint16_t ibin = 0; ibin < nbins; ibin++) {

     bin_contents.push_back(histo_.first->GetBinContent(ibin + 1));

     bin_errors.push_back(histo_.first->GetBinError(ibin + 1));

     //bin_entries.push_back( histo_.first->GetBinEntries(ibin+1) );

     if (bin_entries[ibin]) {

       if (bin_contents[ibin] > max) {

         max = bin_contents[ibin];

       }

       if (bin_contents[ibin] < min) {

         min = bin_contents[ibin];

       }

       non_zero++;

     }

   }


   //LogTrace(mlCommissioning_) << " Number of bins with non-zero entries: " << non_zero;

   if (bin_contents.size() < 100) {

     anal->addErrorCode(sistrip::numberOfBins_);

     return;

   }


   // Calculate range (max-min) and threshold level (range/2)

   float range = max - min;

   float threshold = min + range / 2.;

   if (range < 50.) {

     anal->addErrorCode(sistrip::smallDataRange_);

     return;

   }

   //LogTrace(mlCommissioning_) << " ADC samples: max/min/range/threshold: "

   //<< max << "/" << min << "/" << range << "/" << threshold;


   // Associate samples with either "tick mark" or "baseline"

   std::vector<float> tick;

   std::vector<float> base;

   for (uint16_t ibin = 0; ibin < nbins; ibin++) {

     if (bin_entries[ibin]) {

       if (bin_contents[ibin] < threshold) {

         base.push_back(bin_contents[ibin]);

       } else {

         tick.push_back(bin_contents[ibin]);

       }

     }

   }

   //LogTrace(mlCommissioning_) << " Number of 'tick mark' samples: " << tick.size()

   //<< " Number of 'baseline' samples: " << base.size();


   // Find median level of tick mark and baseline

   float tickmark = 0.;

   float baseline = 0.;

   sort(tick.begin(), tick.end());

   sort(base.begin(), base.end());

   if (!tick.empty()) {

     tickmark = tick[tick.size() % 2 ? tick.size() / 2 : tick.size() / 2];

   }

   if (!base.empty()) {

     baseline = base[base.size() % 2 ? base.size() / 2 : base.size() / 2];

   }

   //LogTrace(mlCommissioning_) << " Tick mark level: " << tickmark << " Baseline level: " << baseline

   //<< " Range: " << (tickmark-baseline);

   if ((tickmark - baseline) < 50.) {

     anal->addErrorCode(sistrip::smallDataRange_);

     return;

   }


   // Find rms spread in "baseline" samples

   float mean = 0.;

   float mean2 = 0.;

   for (uint16_t ibin = 0; ibin < base.size(); ibin++) {

     mean += base[ibin];

     mean2 += base[ibin] * base[ibin];

   }

   if (!base.empty()) {

     mean = mean / base.size();

     mean2 = mean2 / base.size();

   } else {

     mean = 0.;

     mean2 = 0.;

   }

   float baseline_rms = 0.;

   if (mean2 > mean * mean) {

     baseline_rms = sqrt(mean2 - mean * mean);

   } else {

     baseline_rms = 0.;

   }

   //LogTrace(mlCommissioning_) << " Spread in baseline samples: " << baseline_rms;


   // Find rising edges (derivative across two bins > range/2)

   std::map<uint16_t, float> edges;

   for (uint16_t ibin = 1; ibin < nbins - 1; ibin++) {

     if (bin_entries[ibin + 1] && bin_entries[ibin - 1]) {

       float derivative = bin_contents[ibin + 1] - bin_contents[ibin - 1];

       if (derivative > 5. * baseline_rms) {

         edges[ibin] = derivative;

         //LogTrace(mlCommissioning_) << " Found edge #" << edges.size() << " at bin " << ibin

         //<< " and with derivative " << derivative;

       }

     }

   }


   // Iterate through "edges" std::map

   bool found = false;

   uint16_t deriv_bin = sistrip::invalid_;

   float max_deriv = -1. * sistrip::invalid_;

   std::map<uint16_t, float>::iterator iter = edges.begin();

   while (!found && iter != edges.end()) {

     // Iterate through 50 subsequent samples

     bool valid = true;

     for (uint16_t ii = 0; ii < 50; ii++) {

       uint16_t bin = iter->first + ii;


       // Calc local derivative

       float temp_deriv = 0;

       if (static_cast<uint32_t>(bin) < 1 || static_cast<uint32_t>(bin + 1) >= nbins) {

         continue;

       }

       temp_deriv = bin_contents[bin + 1] - bin_contents[bin - 1];


       // Store max derivative

       if (temp_deriv > max_deriv) {

         max_deriv = temp_deriv;

         deriv_bin = bin;

       }


       // Check if samples following edge are all "high"

       if (ii > 10 && ii < 40 && bin_entries[bin] && bin_contents[bin] < baseline + 5 * baseline_rms) {

         valid = false;

       }

     }


     // Break from loop if tick mark found

     if (valid) {

       found = true;

     } else {

       max_deriv = -1. * sistrip::invalid_;

       deriv_bin = sistrip::invalid_;

       edges.erase(iter);

     }


     iter++;

   }


   // Set monitorables (but not PLL coarse and fine here)

   if (!edges.empty()) {

     anal->time_ = deriv_bin;

     anal->error_ = 0.;

     anal->base_ = baseline;

     anal->peak_ = tickmark;

     anal->height_ = tickmark - baseline;

   } else {

     anal->addErrorCode(sistrip::missingTickMark_);

     anal->base_ = baseline;

     anal->peak_ = tickmark;

     anal->height_ = tickmark - baseline;

   }

 }

newFWLiteAna.base
tuple base
Main Program
Definition: newFWLiteAna.py:92

sistrip::unexpectedTask_
static const char unexpectedTask_[]
Definition: ConstantsForCommissioningAnalysis.h:21

FedTimingAnalysis::error_
float error_
Definition: FedTimingAnalysis.h:57

CommissioningAnalysis::fedKey
const uint32_t & fedKey() const
Definition: CommissioningAnalysis.h:134

funct::derivative
Derivative< X, A >::type derivative(const A &_)
Definition: Derivative.h:18

MessageLogger.h

SiStripHistoTitle
Utility class that holds histogram title.
Definition: SiStripHistoTitle.h:20

SiStripEnumsAndStrings.h

sistrip::numberOfHistos_
static const char numberOfHistos_[]
Definition: ConstantsForCommissioningAnalysis.h:16

TrackValidation_cff.pset
tuple pset
Definition: TrackValidation_cff.py:591

SiStripPI::mean
Definition: SiStripPayloadInspectorHelper.h:169

cuy.ii
int ii
Definition: cuy.py:589

sistrip::numberOfBins_
static const char numberOfBins_[]
Definition: ConstantsForCommissioningAnalysis.h:18

FedTimingAlgorithm::analyse
void analyse() override
Definition: FedTimingAlgorithm.cc:63

sistrip::SpyUtilities::range
const uint16_t range(const Frame &aFrame)
Definition: SiStripSpyUtilities.cc:76

CommissioningAlgorithm::extractFedKey
uint32_t extractFedKey(const TH1 *const)
Definition: CommissioningAlgorithm.cc:29

FedTimingAnalysis::time_
float time_
Definition: FedTimingAnalysis.h:48

FedTimingAnalysis::height_
float height_
Definition: FedTimingAnalysis.h:66

sistrip::missingTickMark_
static const char missingTickMark_[]
Definition: ConstantsForCommissioningAnalysis.h:40

newFWLiteAna.bin
string bin
Definition: newFWLiteAna.py:161

FedTimingAlgorithm::extract
void extract(const std::vector< TH1 * > &) override
Definition: FedTimingAlgorithm.cc:23

sistrip::mlCommissioning_
static const char mlCommissioning_[]
Definition: ConstantsForLogger.h:15

mathSSE::sqrt
T sqrt(T t)
Definition: SSEVec.h:19

FedTimingAnalysis::peak_
float peak_
Definition: FedTimingAnalysis.h:63

FedTimingAnalysis::base_
float base_
Definition: FedTimingAnalysis.h:60

CommissioningAnalysis::addErrorCode
virtual void addErrorCode(const std::string &error)
Definition: CommissioningAnalysis.h:148

dtDQMClient_cfg.threshold
tuple threshold
Definition: dtDQMClient_cfg.py:15

min
T min(T a, T b)
Definition: MathUtil.h:58

FedTimingAnalysis
Analysis for timing run using APV tick marks.
Definition: FedTimingAnalysis.h:16

SiStripPI::max
Definition: SiStripPayloadInspectorHelper.h:169

FedTimingAnalysis.h

CommissioningAlgorithm
Definition: CommissioningAlgorithm.h:17

FedTimingAlgorithm::histo_
Histo histo_
Definition: FedTimingAlgorithm.h:34

sistrip::invalid_
static const uint16_t invalid_
Definition: Constants.h:16

SiStripHistoTitle.h

FedTimingAlgorithm::FedTimingAlgorithm
FedTimingAlgorithm()
Definition: FedTimingAlgorithm.h:26

sistrip::smallDataRange_
static const char smallDataRange_[]
Definition: ConstantsForCommissioningAnalysis.h:38

runGCPTkAlMap.title
string title
Definition: runGCPTkAlMap.py:94

FedTimingAlgorithm.h

mergeVDriftHistosByStation.histos
dictionary histos
Definition: mergeVDriftHistosByStation.py:61

edm::ParameterSet
Definition: ParameterSet.h:47

hlt_dqm_clientPB-live_cfg.nbins
tuple nbins
Definition: hlt_dqm_clientPB-live_cfg.py:50

CommissioningAnalysis
Abstract base for derived classes that provide analysis of commissioning histograms.
Definition: CommissioningAnalysis.h:18

edm::LogWarning
Log< level::Warning, false > LogWarning
Definition: MessageLogger.h:122

createJobs.tmp
tmp
align.sh
Definition: createJobs.py:716

newFWLiteAna.found
found
Definition: newFWLiteAna.py:118

sistrip::FED_TIMING
Definition: ConstantsForRunType.h:80

CommissioningAlgorithm::anal
CommissioningAnalysis *const anal() const
Definition: CommissioningAlgorithm.h:50

sistrip::nullPtr_
static const char nullPtr_[]
Definition: ConstantsForCommissioningAnalysis.h:17