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AngleConverter Class Reference

#include <AngleConverter.h>

Public Member Functions

 AngleConverter ()
 
void checkAndUpdateGeometry (const edm::EventSetup &, unsigned int)
 Update the Geometry with current Event Setup. More...
 
int getGlobalEta (unsigned int rawid, const L1MuDTChambPhDigi &aDigi, const L1MuDTChambThContainer *dtThDigis)
 Convert local eta coordinate to global digital microGMT scale. More...
 
int getGlobalEta (unsigned int rawid, const CSCCorrelatedLCTDigi &aDigi)
 Convert local eta coordinate to global digital microGMT scale. More...
 
int getGlobalEta (unsigned int rawid, const unsigned int &aDigi)
 Convert local eta coordinate to global digital microGMT scale. More...
 
int getProcessorPhi (unsigned int iProcessor, l1t::tftype part, const L1MuDTChambPhDigi &digi) const
 
int getProcessorPhi (unsigned int iProcessor, l1t::tftype part, const CSCDetId &csc, const CSCCorrelatedLCTDigi &digi) const
 
int getProcessorPhi (unsigned int iProcessor, l1t::tftype part, const RPCDetId &rollId, const unsigned int &digi) const
 
int getProcessorPhi (unsigned int iProcessor, l1t::tftype part, const RPCDetId &rollId, const unsigned int &digi1, const unsigned int &digi2) const
 
 ~AngleConverter ()
 

Private Member Functions

const int findBTIgroup (const L1MuDTChambPhDigi &aDigi, const L1MuDTChambThContainer *dtThDigis)
 Find BTI group. More...
 
bool isCSCCounterClockwise (const std::unique_ptr< const CSCLayer > &layer) const
 Check orientation of strips in given CSC chamber. More...
 

Private Attributes

edm::ESHandle< CSCGeometry_geocsc
 
edm::ESHandle< DTGeometry_geodt
 
unsigned long long _geom_cache_id
 
edm::ESHandle< RPCGeometry_georpc
 
unsigned int nPhiBins
 Number of phi bins along 2Pi. More...
 

Detailed Description

Definition at line 27 of file AngleConverter.h.

Constructor & Destructor Documentation

AngleConverter::AngleConverter ( )

Definition at line 108 of file AngleConverter.cc.

108 : _geom_cache_id(0ULL) { }
unsigned long long _geom_cache_id
AngleConverter::~AngleConverter ( )

Definition at line 111 of file AngleConverter.cc.

111 { }

Member Function Documentation

void AngleConverter::checkAndUpdateGeometry ( const edm::EventSetup es,
unsigned int  phiBins 
)

Update the Geometry with current Event Setup.

Definition at line 114 of file AngleConverter.cc.

References _geocsc, _geodt, _geom_cache_id, _georpc, edm::eventsetup::EventSetupRecord::cacheIdentifier(), relativeConstraints::geom, edm::EventSetup::get(), edm::eventsetup::DependentRecordImplementation< RecordT, ListT >::get(), and nPhiBins.

Referenced by OMTFinputMaker::initialize().

114  {
116  unsigned long long geomid = geom.cacheIdentifier();
117  if( _geom_cache_id != geomid ) {
118  geom.get(_georpc);
119  geom.get(_geocsc);
120  geom.get(_geodt);
121  _geom_cache_id = geomid;
122  }
123 
124  nPhiBins = phiBins;
125 
126 }
unsigned long long cacheIdentifier() const
unsigned long long _geom_cache_id
ProductT const & get(ESGetToken< ProductT, DepRecordT > const &iToken) const
unsigned int nPhiBins
Number of phi bins along 2Pi.
T get() const
Definition: EventSetup.h:71
edm::ESHandle< CSCGeometry > _geocsc
edm::ESHandle< RPCGeometry > _georpc
edm::ESHandle< DTGeometry > _geodt
const int AngleConverter::findBTIgroup ( const L1MuDTChambPhDigi aDigi,
const L1MuDTChambThContainer dtThDigis 
)
private

Find BTI group.

If there are more than one theta digi we do not take is due to unresolvet ambiguity. In this case we take eta of the middle of the chamber.

Definition at line 438 of file AngleConverter.cc.

References L1MuDTChambPhDigi::bxNum(), L1MuDTChambThContainer::chThetaSegm(), mps_fire::i, L1MuDTChambThDigi::position(), L1MuDTChambPhDigi::scNum(), L1MuDTChambPhDigi::stNum(), and L1MuDTChambPhDigi::whNum().

439  {
440 
441  int bti_group = -1;
442 
443  const L1MuDTChambThDigi *theta_segm = dtThDigis->chThetaSegm(aDigi.whNum(),
444  aDigi.stNum(),
445  aDigi.scNum(),
446  aDigi.bxNum());
447  if(!theta_segm) return bti_group;
448 
449  for(unsigned int i = 0; i < 7; ++i ){
450  if(theta_segm->position(i) && bti_group<0) bti_group = i;
454  else if(theta_segm->position(i) && bti_group>-1) return -1;
455  }
456 
457  return bti_group;
458 }
int position(const int i) const
L1MuDTChambThDigi const * chThetaSegm(int wheel, int stat, int sect, int bx) const
int AngleConverter::getGlobalEta ( unsigned int  rawid,
const L1MuDTChambPhDigi aDigi,
const L1MuDTChambThContainer dtThDigis 
)

Convert local eta coordinate to global digital microGMT scale.

Definition at line 276 of file AngleConverter.cc.

References _geodt, L1MuDTChambPhDigi::bxNum(), DTGeometry::chamber(), L1MuDTChambThContainer::chThetaSegm(), PV3DBase< T, PVType, FrameType >::eta(), mps_fire::i, L1MuDTChambThDigi::position(), L1MuDTChambPhDigi::scNum(), FWPFMaths::sgn(), L1MuDTChambPhDigi::stNum(), and L1MuDTChambPhDigi::whNum().

Referenced by OMTFinputMaker::processCSC(), OMTFinputMaker::processDT(), and OMTFinputMaker::processRPC().

278  {
279 
280 
281  const DTChamberId baseid(aDigi.whNum(),aDigi.stNum(),aDigi.scNum()+1);
282 
283  // do not use this pointer for anything other than creating a trig geom
284  std::unique_ptr<DTChamber> chamb(const_cast<DTChamber*>(_geodt->chamber(baseid)));
285 
286  std::unique_ptr<DTTrigGeom> trig_geom( new DTTrigGeom(chamb.get(),false) );
287  chamb.release(); // release it here so no one gets funny ideas
288  // super layer one is the theta superlayer in a DT chamber
289  // station 4 does not have a theta super layer
290  // the BTI index from the theta trigger is an OR of some BTI outputs
291  // so, we choose the BTI that's in the middle of the group
292  // as the BTI that we get theta from
293  // TODO:::::>>> need to make sure this ordering doesn't flip under wheel sign
294  const int NBTI_theta = ( (baseid.station() != 4) ? trig_geom->nCell(2) : trig_geom->nCell(3) );
295 
296 // const int bti_group = findBTIgroup(aDigi,dtThDigis);
297 // const unsigned bti_actual = bti_group*NBTI_theta/7 + NBTI_theta/14 + 1;
298 // DTBtiId thetaBTI;
299 // if ( baseid.station() != 4 && bti_group != -1) {
300 // thetaBTI = DTBtiId(baseid,2,bti_actual);
301 // } else {
302 // // since this is phi oriented it'll give us theta in the middle
303 // // of the chamber
304 // thetaBTI = DTBtiId(baseid,3,1);
305 // }
306 // const GlobalPoint theta_gp = trig_geom->CMSPosition(thetaBTI);
307 // int iEta = theta_gp.eta()/2.61*240;
308 // return iEta;
309 
310  const L1MuDTChambThDigi *theta_segm = dtThDigis->chThetaSegm(aDigi.whNum(), aDigi.stNum(), aDigi.scNum(), aDigi.bxNum());
311  int bti_group = -1;
312  if (theta_segm) {
313  for(unsigned int i = 0; i < 7; ++i ) if(theta_segm->position(i) && bti_group<0) bti_group = i;
314  else if(theta_segm->position(i) && bti_group>-1) bti_group = 511;
315  }
316 
317  int iEta = 0;
318  if (bti_group == 511) iEta = 95;
319  else if ( bti_group == -1 && aDigi.stNum() == 1) iEta = 92;
320  else if ( bti_group == -1 && aDigi.stNum() == 2) iEta = 79;
321  else if ( bti_group == -1 && aDigi.stNum() == 3) iEta = 75;
322  else if (baseid.station() != 4 && bti_group >= 0) {
323 // bti_group = 6-bti_group;
324  unsigned bti_actual = bti_group*NBTI_theta/7 + NBTI_theta/14 + 1;
325  DTBtiId thetaBTI = DTBtiId(baseid,2,bti_actual);
326  GlobalPoint theta_gp = trig_geom->CMSPosition(thetaBTI);
327  iEta = etaVal2Code( fabs(theta_gp.eta()) );
328  }
329  int signEta = sgn(aDigi.whNum());
330  iEta *= signEta;
331  return iEta;
332 }
const DTChamber * chamber(const DTChamberId &id) const
Return a DTChamber given its id.
Definition: DTGeometry.cc:117
float sgn(float val)
Definition: FWPFMaths.cc:9
int position(const int i) const
L1MuDTChambThDigi const * chThetaSegm(int wheel, int stat, int sect, int bx) const
T eta() const
Definition: PV3DBase.h:76
edm::ESHandle< DTGeometry > _geodt
int AngleConverter::getGlobalEta ( unsigned int  rawid,
const CSCCorrelatedLCTDigi aDigi 
)

Convert local eta coordinate to global digital microGMT scale.

Code taken from GeometryTranslator.

Will be replaced by direct CSC phi local to global scale transformation as used in FPGA implementation

Definition at line 336 of file AngleConverter.cc.

References _geocsc, CSCGeometry::chamber(), CSCPatternLUT::get2007Position(), CSCCorrelatedLCTDigi::getKeyWG(), CSCCorrelatedLCTDigi::getPattern(), CSCCorrelatedLCTDigi::getStrip(), triggerObjects_cff::id, isCSCCounterClockwise(), CSCConstants::KEY_ALCT_LAYER, PV3DBase< T, PVType, FrameType >::mag(), PFRecoTauDiscriminationByIsolation_cfi::offset, listBenchmarks::pattern, PV3DBase< T, PVType, FrameType >::phi(), digitizers_cfi::strip, and PV3DBase< T, PVType, FrameType >::theta().

336  {
337 
341 
342 
343  // alot of this is transcription and consolidation of the CSC
344  // global phi calculation code
345  // this works directly with the geometry
346  // rather than using the old phi luts
347  const CSCDetId id(rawid);
348  // we should change this to weak_ptrs at some point
349  // requires introducing std::shared_ptrs to geometry
350  std::unique_ptr<const CSCChamber> chamb(_geocsc->chamber(id));
351  std::unique_ptr<const CSCLayerGeometry> layer_geom(
352  chamb->layer(CSCConstants::KEY_ALCT_LAYER)->geometry()
353  );
354  std::unique_ptr<const CSCLayer> layer(
355  chamb->layer(CSCConstants::KEY_ALCT_LAYER)
356  );
357 
358  const uint16_t halfstrip = aDigi.getStrip();
359  const uint16_t pattern = aDigi.getPattern();
360  const uint16_t keyWG = aDigi.getKeyWG();
361  //const unsigned maxStrips = layer_geom->numberOfStrips();
362 
363  // so we can extend this later
364  // assume TMB2007 half-strips only as baseline
365  double offset = 0.0;
366  switch(1) {
367  case 1:
368  offset = CSCPatternLUT::get2007Position(pattern);
369  }
370  const unsigned halfstrip_offs = unsigned(0.5 + halfstrip + offset);
371  const unsigned strip = halfstrip_offs/2 + 1; // geom starts from 1
372 
373  // the rough location of the hit at the ALCT key layer
374  // we will refine this using the half strip information
375  const LocalPoint coarse_lp =
376  layer_geom->stripWireGroupIntersection(strip,keyWG);
377  const GlobalPoint coarse_gp = layer->surface().toGlobal(coarse_lp);
378 
379  // the strip width/4.0 gives the offset of the half-strip
380  // center with respect to the strip center
381  const double hs_offset = layer_geom->stripPhiPitch()/4.0;
382 
383  // determine handedness of the chamber
384  const bool ccw = isCSCCounterClockwise(layer);
385  // we need to subtract the offset of even half strips and add the odd ones
386  const double phi_offset = ( ( halfstrip_offs%2 ? 1 : -1)*
387  ( ccw ? -hs_offset : hs_offset ) );
388 
389  // the global eta calculation uses the middle of the strip
390  // so no need to increment it
391  const GlobalPoint final_gp( GlobalPoint::Polar( coarse_gp.theta(),
392  (coarse_gp.phi().value() +
393  phi_offset),
394  coarse_gp.mag() ) );
395  // release ownership of the pointers
396  chamb.release();
397  layer_geom.release();
398  layer.release();
399 
400 // std::cout <<id<<" st: " << id.station()<< "ri: "<<id.ring()<<" eta: " << final_gp.eta()
401 // <<" etaCode_simple: " << etaVal2Code( final_gp.eta() )<< " KW: "<<keyWG <<" etaKeyWG2Code: "<<etaKeyWG2Code(id,keyWG)<< std::endl;
402 // int station = (id.endcap()==1) ? id.station() : -id.station();
403 // std::cout <<"ETA_CSC: " << station <<" "<<id.ring()<<" "<< final_gp.eta()<<" "<<keyWG <<" "<< etaKeyWG2Code(id,keyWG) << std::endl;
404 
405  return etaKeyWG2Code(id,keyWG);
406 
407 // return etaVal2Code( final_gp.eta() );
408 // int iEta = final_gp.eta()/2.61*240;
409 // return iEta;
410 }
int getStrip() const
return the key halfstrip from 0,159
Geom::Phi< T > phi() const
Definition: PV3DBase.h:69
Geom::Theta< T > theta() const
Definition: PV3DBase.h:75
T mag() const
Definition: PV3DBase.h:67
bool isCSCCounterClockwise(const std::unique_ptr< const CSCLayer > &layer) const
Check orientation of strips in given CSC chamber.
static double get2007Position(int pattern)
const CSCChamber * chamber(CSCDetId id) const
Return the chamber corresponding to given DetId.
Definition: CSCGeometry.cc:133
int getPattern() const
return pattern
edm::ESHandle< CSCGeometry > _geocsc
int getKeyWG() const
return the key wire group. counts from 0.
int AngleConverter::getGlobalEta ( unsigned int  rawid,
const unsigned int &  aDigi 
)

Convert local eta coordinate to global digital microGMT scale.

Definition at line 413 of file AngleConverter.cc.

References _georpc, PV3DBase< T, PVType, FrameType >::eta(), runTauDisplay::gp, triggerObjects_cff::id, isCSCCounterClockwise(), and RPCGeometry::roll().

413  {
414 
415  const RPCDetId id(rawid);
416  std::unique_ptr<const RPCRoll> roll(_georpc->roll(id));
417  const LocalPoint lp = roll->centreOfStrip((int)strip);
418  const GlobalPoint gp = roll->toGlobal(lp);
419  roll.release();
420 
421  return etaVal2Code(gp.eta());
422 // float iEta = gp.eta()/2.61*240;
423 // return iEta;
424 
425 }
T eta() const
Definition: PV3DBase.h:76
edm::ESHandle< RPCGeometry > _georpc
const RPCRoll * roll(RPCDetId id) const
Return a roll given its id.
Definition: RPCGeometry.cc:75
int AngleConverter::getProcessorPhi ( unsigned int  iProcessor,
l1t::tftype  part,
const L1MuDTChambPhDigi digi 
) const

get phi of DT,CSC and RPC azimutal angle digi in processor scale, used by OMTF algorithm. in case of wrong phi returns OMTFConfiguration::instance()->nPhiBins

Definition at line 129 of file AngleConverter.cc.

References M_PI, nPhiBins, l1t::omtf_pos, phi, L1MuDTChambPhDigi::phi(), funct::pow(), Scenarios_cff::scale, L1MuDTChambPhDigi::scNum(), relativeConstraints::station, L1MuDTChambPhDigi::stNum(), makeMuonMisalignmentScenario::wheel, and L1MuDTChambPhDigi::whNum().

Referenced by OMTFinputMaker::processCSC(), OMTFinputMaker::processDT(), and OMTFinputMaker::processRPC().

130 {
131 
132  double hsPhiPitch = 2*M_PI/nPhiBins; // width of phi Pitch, related to halfStrip at CSC station 2
133  const int dummy = nPhiBins;
134  int processor= iProcessor+1; // FIXME: get from OMTF name when available
135  int posneg = (part==l1t::tftype::omtf_pos) ? 1 : -1; // FIXME: get from OMTF name
136 
137  int sector = digi.scNum()+1; //NOTE: there is a inconsistency in DT sector numb. Thus +1 needed to get detector numb.
138  int wheel = digi.whNum();
139  int station = digi.stNum();
140  int phiDT = digi.phi();
141 
142  if (posneg*2 != wheel) return dummy;
143  if (station > 3 ) return dummy;
144 
145  //FIXME: update the following two lines with proper method when Connections introduced
146  if (processor !=6 && !(sector >= processor*2-1 && sector <= processor*2+1) ) return dummy;
147  if (processor ==6 && !(sector >= 11 || sector==1) ) return dummy;
148 
149  // ichamber is consecutive chamber connected to processor, starting from 0 (overlaping one)
150  int ichamber = sector-1-2*(processor-1);
151  if (ichamber < 0) ichamber += 12;
152 
153  int offsetLoc = lround( ((ichamber-1)*M_PI/6+M_PI/12.)/hsPhiPitch );
154  double scale = 1./4096/hsPhiPitch;
155  int scale_coeff = lround(scale* pow(2,11));
156 // int phi = static_cast<int>(phiDT*scale) + offsetLoc;
157  int phi = floor(phiDT*scale_coeff/pow(2,11)) + offsetLoc;
158 
159  return phi;
160 }
#define M_PI
unsigned int nPhiBins
Number of phi bins along 2Pi.
part
Definition: HCALResponse.h:20
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:40
int AngleConverter::getProcessorPhi ( unsigned int  iProcessor,
l1t::tftype  part,
const CSCDetId csc,
const CSCCorrelatedLCTDigi digi 
) const

Definition at line 163 of file AngleConverter.cc.

References _geocsc, CSCLayer::centerOfStrip(), relativeConstraints::chamber, CSCDetId::chamber(), CSCGeometry::chamber(), CSCCorrelatedLCTDigi::getStrip(), CSCChamber::layer(), M_PI, nPhiBins, l1t::omtf_pos, phi, PV3DBase< T, PVType, FrameType >::phi(), CSCDetId::ring(), Scenarios_cff::scale, CSCChamber::specs(), CSCDetId::station(), CSCChamberSpecs::stripPhiPitch(), and CSCDetId::zendcap().

164 {
165 
166  const double hsPhiPitch = 2*M_PI/nPhiBins;
167  const int dummy = nPhiBins;
168  int processor= iProcessor+1; // FIXME: get from OMTF name when available
169  int posneg = (part==l1t::tftype::omtf_pos) ? 1 : -1; // FIXME: get from OMTF name
170 
171 
172 
173  // filter out chambers not connected to OMTF board
174  // FIXME: temporary - use Connections or relay that filtering done before.
175  if (posneg != csc.zendcap()) return dummy;
176  if ( csc.ring() != 3 && !(csc.ring()==2 && (csc.station()==2 || csc.station()==3 || csc.station()==1)) ) return dummy;
177  if (processor !=6) {
178  if (csc.chamber() < (processor-1)*6 + 2) return dummy;
179  if (csc.chamber() > (processor-1)*6 + 8) return dummy;
180  } else {
181  if (csc.chamber() > 2 && csc.chamber() < 32) return dummy;
182  }
183 
184  //
185  // assign number 0..6, consecutive processor for a processor
186  //
187  //int ichamber = (csc.chamber()-2-6*(processor-1));
188  //if (ichamber < 0) ichamber += 36;
189 
190  //
191  // get offset for each chamber.
192  // FIXME: These parameters depends on processor and chamber only so may be precomputed and put in map
193  //
194  const CSCChamber* chamber = _geocsc->chamber(csc);
195  const CSCChamberSpecs* cspec = chamber->specs();
196  const CSCLayer* layer = chamber->layer(3);
197  int order = ( layer->centerOfStrip(2).phi() - layer->centerOfStrip(1).phi()> 0) ? 1 : -1;
198  double stripPhiPitch = cspec->stripPhiPitch();
199  double scale = fabs(stripPhiPitch/hsPhiPitch/2.); if ( fabs(scale-1.) < 0.0002) scale=1.;
200  double phi15deg = M_PI/3.*(processor-1)+M_PI/12.;
201  double phiHalfStrip0 = layer->centerOfStrip(10).phi() - order*9*stripPhiPitch - order*stripPhiPitch/4.;
202  if ( processor==6 || phiHalfStrip0<0) phiHalfStrip0 += 2*M_PI;
203  int offsetLoc = lround( (phiHalfStrip0-phi15deg)/hsPhiPitch );
204 
205  int halfStrip = digi.getStrip(); // returns halfStrip 0..159
206  //FIXME: to be checked (only important for ME1/3) keep more bits for offset, truncate at the end
207 
208  // a quick fix for towards geometry changes due to global tag.
209  // in case of MC tag fixOff shold be identical to offsetLoc
210  int fixOff = fixCscOffsetGeom(offsetLoc);
211 
212  int phi = fixOff + order*scale*halfStrip;
213 
214 // std::cout <<" hs: "<< halfStrip <<" offset: " << offsetLoc <<" oder*scale: "<< order*scale
215 // <<" phi: " <<phi<<" ("<<offsetLoc + order*scale*halfStrip<<")"<< std::endl;
216 
217  return phi;
218 }
int chamber() const
Definition: CSCDetId.h:68
int getStrip() const
return the key halfstrip from 0,159
Geom::Phi< T > phi() const
Definition: PV3DBase.h:69
float stripPhiPitch() const
const CSCChamberSpecs * specs() const
Definition: CSCChamber.h:42
const CSCLayer * layer(CSCDetId id) const
Return the layer corresponding to the given id.
Definition: CSCChamber.cc:39
#define M_PI
unsigned int nPhiBins
Number of phi bins along 2Pi.
int ring() const
Definition: CSCDetId.h:75
short int zendcap() const
Definition: CSCDetId.h:100
GlobalPoint centerOfStrip(int strip) const
Definition: CSCLayer.cc:4
part
Definition: HCALResponse.h:20
const CSCChamber * chamber(CSCDetId id) const
Return the chamber corresponding to given DetId.
Definition: CSCGeometry.cc:133
edm::ESHandle< CSCGeometry > _geocsc
int station() const
Definition: CSCDetId.h:86
int AngleConverter::getProcessorPhi ( unsigned int  iProcessor,
l1t::tftype  part,
const RPCDetId rollId,
const unsigned int &  digi 
) const

Definition at line 250 of file AngleConverter.cc.

References _georpc, RPCRoll::centreOfStrip(), M_PI, nPhiBins, RPCGeometry::roll(), and GeomDet::toGlobal().

251 {
252 
253  const double hsPhiPitch = 2*M_PI/nPhiBins;
254  const int dummy = nPhiBins;
255  int processor = iProcessor+1;
256  const RPCRoll* roll = _georpc->roll(rollId);
257  if (!roll) return dummy;
258 
259  double phi15deg = M_PI/3.*(processor-1)+M_PI/12.; // "0" is 15degree moved cyclicaly to each processor, note [0,2pi]
260  double stripPhi = (roll->toGlobal(roll->centreOfStrip((int)digi))).phi(); // note [-pi,pi]
261 
262  // adjust [0,2pi] and [-pi,pi] to get deltaPhi difference properly
263  switch (processor) {
264  case 1: break;
265  case 6: {phi15deg -= 2*M_PI; break; }
266  default : {if (stripPhi < 0) stripPhi += 2*M_PI; break; }
267  }
268 
269  // local angle in CSC halfStrip usnits
270  int halfStrip = lround ( (stripPhi-phi15deg)/hsPhiPitch );
271 
272  return halfStrip;
273 }
LocalPoint centreOfStrip(int strip) const
Definition: RPCRoll.cc:52
GlobalPoint toGlobal(const Local2DPoint &lp) const
Conversion to the global R.F. from the R.F. of the GeomDet.
Definition: GeomDet.h:54
#define M_PI
unsigned int nPhiBins
Number of phi bins along 2Pi.
edm::ESHandle< RPCGeometry > _georpc
const RPCRoll * roll(RPCDetId id) const
Return a roll given its id.
Definition: RPCGeometry.cc:75
int AngleConverter::getProcessorPhi ( unsigned int  iProcessor,
l1t::tftype  part,
const RPCDetId rollId,
const unsigned int &  digi1,
const unsigned int &  digi2 
) const

Definition at line 222 of file AngleConverter.cc.

References _georpc, RPCRoll::centreOfStrip(), M_PI, nPhiBins, RPCGeometry::roll(), and GeomDet::toGlobal().

223 {
224 
225  const double hsPhiPitch = 2*M_PI/nPhiBins;
226  const int dummy = nPhiBins;
227  int processor = iProcessor+1;
228  const RPCRoll* roll = _georpc->roll(rollId);
229  if (!roll) return dummy;
230 
231  double phi15deg = M_PI/3.*(processor-1)+M_PI/12.; // "0" is 15degree moved cyclicaly to each processor, note [0,2pi]
232  double stripPhi1 = (roll->toGlobal(roll->centreOfStrip((int)digi1))).phi(); // note [-pi,pi]
233  double stripPhi2 = (roll->toGlobal(roll->centreOfStrip((int)digi2))).phi(); // note [-pi,pi]
234 
235  // stripPhi from geometry is given in [-pi,pi] range.
236  // Keep like that for OMTFp1 [15-10deg,75deg] and OMTFp6 [-45-10deg,15deg].
237  // For OMTFp2..OMTFp5 move to [0,2pi] range
238  switch (processor) {
239  case 1: break;
240  case 6: {phi15deg -= 2*M_PI; break; }
241  default : { if (stripPhi1 < 0) stripPhi1 += 2*M_PI; if(stripPhi2 < 0 ) stripPhi2 += 2*M_PI; break; }
242  }
243 
244  // local angle in CSC halfStrip usnits
245  int halfStrip = lround ( ( (stripPhi1+stripPhi2)/2.-phi15deg)/hsPhiPitch );
246 
247  return halfStrip;
248 }
LocalPoint centreOfStrip(int strip) const
Definition: RPCRoll.cc:52
GlobalPoint toGlobal(const Local2DPoint &lp) const
Conversion to the global R.F. from the R.F. of the GeomDet.
Definition: GeomDet.h:54
#define M_PI
unsigned int nPhiBins
Number of phi bins along 2Pi.
edm::ESHandle< RPCGeometry > _georpc
const RPCRoll * roll(RPCDetId id) const
Return a roll given its id.
Definition: RPCGeometry.cc:75
bool AngleConverter::isCSCCounterClockwise ( const std::unique_ptr< const CSCLayer > &  layer) const
private

Check orientation of strips in given CSC chamber.

Definition at line 429 of file AngleConverter.cc.

References funct::abs(), and M_PI.

Referenced by getGlobalEta().

429  {
430  const int nStrips = layer->geometry()->numberOfStrips();
431  const double phi1 = layer->centerOfStrip(1).phi();
432  const double phiN = layer->centerOfStrip(nStrips).phi();
433  return ( (std::abs(phi1 - phiN) < M_PI && phi1 >= phiN) ||
434  (std::abs(phi1 - phiN) >= M_PI && phi1 < phiN) );
435 }
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
#define M_PI

Member Data Documentation

edm::ESHandle<CSCGeometry> AngleConverter::_geocsc
private

Definition at line 65 of file AngleConverter.h.

Referenced by checkAndUpdateGeometry(), getGlobalEta(), and getProcessorPhi().

edm::ESHandle<DTGeometry> AngleConverter::_geodt
private

Definition at line 66 of file AngleConverter.h.

Referenced by checkAndUpdateGeometry(), and getGlobalEta().

unsigned long long AngleConverter::_geom_cache_id
private

Definition at line 63 of file AngleConverter.h.

Referenced by checkAndUpdateGeometry().

edm::ESHandle<RPCGeometry> AngleConverter::_georpc
private

Definition at line 64 of file AngleConverter.h.

Referenced by checkAndUpdateGeometry(), getGlobalEta(), and getProcessorPhi().

unsigned int AngleConverter::nPhiBins
private

Number of phi bins along 2Pi.

Definition at line 69 of file AngleConverter.h.

Referenced by checkAndUpdateGeometry(), and getProcessorPhi().