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Public Member Functions | |
| void | afterAlignment (const edm::EventSetup &iSetup) |
| AlignmentMonitorSegmentDifferences (const edm::ParameterSet &cfg) | |
| void | book () |
| Book or retrieve histograms; MUST be reimplemented. | |
| void | event (const edm::Event &iEvent, const edm::EventSetup &iSetup, const ConstTrajTrackPairCollection &iTrajTracks) |
| Called for each event (by "run()"): may be reimplemented. | |
| void | processMuonResidualsFromTrack (MuonResidualsFromTrack &mrft) |
| ~AlignmentMonitorSegmentDifferences () | |
Private Attributes | |
| bool | m_allowTIDTEC |
| TProfile * | m_cscinner_resid [2][18][3] |
| TProfile * | m_cscinner_slope [2][18][3] |
| TProfile * | m_cscouter_resid [2][36][2] |
| TProfile * | m_cscouter_slope [2][36][2] |
| bool | m_doCSC |
| bool | m_doDT |
| TProfile * | m_dt13_resid [5][12][3] |
| TProfile * | m_dt13_slope [5][12][3] |
| TProfile * | m_dt2_resid [5][12][2] |
| TProfile * | m_dt2_slope [5][12][2] |
| double | m_maxDxy |
| double | m_maxTrackerRedChi2 |
| int | m_minCSCHits |
| int | m_minDT13Hits |
| int | m_minDT2Hits |
| bool | m_minNCrossedChambers |
| int | m_minTrackerHits |
| double | m_minTrackP |
| double | m_minTrackPt |
| edm::InputTag | m_muonCollectionTag |
| TH1F * | m_negcscinner_resid [2][18][3] |
| TH1F * | m_negcscinner_slope [2][18][3] |
| TH1F * | m_negcscouter_resid [2][36][2] |
| TH1F * | m_negcscouter_slope [2][36][2] |
| TH1F * | m_negdt13_resid [5][12][3] |
| TH1F * | m_negdt13_slope [5][12][3] |
| TH1F * | m_negdt2_resid [5][12][2] |
| TH1F * | m_negdt2_slope [5][12][2] |
| TH1F * | m_poscscinner_resid [2][18][3] |
| TH1F * | m_poscscinner_slope [2][18][3] |
| TH1F * | m_poscscouter_resid [2][36][2] |
| TH1F * | m_poscscouter_slope [2][36][2] |
| TH1F * | m_posdt13_resid [5][12][3] |
| TH1F * | m_posdt13_slope [5][12][3] |
| TH1F * | m_posdt2_resid [5][12][2] |
| TH1F * | m_posdt2_slope [5][12][2] |
| TH1F * | m_x_neg_dt1_csc1_resid [2][12] |
| TH1F * | m_x_neg_dt1_csc2_resid [2][12] |
| TH1F * | m_x_neg_dt2_csc1_resid [2][12] |
| TH1F * | m_x_pos_dt1_csc1_resid [2][12] |
| TH1F * | m_x_pos_dt1_csc2_resid [2][12] |
| TH1F * | m_x_pos_dt2_csc1_resid [2][12] |
Definition at line 28 of file AlignmentMonitorSegmentDifferences.cc.
| AlignmentMonitorSegmentDifferences::AlignmentMonitorSegmentDifferences | ( | const edm::ParameterSet & | cfg | ) |
Definition at line 106 of file AlignmentMonitorSegmentDifferences.cc.
: AlignmentMonitorBase(cfg, "AlignmentMonitorSegmentDifferences") , m_muonCollectionTag(cfg.getParameter<edm::InputTag>("muonCollectionTag")) , m_minTrackPt(cfg.getParameter<double>("minTrackPt")) , m_minTrackP(cfg.getParameter<double>("minTrackP")) , m_maxDxy(cfg.getParameter<double>("maxDxy")) , 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_minDT13Hits(cfg.getParameter<int>("minDT13Hits")) , m_minDT2Hits(cfg.getParameter<int>("minDT2Hits")) , m_minCSCHits(cfg.getParameter<int>("minCSCHits")) , m_doDT(cfg.getParameter<bool>("doDT")) , m_doCSC(cfg.getParameter<bool>("doCSC")) { }
| AlignmentMonitorSegmentDifferences::~AlignmentMonitorSegmentDifferences | ( | ) | [inline] |
Definition at line 32 of file AlignmentMonitorSegmentDifferences.cc.
{}
| void AlignmentMonitorSegmentDifferences::afterAlignment | ( | const edm::EventSetup & | iSetup | ) | [inline, virtual] |
Called after updating AlignableTracker and AlignableMuon (by "endOfLoop()"): may be reimplemented
Reimplemented from AlignmentMonitorBase.
Definition at line 39 of file AlignmentMonitorSegmentDifferences.cc.
{}
| void AlignmentMonitorSegmentDifferences::book | ( | ) | [virtual] |
Book or retrieve histograms; MUST be reimplemented.
Implements AlignmentMonitorBase.
Definition at line 124 of file AlignmentMonitorSegmentDifferences.cc.
References AlignmentMonitorBase::book1D(), AlignmentMonitorBase::bookProfile(), alignCSCRings::e, Reference_intrackfit_cff::endcap, m_cscinner_resid, m_cscinner_slope, m_cscouter_resid, m_cscouter_slope, m_doCSC, m_doDT, m_dt13_resid, m_dt13_slope, m_dt2_resid, m_dt2_slope, m_minTrackPt, m_negcscinner_resid, m_negcscinner_slope, m_negcscouter_resid, m_negcscouter_slope, m_negdt13_resid, m_negdt13_slope, m_negdt2_resid, m_negdt2_slope, m_poscscinner_resid, m_poscscinner_slope, m_poscscouter_resid, m_poscscouter_slope, m_posdt13_resid, m_posdt13_slope, m_posdt2_resid, m_posdt2_slope, m_x_neg_dt1_csc1_resid, m_x_neg_dt1_csc2_resid, m_x_neg_dt2_csc1_resid, m_x_pos_dt1_csc1_resid, m_x_pos_dt1_csc2_resid, m_x_pos_dt2_csc1_resid, mergeVDriftHistosByStation::name, neg, pos, alignCSCRings::s, and AlCaHLTBitMon_QueryRunRegistry::string.
{
char name[222], pos[222], neg[222];
double max_curv = 1./m_minTrackPt;
if (m_doDT) for (int wheel = -2; wheel <= +2; wheel++)
{
char wheel_label[][2]={"A","B","C","D","E"};
for (int sector = 1; sector <= 12; sector++)
{
char wheel_sector[50];
sprintf(wheel_sector,"%s_%02d", wheel_label[wheel+2], sector );
int nb = 100;
double wnd = 25.;
sprintf(name, "dt13_resid_%s_12", wheel_sector);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_dt13_resid[wheel+2][sector-1][0] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -100., 100., " ");
m_posdt13_resid[wheel+2][sector-1][0] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negdt13_resid[wheel+2][sector-1][0] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(name, "dt13_resid_%s_23", wheel_sector);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_dt13_resid[wheel+2][sector-1][1] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -100., 100., " ");
m_posdt13_resid[wheel+2][sector-1][1] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negdt13_resid[wheel+2][sector-1][1] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(name, "dt13_resid_%s_34", wheel_sector);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_dt13_resid[wheel+2][sector-1][2] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -100., 100., " ");
m_posdt13_resid[wheel+2][sector-1][2] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negdt13_resid[wheel+2][sector-1][2] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(name, "dt2_resid_%s_12", wheel_sector);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_dt2_resid[wheel+2][sector-1][0] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -200., 200., " ");
m_posdt2_resid[wheel+2][sector-1][0] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negdt2_resid[wheel+2][sector-1][0] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(name, "dt2_resid_%s_23", wheel_sector);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_dt2_resid[wheel+2][sector-1][1] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -200., 200., " ");
m_posdt2_resid[wheel+2][sector-1][1] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negdt2_resid[wheel+2][sector-1][1] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(name, "dt13_slope_%s_12", wheel_sector);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_dt13_slope[wheel+2][sector-1][0] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -100., 100., " ");
m_posdt13_slope[wheel+2][sector-1][0] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negdt13_slope[wheel+2][sector-1][0] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(name, "dt13_slope_%s_23", wheel_sector);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_dt13_slope[wheel+2][sector-1][1] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -100., 100., " ");
m_posdt13_slope[wheel+2][sector-1][1] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negdt13_slope[wheel+2][sector-1][1] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(name, "dt13_slope_%s_34", wheel_sector);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_dt13_slope[wheel+2][sector-1][2] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -100., 100., " ");
m_posdt13_slope[wheel+2][sector-1][2] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negdt13_slope[wheel+2][sector-1][2] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(name, "dt2_slope_%s_12", wheel_sector);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_dt2_slope[wheel+2][sector-1][0] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -1000., 1000., " ");
m_posdt2_slope[wheel+2][sector-1][0] = book1D("/iterN/", pos, pos, nb, -100., 100.);
m_negdt2_slope[wheel+2][sector-1][0] = book1D("/iterN/", neg, neg, nb, -100., 100.);
sprintf(name, "dt2_slope_%s_23", wheel_sector);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_dt2_slope[wheel+2][sector-1][1] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -1000., 1000., " ");
m_posdt2_slope[wheel+2][sector-1][1] = book1D("/iterN/", pos, pos, nb, -100., 100.);
m_negdt2_slope[wheel+2][sector-1][1] = book1D("/iterN/", neg, neg, nb, -100., 100.);
}
}
if (m_doCSC) for (int endcap = 1; endcap <= 2; endcap++)
{
std::string endcapletter;
if (endcap == 1) endcapletter = "p";
else if (endcap == 2) endcapletter = "m";
for (int chamber = 1; chamber <= 36; chamber++)
{
char ec_chamber[50];
sprintf(ec_chamber,"%s_%02d", endcapletter.c_str(), chamber );
int nb = 100;
double wnd = 60.;
sprintf(name, "cscouter_resid_%s_12",ec_chamber);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_cscouter_resid[endcap-1][chamber-1][0] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -100., 100., " ");
m_poscscouter_resid[endcap-1][chamber-1][0] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negcscouter_resid[endcap-1][chamber-1][0] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(name, "cscouter_resid_%s_23",ec_chamber);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_cscouter_resid[endcap-1][chamber-1][1] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -100., 100., " ");
m_poscscouter_resid[endcap-1][chamber-1][1] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negcscouter_resid[endcap-1][chamber-1][1] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(name, "cscouter_slope_%s_12",ec_chamber);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_cscouter_slope[endcap-1][chamber-1][0] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -100., 100., " ");
m_poscscouter_slope[endcap-1][chamber-1][0] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negcscouter_slope[endcap-1][chamber-1][0] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(name, "cscouter_slope_%s_23",ec_chamber);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_cscouter_slope[endcap-1][chamber-1][1] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -100., 100., " ");
m_poscscouter_slope[endcap-1][chamber-1][1] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negcscouter_slope[endcap-1][chamber-1][1] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
}
for (int chamber = 1; chamber <= 18; chamber++)
{
char ec_chamber[50];
sprintf(ec_chamber,"%s_%02d", endcapletter.c_str(), chamber );
int nb = 100;
double wnd = 40.;
sprintf(name, "cscinner_resid_%s_12",ec_chamber);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_cscinner_resid[endcap-1][chamber-1][0] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -100., 100., " ");
m_poscscinner_resid[endcap-1][chamber-1][0] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negcscinner_resid[endcap-1][chamber-1][0] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(name, "cscinner_resid_%s_23",ec_chamber);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_cscinner_resid[endcap-1][chamber-1][1] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -100., 100., " ");
m_poscscinner_resid[endcap-1][chamber-1][1] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negcscinner_resid[endcap-1][chamber-1][1] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(name, "cscinner_resid_%s_34",ec_chamber);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_cscinner_resid[endcap-1][chamber-1][2] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -100., 100., " ");
m_poscscinner_resid[endcap-1][chamber-1][2] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negcscinner_resid[endcap-1][chamber-1][2] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(name, "cscinner_slope_%s_12",ec_chamber);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_cscinner_slope[endcap-1][chamber-1][0] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -100., 100., " ");
m_poscscinner_slope[endcap-1][chamber-1][0] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negcscinner_slope[endcap-1][chamber-1][0] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(name, "cscinner_slope_%s_23",ec_chamber);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_cscinner_slope[endcap-1][chamber-1][1] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -100., 100., " ");
m_poscscinner_slope[endcap-1][chamber-1][1] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negcscinner_slope[endcap-1][chamber-1][1] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(name, "cscinner_slope_%s_34",ec_chamber);
sprintf(pos,"pos%s", name);
sprintf(neg,"neg%s", name);
m_cscinner_slope[endcap-1][chamber-1][2] = bookProfile("/iterN/", name, name, 20, -max_curv, max_curv, 1, -100., 100., " ");
m_poscscinner_slope[endcap-1][chamber-1][2] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_negcscinner_slope[endcap-1][chamber-1][2] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
}
}
// cross-system
for (int e = 1; e<=2; e++)
for (int s = 1; s <= 12; s++)
{
char endcap_sector[50];
if (e == 1) sprintf(endcap_sector,"Wp2S%02d", s);
if (e == 2) sprintf(endcap_sector,"Wm2S%02d", s);
int nb = 200;
double wnd = 100.;
sprintf(pos,"pos_x_dt1_csc1_%s", endcap_sector);
sprintf(neg,"neg_x_dt1_csc1_%s", endcap_sector);
m_x_pos_dt1_csc1_resid[e-1][s-1] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_x_neg_dt1_csc1_resid[e-1][s-1] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(pos,"pos_x_dt1_csc2_%s", endcap_sector);
sprintf(neg,"neg_x_dt1_csc2_%s", endcap_sector);
m_x_pos_dt1_csc2_resid[e-1][s-1] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_x_neg_dt1_csc2_resid[e-1][s-1] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
sprintf(pos,"pos_x_dt2_csc1_%s", endcap_sector);
sprintf(neg,"neg_x_dt2_csc1_%s", endcap_sector);
m_x_pos_dt2_csc1_resid[e-1][s-1] = book1D("/iterN/", pos, pos, nb, -wnd, wnd);
m_x_neg_dt2_csc1_resid[e-1][s-1] = book1D("/iterN/", neg, neg, nb, -wnd, wnd);
}
}
| void AlignmentMonitorSegmentDifferences::event | ( | const edm::Event & | iEvent, |
| const edm::EventSetup & | iSetup, | ||
| const ConstTrajTrackPairCollection & | iTrajTracks | ||
| ) | [virtual] |
Called for each event (by "run()"): may be reimplemented.
Reimplemented from AlignmentMonitorBase.
Definition at line 338 of file AlignmentMonitorSegmentDifferences.cc.
References SiPixelRawToDigiRegional_cfi::beamSpot, reco::TrackBase::dxy(), edm::EventSetup::get(), edm::Event::getByLabel(), edm::InputTag::label(), AlignmentMonitorBase::m_beamSpotTag, m_maxDxy, m_minTrackP, m_minTrackPt, m_muonCollectionTag, metsig::muon, patZpeak::muons, reco::TrackBase::p(), AlignmentMonitorBase::pNavigator(), processMuonResidualsFromTrack(), and reco::TrackBase::pt().
{
edm::ESHandle<GlobalTrackingGeometry> globalGeometry;
iSetup.get<GlobalTrackingGeometryRecord>().get(globalGeometry);
edm::Handle<reco::BeamSpot> beamSpot;
iEvent.getByLabel(m_beamSpotTag, beamSpot);
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(globalGeometry, traj, track, pNavigator(), 1000.);
processMuonResidualsFromTrack(muonResidualsFromTrack);
}
} // 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 AlignmentMonitorSegmentDifferences::processMuonResidualsFromTrack | ( | MuonResidualsFromTrack & | mrft | ) |
Definition at line 379 of file AlignmentMonitorSegmentDifferences.cc.
References abs, MuonChamberResidual::chamberAlignable(), MuonResidualsFromTrack::chamberIds(), MuonResidualsFromTrack::chamberResidual(), reco::TrackBase::charge(), MuonResidualsFromTrack::contains_TIDTEC(), CSC(), GeomDetEnumerators::DT, MuonResidualsFromTrack::getTrack(), MuonChamberResidual::global_residual(), MuonChamberResidual::global_resslope(), SurfaceOrientation::inner, MuonChamberResidual::kCSC, MuonChamberResidual::kDT13, MuonChamberResidual::kDT2, m_allowTIDTEC, m_cscinner_resid, m_cscinner_slope, m_cscouter_resid, m_cscouter_slope, m_doCSC, m_doDT, m_dt13_resid, m_dt13_slope, m_dt2_resid, m_dt2_slope, m_maxTrackerRedChi2, m_minCSCHits, m_minDT13Hits, m_minDT2Hits, m_minNCrossedChambers, m_minTrackerHits, m_negcscinner_resid, m_negcscinner_slope, m_negcscouter_resid, m_negcscouter_slope, m_negdt13_resid, m_negdt13_slope, m_negdt2_resid, m_negdt2_slope, m_poscscinner_resid, m_poscscinner_slope, m_poscscouter_resid, m_poscscouter_slope, m_posdt13_resid, m_posdt13_slope, m_posdt2_resid, m_posdt2_slope, m_x_neg_dt1_csc1_resid, m_x_neg_dt1_csc2_resid, m_x_neg_dt2_csc1_resid, m_x_pos_dt1_csc1_resid, m_x_pos_dt1_csc2_resid, m_x_pos_dt2_csc1_resid, DetId::Muon, MuonResidualsFromTrack::normalizedChi2(), NULL, MuonChamberResidual::numHits(), SurfaceOrientation::outer, reco::TrackBase::pt(), reco::TrackBase::pz(), MuonResidualsFromTrack::trackerNumHits(), MuonChamberResidual::trackx(), and MuonChamberResidual::tracky().
Referenced by event().
{
if (mrft.trackerNumHits() < m_minTrackerHits) return;
if (!m_allowTIDTEC && mrft.contains_TIDTEC()) return;
if (mrft.normalizedChi2() > m_maxTrackerRedChi2) 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;
double qoverpt = (mrft.getTrack()->charge() > 0 ? 1. : -1.) / 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;
// **************** DT ****************
if (m_doDT && chamberId->subdetId() == MuonSubdetId::DT)
{
MuonChamberResidual *dt13 = mrft.chamberResidual(*chamberId, MuonChamberResidual::kDT13);
MuonChamberResidual *dt2 = mrft.chamberResidual(*chamberId, MuonChamberResidual::kDT2);
if (dt13 != NULL && dt13->numHits() >= m_minDT13Hits)
{
DTChamberId thisid(chamberId->rawId());
for (std::vector<DetId>::const_iterator otherId = chamberIds.begin(); otherId != chamberIds.end(); ++otherId)
{
if (otherId->det() == DetId::Muon && otherId->subdetId() == MuonSubdetId::DT)
{
DTChamberId thatid(otherId->rawId());
if (thisid.rawId() != thatid.rawId() && thisid.wheel() == thatid.wheel() && thisid.sector() == thatid.sector())
{
MuonChamberResidual *dt13other = mrft.chamberResidual(*otherId, MuonChamberResidual::kDT13);
if (dt13other != NULL && dt13other->numHits() >= m_minDT13Hits)
{
double slopediff = 1000. * (dt13->global_resslope() - dt13other->global_resslope());
//double length = dt13->chamberAlignable()->surface().toGlobal(align::LocalPoint(0,0,0)).perp() -
// dt13other->chamberAlignable()->surface().toGlobal(align::LocalPoint(0,0,0)).perp();
//double residdiff = 10. * (dt13->global_residual() + length*dt13->global_resslope() - dt13other->global_residual());
double residdiff = 10. * (dt13->global_residual() - dt13other->global_residual());
int st = 0;
if (thatid.station() - thisid.station() == 1) st = thisid.station();
if (st>0)
{
m_dt13_resid[thisid.wheel()+2][thisid.sector()-1][st-1]->Fill(qoverpt, residdiff);
m_dt13_slope[thisid.wheel()+2][thisid.sector()-1][st-1]->Fill(qoverpt, slopediff);
if (qoverpt > 0)
{
m_posdt13_resid[thisid.wheel()+2][thisid.sector()-1][st-1]->Fill(residdiff);
m_posdt13_slope[thisid.wheel()+2][thisid.sector()-1][st-1]->Fill(slopediff);
}
else
{
m_negdt13_resid[thisid.wheel()+2][thisid.sector()-1][st-1]->Fill(residdiff);
m_negdt13_slope[thisid.wheel()+2][thisid.sector()-1][st-1]->Fill(slopediff);
}
}
} // end other numhits
} // end this near other
} // end other is DT
// cross-system: other is CSC
// only do it for DT stubs in W+-2 St1&2:
if ( !(abs(thisid.wheel()) == 2 && (thisid.station() == 1 || thisid.station() == 2)) ) continue;
if (otherId->det() == DetId::Muon && otherId->subdetId() == MuonSubdetId::CSC)
{
CSCDetId thatid(otherId->rawId());
//only do it for CSC stubs in St1R3 or St2R2:
if ( !( (thatid.station()==1 && thatid.ring()==3) || (thatid.station()==2 && thatid.ring()==2) ) ) continue;
MuonChamberResidual *cscother = mrft.chamberResidual(*otherId, MuonChamberResidual::kCSC);
if (cscother != NULL && cscother->numHits() >= m_minCSCHits)
{
// scale to adjust the csc residual size to be comparabe to dt's one
double csc_scale = dt13->chamberAlignable()->surface().toGlobal(align::LocalPoint(dt13->trackx(), dt13->tracky(),0)).perp() /
cscother->chamberAlignable()->surface().toGlobal(align::LocalPoint(cscother->trackx(), cscother->tracky(),0)).perp();
double residdiff = 10. * (dt13->global_residual() - cscother->global_residual() * csc_scale);
if (thisid.station() == 1 && thatid.station()==1)
{
if (qoverpt > 0) m_x_pos_dt1_csc1_resid[thatid.endcap()-1][thisid.sector()-1]->Fill(residdiff);
else m_x_neg_dt1_csc1_resid[thatid.endcap()-1][thisid.sector()-1]->Fill(residdiff);
}
else if (thisid.station() == 1 && thatid.station()==2)
{
if (qoverpt > 0) m_x_pos_dt1_csc2_resid[thatid.endcap()-1][thisid.sector()-1]->Fill(residdiff);
else m_x_neg_dt1_csc2_resid[thatid.endcap()-1][thisid.sector()-1]->Fill(residdiff);
}
else if (thisid.station() == 2 && thatid.station()==1)
{
if (qoverpt > 0) m_x_pos_dt2_csc1_resid[thatid.endcap()-1][thisid.sector()-1]->Fill(residdiff);
else m_x_neg_dt2_csc1_resid[thatid.endcap()-1][thisid.sector()-1]->Fill(residdiff);
}
}
} // end other is CSC
} // end loop over other
} // end if DT13
// z-direction
if (dt2 != NULL && dt2->numHits() >= m_minDT2Hits)
{
DTChamberId thisid(chamberId->rawId());
for (std::vector<DetId>::const_iterator otherId = chamberIds.begin(); otherId != chamberIds.end(); ++otherId)
{
if (otherId->det() == DetId::Muon && otherId->subdetId() == MuonSubdetId::DT)
{
DTChamberId thatid(otherId->rawId());
if (thisid.rawId() != thatid.rawId() && thisid.wheel() == thatid.wheel() && thisid.sector() == thatid.sector())
{
MuonChamberResidual *dt2other = mrft.chamberResidual(*otherId, MuonChamberResidual::kDT2);
if (dt2other != NULL && dt2other->numHits() >= m_minDT2Hits)
{
double slopediff = 1000. * (dt2->global_resslope() - dt2other->global_resslope());
//double length = dt2->chamberAlignable()->surface().toGlobal(align::LocalPoint(0,0,0)).perp() -
// dt2other->chamberAlignable()->surface().toGlobal(align::LocalPoint(0,0,0)).perp();
//double residdiff = 10. * (dt2->global_residual() + length*dt2->global_resslope() - dt2other->global_residual());
double residdiff = 10. * (dt2->global_residual() - dt2other->global_residual());
int st = 0;
if (thatid.station() - thisid.station() == 1) st = thisid.station();
if (st>0)
{
m_dt2_resid[thisid.wheel()+2][thisid.sector()-1][st-1]->Fill(qoverpt, residdiff);
m_dt2_slope[thisid.wheel()+2][thisid.sector()-1][st-1]->Fill(qoverpt, slopediff);
if (qoverpt > 0)
{
m_posdt2_resid[thisid.wheel()+2][thisid.sector()-1][st-1]->Fill(residdiff);
m_posdt2_slope[thisid.wheel()+2][thisid.sector()-1][st-1]->Fill(slopediff);
}
else
{
m_negdt2_resid[thisid.wheel()+2][thisid.sector()-1][st-1]->Fill(residdiff);
m_negdt2_slope[thisid.wheel()+2][thisid.sector()-1][st-1]->Fill(slopediff);
}
}
} // end other numhits
} // end this near other
} // end other is DT
} // end loop over other
} // end if DT2
} // end if DT
// **************** CSC ****************
else if (m_doCSC && chamberId->subdetId() == MuonSubdetId::CSC)
{
MuonChamberResidual *csc = mrft.chamberResidual(*chamberId, MuonChamberResidual::kCSC);
if (csc->numHits() >= m_minCSCHits)
{
CSCDetId thisid(chamberId->rawId());
for (std::vector<DetId>::const_iterator otherId = chamberIds.begin(); otherId != chamberIds.end(); ++otherId)
{
if (otherId->det() == DetId::Muon && otherId->subdetId() == MuonSubdetId::CSC)
{
CSCDetId thatid(otherId->rawId());
if (thisid.rawId() != thatid.rawId() && thisid.endcap() == thatid.endcap())
{
MuonChamberResidual *cscother = mrft.chamberResidual(*otherId, MuonChamberResidual::kCSC);
if (cscother != NULL && cscother->numHits() >= m_minCSCHits)
{
double slopediff = 1000. * (csc->global_resslope() - cscother->global_resslope());
//double length = csc->chamberAlignable()->surface().toGlobal(align::LocalPoint(0,0,0)).z() -
// cscother->chamberAlignable()->surface().toGlobal(align::LocalPoint(0,0,0)).z();
//double residdiff = 10. * (csc->global_residual() + length*csc->global_resslope() - cscother->global_residual());
double residdiff = 10. * (csc->global_residual() - cscother->global_residual());
int thischamber = thisid.chamber();
int thisring = thisid.ring();
if (thisid.station() == 1 && (thisring == 1 || thisring == 4))
{
thischamber = (thischamber - 1) / 2 + 1;
thisring = 1;
}
if (thisring == thatid.ring() && thischamber == thatid.chamber())
{
bool inner = (thisring == 1);
bool outer = (thisring == 2);
int st = 0;
if (thatid.station() - thisid.station() == 1 && (inner || thisid.station()<3) ) st = thisid.station();
if (outer && st>0)
{
m_cscouter_resid[thisid.endcap()-1][thischamber-1][st-1]->Fill(qoverpz, residdiff);
m_cscouter_slope[thisid.endcap()-1][thischamber-1][st-1]->Fill(qoverpz, slopediff);
if (qoverpz > 0)
{
m_poscscouter_resid[thisid.endcap()-1][thischamber-1][st-1]->Fill(residdiff);
m_poscscouter_slope[thisid.endcap()-1][thischamber-1][st-1]->Fill(slopediff);
}
else
{
m_negcscouter_resid[thisid.endcap()-1][thischamber-1][st-1]->Fill(residdiff);
m_negcscouter_slope[thisid.endcap()-1][thischamber-1][st-1]->Fill(slopediff);
}
}
if (inner && st>0)
{
m_cscinner_resid[thisid.endcap()-1][thischamber-1][st-1]->Fill(qoverpz, residdiff);
m_cscinner_slope[thisid.endcap()-1][thischamber-1][st-1]->Fill(qoverpz, slopediff);
if (qoverpz > 0)
{
m_poscscinner_resid[thisid.endcap()-1][thischamber-1][st-1]->Fill(residdiff);
m_poscscinner_slope[thisid.endcap()-1][thischamber-1][st-1]->Fill(slopediff);
}
else
{
m_negcscinner_resid[thisid.endcap()-1][thischamber-1][st-1]->Fill(residdiff);
m_negcscinner_slope[thisid.endcap()-1][thischamber-1][st-1]->Fill(slopediff);
}
}
} // end of same ring&chamber
} // end other min numhits
} // end this near other
} // end other is CSC
} // end loop over other
} // end if this min numhits
} // end if CSC
} // end loop over chamberIds
}
bool AlignmentMonitorSegmentDifferences::m_allowTIDTEC [private] |
Definition at line 49 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by processMuonResidualsFromTrack().
TProfile* AlignmentMonitorSegmentDifferences::m_cscinner_resid[2][18][3] [private] |
Definition at line 74 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TProfile* AlignmentMonitorSegmentDifferences::m_cscinner_slope[2][18][3] [private] |
Definition at line 75 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TProfile* AlignmentMonitorSegmentDifferences::m_cscouter_resid[2][36][2] [private] |
Definition at line 72 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TProfile* AlignmentMonitorSegmentDifferences::m_cscouter_slope[2][36][2] [private] |
Definition at line 73 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
bool AlignmentMonitorSegmentDifferences::m_doCSC [private] |
Definition at line 55 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
bool AlignmentMonitorSegmentDifferences::m_doDT [private] |
Definition at line 54 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TProfile* AlignmentMonitorSegmentDifferences::m_dt13_resid[5][12][3] [private] |
Definition at line 58 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TProfile* AlignmentMonitorSegmentDifferences::m_dt13_slope[5][12][3] [private] |
Definition at line 59 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TProfile* AlignmentMonitorSegmentDifferences::m_dt2_resid[5][12][2] [private] |
Definition at line 60 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TProfile* AlignmentMonitorSegmentDifferences::m_dt2_slope[5][12][2] [private] |
Definition at line 61 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
double AlignmentMonitorSegmentDifferences::m_maxDxy [private] |
Definition at line 46 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by event().
double AlignmentMonitorSegmentDifferences::m_maxTrackerRedChi2 [private] |
Definition at line 48 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by processMuonResidualsFromTrack().
int AlignmentMonitorSegmentDifferences::m_minCSCHits [private] |
Definition at line 53 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by processMuonResidualsFromTrack().
int AlignmentMonitorSegmentDifferences::m_minDT13Hits [private] |
Definition at line 51 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by processMuonResidualsFromTrack().
int AlignmentMonitorSegmentDifferences::m_minDT2Hits [private] |
Definition at line 52 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by processMuonResidualsFromTrack().
bool AlignmentMonitorSegmentDifferences::m_minNCrossedChambers [private] |
Definition at line 50 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by processMuonResidualsFromTrack().
int AlignmentMonitorSegmentDifferences::m_minTrackerHits [private] |
Definition at line 47 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by processMuonResidualsFromTrack().
double AlignmentMonitorSegmentDifferences::m_minTrackP [private] |
Definition at line 45 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by event().
double AlignmentMonitorSegmentDifferences::m_minTrackPt [private] |
Definition at line 44 of file AlignmentMonitorSegmentDifferences.cc.
Definition at line 43 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by event().
TH1F* AlignmentMonitorSegmentDifferences::m_negcscinner_resid[2][18][3] [private] |
Definition at line 82 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_negcscinner_slope[2][18][3] [private] |
Definition at line 83 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_negcscouter_resid[2][36][2] [private] |
Definition at line 80 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_negcscouter_slope[2][36][2] [private] |
Definition at line 81 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_negdt13_resid[5][12][3] [private] |
Definition at line 66 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_negdt13_slope[5][12][3] [private] |
Definition at line 67 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_negdt2_resid[5][12][2] [private] |
Definition at line 68 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_negdt2_slope[5][12][2] [private] |
Definition at line 69 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_poscscinner_resid[2][18][3] [private] |
Definition at line 78 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_poscscinner_slope[2][18][3] [private] |
Definition at line 79 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_poscscouter_resid[2][36][2] [private] |
Definition at line 76 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_poscscouter_slope[2][36][2] [private] |
Definition at line 77 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_posdt13_resid[5][12][3] [private] |
Definition at line 62 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_posdt13_slope[5][12][3] [private] |
Definition at line 63 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_posdt2_resid[5][12][2] [private] |
Definition at line 64 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_posdt2_slope[5][12][2] [private] |
Definition at line 65 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_x_neg_dt1_csc1_resid[2][12] [private] |
Definition at line 89 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_x_neg_dt1_csc2_resid[2][12] [private] |
Definition at line 90 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_x_neg_dt2_csc1_resid[2][12] [private] |
Definition at line 91 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_x_pos_dt1_csc1_resid[2][12] [private] |
Definition at line 86 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_x_pos_dt1_csc2_resid[2][12] [private] |
Definition at line 87 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
TH1F* AlignmentMonitorSegmentDifferences::m_x_pos_dt2_csc1_resid[2][12] [private] |
Definition at line 88 of file AlignmentMonitorSegmentDifferences.cc.
Referenced by book(), and processMuonResidualsFromTrack().
1.7.3