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#include <SETSeedFinder.h>
I. Bloch, E. James, S. Stoynev
Definition at line 12 of file SETSeedFinder.h.
Definition at line 15 of file SETSeedFinder.h.
| SETSeedFinder::SETSeedFinder | ( | const edm::ParameterSet & | pset | ) | [explicit] |
Definition at line 24 of file SETSeedFinder.cc.
References apply_prePruning, edm::ParameterSet::getParameter(), and MuonSeedVFinder::thePtExtractor.
: MuonSeedVFinder() { // Parameter set for the Builder ParameterSet trajectoryBuilderParameters = parameterSet.getParameter<ParameterSet>("SETTrajBuilderParameters"); apply_prePruning = trajectoryBuilderParameters.getParameter<bool>("Apply_prePruning"); // load pT seed parameters thePtExtractor = new MuonSeedPtExtractor(trajectoryBuilderParameters); }
| virtual SETSeedFinder::~SETSeedFinder | ( | ) | [inline, virtual] |
Definition at line 18 of file SETSeedFinder.h.
References MuonSeedVFinder::thePtExtractor.
{delete thePtExtractor;}
| std::pair< int, int > SETSeedFinder::checkAngleDeviation | ( | double | dPhi_1, |
| double | dPhi_2 | ||
| ) | const |
Definition at line 317 of file SETSeedFinder.cc.
References VarParsing::mult.
Referenced by pre_prune().
{
// Two conditions:
// a) deviations should be only to one side (above some absolute value cut to avoid
// material effects; this should be refined)
// b) deviatiation in preceding steps should be bigger due to higher magnetic field
// (again - a minimal value cut should be in place; this also should account for
// the small (Z) distances in overlaping CSC chambers)
double mult = dPhi_1 * dPhi_2;
int signVal = 1;
if(fabs(dPhi_1)<fabs(dPhi_2)){
signVal = -1;
}
int signMult = -1;
if(mult>0) signMult = 1;
std::pair <int, int> sign;
sign = make_pair (signVal, signMult);
return sign;
}
| void SETSeedFinder::estimateMomentum | ( | const MuonRecHitContainer & | validSet, |
| CLHEP::Hep3Vector & | momentum, | ||
| int & | charge | ||
| ) | const |
Definition at line 484 of file SETSeedFinder.cc.
References DeDxDiscriminatorTools::charge(), pat::helper::ParametrizationHelper::dimension(), python::cmstools::loop(), funct::pow(), MuonSeedPtExtractor::pT_extract(), and MuonSeedVFinder::thePtExtractor.
Referenced by fillSeedCandidates().
{
int firstMeasurement = -1;
int lastMeasurement = -1;
// don't use 2D measurements for momentum estimation
//if( 4==allValidSets[iSet].front()->dimension() &&
//(allValidSets[iSet].front()->isCSC() || allValidSets[iSet].front()->isDT())){
//firstMeasurement = 0;
//}
//else{
// which is the "first" hit (4D)?
for(unsigned int iMeas = 0;iMeas<validSet.size();++iMeas){
if(4==validSet[iMeas]->dimension() &&
(validSet[iMeas]->isCSC() || validSet[iMeas]->isDT())){
firstMeasurement = iMeas;
break;
}
}
//}
std::vector<double> momentum_estimate;
double pT = 0.;
MuonTransientTrackingRecHit::ConstMuonRecHitPointer firstHit;
MuonTransientTrackingRecHit::ConstMuonRecHitPointer secondHit;
// which is the second hit?
for(int loop = 0; loop<2; ++loop){// it is actually not used; to be removed
// this is the last measurement
if(!loop){// this is what is used currently
// 23.04.09 : it becomes a problem with introduction of ME42 chambers -
// the initial pT parametrization is incorrect for them
for(int iMeas = validSet.size()-1;iMeas>-1;--iMeas){
if(4==validSet[iMeas]->dimension() &&
(validSet[iMeas]->isCSC() || validSet[iMeas]->isDT()) &&
// below is a fix saying "don't use ME4 chambers for initial pT estimation";
// not using ME41 should not be a big loss too (and is more "symmetric" solution)
fabs(validSet[iMeas]->globalPosition().z())<1000.){
lastMeasurement = iMeas;
break;
}
}
}
else{
// this is the second measurement
for(unsigned int iMeas = 1;iMeas<validSet.size();++iMeas){
if(4==validSet[iMeas]->dimension() &&
(validSet[iMeas]->isCSC() || validSet[iMeas]->isDT())){
lastMeasurement = iMeas;
break;
}
}
}
// only 2D measurements (it should have been already abandoned)
if(-1==lastMeasurement && -1==firstMeasurement){
firstMeasurement = 0;
lastMeasurement = validSet.size()-1;
}
// because of the ME42 above lastMeasurement could be -1
else if(-1==lastMeasurement){
lastMeasurement = firstMeasurement;
}
else if(-1==firstMeasurement){
firstMeasurement = lastMeasurement;
}
firstHit = validSet[firstMeasurement];
secondHit = validSet[lastMeasurement];
if(firstHit->isRPC() && secondHit->isRPC()){ // remove all RPCs from here?
momentum_estimate.push_back(300.);
momentum_estimate.push_back(300.);
}
else{
if(firstHit->isRPC()){
firstHit = secondHit;
}
else if(secondHit->isRPC()){
secondHit = firstHit;
}
//---- estimate pT given two hits
//std::cout<<" hits for initial pT estimate: first -> dim = "<<firstHit->dimension()<<" pos = "<<firstHit->globalPosition()<<
//" , second -> "<<" dim = "<<secondHit->dimension()<<" pos = "<<secondHit->globalPosition()<<std::endl;
//---- pT throws exception if hits are MB4
// (no coding for them - 2D hits in the outer station)
if(2==firstHit->dimension() && 2==secondHit->dimension()){
momentum_estimate.push_back(999999999.);
momentum_estimate.push_back(999999999.);
}
else{
momentum_estimate = thePtExtractor->pT_extract(firstHit, secondHit);
}
}
pT = fabs(momentum_estimate[0]);
if(1 || pT>40.){ //it is skipped; we have to look at least into number of hits in the chamber actually...
// and then decide which segment to use
// use the last measurement, otherwise use the second; this is to be investigated
break;
}
}
const float pT_min = 1.99;// many hardcoded - remove them!
if(pT>3000.){
pT=3000.;
}
else if(pT<pT_min ){
if(pT>0){
pT=pT_min ;
}
else if(pT>(-1)*pT_min ){
pT=(-1)*pT_min ;
}
else if (pT<-3000.){
pT= -3000;
}
}
//std::cout<<" THE pT from the parametrization: "<<momentum_estimate[0]<<std::endl;
// estimate the charge of the track candidate from the delta phi of two segments:
//int charge = dPhi > 0 ? 1 : -1; // what we want is: dphi < 0 => charge = -1
charge = momentum_estimate[0]> 0 ? 1 : -1;
// we have the pT - get the 3D momentum estimate as well
// this is already final info:
double xHit = validSet[firstMeasurement]->globalPosition().x();
double yHit = validSet[firstMeasurement]->globalPosition().y();
double rHit = TMath::Sqrt(pow(xHit,2) + pow(yHit,2));
double thetaInner = validSet[firstMeasurement]->globalPosition().theta();
// if some of the segments is missing r-phi measurement then we should
// use only the 4D phi estimate (also use 4D eta estimate only)
// the direction is not so important (it will be corrected)
double rTrack = (pT /(0.3*3.8))*100.; //times 100 for conversion to cm!
double par = -1.*(2./charge)*(TMath::ASin(rHit/(2*rTrack)));
double sinPar = TMath::Sin( par );
double cosPar = TMath::Cos( par );
// calculate phi at coordinate origin (0,0,0).
double sinPhiH = 1./(2.*charge*rTrack)*(xHit + ((sinPar)/(cosPar-1.))*yHit);
double cosPhiH = -1./(2.*charge*rTrack)*(((sinPar)/(1.-cosPar))*xHit + yHit);
// finally set the return vector
// try out the reco info:
momEstimate = CLHEP::Hep3Vector(pT*cosPhiH, pT*sinPhiH, pT/TMath::Tan(thetaInner)); // should used into to theta directly here (rather than tan(atan2(...)))
//Hep3Vector momEstimate(6.97961, 5.89732, -50.0855);
const float minMomenum = 5.; //hardcoded - remove it! same in SETFilter
if (momEstimate.mag()<minMomenum){
int sign = (pT<0.) ? -1: 1;
pT = sign * (fabs(pT)+1);
CLHEP::Hep3Vector momEstimate2(pT*cosPhiH, pT*sinPhiH, pT/TMath::Tan(thetaInner));
momEstimate = momEstimate2;
if (momEstimate.mag()<minMomenum){
pT = sign * (fabs(pT)+1);
CLHEP::Hep3Vector momEstimate3(pT*cosPhiH, pT*sinPhiH, pT/TMath::Tan(thetaInner));
momEstimate = momEstimate3;
if (momEstimate.mag()<minMomenum){
pT = sign * (fabs(pT)+1);
CLHEP::Hep3Vector momEstimate4(pT*cosPhiH, pT*sinPhiH, pT/TMath::Tan(thetaInner));
momEstimate = momEstimate4;
}
}
}
}
| std::vector< SeedCandidate > SETSeedFinder::fillSeedCandidates | ( | std::vector< MuonRecHitContainer > & | allValidSets | ) |
Definition at line 451 of file SETSeedFinder.cc.
References SeedCandidate::charge, estimateMomentum(), SeedCandidate::momentum, and SeedCandidate::theSet.
Referenced by SETMuonSeedProducer::produce().
{
//---- we have the valid sets constructed; transform the information in an
//---- apropriate form; meanwhile - estimate the momentum for a given set
// RPCs should not be used (no parametrization)
std::vector <SeedCandidate> seedCandidates_inCluster;
// calculate and fill the inputs needed
// loop over all valid sets
for(unsigned int iSet = 0;iSet<allValidSets.size();++iSet){
//
//std::cout<<" This is SET number : "<<iSet<<std::endl;
//for(unsigned int iHit = 0;iHit<allValidSets[iSet].size();++iHit){
//std::cout<<" measurements in the SET: iHit = "<<iHit<<" pos = "<<allValidSets[iSet][iHit]->globalPosition()<<
//" dim = "<<allValidSets[iSet][iHit]->dimension()<<std::endl;
//}
CLHEP::Hep3Vector momEstimate;
int chargeEstimate;
estimateMomentum(allValidSets[iSet], momEstimate, chargeEstimate);
MuonRecHitContainer MuonRecHitContainer_theSet_prep;
// currently hardcoded - will be in proper loop of course:
SeedCandidate seedCandidates_inCluster_prep;
seedCandidates_inCluster_prep.theSet = allValidSets[iSet];
seedCandidates_inCluster_prep.momentum = momEstimate;
seedCandidates_inCluster_prep.charge = chargeEstimate;
seedCandidates_inCluster.push_back(seedCandidates_inCluster_prep);
// END estimateMomentum
}
return seedCandidates_inCluster;
}
| std::vector< SETSeedFinder::MuonRecHitContainer > SETSeedFinder::findAllValidSets | ( | const std::vector< MuonRecHitContainer > & | MuonRecHitContainer_perLayer | ) |
Definition at line 166 of file SETSeedFinder.cc.
References findQualityFiles::size.
Referenced by SETMuonSeedProducer::produce().
{
std::vector <MuonRecHitContainer> allValidSets;
// build all possible combinations (i.e valid sets; the algorithm name is after this feature -
// SET algorithm)
//
// ugly... use recursive function?!
// or implement Ingo's suggestion (a la ST)
unsigned nLayers = MuonRecHitContainer_perLayer.size();
if(1==nLayers){
return allValidSets;
}
MuonRecHitContainer validSet;
unsigned int iPos0 = 0;
std::vector <unsigned int> iLayer(12);// could there be more than 11 layers?
std::vector <unsigned int> size(12);
if(iPos0<nLayers){
size.at(iPos0) = MuonRecHitContainer_perLayer.at(iPos0).size();
for(iLayer[iPos0] = 0; iLayer[iPos0]<size[iPos0];++iLayer[iPos0]){
validSet.clear();
validSet.push_back(MuonRecHitContainer_perLayer[iPos0][iLayer[iPos0]]);
unsigned int iPos1 = 1;
if(iPos1<nLayers){
size.at(iPos1) = MuonRecHitContainer_perLayer.at(iPos1).size();
for(iLayer[iPos1] = 0; iLayer[iPos1]<size[iPos1];++iLayer[iPos1]){
validSet.resize(iPos1);
validSet.push_back(MuonRecHitContainer_perLayer[iPos1][iLayer[iPos1]]);
unsigned int iPos2 = 2;
if(iPos2<nLayers){
size.at(iPos2) = MuonRecHitContainer_perLayer.at(iPos2).size();
for(iLayer[iPos2] = 0; iLayer[iPos2]<size[iPos2];++iLayer[iPos2]){
validSet.resize(iPos2);
validSet.push_back(MuonRecHitContainer_perLayer[iPos2][iLayer[iPos2]]);
unsigned int iPos3 = 3;
if(iPos3<nLayers){
size.at(iPos3) = MuonRecHitContainer_perLayer.at(iPos3).size();
for(iLayer[iPos3] = 0; iLayer[iPos3]<size[iPos3];++iLayer[iPos3]){
validSet.resize(iPos3);
validSet.push_back(MuonRecHitContainer_perLayer[iPos3][iLayer[iPos3]]);
unsigned int iPos4 = 4;
if(iPos4<nLayers){
size.at(iPos4) = MuonRecHitContainer_perLayer.at(iPos4).size();
for(iLayer[iPos4] = 0; iLayer[iPos4]<size[iPos4];++iLayer[iPos4]){
validSet.resize(iPos4);
validSet.push_back(MuonRecHitContainer_perLayer[iPos4][iLayer[iPos4]]);
unsigned int iPos5 = 5;
if(iPos5<nLayers){
size.at(iPos5) = MuonRecHitContainer_perLayer.at(iPos5).size();
for(iLayer[iPos5] = 0; iLayer[iPos5]<size[iPos5];++iLayer[iPos5]){
validSet.resize(iPos5);
validSet.push_back(MuonRecHitContainer_perLayer[iPos5][iLayer[iPos5]]);
unsigned int iPos6 = 6;
if(iPos6<nLayers){
size.at(iPos6) = MuonRecHitContainer_perLayer.at(iPos6).size();
for(iLayer[iPos6] = 0; iLayer[iPos6]<size[iPos6];++iLayer[iPos6]){
validSet.resize(iPos6);
validSet.push_back(MuonRecHitContainer_perLayer[iPos6][iLayer[iPos6]]);
unsigned int iPos7 = 7;
if(iPos7<nLayers){
size.at(iPos7) = MuonRecHitContainer_perLayer.at(iPos7).size();
for(iLayer[iPos7] = 0; iLayer[iPos7]<size[iPos7];++iLayer[iPos7]){
validSet.resize(iPos7);
validSet.push_back(MuonRecHitContainer_perLayer[iPos7][iLayer[iPos7]]);
unsigned int iPos8 = 8;
if(iPos8<nLayers){
size.at(iPos8) = MuonRecHitContainer_perLayer.at(iPos8).size();
for(iLayer[iPos8] = 0; iLayer[iPos8]<size[iPos8];++iLayer[iPos8]){
validSet.resize(iPos8);
validSet.push_back(MuonRecHitContainer_perLayer[iPos8][iLayer[iPos8]]);
unsigned int iPos9 = 9;
if(iPos9<nLayers){
size.at(iPos9) = MuonRecHitContainer_perLayer.at(iPos9).size();
for(iLayer[iPos9] = 0; iLayer[iPos9]<size[iPos9];++iLayer[iPos9]){
validSet.resize(iPos9);
validSet.push_back(MuonRecHitContainer_perLayer[iPos9][iLayer[iPos9]]);
unsigned int iPos10 = 10;
if(iPos10<nLayers){
size.at(iPos10) = MuonRecHitContainer_perLayer.at(iPos10).size();
for(iLayer[iPos10] = 0; iLayer[iPos10]<size[iPos10];++iLayer[iPos10]){
validSet.resize(iPos10);
validSet.push_back(MuonRecHitContainer_perLayer[iPos10][iLayer[iPos10]]);
unsigned int iPos11 = 11;// more?
if(iPos11<nLayers){
size.at(iPos11) = MuonRecHitContainer_perLayer.at(iPos11).size();
for(iLayer[iPos11] = 0; iLayer[iPos11]<size[iPos11];++iLayer[iPos11]){
}
}
else{
allValidSets.push_back(validSet);
}
}
}
else{
allValidSets.push_back(validSet);
}
}
}
else{
allValidSets.push_back(validSet);
}
}
}
else{
allValidSets.push_back(validSet);
}
}
}
else{
allValidSets.push_back(validSet);
}
}
}
else{
allValidSets.push_back(validSet);
}
}
}
else{
allValidSets.push_back(validSet);
}
}
}
else{
allValidSets.push_back(validSet);
}
}
}
else{
allValidSets.push_back(validSet);
}
}
}
else{
allValidSets.push_back(validSet);
}
}
}
else{
allValidSets.push_back(validSet);
}
}
}
else{
allValidSets.push_back(validSet);
}
return allValidSets;
}
| void SETSeedFinder::limitCombinatorics | ( | std::vector< MuonRecHitContainer > & | MuonRecHitContainer_perLayer | ) |
Definition at line 129 of file SETSeedFinder.cc.
References i.
Referenced by SETMuonSeedProducer::produce().
{
const int maximumNumberOfCombinations = 1000000;
unsigned nLayers = MuonRecHitContainer_perLayer.size();
if(1==nLayers){
return ;
}
// maximal number of (segment) layers would be upto ~12; see next function
// below is just a quick fix for a rare "overflow"
if(MuonRecHitContainer_perLayer.size()>15){
MuonRecHitContainer_perLayer.resize(1);
return;
}
std::vector <double> sizeOfLayer(nLayers);
//std::cout<<" nLayers = "<<nLayers<<std::endl;
double nAllCombinations = 1.;
for(unsigned int i = 0;i<nLayers;++i ){
//std::cout<<" i = "<<i<<" size = "<<MuonRecHitContainer_perLayer.at(i).size()<<std::endl;
sizeOfLayer.at(i) = MuonRecHitContainer_perLayer.at(i).size();
nAllCombinations*=MuonRecHitContainer_perLayer.at(i).size();
}
//std::cout<<"nAllCombinations = "<<nAllCombinations<<std::endl;
//---- Erase most busy detector layers until we get less than maximumNumberOfCombinations combinations
int iCycle = 0;
while(nAllCombinations > float(maximumNumberOfCombinations)){
++iCycle;
std::vector <double>::iterator maxEl_it = max_element(sizeOfLayer.begin(),sizeOfLayer.end());
int maxEl = maxEl_it - sizeOfLayer.begin();
nAllCombinations/=MuonRecHitContainer_perLayer.at(maxEl).size();
//std::cout<<" iCycle = "<<iCycle<<" nAllCombinations = "<<nAllCombinations<<std::endl;
MuonRecHitContainer_perLayer.erase(MuonRecHitContainer_perLayer.begin()+maxEl);
sizeOfLayer.erase(sizeOfLayer.begin()+maxEl);
}
return;
}
| TrajectorySeed SETSeedFinder::makeSeed | ( | const TrajectoryStateOnSurface & | tsos, |
| const TransientTrackingRecHit::ConstRecHitContainer & | hits | ||
| ) | const |
Definition at line 653 of file SETSeedFinder.cc.
References alongMomentum, dir, oppositeToMomentum, trajectoryStateTransform::persistentState(), edm::OwnVector< T, P >::push_back(), and useSegmentsInTrajectory.
{
edm::OwnVector<TrackingRecHit> recHitsContainer;
for(unsigned int iHit = 0;iHit < hits.size();++iHit){
recHitsContainer.push_back(hits.at(iHit)->hit()->clone());
}
PropagationDirection dir = oppositeToMomentum;
if(useSegmentsInTrajectory){
dir = alongMomentum;// why forward (for rechits) later?
}
PTrajectoryStateOnDet const & seedTSOS =
trajectoryStateTransform::persistentState( firstTSOS, hits.at(0)->geographicalId().rawId());
TrajectorySeed seed(seedTSOS,recHitsContainer,dir);
//MuonPatternRecoDumper debug;
//std::cout<<" firstTSOS = "<<debug.dumpTSOS(firstTSOS)<<std::endl;
//std::cout<<" iTraj = ???"<<" hits = "<<range.second-range.first<<std::endl;
//std::cout<<" nhits = "<<hits.size()<<std::endl;
//for(unsigned int iRH=0;iRH<hits.size();++iRH){
//std::cout<<" RH = "<<iRH+1<<" globPos = "<<hits.at(iRH)->globalPosition()<<std::endl;
//}
return seed;
}
| void SETSeedFinder::pre_prune | ( | SETSeedFinder::MuonRecHitContainer & | validSet | ) | const |
Definition at line 352 of file SETSeedFinder.cc.
References checkAngleDeviation(), prof2calltree::count, pat::helper::ParametrizationHelper::dimension(), dPhi(), and phi.
Referenced by validSetsPrePruning().
{
unsigned nHits = validSet.size();
if(nHits>3){ // to decide we need at least 4 measurements
// any information could be used to make a decision for pruning
// maybe dPhi (delta Phi) is enough
std::vector <double> dPhi;
double dPhi_tmp;
bool wildCandidate;
int pruneHit_tmp;
for(unsigned int iHit = 1;iHit<nHits;++iHit){
dPhi_tmp = validSet[iHit]->globalPosition().phi() -
validSet[iHit-1]->globalPosition().phi();
dPhi.push_back(dPhi_tmp);
}
std::vector <int> pruneHit;
//---- loop over all the hits in a set
for(unsigned int iHit = 0;iHit<nHits;++iHit){
double dPHI_MIN = 0.02;//?? hardcoded - remove it
if(iHit){
// if we have to remove the very first hit (iHit == 0) then
// we'll probably be in trouble already
wildCandidate = false;
// actually 2D is bad only if not r-phi... Should I refine it?
// a hit is a candidate for pruning only if dPhi > dPHI_MIN;
// pruning decision is based on combination of hits characteristics
if(4==validSet[iHit-1]->dimension() && 4 == validSet[iHit]->dimension() &&
fabs(validSet[iHit]->globalPosition().phi() -
validSet[iHit-1]->globalPosition().phi())>dPHI_MIN ){
wildCandidate = true;
}
pruneHit_tmp = -1;
if(wildCandidate){
// OK - this couple doesn't look good (and is from 4D segments); proceed...
if(1==iHit){// the first and the last hits are special case
if(4==validSet[iHit+1]->dimension() && 4 == validSet[iHit+2]->dimension()){//4D?
// is the picture better if we remove the second hit?
dPhi_tmp = validSet[iHit+1]->globalPosition().phi() -
validSet[iHit-1]->globalPosition().phi();
// is the deviation what we expect (sign, not magnitude)?
std::pair <int, int> sign = checkAngleDeviation(dPhi_tmp, dPhi[2]);
if( 1==sign.first && 1==sign.second){
pruneHit_tmp = iHit;// mark the hit 1 for removing
}
}
}
else if(iHit>1 && iHit<validSet.size()-1){
if(4 == validSet[0]->dimension() && // we rely on the first (most important) couple
4 == validSet[1]->dimension() &&
pruneHit.back()!=int(iHit-1) && pruneHit.back()!=1){// check if hits are already marked
// decide which of the two hits should be removed (if any; preferably the outer one i.e.
// iHit rather than iHit-1); here - check what we get by removing iHit
dPhi_tmp = validSet[iHit+1]->globalPosition().phi() -
validSet[iHit-1]->globalPosition().phi();
// first couple is most important anyway so again compare to it
std::pair <int, int> sign = checkAngleDeviation(dPhi[0],dPhi_tmp);
if( 1==sign.first && 1==sign.second){
pruneHit_tmp = iHit; // mark the hit iHit for removing
}
else{ // iHit is not to be removed; proceed...
// what if we remove (iHit - 1) instead of iHit?
dPhi_tmp = validSet[iHit+1]->globalPosition().phi() -
validSet[iHit]->globalPosition().phi();
std::pair <int, int> sign = checkAngleDeviation(dPhi[0],dPhi_tmp);
if( 1==sign.first && 1==sign.second){
pruneHit_tmp = iHit-1;// mark the hit (iHit -1) for removing
}
}
}
}
else{
// the last hit: if picture is not good - remove it
if(pruneHit.size()>1 && pruneHit[pruneHit.size()-1]<0 && pruneHit[pruneHit.size()-2]<0){
std::pair <int, int> sign = checkAngleDeviation(dPhi[dPhi.size()-2], dPhi[dPhi.size()-1]);
if( -1==sign.first && -1==sign.second){// here logic is a bit twisted
pruneHit_tmp = iHit; // mark the last hit for removing
}
}
}
}
pruneHit.push_back(pruneHit_tmp);
}
}
// }
// actual pruning
for(unsigned int iHit = 1;iHit<nHits;++iHit){
int count = 0;
if(pruneHit[iHit-1]>0){
validSet.erase(validSet.begin()+pruneHit[iHit-1]-count);
++count;
}
}
}
}
| void SETSeedFinder::seeds | ( | const MuonRecHitContainer & | cluster, |
| std::vector< TrajectorySeed > & | result | ||
| ) | [virtual] |
The container sent in is expected to be a cluster, which isn't the same as a pattern. A cluster can have more than one hit on a layer. Internally, this method splits the cluster into patterns, and chooses the best one via a chi2. But it calculates the trajectoryMeasurements at the same time, so we can't really separate the steps.
Implements MuonSeedVFinder.
Definition at line 36 of file SETSeedFinder.cc.
{
}
| virtual void SETSeedFinder::setBField | ( | const MagneticField * | field | ) | [inline, virtual] |
ignore - uses MuonServiceProxy
Implements MuonSeedVFinder.
Definition at line 20 of file SETSeedFinder.h.
{}
| void SETSeedFinder::setServiceProxy | ( | MuonServiceProxy * | service | ) | [inline] |
Definition at line 32 of file SETSeedFinder.h.
References theService.
Referenced by SETMuonSeedProducer::SETMuonSeedProducer().
{theService = service;}
| std::vector< SETSeedFinder::MuonRecHitContainer > SETSeedFinder::sortByLayer | ( | MuonRecHitContainer & | cluster | ) | const |
Definition at line 55 of file SETSeedFinder.cc.
References MuonSubdetId::CSC, CSC(), GeomDetEnumerators::DT, MuonSubdetId::DT, Plane::localZ(), mag(), CSCDetId::ring(), sortSegRadius, CSCDetId::station(), DTChamberId::station(), DetId::subdetId(), GeomDet::surface(), and theService.
Referenced by SETMuonSeedProducer::produce().
{
stable_sort(cluster.begin(), cluster.end(),sortSegRadius);
//---- group hits in detector layers (if in same layer); the idea is that
//---- some hits could not belong to a track simultaneously - these will be in a
//---- group; two hits from one and the same group will not go to the same track
std::vector< MuonRecHitContainer > MuonRecHitContainer_perLayer;
if(cluster.size()){
int iHit =0;
MuonRecHitContainer hitsInThisLayer;
hitsInThisLayer.push_back(cluster[iHit]);
DetId detId = cluster[iHit]->hit()->geographicalId();
const GeomDet* geomDet = theService->trackingGeometry()->idToDet( detId );
while(iHit<int(cluster.size())-1){
DetId detId_2 = cluster[iHit+1]->hit()->geographicalId();
const GlobalPoint gp_nextHit = cluster[iHit+1]->globalPosition();
// this is the distance of the "second" hit to the "first" detector (containing the "first hit")
float distanceToDetector = fabs(geomDet->surface().localZ(gp_nextHit));
//---- hits from DT and CSC could be very close in angle but incosistent with
//---- belonging to a common track (and these are different surfaces);
//---- also DT (and CSC now - 090822) hits from a station (in a pre-cluster) should be always in a group together;
//---- take this into account and put such hits in a group together
bool specialCase = false;
if( detId.subdetId() == MuonSubdetId::DT &&
detId_2.subdetId() == MuonSubdetId::DT ){
DTChamberId dtCh(detId);
DTChamberId dtCh_2(detId_2);
specialCase = (dtCh.station() == dtCh_2.station());
}
else if(detId.subdetId() == MuonSubdetId::CSC &&
detId_2.subdetId() == MuonSubdetId::CSC){
CSCDetId cscCh(detId);
CSCDetId cscCh_2(detId_2);
specialCase = (cscCh.station() == cscCh_2.station() && cscCh.ring() == cscCh_2.ring());
}
if(distanceToDetector<0.001 || true==specialCase){ // hardcoded value - remove!
hitsInThisLayer.push_back(cluster[iHit+1]);
}
else{
specialCase = false;
if(( (cluster[iHit]->isDT() &&
cluster[iHit+1]->isCSC()) ||
(cluster[iHit]->isCSC() &&
cluster[iHit+1]->isDT())) &&
//---- what is the minimal distance between a DT and a CSC hit belonging
//---- to a common track? (well, with "reasonable" errors; put 10 cm for now)
fabs(cluster[iHit+1]->globalPosition().mag() -
cluster[iHit]->globalPosition().mag())<10.){
hitsInThisLayer.push_back(cluster[iHit+1]);
// change to Stoyan - now we also update the detID here... give it a try. IBL 080905
detId = cluster[iHit+1]->hit()->geographicalId();
geomDet = theService->trackingGeometry()->idToDet( detId );
}
else if(!specialCase){
//---- put the group of hits in the vector (containing the groups of hits)
//---- and continue with next layer (group)
MuonRecHitContainer_perLayer.push_back(hitsInThisLayer);
hitsInThisLayer.clear();
hitsInThisLayer.push_back(cluster[iHit+1]);
detId = cluster[iHit+1]->hit()->geographicalId();
geomDet = theService->trackingGeometry()->idToDet( detId );
}
}
++iHit;
}
MuonRecHitContainer_perLayer.push_back(hitsInThisLayer);
}
return MuonRecHitContainer_perLayer;
}
| void SETSeedFinder::validSetsPrePruning | ( | std::vector< MuonRecHitContainer > & | allValidSets | ) |
Definition at line 340 of file SETSeedFinder.cc.
References pre_prune().
Referenced by SETMuonSeedProducer::produce().
{
//---- this actually is a pre-pruning; it does not include any fit information;
//---- it is intended to remove only very "wild" segments from a set;
//---- no "good" segment is to be lost (otherwise - widen the parameters)
for(unsigned int iSet = 0;iSet<allValidSets.size();++iSet){
pre_prune(allValidSets[iSet]);
}
}
bool SETSeedFinder::apply_prePruning [private] |
Definition at line 61 of file SETSeedFinder.h.
Referenced by SETSeedFinder().
MuonServiceProxy* SETSeedFinder::theService [private] |
Definition at line 59 of file SETSeedFinder.h.
Referenced by setServiceProxy(), and sortByLayer().
bool SETSeedFinder::useSegmentsInTrajectory [private] |
Definition at line 62 of file SETSeedFinder.h.
Referenced by makeSeed().
1.7.3