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MuonDTLocalMillepedeAlgorithm Class Reference

#include <MuonDTLocalMillepedeAlgorithm.h>

Inheritance diagram for MuonDTLocalMillepedeAlgorithm:
AlignmentAlgorithmBase

Classes

struct  Info1D
 

Public Member Functions

void initialize (const edm::EventSetup &setup, AlignableTracker *tracker, AlignableMuon *muon, AlignmentParameterStore *store)
 Call at beginning of job. More...
 
 MuonDTLocalMillepedeAlgorithm (const edm::ParameterSet &cfg)
 Constructor. More...
 
void run (const edm::EventSetup &setup, const EventInfo &eventInfo)
 Run the algorithm on trajectories and tracks. More...
 
void terminate (void)
 Call at end of job. More...
 
 ~MuonDTLocalMillepedeAlgorithm ()
 Destructor. More...
 
- Public Member Functions inherited from AlignmentAlgorithmBase
virtual bool addCalibrations (const std::vector< IntegratedCalibrationBase * > &iCals)
 
 AlignmentAlgorithmBase (const edm::ParameterSet &cfg)
 Constructor. More...
 
virtual void beginLuminosityBlock (const edm::EventSetup &setup)
 called at begin of luminosity block (no lumi block info passed yet) More...
 
virtual void beginRun (const edm::EventSetup &setup)
 called at begin of run More...
 
virtual void endLuminosityBlock (const edm::EventSetup &setup)
 called at end of luminosity block (no lumi block info passed yet) More...
 
virtual void endRun (const EndRunInfo &runInfo, const edm::EventSetup &setup)
 called at end of run - order of arguments like in EDProducer etc. More...
 
virtual void initialize (const edm::EventSetup &setup, AlignableTracker *tracker, AlignableMuon *muon, AlignableExtras *extras, AlignmentParameterStore *store)=0
 Call at beginning of job (must be implemented in derived class) More...
 
virtual bool setParametersForRunRange (const RunRange &rr)
 
virtual void startNewLoop ()
 
virtual void terminate (const edm::EventSetup &iSetup)=0
 Call at end of each loop (must be implemented in derived class) More...
 
virtual ~AlignmentAlgorithmBase ()
 Destructor. More...
 

Private Member Functions

bool build4DSegments ()
 
void setBranchTrees ()
 

Private Attributes

float charge
 
edm::InputTag consTraj
 
float dxdzSl [5]
 
float dxdzSlSL1 [5]
 
float dxdzSlSL3 [5]
 
float dydzSl [5]
 
float edxdzSl [5]
 
float edxdzSlSL1 [5]
 
float edxdzSlSL3 [5]
 
float edydzSl [5]
 
float eta
 
float ex [5][14]
 
float excp [5][14]
 
float exdxdzSl [5]
 
float exdxdzSlSL1 [5]
 
float exdxdzSlSL3 [5]
 
float exSl [5]
 
float exSlSL1 [5]
 
float exSlSL3 [5]
 
float eycp [5][14]
 
float eydydzSl [5]
 
float eySl [5]
 
TFile * f
 
edm::Service< TFileServicefs
 
edm::InputTag globalTracks
 
int la [5][14]
 
float meandxdz [5][4][14]
 
float meandydz [5][4][14]
 
float meanx [5][4][14]
 
float meany [5][4][14]
 
Info1D myTrack1D
 
int nhits [5]
 
int nMtxSection
 
int nphihits [5]
 
float nPhihits
 
int nseg
 
int nthetahits [5]
 
float nThetahits
 
std::string ntuplePath
 
int numberOfRootFiles
 
float numberOfSigmasDXDZ
 
float numberOfSigmasDYDZ
 
float numberOfSigmasX
 
float numberOfSigmasY
 
float p
 
float phi
 
float pt
 
float ptMax
 
float ptMin
 
float sigmadxdz [5][4][14]
 
float sigmadydz [5][4][14]
 
float sigmax [5][4][14]
 
float sigmay [5][4][14]
 
int sl [5][14]
 
int sr [5]
 
int st [5]
 
TChain * tali
 
AlignableNavigatortheAlignableDetAccessor
 
std::vector< Alignable * > theAlignables
 
AlignmentParameterStoretheAlignmentParameterStore
 
TTree * ttreeOutput
 
int wh [5]
 
int workingmode
 
float xc [5][14]
 
float xcp [5][14]
 
float xSl [5]
 
float xSL1SL3 [5]
 
float xSL3SL1 [5]
 
float xSlSL1 [5]
 
float xSlSL3 [5]
 
float yc [5][14]
 
float ycp [5][14]
 
float ySl [5]
 
float zc [5][14]
 

Additional Inherited Members

- Public Types inherited from AlignmentAlgorithmBase
typedef std::pair< const
Trajectory *, const
reco::Track * > 
ConstTrajTrackPair
 
typedef std::vector
< ConstTrajTrackPair
ConstTrajTrackPairCollection
 
typedef cond::RealTimeType
< cond::runnumber >::type 
RunNumber
 
typedef std::pair< RunNumber,
RunNumber
RunRange
 

Detailed Description

Definition at line 30 of file MuonDTLocalMillepedeAlgorithm.h.

Constructor & Destructor Documentation

MuonDTLocalMillepedeAlgorithm::MuonDTLocalMillepedeAlgorithm ( const edm::ParameterSet cfg)

Constructor.

Definition at line 41 of file MuonDTLocalMillepedeAlgorithm.cc.

References f, edm::ParameterSet::getParameter(), nMtxSection, nPhihits, nThetahits, ntuplePath, numberOfRootFiles, numberOfSigmasDXDZ, numberOfSigmasDYDZ, numberOfSigmasX, numberOfSigmasY, ptMax, ptMin, setBranchTrees(), AlCaHLTBitMon_QueryRunRegistry::string, and workingmode.

41  :
43 {
44 
45  edm::LogInfo("Alignment") << "[MuonDTLocalMillepedeAlgorithm] constructed.";
46 
47  //Parse parameters. In the future this section should be completed with more options
48  ntuplePath = cfg.getParameter<std::string>( "ntuplePath" );
49  numberOfRootFiles = cfg.getParameter<int>( "numberOfRootFiles" );
50  ptMax = cfg.getParameter<double>( "ptMax" );
51  ptMin = cfg.getParameter<double>( "ptMin" );
52  numberOfSigmasX = cfg.getParameter<double>( "numberOfSigmasX" );
53  numberOfSigmasDXDZ = cfg.getParameter<double>( "numberOfSigmasDXDZ" );
54  numberOfSigmasY = cfg.getParameter<double>( "numberOfSigmasY" );
55  numberOfSigmasDYDZ = cfg.getParameter<double>( "numberOfSigmasDYDZ" );
56  nPhihits = cfg.getParameter<double>( "nPhihits" );
57  nThetahits = cfg.getParameter<double>( "nThetahits" );
58  workingmode = cfg.getParameter<int>( "workingMode" );
59  nMtxSection = cfg.getParameter<int>( "nMtxSection" );
60 
61 
62  //The algorithm has three working modes:
63  //0.- aligment information is extracted from the events and stored in root files
64  //1.- The SLtoSl algorithm
65  //2.- The local MuonMillepede algorithm
66  if(workingmode == 0) {
67  edm::LogInfo("Alignment") << "[MuonDTLocalMillepedeAlgorithm] Running on production mode.";
68  char nameOfFile[200];
69  snprintf(nameOfFile, sizeof(nameOfFile), "%s/MyNtupleResidual.root", ntuplePath.c_str());
70  f = new TFile(nameOfFile, "RECREATE");
71  f->cd();
73  } else if (workingmode == 1) {
74  edm::LogInfo("Alignment") << "[MuonDTLocalMillepedeAlgorithm] Running SLToSL algorithm.";
75  } else {
76  edm::LogInfo("Alignment") << "[MuonDTLocalMillepedeAlgorithm] Running Local Millepede algorithm.";
77  }
78 
79 }
T getParameter(std::string const &) const
AlignmentAlgorithmBase(const edm::ParameterSet &cfg)
Constructor.
MuonDTLocalMillepedeAlgorithm::~MuonDTLocalMillepedeAlgorithm ( )
inline

Destructor.

Definition at line 39 of file MuonDTLocalMillepedeAlgorithm.h.

39 {};

Member Function Documentation

bool MuonDTLocalMillepedeAlgorithm::build4DSegments ( )
private

Definition at line 214 of file MuonDTLocalMillepedeAlgorithm.cc.

References counter, dxdzSl, dxdzSlSL1, dxdzSlSL3, dydzSl, edxdzSl, edxdzSlSL1, edxdzSlSL3, edydzSl, MuonDTLocalMillepedeAlgorithm::Info1D::erx, ex, excp, exdxdzSl, exdxdzSlSL1, exdxdzSlSL3, exSl, exSlSL1, exSlSL3, eycp, eydydzSl, eySl, gen::k, MuonDTLocalMillepedeAlgorithm::Info1D::la, la, MAX_HIT_CHAM, MAX_SEGMENT, myTrack1D, MuonDTLocalMillepedeAlgorithm::Info1D::nhits, nhits, nphihits, nPhihits, nseg, nthetahits, nThetahits, alignCSCRings::s, MuonDTLocalMillepedeAlgorithm::Info1D::sl, sl, MuonDTLocalMillepedeAlgorithm::Info1D::sr, sr, MuonDTLocalMillepedeAlgorithm::Info1D::st, st, MuonDTLocalMillepedeAlgorithm::Info1D::wh, wh, MuonDTLocalMillepedeAlgorithm::Info1D::xc, xc, xcp, xSl, xSL1SL3, xSL3SL1, xSlSL1, xSlSL3, MuonDTLocalMillepedeAlgorithm::Info1D::yc, yc, ycp, ySl, MuonDTLocalMillepedeAlgorithm::Info1D::zc, and zc.

Referenced by run().

214  {
215 
216  bool saveThis = false;
217 
218  //Set to 0
219  int id[20][5];
220  int numlayer[20][12];
221  for(int s = 0; s < 20; ++s) {
222  for(int k = 0; k < 5; ++k) id[s][k] = 0;
223  for(int k = 0; k < 12; ++k) numlayer[s][k] = 0;
224  }
225 
226 
227  int nChambers = 0;
228  for(int counter = 0; counter < myTrack1D.nhits; ++counter) {
229  bool isNew = true;
230  for(int counterCham = 0; counterCham < nChambers; counterCham++) {
231  if(myTrack1D.wh[counter] == id[counterCham][0] &&
232  myTrack1D.st[counter] == id[counterCham][1] &&
233  myTrack1D.sr[counter] == id[counterCham][2]) {
234  if(myTrack1D.sl[counter] == 2) {
235  id[counterCham][4]++;
236  } else {
237  id[counterCham][3]++;
238  }
239  for (int ila = 1; ila<=4; ila++)
240  if (myTrack1D.la[counter]==ila) {
241  int jla = (myTrack1D.sl[counter]-1)*4 + ila -1;
242  numlayer[counterCham][jla]++;
243  }
244  isNew = false;
245  }
246  }
247  if(isNew) {
248  id[nChambers][0] = myTrack1D.wh[counter];
249  id[nChambers][1] = myTrack1D.st[counter];
250  id[nChambers][2] = myTrack1D.sr[counter];
251  if(myTrack1D.sl[counter] == 2) {
252  id[nChambers][4]++;
253  } else {
254  id[nChambers][3]++;
255  }
256  for (int ila = 1; ila<=4; ila++)
257  if (myTrack1D.la[counter]==ila) {
258  int jla = (myTrack1D.sl[counter]-1)*4 + ila -1;
259  numlayer[nChambers][jla]++;
260  }
261  nChambers++;
262  }
263  }
264 
265  for (int iseg = 0; iseg<MAX_SEGMENT; iseg++)
266  for (int ihit = 0; ihit<MAX_HIT_CHAM; ihit++) {
267  xc[iseg][ihit] = -250.;
268  yc[iseg][ihit] = -250.;
269  zc[iseg][ihit] = -250.;
270  ex[iseg][ihit] = -250.;
271  xcp[iseg][ihit] = -250.;
272  ycp[iseg][ihit] = -250.;
273  excp[iseg][ihit] = -250.;
274  eycp[iseg][ihit] = -250.;
275  sl[iseg][ihit] = 0;
276  la[iseg][ihit] = 0;
277  }
278 
279  nseg = 0;
280  for(int counter = 0; counter < nChambers; ++counter) {
281 
282  bool GoodPhiChamber = true, GoodThetaChamber = true;
283  for (int ila = 1; ila<=12; ila++) {
284  if (numlayer[counter][ila-1]!=1 && (ila<5 || ila>8)) GoodPhiChamber = false;
285  if (numlayer[counter][ila-1]!=1 && (ila<9 || ila>4) && id[counter][1]!=4) GoodThetaChamber = false;
286  }
287 
288  if(id[counter][3] >= nPhihits && (id[counter][4] >= nThetahits || id[counter][1] == 4) &&
289  GoodPhiChamber && GoodThetaChamber) {
290 
291  TMatrixD phiProjection(2,2);
292  TMatrixD thetaProjection(2,2);
293  TMatrixD bphiProjection(2,1);
294  TMatrixD bthetaProjection(2,1);
295 
296  TMatrixD phiProjectionSL1(2,2);
297  TMatrixD bphiProjectionSL1(2,1);
298  TMatrixD phiProjectionSL3(2,2);
299  TMatrixD bphiProjectionSL3(2,1);
300 
301  float SL1_z_ave = 0;
302  float SL3_z_ave = 0;
303 
304  int numh1 = 0, numh2 = 0, numh3 = 0;
305  for(int counterH = 0; counterH < myTrack1D.nhits; ++counterH) {
306  if(myTrack1D.wh[counterH] == id[counter][0] && myTrack1D.st[counterH] == id[counter][1] &&
307  myTrack1D.sr[counterH] == id[counter][2]) {
308  if(myTrack1D.sl[counterH] == 2) {
309  numh2++;
310  thetaProjection(0,0) += 1.0/myTrack1D.erx[counterH];
311  thetaProjection(0,1) += myTrack1D.zc[counterH]/myTrack1D.erx[counterH];
312  thetaProjection(1,0) += myTrack1D.zc[counterH]/myTrack1D.erx[counterH];
313  thetaProjection(1,1) += myTrack1D.zc[counterH]*myTrack1D.zc[counterH]/myTrack1D.erx[counterH];
314  bthetaProjection(0,0) += myTrack1D.yc[counterH]/myTrack1D.erx[counterH];
315  bthetaProjection(1,0) += myTrack1D.yc[counterH]*myTrack1D.zc[counterH]/myTrack1D.erx[counterH];
316  } else {
317  phiProjection(0,0) += 1.0/myTrack1D.erx[counterH];
318  phiProjection(0,1) += myTrack1D.zc[counterH]/myTrack1D.erx[counterH];
319  phiProjection(1,0) += myTrack1D.zc[counterH]/myTrack1D.erx[counterH];
320  phiProjection(1,1) += myTrack1D.zc[counterH]*myTrack1D.zc[counterH]/myTrack1D.erx[counterH];
321  bphiProjection(0,0) += myTrack1D.xc[counterH]/myTrack1D.erx[counterH];
322  bphiProjection(1,0) += myTrack1D.xc[counterH]*myTrack1D.zc[counterH]/myTrack1D.erx[counterH];
323  if(myTrack1D.sl[counterH] == 1) {
324  numh1++;
325  phiProjectionSL1(0,0) += 1.0/myTrack1D.erx[counterH];
326  phiProjectionSL1(0,1) += myTrack1D.zc[counterH]/myTrack1D.erx[counterH];
327  phiProjectionSL1(1,0) += myTrack1D.zc[counterH]/myTrack1D.erx[counterH];
328  phiProjectionSL1(1,1) += myTrack1D.zc[counterH]*myTrack1D.zc[counterH]/myTrack1D.erx[counterH];
329  bphiProjectionSL1(0,0) += myTrack1D.xc[counterH]/myTrack1D.erx[counterH];
330  bphiProjectionSL1(1,0) += myTrack1D.xc[counterH]*myTrack1D.zc[counterH]/myTrack1D.erx[counterH];
331  SL1_z_ave += myTrack1D.zc[counterH];
332  } else {
333  numh3++;
334  phiProjectionSL3(0,0) += 1.0/myTrack1D.erx[counterH];
335  phiProjectionSL3(0,1) += myTrack1D.zc[counterH]/myTrack1D.erx[counterH];
336  phiProjectionSL3(1,0) += myTrack1D.zc[counterH]/myTrack1D.erx[counterH];
337  phiProjectionSL3(1,1) += myTrack1D.zc[counterH]*myTrack1D.zc[counterH]/myTrack1D.erx[counterH];
338  bphiProjectionSL3(0,0) += myTrack1D.xc[counterH]/myTrack1D.erx[counterH];
339  bphiProjectionSL3(1,0) += myTrack1D.xc[counterH]*myTrack1D.zc[counterH]/myTrack1D.erx[counterH];
340  SL3_z_ave += myTrack1D.zc[counterH];
341  }
342  }
343  }
344  }
345 
346  SL1_z_ave /= 4.0;
347  SL3_z_ave /= 4.0;
348 
349  if (phiProjection(0,0) != 0 && phiProjectionSL1(0,0) != 0 && phiProjectionSL3(0,0) != 0 &&
350  (thetaProjection(0,0) != 0 || id[counter][1] == 4)) {
351 
352  wh[nseg] = id[counter][0];
353  st[nseg] = id[counter][1];
354  sr[nseg] = id[counter][2];
355 
356  if(thetaProjection(0,0) != 0 && id[counter][1] != 4) { // Already asked (almost)
357  thetaProjection.Invert();
358  TMatrixD solution = thetaProjection*bthetaProjection;
359  ySl[nseg] = solution(0,0);
360  dydzSl[nseg] = solution(1,0);
361  eySl[nseg] = thetaProjection(0,0);
362  edydzSl[nseg] = thetaProjection(1,1);
363  eydydzSl[nseg] = thetaProjection(0,1);
364  }
365  phiProjection.Invert();
366  phiProjectionSL1.Invert();
367  phiProjectionSL3.Invert();
368  TMatrixD solution = phiProjection*bphiProjection;
369  TMatrixD solutionSL1 = phiProjectionSL1*bphiProjectionSL1;
370  TMatrixD solutionSL3 = phiProjectionSL3*bphiProjectionSL3;
371  xSl[nseg] = solution(0,0);
372  dxdzSl[nseg] = solution(1,0);
373  exSl[nseg] = phiProjection(0,0);
374  edxdzSl[nseg] = phiProjection(1,1);
375  exdxdzSl[nseg] = phiProjection(0,0);
376  xSlSL1[nseg] = solutionSL1(0,0);
377  dxdzSlSL1[nseg] = solutionSL1(1,0);
378  exSlSL1[nseg] = phiProjectionSL1(0,0);
379  edxdzSlSL1[nseg] = phiProjectionSL1(1,1);
380  exdxdzSlSL1[nseg] = phiProjectionSL1(0,0);
381  xSL1SL3[nseg] = solutionSL1(0,0) + SL3_z_ave * solutionSL1(1,0);
382  xSlSL3[nseg] = solutionSL3(0,0);
383  dxdzSlSL3[nseg] = solutionSL3(1,0);
384  exSlSL3[nseg] = phiProjectionSL3(0,0);
385  edxdzSlSL3[nseg] = phiProjectionSL3(1,1);
386  exdxdzSlSL3[nseg] = phiProjectionSL3(0,0);
387  xSL3SL1[nseg] = solutionSL3(0,0) + SL1_z_ave * solutionSL3(1,0);
388  int hitcounter = 0;
389  for(int counterH = 0; counterH < myTrack1D.nhits; ++counterH) {
390  if(myTrack1D.wh[counterH] == wh[nseg] && myTrack1D.st[counterH] == st[nseg] &&
391  myTrack1D.sr[counterH] == sr[nseg]) {
392  xc[nseg][hitcounter] = myTrack1D.xc[counterH];
393  yc[nseg][hitcounter] = myTrack1D.yc[counterH];
394  zc[nseg][hitcounter] = myTrack1D.zc[counterH];
395  ex[nseg][hitcounter] = myTrack1D.erx[counterH];
396  xcp[nseg][hitcounter] = xSl[nseg]+dxdzSl[nseg]*myTrack1D.zc[counterH];
397  ycp[nseg][hitcounter] = ySl[nseg]+dydzSl[nseg]*myTrack1D.zc[counterH];
398  excp[nseg][hitcounter] = exSl[nseg]*exSl[nseg]+ (edxdzSl[nseg]*edxdzSl[nseg])*myTrack1D.zc[counterH];
399  eycp[nseg][hitcounter] = eySl[nseg]*eySl[nseg]+ (edydzSl[nseg]*edydzSl[nseg])*myTrack1D.zc[counterH];
400  sl[nseg][hitcounter] = myTrack1D.sl[counterH];
401  la[nseg][hitcounter] = myTrack1D.la[counterH];
402  saveThis = true;
403  hitcounter++;
404  }
405  }
406  nphihits[nseg] = id[counter][3];
407  nthetahits[nseg] = id[counter][4];
408  nhits[nseg] = hitcounter;
409  nseg++;
410  }
411  }
412  }
413  return saveThis;
414 }
#define MAX_SEGMENT
int k[5][pyjets_maxn]
static std::atomic< unsigned int > counter
#define MAX_HIT_CHAM
void MuonDTLocalMillepedeAlgorithm::initialize ( const edm::EventSetup setup,
AlignableTracker tracker,
AlignableMuon muon,
AlignmentParameterStore store 
)

Call at beginning of job.

Definition at line 86 of file MuonDTLocalMillepedeAlgorithm.cc.

References AlignmentParameterStore::alignables(), theAlignableDetAccessor, theAlignables, and theAlignmentParameterStore.

89 {
90 
91  // accessor Det->AlignableDet
92  if ( !muon )
94  else if ( !tracker )
96  else
97  theAlignableDetAccessor = new AlignableNavigator(tracker,muon);
98 
99  // set alignmentParameterStore
101 
102  // get alignables
104 
105 }
AlignmentParameterStore * theAlignmentParameterStore
const align::Alignables & alignables(void) const
get all alignables
void MuonDTLocalMillepedeAlgorithm::run ( const edm::EventSetup setup,
const EventInfo eventInfo 
)
virtual

Run the algorithm on trajectories and tracks.

Implements AlignmentAlgorithmBase.

Definition at line 132 of file MuonDTLocalMillepedeAlgorithm.cc.

References build4DSegments(), charge, reco::TrackBase::charge(), DetId::det(), TrackingRecHit::det(), MuonDTLocalMillepedeAlgorithm::Info1D::erx, eta, reco::TrackBase::eta(), GeomDet::geographicalId(), TrackingRecHit::isValid(), MuonDTLocalMillepedeAlgorithm::Info1D::la, Trajectory::measurements(), myTrack1D, MuonDTLocalMillepedeAlgorithm::Info1D::nhits, p, reco::TrackBase::p(), phi, reco::TrackBase::phi(), pt, reco::TrackBase::pt(), ptMax, DetId::rawId(), TrajectoryMeasurement::recHit(), MuonDTLocalMillepedeAlgorithm::Info1D::sl, MuonDTLocalMillepedeAlgorithm::Info1D::sr, MuonDTLocalMillepedeAlgorithm::Info1D::st, DetId::subdetId(), theAlignableDetAccessor, GeomDet::toGlobal(), testEve_cfg::tracks, AlignmentAlgorithmBase::EventInfo::trajTrackPairs(), ttreeOutput, MuonDTLocalMillepedeAlgorithm::Info1D::wh, workingmode, PV3DBase< T, PVType, FrameType >::x(), MuonDTLocalMillepedeAlgorithm::Info1D::xc, PV3DBase< T, PVType, FrameType >::y(), MuonDTLocalMillepedeAlgorithm::Info1D::yc, PV3DBase< T, PVType, FrameType >::z(), and MuonDTLocalMillepedeAlgorithm::Info1D::zc.

Referenced by Types.EventID::cppID(), and Types.LuminosityBlockID::cppID().

134 {
135 
136  //Only important in the production mode
137  if(workingmode != 0) return;
138 
139  const ConstTrajTrackPairCollection &tracks = eventInfo.trajTrackPairs();
140  for( ConstTrajTrackPairCollection::const_iterator it=tracks.begin();
141  it!=tracks.end();it++) {
142 
143  const Trajectory *traj = (*it).first;
144  const reco::Track *track = (*it).second;
145 
146  p = track->p();
147  pt = track->pt();
148  eta = track->eta();
149  phi = track->phi();
150  charge = track->charge();
151 
152 
153  if(pt < ptMin || pt > ptMax) continue;
154 
155  vector<const TransientTrackingRecHit*> hitvec;
156  vector<TrajectoryMeasurement> measurements = traj->measurements();
157 
158  //In this loop the measurements and hits are extracted and put into two vectors
159  int ch_muons = 0;
160  for (vector<TrajectoryMeasurement>::iterator im=measurements.begin();
161  im!=measurements.end(); im++) {
162  TrajectoryMeasurement meas = *im;
163  const TransientTrackingRecHit* hit = &(*meas.recHit());
164  //We are not very strict at this point
165  if (hit->isValid()) {
166  if(hit->det()->geographicalId().det() == 2 && hit->det()->geographicalId().subdetId() == 1) {
167  hitvec.push_back(hit);
168  ch_muons++;
169  }
170  }
171  }
172 
173 
174  vector<const TransientTrackingRecHit*>::const_iterator ihit=hitvec.begin();
175  //Information is stored temporally in the myTrack1D object, which is analyzed
176  //in the build4DSegments method in order to associate hits to segments.
177  int ch_counter = 0;
178  while (ihit != hitvec.end())
179  {
180  const GeomDet* det=(*ihit)->det();
181  if(det->geographicalId().det() == 2) {
182  if(det->geographicalId().subdetId() == 1) {
183  DTLayerId mLayer(det->geographicalId().rawId());
184  DTChamberId mChamber(mLayer.wheel(), mLayer.station(), mLayer.sector());
185  AlignableDet *aliDet = theAlignableDetAccessor->alignableDetFromDetId(mChamber);
186  myTrack1D.wh[ch_counter] = mLayer.wheel();
187  myTrack1D.st[ch_counter] = mLayer.station();
188  myTrack1D.sr[ch_counter] = mLayer.sector();
189  myTrack1D.sl[ch_counter] = mLayer.superlayer();
190  myTrack1D.la[ch_counter] = mLayer.layer();
191  myTrack1D.erx[ch_counter] = (*ihit)->localPositionError().xx();
192  align::GlobalPoint globhit = det->toGlobal((*ihit)->localPosition());
193  align::LocalPoint seghit = aliDet->surface().toLocal(globhit);
194  myTrack1D.xc[ch_counter] = seghit.x();
195  myTrack1D.yc[ch_counter] = seghit.y();
196  myTrack1D.zc[ch_counter] = seghit.z();
197  ch_counter++;
198  }
199  }
200  ihit++;
201  }
202  myTrack1D.nhits = ch_counter;
203  if(build4DSegments()) ttreeOutput->Fill();
204  }
205 
206 }
double p() const
momentum vector magnitude
Definition: TrackBase.h:127
ConstRecHitPointer const & recHit() const
GlobalPoint toGlobal(const Local2DPoint &lp) const
Conversion to the global R.F. from the R.F. of the GeomDet.
Definition: GeomDet.h:47
T y() const
Definition: PV3DBase.h:63
double phi() const
azimuthal angle of momentum vector
Definition: TrackBase.h:137
uint32_t rawId() const
get the raw id
Definition: DetId.h:43
DataContainer const & measurements() const
Definition: Trajectory.h:203
double eta() const
pseudorapidity of momentum vector
Definition: TrackBase.h:139
const GeomDet * det() const
double pt() const
track transverse momentum
Definition: TrackBase.h:129
T z() const
Definition: PV3DBase.h:64
DetId geographicalId() const
The label of this GeomDet.
Definition: GeomDet.h:72
int subdetId() const
get the contents of the subdetector field (not cast into any detector&#39;s numbering enum) ...
Definition: DetId.h:37
tuple tracks
Definition: testEve_cfg.py:39
bool isValid() const
int charge() const
track electric charge
Definition: TrackBase.h:111
Detector det() const
get the detector field from this detid
Definition: DetId.h:35
T x() const
Definition: PV3DBase.h:62
std::vector< ConstTrajTrackPair > ConstTrajTrackPairCollection
void MuonDTLocalMillepedeAlgorithm::setBranchTrees ( )
private

Definition at line 419 of file MuonDTLocalMillepedeAlgorithm.cc.

References charge, dxdzSl, dxdzSlSL1, dxdzSlSL3, dydzSl, edxdzSl, edxdzSlSL1, edxdzSlSL3, edydzSl, eta, ex, excp, exSl, exSlSL1, exSlSL3, eycp, eydydzSl, eySl, la, nhits, nphihits, nseg, nthetahits, p, phi, pt, sl, sr, st, ttreeOutput, wh, xc, xcp, xSl, xSL1SL3, xSL3SL1, xSlSL1, xSlSL3, yc, ycp, ySl, and zc.

Referenced by MuonDTLocalMillepedeAlgorithm().

419  {
420 
421  ttreeOutput = new TTree("InfoTuple", "InfoTuple");
422 
423  ttreeOutput->Branch("p", &p, "p/F");
424  ttreeOutput->Branch("pt", &pt, "pt/F");
425  ttreeOutput->Branch("eta", &eta, "eta/F");
426  ttreeOutput->Branch("phi", &phi, "phi/F");
427  ttreeOutput->Branch("charge", &charge, "charge/F");
428  ttreeOutput->Branch("nseg", &nseg, "nseg/I");
429  ttreeOutput->Branch("nphihits", nphihits, "nphihits[nseg]/I");
430  ttreeOutput->Branch("nthetahits", nthetahits, "nthetahits[nseg]/I");
431  ttreeOutput->Branch("nhits", nhits, "nhits[nseg]/I");
432  ttreeOutput->Branch("xSl", xSl, "xSl[nseg]/F");
433  ttreeOutput->Branch("dxdzSl", dxdzSl, "dxdzSl[nseg]/F");
434  ttreeOutput->Branch("exSl", exSl, "exSl[nseg]/F");
435  ttreeOutput->Branch("edxdzSl", edxdzSl, "edxdzSl[nseg]/F");
436  ttreeOutput->Branch("exdxdzSl", edxdzSl, "exdxdzSl[nseg]/F");
437  ttreeOutput->Branch("ySl", ySl, "ySl[nseg]/F");
438  ttreeOutput->Branch("dydzSl", dydzSl, "dydzSl[nseg]/F");
439  ttreeOutput->Branch("eySl", eySl, "eySl[nseg]/F");
440  ttreeOutput->Branch("edydzSl", edydzSl, "edydzSl[nseg]/F");
441  ttreeOutput->Branch("eydydzSl", eydydzSl, "eydydzSl[nseg]/F");
442  ttreeOutput->Branch("xSlSL1", xSlSL1, "xSlSL1[nseg]/F");
443  ttreeOutput->Branch("dxdzSlSL1", dxdzSlSL1, "dxdzSlSL1[nseg]/F");
444  ttreeOutput->Branch("exSlSL1", exSlSL1, "exSlSL1[nseg]/F");
445  ttreeOutput->Branch("edxdzSlSL1", edxdzSlSL1, "edxdzSlSL1[nseg]/F");
446  ttreeOutput->Branch("xSL1SL3", xSL1SL3, "xSL1SL3[nseg]/F");
447  ttreeOutput->Branch("xSlSL3", xSlSL3, "xSlSL3[nseg]/F");
448  ttreeOutput->Branch("dxdzSlSL3", dxdzSlSL3, "dxdzSlSL3[nseg]/F");
449  ttreeOutput->Branch("exSlSL3", exSlSL3, "exSlSL3[nseg]/F");
450  ttreeOutput->Branch("edxdzSlSL3", edxdzSlSL3, "edxdzSlSL3[nseg]/F");
451  ttreeOutput->Branch("xSL3SL1", xSL3SL1, "xSL3SL1[nseg]/F");
452  ttreeOutput->Branch("xc", xc, "xc[nseg][14]/F");
453  ttreeOutput->Branch("yc", yc, "yc[nseg][14]/F");
454  ttreeOutput->Branch("zc", zc, "zc[nseg][14]/F");
455  ttreeOutput->Branch("ex", ex, "ex[nseg][14]/F");
456  ttreeOutput->Branch("xcp", xcp, "xcp[nseg][14]/F");
457  ttreeOutput->Branch("ycp", ycp, "ycp[nseg][14]/F");
458  ttreeOutput->Branch("excp", excp, "excp[nseg][14]/F");
459  ttreeOutput->Branch("eycp", eycp, "eycp[nseg][14]/F");
460  ttreeOutput->Branch("wh", wh, "wh[nseg]/I");
461  ttreeOutput->Branch("st", st, "st[nseg]/I");
462  ttreeOutput->Branch("sr", sr, "sr[nseg]/I");
463  ttreeOutput->Branch("sl", sl, "sl[nseg][14]/I");
464  ttreeOutput->Branch("la", la, "la[nseg][14]/I");
465 
466 }
void MuonDTLocalMillepedeAlgorithm::terminate ( void  )

Call at end of job.

Definition at line 110 of file MuonDTLocalMillepedeAlgorithm.cc.

References f, nMtxSection, nPhihits, nThetahits, ntuplePath, numberOfRootFiles, ptMax, ptMin, and workingmode.

111 {
112 
113  //If workingmode equals 1 or 2, the algorithms are run before saving.
114  if(workingmode == 1) {
115  edm::LogInfo("Alignment") << "[MuonDTLocalMillepedeAlgorithm] Starting SLToSL algorithm";
117  } else if(workingmode >= 2) {
118  edm::LogInfo("Alignment") << "[MuonDTLocalMillepedeAlgorithm] Starting local MuonMillepede algorithm";
120  }
121 
122  if (workingmode==0) {
123  f->Write();
124  f->Close();
125  }
126 
127 }

Member Data Documentation

float MuonDTLocalMillepedeAlgorithm::charge
private
edm::InputTag MuonDTLocalMillepedeAlgorithm::consTraj
private

Definition at line 135 of file MuonDTLocalMillepedeAlgorithm.h.

float MuonDTLocalMillepedeAlgorithm::dxdzSl[5]
private

Definition at line 84 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::dxdzSlSL1[5]
private

Definition at line 94 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::dxdzSlSL3[5]
private

Definition at line 100 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::dydzSl[5]
private

Definition at line 89 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::edxdzSl[5]
private

Definition at line 86 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::edxdzSlSL1[5]
private

Definition at line 96 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::edxdzSlSL3[5]
private

Definition at line 102 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::edydzSl[5]
private

Definition at line 91 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::eta
private

Definition at line 78 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by run(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::ex[5][14]
private

Definition at line 108 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::excp[5][14]
private

Definition at line 111 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::exdxdzSl[5]
private

Definition at line 87 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments().

float MuonDTLocalMillepedeAlgorithm::exdxdzSlSL1[5]
private

Definition at line 97 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments().

float MuonDTLocalMillepedeAlgorithm::exdxdzSlSL3[5]
private

Definition at line 103 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments().

float MuonDTLocalMillepedeAlgorithm::exSl[5]
private

Definition at line 85 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::exSlSL1[5]
private

Definition at line 95 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::exSlSL3[5]
private

Definition at line 101 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::eycp[5][14]
private

Definition at line 112 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::eydydzSl[5]
private

Definition at line 92 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::eySl[5]
private

Definition at line 90 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

TFile* MuonDTLocalMillepedeAlgorithm::f
private
edm::Service<TFileService> MuonDTLocalMillepedeAlgorithm::fs
private

Definition at line 132 of file MuonDTLocalMillepedeAlgorithm.h.

edm::InputTag MuonDTLocalMillepedeAlgorithm::globalTracks
private

Definition at line 134 of file MuonDTLocalMillepedeAlgorithm.h.

int MuonDTLocalMillepedeAlgorithm::la[5][14]
private

Definition at line 115 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::meandxdz[5][4][14]
private

Definition at line 154 of file MuonDTLocalMillepedeAlgorithm.h.

float MuonDTLocalMillepedeAlgorithm::meandydz[5][4][14]
private

Definition at line 158 of file MuonDTLocalMillepedeAlgorithm.h.

float MuonDTLocalMillepedeAlgorithm::meanx[5][4][14]
private

Definition at line 152 of file MuonDTLocalMillepedeAlgorithm.h.

float MuonDTLocalMillepedeAlgorithm::meany[5][4][14]
private

Definition at line 156 of file MuonDTLocalMillepedeAlgorithm.h.

Info1D MuonDTLocalMillepedeAlgorithm::myTrack1D
private

Definition at line 73 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and run().

int MuonDTLocalMillepedeAlgorithm::nhits[5]
private

Definition at line 82 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

int MuonDTLocalMillepedeAlgorithm::nMtxSection
private

Definition at line 143 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by MuonDTLocalMillepedeAlgorithm(), and terminate().

int MuonDTLocalMillepedeAlgorithm::nphihits[5]
private

Definition at line 80 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::nPhihits
private
int MuonDTLocalMillepedeAlgorithm::nseg
private

Definition at line 79 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

int MuonDTLocalMillepedeAlgorithm::nthetahits[5]
private

Definition at line 81 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::nThetahits
private
std::string MuonDTLocalMillepedeAlgorithm::ntuplePath
private

Definition at line 136 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by MuonDTLocalMillepedeAlgorithm(), and terminate().

int MuonDTLocalMillepedeAlgorithm::numberOfRootFiles
private

Definition at line 142 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by MuonDTLocalMillepedeAlgorithm(), and terminate().

float MuonDTLocalMillepedeAlgorithm::numberOfSigmasDXDZ
private

Definition at line 148 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by MuonDTLocalMillepedeAlgorithm().

float MuonDTLocalMillepedeAlgorithm::numberOfSigmasDYDZ
private

Definition at line 150 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by MuonDTLocalMillepedeAlgorithm().

float MuonDTLocalMillepedeAlgorithm::numberOfSigmasX
private

Definition at line 147 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by MuonDTLocalMillepedeAlgorithm().

float MuonDTLocalMillepedeAlgorithm::numberOfSigmasY
private

Definition at line 149 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by MuonDTLocalMillepedeAlgorithm().

float MuonDTLocalMillepedeAlgorithm::p
private
float MuonDTLocalMillepedeAlgorithm::phi
private

Definition at line 78 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by run(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::pt
private

Definition at line 78 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by run(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::ptMax
private

Definition at line 137 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by MuonDTLocalMillepedeAlgorithm(), run(), and terminate().

float MuonDTLocalMillepedeAlgorithm::ptMin
private

Definition at line 138 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by MuonDTLocalMillepedeAlgorithm(), and terminate().

float MuonDTLocalMillepedeAlgorithm::sigmadxdz[5][4][14]
private

Definition at line 155 of file MuonDTLocalMillepedeAlgorithm.h.

float MuonDTLocalMillepedeAlgorithm::sigmadydz[5][4][14]
private

Definition at line 159 of file MuonDTLocalMillepedeAlgorithm.h.

float MuonDTLocalMillepedeAlgorithm::sigmax[5][4][14]
private

Definition at line 153 of file MuonDTLocalMillepedeAlgorithm.h.

float MuonDTLocalMillepedeAlgorithm::sigmay[5][4][14]
private

Definition at line 157 of file MuonDTLocalMillepedeAlgorithm.h.

int MuonDTLocalMillepedeAlgorithm::sl[5][14]
private

Definition at line 114 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

int MuonDTLocalMillepedeAlgorithm::sr[5]
private

Definition at line 113 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

int MuonDTLocalMillepedeAlgorithm::st[5]
private

Definition at line 113 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

TChain* MuonDTLocalMillepedeAlgorithm::tali
private

Definition at line 124 of file MuonDTLocalMillepedeAlgorithm.h.

AlignableNavigator* MuonDTLocalMillepedeAlgorithm::theAlignableDetAccessor
private

Definition at line 129 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by initialize(), and run().

std::vector<Alignable*> MuonDTLocalMillepedeAlgorithm::theAlignables
private

Definition at line 128 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by initialize().

AlignmentParameterStore* MuonDTLocalMillepedeAlgorithm::theAlignmentParameterStore
private

Definition at line 127 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by initialize().

TTree* MuonDTLocalMillepedeAlgorithm::ttreeOutput
private

Definition at line 123 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by run(), and setBranchTrees().

int MuonDTLocalMillepedeAlgorithm::wh[5]
private

Definition at line 113 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

int MuonDTLocalMillepedeAlgorithm::workingmode
private

Definition at line 141 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by MuonDTLocalMillepedeAlgorithm(), run(), and terminate().

float MuonDTLocalMillepedeAlgorithm::xc[5][14]
private

Definition at line 105 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::xcp[5][14]
private

Definition at line 109 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::xSl[5]
private

Definition at line 83 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::xSL1SL3[5]
private

Definition at line 98 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::xSL3SL1[5]
private

Definition at line 104 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::xSlSL1[5]
private

Definition at line 93 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::xSlSL3[5]
private

Definition at line 99 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::yc[5][14]
private

Definition at line 106 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::ycp[5][14]
private

Definition at line 110 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::ySl[5]
private

Definition at line 88 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().

float MuonDTLocalMillepedeAlgorithm::zc[5][14]
private

Definition at line 107 of file MuonDTLocalMillepedeAlgorithm.h.

Referenced by build4DSegments(), and setBranchTrees().