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00001 // -*- C++ -*-
00002 //
00003 // Package:    RPCNoise
00004 // Class:      RPCNoise
00005 // 
00013 //
00014 // Original Author:  Michael Henry Schmitt
00015 //         Created:  Thu Oct 30 21:31:44 CET 2008
00016 // $Id: RPCNoise.cc,v 1.3 2010/08/07 14:55:55 wmtan Exp $
00017 //
00018 //
00019 // system include files
00020 #include <memory>
00021 #include <iostream>
00022 #include <vector>
00023 #include <map>
00024 #include <string>
00025 #include <iomanip>
00026 #include <fstream>
00027 #include <ctime>
00028 
00029 // user include files
00030 #include "FWCore/Framework/interface/Frameworkfwd.h"
00031 #include "FWCore/Framework/interface/EDFilter.h"
00032 
00033 #include "FWCore/Framework/interface/Event.h"
00034 #include "FWCore/Framework/interface/MakerMacros.h"
00035 
00036 #include "FWCore/ParameterSet/interface/ParameterSet.h"
00037 
00038 #include <Geometry/CommonDetUnit/interface/GeomDet.h>//
00039 #include <FWCore/ServiceRegistry/interface/Service.h>
00040 #include <FWCore/MessageLogger/interface/MessageLogger.h>
00041 #include <DataFormats/RPCRecHit/interface/RPCRecHit.h>
00042 #include "DataFormats/RPCRecHit/interface/RPCRecHitCollection.h"
00043 #include <DataFormats/RPCDigi/interface/RPCDigiCollection.h>
00044 #include "SimDataFormats/TrackingHit/interface/PSimHitContainer.h"
00045 
00046 #include "Geometry/RPCGeometry/interface/RPCGeometry.h"
00047 #include <Geometry/RPCGeometry/interface/RPCRoll.h>
00048 #include <Geometry/Records/interface/MuonGeometryRecord.h>
00049 
00050 #include "EventFilter/RPCRawToDigi/interface/RPCRawDataCounts.h"
00051 #include "EventFilter/RPCRawToDigi/interface/RPCRecordFormatter.h"
00052 //#include "EventFilter/RPCRawToDigi/interface/RPCRawSynchro.h"
00053 
00054 #include "CondFormats/RPCObjects/interface/RPCReadOutMapping.h"
00055 #include "CondFormats/RPCObjects/interface/RPCEMap.h"
00056 #include "CondFormats/DataRecord/interface/RPCEMapRcd.h"
00057 
00058 #include "DataFormats/MuonDetId/interface/CSCDetId.h"
00059 #include "DataFormats/CSCDigi/interface/CSCWireDigi.h"
00060 #include "DataFormats/CSCDigi/interface/CSCWireDigiCollection.h"
00061 #include "DataFormats/CSCDigi/interface/CSCStripDigi.h"
00062 #include "DataFormats/CSCDigi/interface/CSCStripDigiCollection.h"
00063 
00064 #include "DataFormats/DTDigi/interface/DTDigiCollection.h"
00065 #include "CondFormats/DTObjects/interface/DTT0.h"
00066 
00067 #include "DataFormats/GeometryVector/interface/GlobalPoint.h"
00068 #include "DataFormats/GeometryVector/interface/GlobalVector.h"
00069 #include "DataFormats/GeometryVector/interface/LocalPoint.h"
00070 #include "DataFormats/GeometryVector/interface/LocalVector.h"
00071 
00072 #include "TVector3.h"
00073 #include "TH1F.h"
00074 #include "TH2F.h"
00075 #include "TFile.h"
00076 #include "TString.h"
00077 #include "TTree.h"
00078 #include "TProfile.h"
00079 
00080 using namespace std;
00081 using namespace edm;
00082 
00083 
00084 //
00085 // class declaration
00086 //
00087 
00088 class RPCNoise : public edm::EDFilter {
00089    public:
00090       explicit RPCNoise(const edm::ParameterSet&);
00091       ~RPCNoise();
00092 
00093    private:
00094       virtual void beginJob() ;
00095       virtual bool filter(edm::Event&, const edm::EventSetup&);
00096       virtual void endJob() ;
00097 
00098   // counters
00099   int nEventsAnalyzed;
00100   int nEventsSelected;
00101   int iRun;
00102   int iEvent;
00103   int firstOrbit;
00104   int lastOrbit;
00105   int thisOrbit;
00106   // control parameters
00107   bool fillHistograms;
00108   int nRPCHitsCut;
00109   int nCSCStripsCut;
00110   int nCSCWiresCut;
00111   int nDTDigisCut;
00112   // histogram
00113   std::string histogramFileName;
00114   // The root file for the histograms.
00115   TFile *theHistogramFile;
00116   // histograms
00117   TH1F *nWires;
00118   TH1F *nStrips;
00119   TH1F *nWiresH;
00120   TH1F *nStripsH;
00121   TH1F *nDTDigis;
00122   TH1F *nDTDigisH;
00123   TH1F *t0All;
00124   TH1F *t0AllH;
00125   TH1F *nDTDigisIn;
00126   TH1F *nDTDigisInH;
00127   TH1F *nDTDigisOut;
00128   TH1F *nDTDigisOutH;
00129   TH1F *fDTDigisOut;
00130   TH1F *fDTDigisOutH;
00131   TH1F *nRPCRecHits;
00132   TH1F *nRPCRecHitsLong;
00133   TProfile *hitsVsSerial;
00134   TProfile *orbitVsSerial;
00135   TProfile *hitsVsOrbit;
00136   TH1F *dOrbit;
00137   TH1F *RPCBX;
00138   TH1F *RPCClSize;
00139   TH1F *RPCBXH;
00140   TH1F *RPCClSizeH;
00141   TH1F *rpcStation;
00142   TH1F *rpcStationH;
00143   TH1F *rpcRing;
00144   TH1F *rpcRingH;
00145   TH1F *rpcSector;
00146   TH1F *rpcSectorH;
00147   TH1F *rpcLayer;
00148   TH1F *rpcLayerH;
00149   TProfile *rpcStationVsOrbit;
00150   TProfile *rpcSectorVsOrbit;
00151   TProfile *rpcRingVsOrbit;
00152   TH1F *rpcCorner;
00153   TH1F *rpcCornerH;
00154   TProfile *rpcCornerVsOrbit;
00155 
00156 };
00157 
00158 RPCNoise::RPCNoise(const edm::ParameterSet& pset)
00159 {
00160   histogramFileName  = pset.getUntrackedParameter<std::string>("histogramFileName","histos.root");
00161   fillHistograms     = pset.getUntrackedParameter<bool>("fillHistograms",true);
00162   nRPCHitsCut        = pset.getUntrackedParameter<int>("nRPCHitsCut",40);
00163   nCSCStripsCut      = pset.getUntrackedParameter<int>("nCSCStripsCut",50);
00164   nCSCWiresCut       = pset.getUntrackedParameter<int>("nCSCWiresCut",10);
00165   nDTDigisCut        = pset.getUntrackedParameter<int>("nDTDigisCut",10);
00166 }
00167 RPCNoise::~RPCNoise()
00168 {
00169 }
00170 
00171 
00172 void 
00173 RPCNoise::beginJob()
00174 {
00175   // initialize variables
00176   nEventsAnalyzed = 0;
00177   nEventsSelected = 0;
00178   iRun = 0;
00179   iEvent = 0;
00180   firstOrbit = lastOrbit = thisOrbit = 0;
00181 
00182   if (fillHistograms) {
00183     // Create the root file for the histograms
00184     theHistogramFile = new TFile(histogramFileName.c_str(), "RECREATE");
00185     theHistogramFile->cd();
00186     // book histograms
00187     nWires  = new TH1F("nWires","number of wire digis", 121, -0.5, 120.5);
00188     nStrips = new TH1F("nStrips","number of strip digis", 201, -0.5, 200.5);
00189     nWiresH  = new TH1F("nWiresH","number of wire digis HIGH", 121, -0.5, 120.5);
00190     nStripsH = new TH1F("nStripsH","number of strip digis HIGH", 201, -0.5, 200.5);
00191     nDTDigis = new TH1F("nDTDigis","number of DT digis",201,-0.5,200.5);
00192     nDTDigisH = new TH1F("nDTDigisH","number of DT digis HIGH",201,-0.5,200.5);
00193     nDTDigisIn    = new TH1F("nDTDigisIn","N DT digis in window",75,0.,150.);
00194     nDTDigisInH   = new TH1F("nDTDigisInH","N DT digis in window HIGH",75,0.,150.);
00195     nDTDigisOut   = new TH1F("nDTDigisOut","N DT digis out window",75,0.,150.);
00196     nDTDigisOutH  = new TH1F("nDTDigisOutH","N DT digis out window HIGH",75,0.,150.);
00197     fDTDigisOut   = new TH1F("fDTDigisOut", "fraction DT digis outside window",55,0.,1.1);
00198     fDTDigisOutH  = new TH1F("fDTDigisOutH","fraction DT digis outside window HIGH",55,0.,1.1);
00199 
00200     t0All  = new TH1F("t0All","t0",700,0.,7000.);
00201     t0AllH = new TH1F("t0AllH","t0 HIGH",700,0.,7000.);
00202     RPCBX  = new TH1F("RPCBX","RPC BX",21,-10.5,10.5);
00203     RPCBXH = new TH1F("RPCBXH","RPC BX HIGH",21,-10.5,10.5);
00204     RPCClSize  = new TH1F("RPCClSize","RPC cluster size",61,-0.5,60.5);
00205     RPCClSizeH = new TH1F("RPCClSizeH","RPC cluster size HIGH",61,-0.5,60.5);
00206     
00207     nRPCRecHits = new TH1F("nRPCRecHits","number of RPC RecHits",101,-0.5,100.5);
00208     nRPCRecHitsLong = new TH1F("nRPCRecHitsLong","number of RPC RecHits",601,-0.5,600.5);
00209     hitsVsSerial  = new TProfile("hitsVsSerial","mean RPC hits vs serial event number",4000,0.,40000.,0.,1000.);
00210     orbitVsSerial = new TProfile("orbitVsSerial","relative orbit number vs serial event number",4000,0.,40000.,0.,1.e10);
00211     hitsVsOrbit   = new TProfile("hitsVsOrbit","mean RPC hits vs orbit number",3000,0.,1200000.,0.,1000.);
00212     dOrbit = new TH1F("dOrbit","difference in orbit number",121,-0.5,120.5);
00213 
00214     rpcStation  = new TH1F("rpcStation",  "RPC station", 6,-0.5,5.5);
00215     rpcStationH = new TH1F("rpcStationH", "RPC station HIGH", 6,-0.5,5.5);
00216     rpcRing     = new TH1F("rpcRing",  "RPC ring", 9,-4.5,4.5);
00217     rpcRingH    = new TH1F("rpcRingH", "RPC ring HIGH", 9,-4.5,4.5);
00218     rpcSector   = new TH1F("rpcSector",  "RPC sector", 15,-0.5,14.5);
00219     rpcSectorH  = new TH1F("rpcSectorH", "RPC sector HIGH", 15,-0.5,14.5);
00220     rpcLayer    = new TH1F("rpcLayer",  "RPC layer", 4,-0.5,3.5);
00221     rpcLayerH   = new TH1F("rpcLayerH", "RPC layer HIGH", 4,-0.5,3.5);
00222     rpcStationVsOrbit = new TProfile("rpcStationVsOrbit","mean RPC station vs. Orbit",3000,0.,1200000.,0.,20.);
00223     rpcSectorVsOrbit  = new TProfile("rpcSectorVsOrbit","mean RPC sector vs. Orbit",  3000,0.,1200000.,0.,20.);
00224     rpcRingVsOrbit    = new TProfile("rpcRingVsOrbit","mean RPC ring vs. Orbit",      3000,0.,1200000.,-20.,20.);
00225     rpcCorner   = new TH1F("rpcCorner", "special corner designation",      4,-0.5,3.5);
00226     rpcCornerH  = new TH1F("rpcCornerH","special corner designation HIGH", 4,-0.5,3.5);
00227     rpcCornerVsOrbit = new TProfile("rpcCornerVsOrbit","special corner vs. Orbit",3000,0.,1200000.,-20.,20.);
00228   }
00229 
00230 }
00231 
00232 
00233 void 
00234 RPCNoise::endJob() {
00235   std::cout << "\n\t===============================================================\n"
00236        << "\tnumber of events analyzed      = " << nEventsAnalyzed << std::endl
00237        << "\tnumber of events selected      = " << nEventsSelected << std::endl
00238        << "\tfirst and last orbit number    : " << firstOrbit << ", " << lastOrbit << ", " << lastOrbit-firstOrbit << std::endl
00239        << "\t===============================================================\n\n";
00240 
00241 
00242   if (fillHistograms) {
00243     // Write the histos to file
00244     printf("\n\n======= write out my histograms ====\n\n");
00245     theHistogramFile->cd();
00246     nWires->Write();
00247     nStrips->Write();
00248     nWiresH->Write();
00249     nStripsH->Write();
00250     nDTDigis->Write();
00251     nDTDigisH->Write();
00252     nDTDigisIn->Write();
00253     nDTDigisInH->Write();
00254     nDTDigisOut->Write();
00255     nDTDigisOutH->Write();
00256     fDTDigisOut->Write();
00257     fDTDigisOutH->Write();
00258     nRPCRecHits->Write();
00259     nRPCRecHitsLong->Write();
00260     hitsVsSerial->Write();
00261     hitsVsOrbit->Write();
00262     orbitVsSerial->Write();
00263     t0All->Write();
00264     t0AllH->Write();
00265     RPCBX->Write();
00266     RPCClSize->Write();
00267     RPCBXH->Write();
00268     RPCClSizeH->Write();
00269     rpcStation->Write();
00270     rpcStationH->Write();
00271     rpcRing->Write();
00272     rpcRingH->Write();
00273     rpcSector->Write();
00274     rpcSectorH->Write();
00275     rpcLayer->Write();
00276     rpcLayerH->Write();
00277     dOrbit->Write();
00278     rpcStationVsOrbit->Write();
00279     rpcSectorVsOrbit->Write();
00280     rpcRingVsOrbit->Write();
00281     rpcCorner->Write();
00282     rpcCornerH->Write();
00283     rpcCornerVsOrbit->Write();
00284     theHistogramFile->Close();
00285   }
00286 }
00287 
00288 
00289 
00290 
00291 bool
00292 RPCNoise::filter(edm::Event& event, const edm::EventSetup& eventSetup){
00293 
00294   bool selectThisEvent = false;
00295 
00296   // increment counter
00297   nEventsAnalyzed++;
00298 
00299   iRun   = event.id().run();
00300   iEvent = event.id().event();
00301 
00302   bool printThisLine = (nEventsAnalyzed%100 == 0);
00303   if (printThisLine) {
00304   std::cout << "======================================"
00305        << " analyzed= " << nEventsAnalyzed 
00306        << ", selected= " << nEventsSelected
00307        << "\trun,event: " << iRun << ", " << iEvent << std::endl;
00308   }
00309 
00310   /*
00311   const edm::Timestamp jTime = event.time();
00312   unsigned int sec  = jTime.value() >> 32;
00313   unsigned int usec = 0xFFFFFFFF & jTime.value() ;
00314   double floatTime = sec + usec/(float)1000000.;
00315   */
00316 
00317   // first event gives
00318   // sec = 1225315493
00319   //    orbit = 202375185
00320   //    bx = 764
00321   //    mtime = 205094517
00322   int bx = event.bunchCrossing();
00323   int thisOrbit = event.orbitNumber();
00324   long mTime = 3564*thisOrbit + bx;
00325   if (firstOrbit == 0) {
00326     firstOrbit = thisOrbit;
00327     lastOrbit = thisOrbit;
00328   }
00329   int deltaOrbit = thisOrbit - lastOrbit;
00330   lastOrbit = thisOrbit;
00331   int relativeOrbit = thisOrbit - firstOrbit;
00332 
00333   if (fillHistograms) {dOrbit->Fill(deltaOrbit);}
00334 
00335   if (nEventsAnalyzed < 200) {
00336     std::cout << iEvent 
00337       //         << "\tsec,usec: " << sec << ", " << usec
00338       //         << "\tfloatTime= " << std::setprecision(16) << floatTime
00339       //         << "\tctime: " << ctime(sec)
00340          << "\torbit,bx,mTime: " << thisOrbit << "," << bx << "," << mTime
00341          << "\tdelta= " << deltaOrbit
00342          << std::endl;
00343   }
00344 
00345 
00346   // ================
00347   // RPC recHits
00348   // ================
00349   edm::Handle<RPCRecHitCollection> rpcRecHits; 
00350   event.getByLabel("rpcRecHits","",rpcRecHits);
00351 
00352   // count the number of RPC rechits
00353   int nRPC = 0;
00354   RPCRecHitCollection::const_iterator rpcIt;
00355   for (rpcIt = rpcRecHits->begin(); rpcIt != rpcRecHits->end(); rpcIt++) {
00356     //    RPCDetId id = (RPCDetId)(*rpcIt).rpcId();
00357     //    LocalPoint rhitlocal = (*rpcIt).localPosition();
00358     nRPC++;
00359   }
00360 
00361   // loop again, this time fill histograms
00362   for (rpcIt = rpcRecHits->begin(); rpcIt != rpcRecHits->end(); rpcIt++) {
00363     RPCDetId id = (RPCDetId)(*rpcIt).rpcId();
00364     int kRegion  = id.region();
00365     int kStation = id.station();
00366     int kRing = id.ring();
00367     int kSector = id.sector();
00368     int kLayer = id.layer();
00369     int bx = (*rpcIt).BunchX();
00370     int clSize = (*rpcIt).clusterSize();
00371     int cornerFlag = 0;
00372     if ( (kStation>3) && (kSector<3) ) {
00373       cornerFlag = 1;
00374       if (kRing < 0) cornerFlag = 2;
00375     }
00376     if (nEventsAnalyzed < 100) {
00377       std::cout << "Region/Station/Ring/Sector/Layer: "
00378            << kRegion << " / "
00379            << kStation << " / "
00380            << kRing << " / "
00381            << kSector << " / "
00382            << kLayer 
00383            << "\tbx,clSize: " << bx << ", " << clSize
00384            << std::endl;
00385     }
00386     if (fillHistograms) {
00387       RPCBX->Fill(bx);
00388       RPCClSize->Fill(min((float)clSize,(float)60.));
00389       rpcStation->Fill(kStation);
00390       rpcRing->Fill(kRing);
00391       rpcSector->Fill(kSector);
00392       rpcLayer->Fill(kLayer);
00393       rpcStationVsOrbit->Fill(relativeOrbit,kStation);
00394       rpcSectorVsOrbit->Fill(relativeOrbit,kSector);
00395       rpcRingVsOrbit->Fill(relativeOrbit,kRing);
00396       rpcCorner->Fill(cornerFlag);
00397       rpcCornerVsOrbit->Fill(relativeOrbit,cornerFlag);
00398       if (nRPC > nRPCHitsCut) {
00399         RPCBXH->Fill(bx);
00400         RPCClSizeH->Fill(min((float)clSize,(float)60.));
00401         rpcStationH->Fill(kStation);
00402         rpcRingH->Fill(kRing);
00403         rpcSectorH->Fill(kSector);
00404         rpcLayerH->Fill(kLayer);
00405         rpcCornerH->Fill(cornerFlag);
00406       }
00407     }
00408 
00409   }
00410 
00411  
00412   // ===============
00413   // CSC DIGIs
00414   // ===============
00415   edm::Handle<CSCWireDigiCollection>  wires;
00416   edm::Handle<CSCStripDigiCollection> strips;
00417   event.getByLabel("muonCSCDigis","MuonCSCWireDigi",wires);
00418   event.getByLabel("muonCSCDigis","MuonCSCStripDigi",strips);
00419 
00420   // count the number of wire digis.
00421   int nW = 0;
00422   for (CSCWireDigiCollection::DigiRangeIterator jW=wires->begin(); jW!=wires->end(); jW++) {
00423     std::vector<CSCWireDigi>::const_iterator wireIterA = (*jW).second.first;
00424     std::vector<CSCWireDigi>::const_iterator lWireA = (*jW).second.second;
00425     for( ; wireIterA != lWireA; ++wireIterA) {
00426       nW++;
00427     }
00428   }
00429 
00430   // count the number of fired strips.
00431   // I am using a crude indicator of signal - this is fast and adequate for
00432   // this purpose, but it would be poor for actual CSC studies.
00433   int nS = 0;
00434   for (CSCStripDigiCollection::DigiRangeIterator jS=strips->begin(); jS!=strips->end(); jS++) {
00435     std::vector<CSCStripDigi>::const_iterator stripItA = (*jS).second.first;
00436     std::vector<CSCStripDigi>::const_iterator lastStripA = (*jS).second.second;
00437     for( ; stripItA != lastStripA; ++stripItA) {
00438       std::vector<int> myADCVals = stripItA->getADCCounts();
00439       int iDiff = myADCVals[4]+myADCVals[5]-myADCVals[0]-myADCVals[1];
00440       if (iDiff > 30) {
00441         nS++;
00442       }
00443     }
00444   }
00445 
00446  
00447   // ===============
00448   // DT DIGIs
00449   // ===============
00450   // see: CalibMuon/DTCalibration/plugins/DTT0Calibration.cc
00451   edm::Handle<DTDigiCollection>  dtDIGIs;
00452   event.getByLabel("muonDTDigis",dtDIGIs);
00453 
00454   // count the number of digis.
00455   int nDT = 0;
00456   int nDTin = 0;
00457   int nDTout = 0;
00458   for (DTDigiCollection::DigiRangeIterator jDT=dtDIGIs->begin(); jDT!=dtDIGIs->end(); ++jDT) {
00459     const DTDigiCollection::Range& digiRange = (*jDT).second;
00460     for (DTDigiCollection::const_iterator digi = digiRange.first;
00461          digi != digiRange.second;
00462          digi++) {
00463       double t0 = (*digi).countsTDC();
00464       nDT++;
00465       if ((t0>3050) && (t0<3700)) {
00466         nDTin++;
00467       } else {
00468         nDTout++;
00469       }
00470       if (fillHistograms) {
00471         t0All->Fill(t0);
00472         if (nRPC > nRPCHitsCut) {t0AllH->Fill(t0);}
00473       }
00474     }
00475   }
00476 
00477   //==============
00478   // Analysis
00479   //==============
00480 
00481   if (nEventsAnalyzed < 1000) {std::cout << "\tnumber of CSC DIGIS = " << nW << ", " << nS 
00482                                     << "\tDT DIGIS = " << nDT
00483                                     << "\tRPC Rechits = " << nRPC << std::endl;}
00484 
00485   if (fillHistograms) {
00486 
00487     nWires->Fill(min((float)nW,(float)120.));
00488     nStrips->Fill(min((float)nS,(float)200.));
00489     
00490     nDTDigis->Fill(min((float)nDT,(float)200.));
00491     nDTDigisIn->Fill(min((float)nDTin,(float)200.));
00492     nDTDigisOut->Fill(min((float)nDTout,(float)200.));
00493     if (nDT > 0) {
00494       float fracOut = float(nDTout)/float(nDT);
00495       fDTDigisOut->Fill(fracOut);
00496     }
00497     nRPCRecHits->Fill(min((float)nRPC,(float)100.));
00498     nRPCRecHitsLong->Fill(min((float)nRPC,(float)1000.));
00499     hitsVsSerial->Fill(nEventsAnalyzed,nRPC);
00500     hitsVsOrbit->Fill(relativeOrbit,nRPC);
00501     orbitVsSerial->Fill(nEventsAnalyzed,relativeOrbit);
00502 
00503     if (nRPC > nRPCHitsCut) {
00504       nWiresH->Fill(min((float)nW,(float)120.));
00505       nStripsH->Fill(min((float)nS,(float)200.));
00506       nDTDigisH->Fill(min((float)nDT,(float)200.));
00507       nDTDigisInH->Fill(min((float)nDTin,(float)200.));
00508       nDTDigisOutH->Fill(min((float)nDTout,(float)200.));
00509       if (nDT > 0) {
00510         float fracOut = float(nDTout)/float(nDT);
00511         fDTDigisOutH->Fill(fracOut);
00512       }
00513     }
00514   }
00515 
00516   // select this event for output?
00517 
00518   selectThisEvent = (nRPC > nRPCHitsCut) && (nW > nCSCWiresCut || nS > nCSCStripsCut) && (nDT > nDTDigisCut);
00519   if (selectThisEvent) {nEventsSelected++;}
00520 
00521   return selectThisEvent;
00522 }
00523 
00524 //define this as a plug-in
00525 DEFINE_FWK_MODULE(RPCNoise);