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/data/refman/pasoursint/CMSSW_5_3_0/src/TrackingTools/GsfTracking/src/GsfMultipleScatteringUpdator.cc

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00001 #include "TrackingTools/GsfTracking/interface/GsfMultipleScatteringUpdator.h"
00002 
00003 #include "DataFormats/GeometrySurface/interface/MediumProperties.h"
00004 
00005 // #include "CommonDet/DetUtilities/interface/DetExceptions.h"
00006 
00007 // #include "Utilities/Notification/interface/Verbose.h"
00008 
00009 void
00010 GsfMultipleScatteringUpdator::compute (const TrajectoryStateOnSurface& TSoS,
00011                                        const PropagationDirection propDir) const 
00012 {
00013   //
00014   // clear cache
00015   //
00016   theWeights.clear();
00017   theDeltaPs.clear();
00018   theDeltaCovs.clear();
00019   //
00020   // Get surface and check presence of medium properties
00021   //
00022   const Surface& surface = TSoS.surface();
00023   //
00024   // calculate components
00025   //
00026   if ( surface.mediumProperties() ) {
00027     LocalVector pvec = TSoS.localMomentum();
00028     double p = TSoS.localMomentum().mag();
00029     pvec *= 1./p;
00030     // thickness in radiation lengths
00031     double rl = surface.mediumProperties()->radLen()/fabs(pvec.z());
00032     // auxiliary variables for modified X0
00033     const double z = 14;                 // atomic number of silicon
00034     const double logz = log(z);
00035     const double h = (z+1)/z*log(287*sqrt(z))/log(159*pow(z,-1./3.));
00036     double beta2 = 1./(1.+mass()*mass()/p/p);
00037     // reduced thickness
00038     double dp1 = rl/beta2/h;
00039     double logdp1 = log(dp1);
00040     double logdp2 = 2./3.*logz + logdp1;
00041     // means are always 0
00042     theDeltaPs.push_back(0.);
00043     theDeltaPs.push_back(0.);
00044     // weights
00045     double w2;
00046     if ( logdp2<log(0.5) )  
00047       w2 = 0.05283+0.0077*logdp2+0.00069*logdp2*logdp2;
00048     else
00049       w2 =-0.01517+0.1151*logdp2-0.00653*logdp2*logdp2;
00050     double w1 = 1.-w2;
00051     theWeights.push_back(w1);
00052     theWeights.push_back(w2);
00053     // reduced variances
00054     double var1 = 0.8510+0.03314*logdp1-0.001825*logdp1*logdp1;
00055     double var2 = (1.-w1*var1)/w2;
00056     for ( int ic=0; ic<2; ic++ ) {
00057       // choose component and multiply with total variance
00058       double var = ic==0 ? var1 : var2;
00059       var *= 225.e-6*dp1/p/p;
00060       AlgebraicSymMatrix55 cov;
00061       // transform from orthogonal planes containing the
00062       // momentum vector to local parameters
00063       double sl = pvec.perp();
00064       double cl = pvec.z();
00065       double cf = pvec.x()/sl;
00066       double sf = pvec.y()/sl;
00067       cov(1,1) = var*(sf*sf*cl*cl + cf*cf)/(cl*cl*cl*cl);
00068       cov(1,2) = var*(cf*sf*sl*sl        )/(cl*cl*cl*cl);
00069       cov(2,2) = var*(cf*cf*cl*cl + sf*sf)/(cl*cl*cl*cl);
00070       theDeltaCovs.push_back(cov);
00071     }
00072   }
00073   else {
00074     theWeights.push_back(1.);
00075     theDeltaPs.push_back(0.);
00076     theDeltaCovs.push_back(AlgebraicSymMatrix55());
00077   }
00078   //
00079   // Save arguments to avoid duplication of computation
00080   //
00081   storeArguments(TSoS,propDir); 
00082 }
00083 
00084 //
00085 // Compare arguments with the ones of the previous call
00086 //
00087 bool 
00088 GsfMultipleScatteringUpdator::newArguments (const TrajectoryStateOnSurface& TSoS, 
00089                                             const PropagationDirection propDir) const {
00090   return TSoS.localMomentum().unit().z()!=theLastDz ||
00091     TSoS.localMomentum().mag()!=theLastP || propDir!=theLastPropDir ||
00092     TSoS.surface().mediumProperties()->radLen()!=theLastRadLength;
00093 }
00094 //
00095 // Save arguments
00096 //
00097 void GsfMultipleScatteringUpdator::storeArguments (const TrajectoryStateOnSurface& TSoS, 
00098                                                    const PropagationDirection propDir) const {
00099   theLastDz = TSoS.localMomentum().unit().z();
00100   theLastP = TSoS.localMomentum().mag();
00101   theLastPropDir = propDir;
00102   theLastRadLength = TSoS.surface().mediumProperties()->radLen();
00103 }