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/data/refman/pasoursint/CMSSW_4_4_5_patch3/src/MagneticField/ParametrizedEngine/plugins/PolyFit3DParametrizedMagneticField.cc

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00001 
00008 #include "PolyFit3DParametrizedMagneticField.h"
00009 #include <FWCore/ParameterSet/interface/ParameterSet.h>
00010 #include <FWCore/MessageLogger/interface/MessageLogger.h>
00011 
00012 #include "BFit3D.h"
00013 
00014 
00015 using namespace std;
00016 using namespace magfieldparam;
00017 
00018 PolyFit3DParametrizedMagneticField::PolyFit3DParametrizedMagneticField(double bVal) : 
00019   theParam(new BFit3D())
00020 {
00021   theParam->SetField(bVal);
00022 }
00023 
00024 
00025 PolyFit3DParametrizedMagneticField::PolyFit3DParametrizedMagneticField(const edm::ParameterSet& parameters) : theParam(new BFit3D()) {
00026   theParam->SetField(parameters.getParameter<double>("BValue"));
00027 
00028   // Additional options (documentation by Vassili):
00029 
00030   // By default, the package accepts signed value of "r". That means,
00031   // one can cross r=0 and orientation of the coordinate "orts"
00032   // e_r and e_phi will not be flipped over.
00033   // In other words for an r<0 the e_r points inward, in the direction r=0.
00034   // This is a "natural" mode. However, the default behavior may be
00035   // changed by the call
00036 
00037   //  theParam->UseSignedRad(false);
00038   
00039   // In that case with crossing of r=0 e_r and e_phi will be flipped in
00040   // such a way that e_r always points outward. In other words instead of 
00041   // (r<0, phi) the (abs(r), phi+PI) will be used in this mode.
00042 
00043   // The expansion coefficients for a nominal field in between measurement
00044   // field values (2.0T, 3.5T, 3.8T and 4.0T) by default are calculated by
00045   // means of a linear piecewise interpolation. Another provided
00046   // interpolation mode is cubic spline. This mode can be switched
00047   // on by the call:
00048 
00049   //  theParam->UseSpline(true);
00050 
00051   // From practical point of view the use of spline interpolation doesn't
00052   // change much, but it makes the coefficients' behavior a bit more
00053   // physical at very low/high field values.
00054 }
00055 
00056 
00057 PolyFit3DParametrizedMagneticField::~PolyFit3DParametrizedMagneticField() {
00058   delete theParam;
00059 }
00060 
00061 
00062 GlobalVector
00063 PolyFit3DParametrizedMagneticField::inTesla(const GlobalPoint& gp) const {
00064 
00065   if (isDefined(gp)) {
00066     return inTeslaUnchecked(gp);
00067   } else {
00068     edm::LogWarning("MagneticField|FieldOutsideValidity") << " Point " << gp << " is outside the validity region of PolyFit3DParametrizedMagneticField";
00069     return GlobalVector();
00070   }
00071 }
00072 
00073 GlobalVector
00074 PolyFit3DParametrizedMagneticField::inTeslaUnchecked(const GlobalPoint& gp) const {
00075   double Br, Bz, Bphi;
00076   theParam->GetField(gp.perp()/100., gp.z()/100., gp.phi(),
00077                      Br, Bz, Bphi);
00078 
00079   double cosphi = cos(gp.phi());
00080   double sinphi = sin(gp.phi());
00081 
00082   return GlobalVector(Br*cosphi - Bphi*sinphi,
00083                       Br*sinphi + Bphi*cosphi, 
00084                       Bz);  
00085 }
00086 
00087 bool
00088 PolyFit3DParametrizedMagneticField::isDefined(const GlobalPoint& gp) const {
00089   double z = fabs(gp.z());
00090   double r = gp.perp();
00091   //"rectangle" |z|<3.5, r<1.9 _except_ the "corners" |z|+2.5*r>6.7, everything in meters
00092   if (z>350. || r>190 || z+2.5*r>670.) return false;
00093   return true;
00094 }