AlignmentMonitorMuonVsCurvature.cc

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/*
 * Package:     CommonAlignmentProducer
 * Class  :     AlignmentMonitorMuonVsCurvature
 *
 * Original Author:  Jim Pivarski
 *         Created:  Fri Feb 19 21:45:02 CET 2010
 *
 * $Id:$
 */

#include "Alignment/CommonAlignmentMonitor/interface/AlignmentMonitorPluginFactory.h"
#include "Alignment/CommonAlignmentMonitor/interface/AlignmentMonitorBase.h"
#include "Alignment/MuonAlignmentAlgorithms/interface/MuonResidualsFromTrack.h"

#include "FWCore/ParameterSet/interface/ParameterSet.h"
#include "FWCore/Utilities/interface/InputTag.h"
#include "FWCore/MessageLogger/interface/MessageLogger.h"
#include "FWCore/Framework/interface/EventSetup.h"
#include "Geometry/CommonDetUnit/interface/GlobalTrackingGeometry.h"
#include "Geometry/Records/interface/GlobalTrackingGeometryRecord.h"

#include <sstream>
#include "TProfile.h"
#include "TH2F.h"
#include "TH1F.h"

#include "TrackingTools/Records/interface/TrackingComponentsRecord.h"
#include "TrackingTools/Records/interface/DetIdAssociatorRecord.h"
#include "TrackingTools/GeomPropagators/interface/Propagator.h"
#include "TrackingTools/TrackAssociator/interface/DetIdAssociator.h"
#include "MagneticField/Records/interface/IdealMagneticFieldRecord.h"
#include "MagneticField/Engine/interface/MagneticField.h"

class AlignmentMonitorMuonVsCurvature : public AlignmentMonitorBase {
public:
  AlignmentMonitorMuonVsCurvature(const edm::ParameterSet &cfg, edm::ConsumesCollector iC);
  ~AlignmentMonitorMuonVsCurvature() override {}

  void book() override;

  void event(const edm::Event &iEvent,
             const edm::EventSetup &iSetup,
             const ConstTrajTrackPairCollection &iTrajTracks) override;
  void processMuonResidualsFromTrack(MuonResidualsFromTrack &mrft, const Trajectory *traj = nullptr);

private:
  // es token
  const edm::ESGetToken<GlobalTrackingGeometry, GlobalTrackingGeometryRecord> m_esTokenGBTGeom;
  const edm::ESGetToken<DetIdAssociator, DetIdAssociatorRecord> m_esTokenDetId;
  const edm::ESGetToken<Propagator, TrackingComponentsRecord> m_esTokenProp;
  const edm::ESGetToken<MagneticField, IdealMagneticFieldRecord> m_esTokenMF;
  const MuonResidualsFromTrack::BuilderToken m_esTokenBuilder;

  // parameters
  edm::InputTag m_muonCollectionTag;
  double m_minTrackPt;
  double m_minTrackP;
  int m_minTrackerHits;
  double m_maxTrackerRedChi2;
  bool m_allowTIDTEC;
  bool m_minNCrossedChambers;
  double m_maxDxy;
  int m_minDT13Hits;
  int m_minDT2Hits;
  int m_minCSCHits;
  int m_layer;
  std::string m_propagator;
  bool m_doDT;
  bool m_doCSC;

  enum { kDeltaX = 0, kDeltaDxDz, kNumComponents };

  // DT [wheel][station][sector]
  TH2F *th2f_wheel_st_sector[5][4][14][kNumComponents];
  TProfile *tprofile_wheel_st_sector[5][4][14][kNumComponents];

  // CSC [endcap*station][ring][chamber]
  TH2F *th2f_st_ring_chamber[8][3][36][kNumComponents];
  TProfile *tprofile_st_ring_chamber[8][3][36][kNumComponents];

  TH1F *th1f_trackerRedChi2;
  TH1F *th1f_trackerRedChi2Diff;
};

AlignmentMonitorMuonVsCurvature::AlignmentMonitorMuonVsCurvature(const edm::ParameterSet &cfg,
                                                                 edm::ConsumesCollector iC)
    : AlignmentMonitorBase(cfg, iC, "AlignmentMonitorMuonVsCurvature"),
      m_esTokenGBTGeom(iC.esConsumes()),
      m_esTokenDetId(iC.esConsumes(edm::ESInputTag("", "MuonDetIdAssociator"))),
      m_esTokenProp(iC.esConsumes(edm::ESInputTag("", "SteppingHelixPropagatorAny"))),
      m_esTokenMF(iC.esConsumes()),
      m_esTokenBuilder(iC.esConsumes(MuonResidualsFromTrack::builderESInputTag())),
      m_muonCollectionTag(cfg.getParameter<edm::InputTag>("muonCollectionTag")),
      m_minTrackPt(cfg.getParameter<double>("minTrackPt")),
      m_minTrackP(cfg.getParameter<double>("minTrackP")),
      m_minTrackerHits(cfg.getParameter<int>("minTrackerHits")),
      m_maxTrackerRedChi2(cfg.getParameter<double>("maxTrackerRedChi2")),
      m_allowTIDTEC(cfg.getParameter<bool>("allowTIDTEC")),
      m_minNCrossedChambers(cfg.getParameter<int>("minNCrossedChambers")),
      m_maxDxy(cfg.getParameter<double>("maxDxy")),
      m_minDT13Hits(cfg.getParameter<int>("minDT13Hits")),
      m_minDT2Hits(cfg.getParameter<int>("minDT2Hits")),
      m_minCSCHits(cfg.getParameter<int>("minCSCHits")),
      m_layer(cfg.getParameter<int>("layer")),
      m_propagator(cfg.getParameter<std::string>("propagator")),
      m_doDT(cfg.getParameter<bool>("doDT")),
      m_doCSC(cfg.getParameter<bool>("doCSC")) {}

void AlignmentMonitorMuonVsCurvature::book() {
  // DT
  std::string wheelname[5] = {"wheelm2_", "wheelm1_", "wheelz_", "wheelp1_", "wheelp2_"};
  if (m_doDT)
    for (int wheel = -2; wheel <= 2; wheel++)
      for (int station = 1; station <= 4; station++)
        for (int sector = 1; sector <= 14; sector++) {
          if (station != 4 && sector > 12)
            continue;

          char stationname[20];
          sprintf(stationname, "st%d_", station);

          char sectorname[20];
          sprintf(sectorname, "sector%02d_", sector);

          for (int component = 0; component < kNumComponents; component++) {
            std::stringstream th2f_name, tprofile_name;
            th2f_name << "th2f_" << wheelname[wheel + 2] << stationname << sectorname;
            tprofile_name << "tprofile_" << wheelname[wheel + 2] << stationname << sectorname;

            double yminmax = 50., xminmax = 0.05;
            if (m_minTrackPt > 0.)
              xminmax = 1. / m_minTrackPt;
            int ynbins = 50;
            if (component == kDeltaX) {
              th2f_name << "deltax";
              tprofile_name << "deltax";
            } else if (component == kDeltaDxDz) {
              th2f_name << "deltadxdz";
              tprofile_name << "deltadxdz";
            }

            th2f_wheel_st_sector[wheel + 2][station - 1][sector - 1][component] =
                book2D("/iterN/", th2f_name.str(), "", 30, -xminmax, xminmax, ynbins, -yminmax, yminmax);
            tprofile_wheel_st_sector[wheel + 2][station - 1][sector - 1][component] =
                bookProfile("/iterN/", tprofile_name.str(), "", 30, -xminmax, xminmax);
          }
        }

  // CSC
  std::string stname[8] = {"Ep_S1_", "Ep_S2_", "Ep_S3_", "Ep_S4_", "Em_S1_", "Em_S2_", "Em_S3_", "Em_S4_"};
  if (m_doCSC)
    for (int station = 0; station < 8; station++)
      for (int ring = 1; ring <= 3; ring++)
        for (int chamber = 1; chamber <= 36; chamber++) {
          int st = station % 4 + 1;
          if (st > 1 && ring > 2)
            continue;  // only station 1 has more then 2 rings
          if (st > 1 && ring == 1 && chamber > 18)
            continue;  // ring 1 stations 1,2,3 have 18 chambers

          char ringname[20];
          sprintf(ringname, "R%d_", ring);

          char chname[20];
          sprintf(chname, "C%02d_", chamber);

          for (int component = 0; component < kNumComponents; component++) {
            std::stringstream componentname;
            double yminmax = 50., xminmax = 0.05;
            if (m_minTrackPt > 0.)
              xminmax = 1. / m_minTrackPt;
            if (ring == 1)
              xminmax *= 0.5;
            if (component == kDeltaX) {
              componentname << "deltax";
            } else if (component == kDeltaDxDz) {
              componentname << "deltadxdz";
            }

            std::stringstream th2f_name, tprofile_name;
            th2f_name << "th2f_" << stname[station] << ringname << chname << componentname.str();
            tprofile_name << "tprofile_" << stname[station] << ringname << chname << componentname.str();

            th2f_st_ring_chamber[station][ring - 1][chamber - 1][component] =
                book2D("/iterN/", th2f_name.str(), "", 30, -xminmax, xminmax, 100, -yminmax, yminmax);
            tprofile_st_ring_chamber[station][ring - 1][chamber - 1][component] =
                bookProfile("/iterN/", tprofile_name.str(), "", 30, -xminmax, xminmax);
          }
        }

  th1f_trackerRedChi2 = book1D("/iterN/", "trackerRedChi2", "Refit tracker reduced chi^2", 100, 0., 30.);
  th1f_trackerRedChi2Diff =
      book1D("/iterN/", "trackerRedChi2Diff", "Fit-minus-refit tracker reduced chi^2", 100, -5., 5.);
}

void AlignmentMonitorMuonVsCurvature::event(const edm::Event &iEvent,
                                            const edm::EventSetup &iSetup,
                                            const ConstTrajTrackPairCollection &trajtracks) {
  edm::Handle<reco::BeamSpot> beamSpot;
  iEvent.getByLabel(m_beamSpotTag, beamSpot);

  const GlobalTrackingGeometry *globalGeometry = &iSetup.getData(m_esTokenGBTGeom);
  const DetIdAssociator *muonDetIdAssociator_ = &iSetup.getData(m_esTokenDetId);
  const Propagator *prop = &iSetup.getData(m_esTokenProp);
  const MagneticField *magneticField = &iSetup.getData(m_esTokenMF);
  auto builder = iSetup.getHandle(m_esTokenBuilder);

  if (m_muonCollectionTag.label().empty())  // use trajectories
  {
    for (ConstTrajTrackPairCollection::const_iterator trajtrack = trajtracks.begin(); trajtrack != trajtracks.end();
         ++trajtrack) {
      const Trajectory *traj = (*trajtrack).first;
      const reco::Track *track = (*trajtrack).second;

      if (track->pt() > m_minTrackPt && track->p() > m_minTrackP && fabs(track->dxy(beamSpot->position())) < m_maxDxy) {
        MuonResidualsFromTrack muonResidualsFromTrack(
            builder, magneticField, globalGeometry, muonDetIdAssociator_, prop, traj, track, pNavigator(), 1000.);
        processMuonResidualsFromTrack(muonResidualsFromTrack, traj);
      }  // end if track pT is within range
    }    // end loop over tracks
  } else {
    edm::Handle<reco::MuonCollection> muons;
    iEvent.getByLabel(m_muonCollectionTag, muons);

    for (reco::MuonCollection::const_iterator muon = muons->begin(); muon != muons->end(); ++muon) {
      if (!(muon->isTrackerMuon() && muon->innerTrack().isNonnull()))
        continue;

      if (m_minTrackPt < muon->pt() && m_minTrackP < muon->p() &&
          fabs(muon->innerTrack()->dxy(beamSpot->position())) < m_maxDxy) {
        MuonResidualsFromTrack muonResidualsFromTrack(globalGeometry, &(*muon), pNavigator(), 100.);
        processMuonResidualsFromTrack(muonResidualsFromTrack);
      }
    }
  }
}

void AlignmentMonitorMuonVsCurvature::processMuonResidualsFromTrack(MuonResidualsFromTrack &mrft,
                                                                    const Trajectory *traj) {
  if (mrft.trackerNumHits() < m_minTrackerHits)
    return;
  if (!m_allowTIDTEC && mrft.contains_TIDTEC())
    return;

  int nMuChambers = 0;
  std::vector<DetId> chamberIds = mrft.chamberIds();
  for (unsigned ch = 0; ch < chamberIds.size(); ch++)
    if (chamberIds[ch].det() == DetId::Muon)
      nMuChambers++;
  if (nMuChambers < m_minNCrossedChambers)
    return;

  th1f_trackerRedChi2->Fill(mrft.trackerRedChi2());
  th1f_trackerRedChi2Diff->Fill(mrft.getTrack()->normalizedChi2() - mrft.trackerRedChi2());

  if (mrft.normalizedChi2() > m_maxTrackerRedChi2)
    return;

  double qoverpt = mrft.getTrack()->charge() / mrft.getTrack()->pt();
  double qoverpz = 0.;
  if (fabs(mrft.getTrack()->pz()) > 0.01)
    qoverpz = mrft.getTrack()->charge() / fabs(mrft.getTrack()->pz());

  for (std::vector<DetId>::const_iterator chamberId = chamberIds.begin(); chamberId != chamberIds.end(); ++chamberId) {
    if (chamberId->det() != DetId::Muon)
      continue;

    if (m_doDT && chamberId->subdetId() == MuonSubdetId::DT) {
      DTChamberId dtid(chamberId->rawId());
      MuonChamberResidual *dt13 = mrft.chamberResidual(*chamberId, MuonChamberResidual::kDT13);

      if (dt13 != nullptr && dt13->numHits() >= m_minDT13Hits) {
        int wheel = dtid.wheel() + 2;
        int station = dtid.station() - 1;
        int sector = dtid.sector() - 1;

        double resid_x = 10. * dt13->global_residual();
        double resid_dxdz = 1000. * dt13->global_resslope();

        if (fabs(resid_x) < 100. && fabs(resid_dxdz) < 100.) {
          th2f_wheel_st_sector[wheel][station][sector][kDeltaX]->Fill(qoverpt, resid_x);
          tprofile_wheel_st_sector[wheel][station][sector][kDeltaX]->Fill(qoverpt, resid_x);
          th2f_wheel_st_sector[wheel][station][sector][kDeltaDxDz]->Fill(qoverpt, resid_dxdz);
          tprofile_wheel_st_sector[wheel][station][sector][kDeltaDxDz]->Fill(qoverpt, resid_dxdz);
        }
      }  // if it's a good segment
    }    // if DT

    if (m_doCSC && chamberId->subdetId() == MuonSubdetId::CSC) {
      CSCDetId cscid(chamberId->rawId());
      MuonChamberResidual *csc = mrft.chamberResidual(*chamberId, MuonChamberResidual::kCSC);

      if (csc != nullptr && csc->numHits() >= m_minCSCHits) {
        int station = 4 * cscid.endcap() + cscid.station() - 5;
        int ring = cscid.ring() - 1;
        if (cscid.station() == 1 && cscid.ring() == 4)
          ring = 0;  // join ME1/a to ME1/b
        int chamber = cscid.chamber() - 1;

        double resid_x = 10. * csc->global_residual();
        double resid_dxdz = 1000. * csc->global_resslope();

        if (fabs(resid_x) < 100. && fabs(resid_dxdz) < 100.) {
          th2f_st_ring_chamber[station][ring][chamber][kDeltaX]->Fill(qoverpz, resid_x);
          tprofile_st_ring_chamber[station][ring][chamber][kDeltaX]->Fill(qoverpz, resid_x);
          th2f_st_ring_chamber[station][ring][chamber][kDeltaDxDz]->Fill(qoverpz, resid_dxdz);
          tprofile_st_ring_chamber[station][ring][chamber][kDeltaDxDz]->Fill(qoverpz, resid_dxdz);
        }
      }  // if it's a good segment
    }    // if CSC

  }  // end loop over chamberIds
}

DEFINE_EDM_PLUGIN(AlignmentMonitorPluginFactory, AlignmentMonitorMuonVsCurvature, "AlignmentMonitorMuonVsCurvature");