#include <ConversionFastHelix.h>
Public Member Functions | |
ConversionFastHelix (const GlobalPoint &outerHit, const GlobalPoint &middleHit, const GlobalPoint &aVertex, const MagneticField *field) | |
FTS | helixStateAtVertex () |
bool | isValid () |
void | makeHelix () |
FTS | stateAtVertex () |
FTS | straightLineStateAtVertex () |
~ConversionFastHelix () | |
Private Types | |
typedef FreeTrajectoryState | FTS |
Private Attributes | |
const MagneticField * | mField |
FastCircle | theCircle |
FTS | theHelix_ |
GlobalPoint | theMiddleHit |
GlobalPoint | theOuterHit |
GlobalPoint | theVertex |
bool | validStateAtVertex |
Generation of track parameters at a vertex using two hits and a vertex.
Definition at line 16 of file ConversionFastHelix.h.
typedef FreeTrajectoryState ConversionFastHelix::FTS [private] |
Definition at line 20 of file ConversionFastHelix.h.
ConversionFastHelix::ConversionFastHelix | ( | const GlobalPoint & | outerHit, |
const GlobalPoint & | middleHit, | ||
const GlobalPoint & | aVertex, | ||
const MagneticField * | field | ||
) |
Definition at line 11 of file ConversionFastHelix.cc.
References makeHelix(), and validStateAtVertex.
: theOuterHit(outerHit), theMiddleHit(middleHit), theVertex(aVertex), theCircle(outerHit, middleHit, aVertex), mField(field) { validStateAtVertex=false; makeHelix(); }
ConversionFastHelix::~ConversionFastHelix | ( | ) | [inline] |
Definition at line 30 of file ConversionFastHelix.h.
{}
FreeTrajectoryState ConversionFastHelix::helixStateAtVertex | ( | ) |
Definition at line 52 of file ConversionFastHelix.cc.
References cmsCodeRulesChecker::arg, funct::C, FastLine::c(), MagneticField::inTesla(), edm::detail::isnan(), mField, ExpressReco_HICollisions_FallBack::pt, lumiQueryAPI::q, FastCircle::rho(), rho, dbtoconf::root, mathSSE::sqrt(), theCircle, theMiddleHit, theOuterHit, theVertex, FreeTrajectoryState::transverseCurvature(), v, validStateAtVertex, PV3DBase< T, PVType, FrameType >::x(), FastCircle::x0(), PV3DBase< T, PVType, FrameType >::y(), FastCircle::y0(), and PV3DBase< T, PVType, FrameType >::z().
Referenced by makeHelix().
{ GlobalPoint pMid(theMiddleHit); GlobalPoint v(theVertex); FTS atVertex; double dydx = 0.; double pt = 0., px = 0., py = 0.; //remember (radius rho in cm): //rho = //100. * pt * //(10./(3.*MagneticField::inTesla(GlobalPoint(0., 0., 0.)).z())); double rho = theCircle.rho(); pt = 0.01 * rho * (0.3*mField->inTesla(GlobalPoint(0,0,0)).z()); // (py/px)|x=v.x() = (dy/dx)|x=v.x() //remember: //y(x) = +-sqrt(rho^2 - (x-x0)^2) + y0 //y(x) = sqrt(rho^2 - (x-x0)^2) + y0 if y(x) >= y0 //y(x) = -sqrt(rho^2 - (x-x0)^2) + y0 if y(x) < y0 //=> (dy/dx) = -(x-x0)/sqrt(Q) if y(x) >= y0 // (dy/dx) = (x-x0)/sqrt(Q) if y(x) < y0 //with Q = rho^2 - (x-x0)^2 double arg=rho*rho - ( (v.x()-theCircle.x0())*(v.x()-theCircle.x0()) ); if ( arg >= 0 ) { // double root = sqrt( rho*rho - ( (v.x()-theCircle.x0())*(v.x()-theCircle.x0()) ) ); double root = sqrt( arg ); if((v.y() - theCircle.y0()) > 0.) dydx = -(v.x() - theCircle.x0()) / root; else dydx = (v.x() - theCircle.x0()) / root; px = pt/sqrt(1. + dydx*dydx); py = px*dydx; // check sign with scalar product if(px*(pMid.x() - v.x()) + py*(pMid.y() - v.y()) < 0.) { px *= -1.; py *= -1.; } //std::cout << " ConversionFastHelix:helixStateAtVertex rho " << rho << " pt " << pt << " v " << v << " theCircle.x0() " <<theCircle.x0() << " theCircle.y0() " << theCircle.y0() << " v.x()-theCircle.x0() " << v.x()-theCircle.x0() << " rho^2 " << rho*rho << " v.x()-theCircle.x0()^2 " << (v.x()-theCircle.x0())*(v.x()-theCircle.x0()) << " root " << root << " arg " << arg << " dydx " << dydx << std::endl; //calculate z0, pz //(z, R*phi) linear relation in a helix //with R, phi defined as radius and angle w.r.t. centre of circle //in transverse plane //pz = pT*(dz/d(R*phi))) FastLine flfit(theOuterHit, theMiddleHit, theCircle.rho()); double z_0 = 0; //std::cout << " ConversionFastHelix:helixStateAtVertex flfit.n2() " << flfit.n2() << " flfit.c() " << flfit.c() << " flfit.n2() " << flfit.n2() << std::endl; if ( flfit.n2() !=0 && !std::isnan( flfit.c()) && !std::isnan(flfit.n2()) ) { // std::cout << " Accepted " << std::endl; z_0 = -flfit.c()/flfit.n2(); double dzdrphi = -flfit.n1()/flfit.n2(); double pz = pt*dzdrphi; //get sign of particle GlobalVector magvtx=mField->inTesla(v); TrackCharge q = ((theCircle.x0()*py - theCircle.y0()*px) / (magvtx.z()) < 0.) ? -1 : 1; AlgebraicSymMatrix55 C = AlgebraicMatrixID(); //MP atVertex = FTS(GlobalTrajectoryParameters(GlobalPoint(v.x(), v.y(), z_0), GlobalVector(px, py, pz), q, mField), CurvilinearTrajectoryError(C)); //std::cout << " ConversionFastHelix:helixStateAtVertex globalPoint " << GlobalPoint(v.x(), v.y(), z_0) << " GlobalVector " << GlobalVector(px, py, pz) << " q " << q << " MField " << mField->inTesla(v) << std::endl; //std::cout << " ConversionFastHelix:helixStateAtVertex atVertex.transverseCurvature() " << atVertex.transverseCurvature() << std::endl; if( atVertex.transverseCurvature() !=0 ) { validStateAtVertex=true; //std::cout << " ConversionFastHelix:helixStateAtVertex validHelixStateAtVertex status " << validStateAtVertex << std::endl; return atVertex; }else return atVertex; } else { //std::cout << " ConversionFastHelix:helixStateAtVertex not accepted validHelixStateAtVertex status " << validStateAtVertex << std::endl; return atVertex; } } else { //std::cout << " ConversionFastHelix:helixStateAtVertex not accepted because arg <0 validHelixStateAtVertex status " << validStateAtVertex << std::endl; return atVertex; } }
bool ConversionFastHelix::isValid | ( | void | ) | [inline] |
Definition at line 35 of file ConversionFastHelix.h.
References validStateAtVertex.
{return validStateAtVertex; }
void ConversionFastHelix::makeHelix | ( | ) |
Definition at line 32 of file ConversionFastHelix.cc.
References helixStateAtVertex(), FastCircle::isValid(), straightLineStateAtVertex(), theCircle, and theHelix_.
Referenced by ConversionFastHelix().
{ if( theCircle.isValid()) { theHelix_=helixStateAtVertex(); } else { theHelix_= straightLineStateAtVertex(); } }
FreeTrajectoryState ConversionFastHelix::stateAtVertex | ( | ) |
Definition at line 45 of file ConversionFastHelix.cc.
References theHelix_.
Referenced by InOutConversionSeedFinder::findSeeds(), and InOutConversionSeedFinder::startSeed().
{ return theHelix_; }
FreeTrajectoryState ConversionFastHelix::straightLineStateAtVertex | ( | ) |
Definition at line 169 of file ConversionFastHelix.cc.
References funct::C, FastLine::c(), edm::detail::isnan(), mField, FastCircle::n1(), FastLine::n1(), FastCircle::n2(), FastLine::n2(), ExpressReco_HICollisions_FallBack::pt, lumiQueryAPI::q, mathSSE::sqrt(), theCircle, theMiddleHit, theOuterHit, theVertex, FreeTrajectoryState::transverseCurvature(), v, validStateAtVertex, PV3DBase< T, PVType, FrameType >::x(), and PV3DBase< T, PVType, FrameType >::y().
Referenced by makeHelix().
{ FTS atVertex; //calculate FTS assuming straight line... GlobalPoint pMid(theMiddleHit); GlobalPoint v(theVertex); double dydx = 0.; double pt = 0., px = 0., py = 0.; if(fabs(theCircle.n1()) > 0. || fabs(theCircle.n2()) > 0.) pt = 1.e+4;// 10 TeV //else no pt if(fabs(theCircle.n2()) > 0.) { dydx = -theCircle.n1()/theCircle.n2(); //else px = 0 } if ( pt==0 && dydx==0. ) { validStateAtVertex=false; return atVertex; } px = pt/sqrt(1. + dydx*dydx); py = px*dydx; // check sign with scalar product if (px*(pMid.x() - v.x()) + py*(pMid.y() - v.y()) < 0.) { px *= -1.; py *= -1.; } //calculate z_0 and pz at vertex using weighted mean //z = z(r) = z0 + (dz/dr)*r //tan(theta) = dr/dz = (dz/dr)^-1 //theta = atan(1./dzdr) //p = pt/sin(theta) //pz = p*cos(theta) = pt/tan(theta) FastLine flfit(theOuterHit, theMiddleHit); double z_0 = 0; if (flfit.n2() !=0 && !std::isnan( flfit.c()) && !std::isnan(flfit.n2()) ) { z_0 = -flfit.c()/flfit.n2(); double dzdr = -flfit.n1()/flfit.n2(); double pz = pt*dzdr; TrackCharge q = 1; AlgebraicSymMatrix66 C = AlgebraicMatrixID(); //MP atVertex = FTS(GlobalTrajectoryParameters(GlobalPoint(v.x(), v.y(), z_0), GlobalVector(px, py, pz), q, mField), CartesianTrajectoryError(C)); // std::cout << " ConversionFastHelix::straightLineStateAtVertex curvature " << atVertex.transverseCurvature() << " signedInverseMomentum " << atVertex.signedInverseMomentum() << std::endl; if ( atVertex.transverseCurvature() == -0 ) { return atVertex; } else { validStateAtVertex=true; return atVertex; } } else { return atVertex; } }
const MagneticField* ConversionFastHelix::mField [private] |
Definition at line 51 of file ConversionFastHelix.h.
Referenced by helixStateAtVertex(), and straightLineStateAtVertex().
FastCircle ConversionFastHelix::theCircle [private] |
Definition at line 50 of file ConversionFastHelix.h.
Referenced by helixStateAtVertex(), makeHelix(), and straightLineStateAtVertex().
FTS ConversionFastHelix::theHelix_ [private] |
Definition at line 45 of file ConversionFastHelix.h.
Referenced by makeHelix(), and stateAtVertex().
GlobalPoint ConversionFastHelix::theMiddleHit [private] |
Definition at line 48 of file ConversionFastHelix.h.
Referenced by helixStateAtVertex(), and straightLineStateAtVertex().
GlobalPoint ConversionFastHelix::theOuterHit [private] |
Definition at line 47 of file ConversionFastHelix.h.
Referenced by helixStateAtVertex(), and straightLineStateAtVertex().
GlobalPoint ConversionFastHelix::theVertex [private] |
Definition at line 49 of file ConversionFastHelix.h.
Referenced by helixStateAtVertex(), and straightLineStateAtVertex().
bool ConversionFastHelix::validStateAtVertex [private] |
Definition at line 46 of file ConversionFastHelix.h.
Referenced by ConversionFastHelix(), helixStateAtVertex(), isValid(), and straightLineStateAtVertex().