* provided "as is" without express or implied warranty. *
**************************************************************************/
-/* $Id$ */
-//----------------------------------------------------------------------
-// Basic magnetic field class
-// Used in all the detectors, and also in the traking classes
-// Author:
-//----------------------------------------------------------------------
+#include <TClass.h>
+#include <TFile.h>
+#include <TSystem.h>
+#include <TPRegexp.h>
#include "AliMagF.h"
+#include "AliMagWrapCheb.h"
+#include "AliLog.h"
ClassImp(AliMagF)
+const Double_t AliMagF::fgkSol2DipZ = -700.;
+const UShort_t AliMagF::fgkPolarityConvention = AliMagF::kConvLHC;
+/*
+ Explanation for polarity conventions: these are the mapping between the
+ current signs and main field components in L3 (Bz) and Dipole (Bx) (in Alice frame)
+ 1) kConvMap2005: used for the field mapping in 2005
+ positive L3 current -> negative Bz
+ positive Dip current -> positive Bx
+ 2) kConvMapDCS2008: defined by the microswitches/cabling of power converters as of 2008 - 1st half 2009
+ positive L3 current -> positive Bz
+ positive Dip current -> positive Bx
+ 3) kConvLHC : defined by LHC
+ positive L3 current -> positive Bz
+ positive Dip current -> negative Bx
+
+ Note: only "negative Bz(L3) with postive Bx(Dipole)" and its inverse was mapped in 2005. Hence
+ the GRP Manager will reject the runs with the current combinations (in the convention defined by the
+ static Int_t AliMagF::GetPolarityConvention()) which do not lead to such field polarities.
+
+ -----------------------------------------------
+
+ Explanation on integrals in the TPC region
+ GetTPCInt(xyz,b) and GetTPCRatInt(xyz,b) give integrals from point (x,y,z) to point (x,y,0)
+ (irrespectively of the z sign) of the following:
+ TPCInt: b contains int{bx}, int{by}, int{bz}
+ TPCRatInt: b contains int{bx/bz}, int{by/bz}, int{(bx/bz)^2+(by/bz)^2}
+
+ The same applies to integral in cylindrical coordinates:
+ GetTPCIntCyl(rphiz,b)
+ GetTPCIntRatCyl(rphiz,b)
+ They accept the R,Phi,Z coordinate (-pi<phi<pi) and return the field
+ integrals in cyl. coordinates.
+
+ Thus, to compute the integral from arbitrary xy_z1 to xy_z2, one should take
+ b = b1-b2 with b1 and b2 coming from GetTPCInt(xy_z1,b1) and GetTPCInt(xy_z2,b2)
+
+ Note: the integrals are defined for the range -300<Z<300 and 0<R<300
+*/
//_______________________________________________________________________
AliMagF::AliMagF():
- fMap(0),
- fType(0),
+ TVirtualMagField(),
+ fMeasuredMap(0),
+ fMapType(k5kG),
+ fSolenoid(0),
+ fBeamType(kNoBeamField),
+ fBeamEnergy(0),
+ //
fInteg(0),
- fFactor(0),
- fMax(0),
- fDebug(0)
-{
+ fPrecInteg(0),
+ fFactorSol(1.),
+ fFactorDip(1.),
+ fMax(15),
+ fDipoleOFF(kFALSE),
//
+ fQuadGradient(0),
+ fDipoleField(0),
+ fCCorrField(0),
+ fACorr1Field(0),
+ fACorr2Field(0),
+ fParNames("","")
+{
// Default constructor
//
}
//_______________________________________________________________________
-AliMagF::AliMagF(const char *name, const char *title, Int_t integ,
- Float_t factor, Float_t fmax):
- TNamed(name,title),
- fMap(0),
- fType(0),
- fInteg(0),
- fFactor(factor),
+AliMagF::AliMagF(const char *name, const char* title, Double_t factorSol, Double_t factorDip,
+ BMap_t maptype, BeamType_t bt, Double_t be,Int_t integ, Double_t fmax, const char* path):
+ TVirtualMagField(name),
+ fMeasuredMap(0),
+ fMapType(maptype),
+ fSolenoid(0),
+ fBeamType(bt),
+ fBeamEnergy(be),
+ //
+ fInteg(integ),
+ fPrecInteg(1),
+ fFactorSol(1.),
+ fFactorDip(1.),
fMax(fmax),
- fDebug(0)
+ fDipoleOFF(factorDip==0.),
+ //
+ fQuadGradient(0),
+ fDipoleField(0),
+ fCCorrField(0),
+ fACorr1Field(0),
+ fACorr2Field(0),
+ fParNames("","")
{
+ // Initialize the field with Geant integration option "integ" and max field "fmax,
+ // Impose scaling of parameterized L3 field by factorSol and of dipole by factorDip.
+ // The "be" is the energy of the beam in GeV/nucleon
+ //
+ SetTitle(title);
+ if(integ<0 || integ > 2) {
+ AliWarning(Form("Invalid magnetic field flag: %5d; Helix tracking chosen instead",integ));
+ fInteg = 2;
+ }
+ if (fInteg == 0) fPrecInteg = 0;
+ //
+ if (fBeamEnergy<=0 && fBeamType!=kNoBeamField) {
+ if (fBeamType == kBeamTypepp) fBeamEnergy = 7000.; // max proton energy
+ else if (fBeamType == kBeamTypeAA) fBeamEnergy = 2750; // max PbPb energy
+ AliInfo("Maximim possible beam energy for requested beam is assumed");
+ }
+ const char* parname = 0;
+ //
+ if (fMapType == k2kG) parname = fDipoleOFF ? "Sol12_Dip0_Hole":"Sol12_Dip6_Hole";
+ else if (fMapType == k5kG) parname = fDipoleOFF ? "Sol30_Dip0_Hole":"Sol30_Dip6_Hole";
+ else if (fMapType == k5kGUniform) parname = "Sol30_Dip6_Uniform";
+ else AliFatal(Form("Unknown field identifier %d is requested\n",fMapType));
//
- // Standard constructor
+ SetDataFileName(path);
+ SetParamName(parname);
//
- if(integ<0 || integ > 2) {
- Warning("SetField",
- "Invalid magnetic field flag: %5d; Helix tracking chosen instead\n"
- ,integ);
- fInteg = 2;
- } else {
- fInteg = integ;
+ LoadParameterization();
+ InitMachineField(fBeamType,fBeamEnergy);
+ double xyz[3]={0.,0.,0.};
+ fSolenoid = GetBz(xyz);
+ SetFactorSol(factorSol);
+ SetFactorDip(factorDip);
+ Print("a");
+}
+
+//_______________________________________________________________________
+AliMagF::AliMagF(const AliMagF &src):
+ TVirtualMagField(src),
+ fMeasuredMap(0),
+ fMapType(src.fMapType),
+ fSolenoid(src.fSolenoid),
+ fBeamType(src.fBeamType),
+ fBeamEnergy(src.fBeamEnergy),
+ fInteg(src.fInteg),
+ fPrecInteg(src.fPrecInteg),
+ fFactorSol(src.fFactorSol),
+ fFactorDip(src.fFactorDip),
+ fMax(src.fMax),
+ fDipoleOFF(src.fDipoleOFF),
+ fQuadGradient(src.fQuadGradient),
+ fDipoleField(src.fDipoleField),
+ fCCorrField(src.fCCorrField),
+ fACorr1Field(src.fACorr1Field),
+ fACorr2Field(src.fACorr2Field),
+ fParNames(src.fParNames)
+{
+ if (src.fMeasuredMap) fMeasuredMap = new AliMagWrapCheb(*src.fMeasuredMap);
+}
+
+//_______________________________________________________________________
+AliMagF::~AliMagF()
+{
+ delete fMeasuredMap;
+}
+
+//_______________________________________________________________________
+Bool_t AliMagF::LoadParameterization()
+{
+ if (fMeasuredMap) {
+ AliFatal(Form("Field data %s are already loaded from %s\n",GetParamName(),GetDataFileName()));
+ }
+ //
+ char* fname = gSystem->ExpandPathName(GetDataFileName());
+ TFile* file = TFile::Open(fname);
+ if (!file) {
+ AliFatal(Form("Failed to open magnetic field data file %s\n",fname));
+ }
+ //
+ fMeasuredMap = dynamic_cast<AliMagWrapCheb*>(file->Get(GetParamName()));
+ if (!fMeasuredMap) {
+ AliFatal(Form("Did not find field %s in %s\n",GetParamName(),fname));
+ }
+ file->Close();
+ delete file;
+ return kTRUE;
+}
+
+
+//_______________________________________________________________________
+void AliMagF::Field(const Double_t *xyz, Double_t *b)
+{
+ // Method to calculate the field at point xyz
+ //
+ // b[0]=b[1]=b[2]=0.0;
+ if (fMeasuredMap && xyz[2]>fMeasuredMap->GetMinZ() && xyz[2]<fMeasuredMap->GetMaxZ()) {
+ fMeasuredMap->Field(xyz,b);
+ if (xyz[2]>fgkSol2DipZ || fDipoleOFF) for (int i=3;i--;) b[i] *= fFactorSol;
+ else for (int i=3;i--;) b[i] *= fFactorDip;
+ }
+ else MachineField(xyz, b);
+ //
+}
+
+//_______________________________________________________________________
+Double_t AliMagF::GetBz(const Double_t *xyz) const
+{
+ // Method to calculate the field at point xyz
+ //
+ if (fMeasuredMap && xyz[2]>fMeasuredMap->GetMinZ() && xyz[2]<fMeasuredMap->GetMaxZ()) {
+ double bz = fMeasuredMap->GetBz(xyz);
+ return (xyz[2]>fgkSol2DipZ || fDipoleOFF) ? bz*fFactorSol : bz*fFactorDip;
+ }
+ else return 0.;
+}
+
+//_______________________________________________________________________
+AliMagF& AliMagF::operator=(const AliMagF& src)
+{
+ if (this != &src && src.fMeasuredMap) {
+ if (fMeasuredMap) delete fMeasuredMap;
+ fMeasuredMap = new AliMagWrapCheb(*src.fMeasuredMap);
+ SetName(src.GetName());
+ fSolenoid = src.fSolenoid;
+ fBeamType = src.fBeamType;
+ fBeamEnergy = src.fBeamEnergy;
+ fInteg = src.fInteg;
+ fPrecInteg = src.fPrecInteg;
+ fFactorSol = src.fFactorSol;
+ fFactorDip = src.fFactorDip;
+ fMax = src.fMax;
+ fDipoleOFF = src.fDipoleOFF;
+ fParNames = src.fParNames;
+ }
+ return *this;
+}
+
+//_______________________________________________________________________
+void AliMagF::InitMachineField(BeamType_t btype, Double_t benergy)
+{
+ if (btype==kNoBeamField) {
+ fQuadGradient = fDipoleField = fCCorrField = fACorr1Field = fACorr2Field = 0.;
+ return;
+ }
+ //
+ double rigScale = benergy/7000.; // scale according to ratio of E/Enominal
+ // for ions assume PbPb (with energy provided per nucleon) and account for A/Z
+ if (btype == kBeamTypeAA) rigScale *= 208./82.;
+ //
+ fQuadGradient = 22.0002*rigScale;
+ fDipoleField = 37.8781*rigScale;
+ //
+ // SIDE C
+ fCCorrField = -9.6980;
+ // SIDE A
+ fACorr1Field = -13.2247;
+ fACorr2Field = 11.7905;
+ //
+}
+
+//_______________________________________________________________________
+void AliMagF::MachineField(const Double_t *x, Double_t *b) const
+{
+ // ---- This is the ZDC part
+ // Compansators for Alice Muon Arm Dipole
+ const Double_t kBComp1CZ = 1075., kBComp1hDZ = 260./2., kBComp1SqR = 4.0*4.0;
+ const Double_t kBComp2CZ = 2049., kBComp2hDZ = 153./2., kBComp2SqR = 4.5*4.5;
+ //
+ const Double_t kTripQ1CZ = 2615., kTripQ1hDZ = 637./2., kTripQ1SqR = 3.5*3.5;
+ const Double_t kTripQ2CZ = 3480., kTripQ2hDZ = 550./2., kTripQ2SqR = 3.5*3.5;
+ const Double_t kTripQ3CZ = 4130., kTripQ3hDZ = 550./2., kTripQ3SqR = 3.5*3.5;
+ const Double_t kTripQ4CZ = 5015., kTripQ4hDZ = 637./2., kTripQ4SqR = 3.5*3.5;
+ //
+ const Double_t kDip1CZ = 6310.8, kDip1hDZ = 945./2., kDip1SqRC = 4.5*4.5, kDip1SqRA = 3.375*3.375;
+ const Double_t kDip2CZ = 12640.3, kDip2hDZ = 945./2., kDip2SqRC = 4.5*4.5, kDip2SqRA = 3.75*3.75;
+ const Double_t kDip2DXC = 9.7, kDip2DXA = 9.4;
+ //
+ double rad2 = x[0] * x[0] + x[1] * x[1];
+ //
+ b[0] = b[1] = b[2] = 0;
+ //
+ // SIDE C **************************************************
+ if(x[2]<0.){
+ if(TMath::Abs(x[2]+kBComp2CZ)<kBComp2hDZ && rad2 < kBComp2SqR){
+ b[0] = fCCorrField*fFactorDip;
+ }
+ else if(TMath::Abs(x[2]+kTripQ1CZ)<kTripQ1hDZ && rad2 < kTripQ1SqR){
+ b[0] = fQuadGradient*x[1];
+ b[1] = fQuadGradient*x[0];
+ }
+ else if(TMath::Abs(x[2]+kTripQ2CZ)<kTripQ2hDZ && rad2 < kTripQ2SqR){
+ b[0] = -fQuadGradient*x[1];
+ b[1] = -fQuadGradient*x[0];
+ }
+ else if(TMath::Abs(x[2]+kTripQ3CZ)<kTripQ3hDZ && rad2 < kTripQ3SqR){
+ b[0] = -fQuadGradient*x[1];
+ b[1] = -fQuadGradient*x[0];
+ }
+ else if(TMath::Abs(x[2]+kTripQ4CZ)<kTripQ4hDZ && rad2 < kTripQ4SqR){
+ b[0] = fQuadGradient*x[1];
+ b[1] = fQuadGradient*x[0];
+ }
+ else if(TMath::Abs(x[2]+kDip1CZ)<kDip1hDZ && rad2 < kDip1SqRC){
+ b[1] = fDipoleField;
+ }
+ else if(TMath::Abs(x[2]+kDip2CZ)<kDip2hDZ && rad2 < kDip2SqRC) {
+ double dxabs = TMath::Abs(x[0])-kDip2DXC;
+ if ( (dxabs*dxabs + x[1]*x[1])<kDip2SqRC) {
+ b[1] = -fDipoleField;
+ }
+ }
+ }
+ //
+ // SIDE A **************************************************
+ else{
+ if(TMath::Abs(x[2]-kBComp1CZ)<kBComp1hDZ && rad2 < kBComp1SqR) {
+ // Compensator magnet at z = 1075 m
+ b[0] = fACorr1Field*fFactorDip;
}
- fType = kUndef;
//
- fDebug = 0;
+ if(TMath::Abs(x[2]-kBComp2CZ)<kBComp2hDZ && rad2 < kBComp2SqR){
+ b[0] = fACorr2Field*fFactorDip;
+ }
+ else if(TMath::Abs(x[2]-kTripQ1CZ)<kTripQ1hDZ && rad2 < kTripQ1SqR){
+ b[0] = -fQuadGradient*x[1];
+ b[1] = -fQuadGradient*x[0];
+ }
+ else if(TMath::Abs(x[2]-kTripQ2CZ)<kTripQ2hDZ && rad2 < kTripQ2SqR){
+ b[0] = fQuadGradient*x[1];
+ b[1] = fQuadGradient*x[0];
+ }
+ else if(TMath::Abs(x[2]-kTripQ3CZ)<kTripQ3hDZ && rad2 < kTripQ3SqR){
+ b[0] = fQuadGradient*x[1];
+ b[1] = fQuadGradient*x[0];
+ }
+ else if(TMath::Abs(x[2]-kTripQ4CZ)<kTripQ4hDZ && rad2 < kTripQ4SqR){
+ b[0] = -fQuadGradient*x[1];
+ b[1] = -fQuadGradient*x[0];
+ }
+ else if(TMath::Abs(x[2]-kDip1CZ)<kDip1hDZ && rad2 < kDip1SqRA){
+ b[1] = -fDipoleField;
+ }
+ else if(TMath::Abs(x[2]-kDip2CZ)<kDip2hDZ && rad2 < kDip2SqRA) {
+ double dxabs = TMath::Abs(x[0])-kDip2DXA;
+ if ( (dxabs*dxabs + x[1]*x[1])<kDip2SqRA) {
+ b[1] = fDipoleField;
+ }
+ }
+ }
+ //
+}
+
+//_______________________________________________________________________
+void AliMagF::GetTPCInt(const Double_t *xyz, Double_t *b) const
+{
+ // Method to calculate the integral_0^z of br,bt,bz
+ b[0]=b[1]=b[2]=0.0;
+ if (fMeasuredMap) {
+ fMeasuredMap->GetTPCInt(xyz,b);
+ for (int i=3;i--;) b[i] *= fFactorSol;
+ }
+}
+
+//_______________________________________________________________________
+void AliMagF::GetTPCRatInt(const Double_t *xyz, Double_t *b) const
+{
+ // Method to calculate the integral_0^z of bx/bz,by/bz and (bx/bz)^2+(by/bz)^2
+ b[0]=b[1]=b[2]=0.0;
+ if (fMeasuredMap) {
+ fMeasuredMap->GetTPCRatInt(xyz,b);
+ b[2] /= 100;
+ }
+}
+
+//_______________________________________________________________________
+void AliMagF::GetTPCIntCyl(const Double_t *rphiz, Double_t *b) const
+{
+ // Method to calculate the integral_0^z of br,bt,bz
+ // in cylindrical coordiates ( -pi<phi<pi convention )
+ b[0]=b[1]=b[2]=0.0;
+ if (fMeasuredMap) {
+ fMeasuredMap->GetTPCIntCyl(rphiz,b);
+ for (int i=3;i--;) b[i] *= fFactorSol;
+ }
+}
+
+//_______________________________________________________________________
+void AliMagF::GetTPCRatIntCyl(const Double_t *rphiz, Double_t *b) const
+{
+ // Method to calculate the integral_0^z of bx/bz,by/bz and (bx/bz)^2+(by/bz)^2
+ // in cylindrical coordiates ( -pi<phi<pi convention )
+ b[0]=b[1]=b[2]=0.0;
+ if (fMeasuredMap) {
+ fMeasuredMap->GetTPCRatIntCyl(rphiz,b);
+ b[2] /= 100;
+ }
+}
+
+//_______________________________________________________________________
+void AliMagF::SetFactorSol(Float_t fc)
+{
+ // set the sign/scale of the current in the L3 according to fgkPolarityConvention
+ switch (fgkPolarityConvention) {
+ case kConvDCS2008: fFactorSol = -fc; break;
+ case kConvLHC : fFactorSol = -fc; break;
+ default : fFactorSol = fc; break; // case kConvMap2005: fFactorSol = fc; break;
+ }
+}
+
+//_______________________________________________________________________
+void AliMagF::SetFactorDip(Float_t fc)
+{
+ // set the sign*scale of the current in the Dipole according to fgkPolarityConvention
+ switch (fgkPolarityConvention) {
+ case kConvDCS2008: fFactorDip = fc; break;
+ case kConvLHC : fFactorDip = -fc; break;
+ default : fFactorDip = fc; break; // case kConvMap2005: fFactorDip = fc; break;
+ }
}
//_______________________________________________________________________
-void AliMagF::Field(Float_t*, Float_t *b)
+Double_t AliMagF::GetFactorSol() const
{
+ // return the sign*scale of the current in the Dipole according to fgkPolarityConventionthe
+ switch (fgkPolarityConvention) {
+ case kConvDCS2008: return -fFactorSol;
+ case kConvLHC : return -fFactorSol;
+ default : return fFactorSol; // case kConvMap2005: return fFactorSol;
+ }
+}
+
+//_______________________________________________________________________
+Double_t AliMagF::GetFactorDip() const
+{
+ // return the sign*scale of the current in the Dipole according to fgkPolarityConventionthe
+ switch (fgkPolarityConvention) {
+ case kConvDCS2008: return fFactorDip;
+ case kConvLHC : return -fFactorDip;
+ default : return fFactorDip; // case kConvMap2005: return fFactorDip;
+ }
+}
+
+//_____________________________________________________________________________
+AliMagF* AliMagF::CreateFieldMap(Float_t l3Cur, Float_t diCur, Int_t convention, Bool_t uniform,
+ Float_t beamenergy, const Char_t *beamtype, const Char_t *path)
+{
+ //------------------------------------------------
+ // The magnetic field map, defined externally...
+ // L3 current 30000 A -> 0.5 T
+ // L3 current 12000 A -> 0.2 T
+ // dipole current 6000 A
+ // The polarities must match the convention (LHC or DCS2008)
+ // unless the special uniform map was used for MC
+ //------------------------------------------------
+ const Float_t l3NominalCurrent1=30000.; // (A)
+ const Float_t l3NominalCurrent2=12000.; // (A)
+ const Float_t diNominalCurrent =6000. ; // (A)
+
+ const Float_t tolerance=0.03; // relative current tolerance
+ const Float_t zero=77.; // "zero" current (A)
+ //
+ BMap_t map;
+ double sclL3,sclDip;
//
- // Method to return the field in one point -- dummy in this case
+ Float_t l3Pol = l3Cur > 0 ? 1:-1;
+ Float_t diPol = diCur > 0 ? 1:-1;
+
+ l3Cur = TMath::Abs(l3Cur);
+ diCur = TMath::Abs(diCur);
//
- Warning("Field","Undefined MagF Field called, returning 0\n");
- b[0]=b[1]=b[2]=0;
+ if (TMath::Abs((sclDip=diCur/diNominalCurrent)-1.) > tolerance && !uniform) {
+ if (diCur <= zero) sclDip = 0.; // some small current.. -> Dipole OFF
+ else {
+ AliFatalGeneral("AliMagF",Form("Wrong dipole current (%f A)!",diCur));
+ }
+ }
+ //
+ if (uniform) {
+ // special treatment of special MC with uniform mag field (normalized to 0.5 T)
+ // no check for scaling/polarities are done
+ map = k5kGUniform;
+ sclL3 = l3Cur/l3NominalCurrent1;
+ }
+ else {
+ if (TMath::Abs((sclL3=l3Cur/l3NominalCurrent1)-1.) < tolerance) map = k5kG;
+ else if (TMath::Abs((sclL3=l3Cur/l3NominalCurrent2)-1.) < tolerance) map = k2kG;
+ else if (l3Cur <= zero && diCur<=zero) { sclL3=0; sclDip=0; map = k5kGUniform;}
+ else {
+ AliFatalGeneral("AliMagF",Form("Wrong L3 current (%f A)!",l3Cur));
+ }
+ }
+ //
+ if (sclDip!=0 && map!=k5kGUniform) {
+ if ( (l3Cur<=zero) || ((convention==kConvLHC && l3Pol!=diPol) || (convention==kConvDCS2008 && l3Pol==diPol)) ) {
+ AliFatalGeneral("AliMagF",Form("Wrong combination for L3/Dipole polarities (%c/%c) for convention %d",
+ l3Pol>0?'+':'-',diPol>0?'+':'-',GetPolarityConvention()));
+ }
+ }
+ //
+ if (l3Pol<0) sclL3 = -sclL3;
+ if (diPol<0) sclDip = -sclDip;
+ //
+ BeamType_t btype = kNoBeamField;
+ TString btypestr = beamtype;
+ btypestr.ToLower();
+ TPRegexp protonBeam("(proton|p)\\s*-?\\s*\\1");
+ TPRegexp ionBeam("(lead|pb|ion|a)\\s*-?\\s*\\1");
+ if (btypestr.Contains(ionBeam)) btype = kBeamTypeAA;
+ else if (btypestr.Contains(protonBeam)) btype = kBeamTypepp;
+ else AliInfoGeneral("AliMagF",Form("Assume no LHC magnet field for the beam type %s, ",beamtype));
+ char ttl[80];
+ sprintf(ttl,"L3: %+5d Dip: %+4d kA; %s | Polarities in %s convention",(int)TMath::Sign(l3Cur,float(sclL3)),
+ (int)TMath::Sign(diCur,float(sclDip)),uniform ? " Constant":"",
+ convention==kConvLHC ? "LHC":"DCS2008");
+ // LHC and DCS08 conventions have opposite dipole polarities
+ if ( GetPolarityConvention() != convention) sclDip = -sclDip;
+ //
+ return new AliMagF("MagneticFieldMap", ttl,sclL3,sclDip,map,btype,beamenergy,2,10.,path);
+ //
+}
+
+//_____________________________________________________________________________
+const char* AliMagF::GetBeamTypeText() const
+{
+ const char *beamNA = "No Beam";
+ const char *beamPP = "p-p";
+ const char *beamPbPb= "Pb-Pb";
+ switch ( fBeamType ) {
+ case kBeamTypepp : return beamPP;
+ case kBeamTypeAA : return beamPbPb;
+ case kNoBeamField:
+ default: return beamNA;
+ }
+}
+
+//_____________________________________________________________________________
+void AliMagF::Print(Option_t *opt) const
+{
+ // print short or long info
+ TString opts = opt; opts.ToLower();
+ AliInfo(Form("%s:%s",GetName(),GetTitle()));
+ AliInfo(Form("Solenoid (%+.2f*)%.0f kG, Dipole %s (%+.2f) %s",
+ GetFactorSol(),(fMapType==k5kG||fMapType==k5kGUniform)?5.:2.,
+ fDipoleOFF ? "OFF":"ON",GetFactorDip(),fMapType==k5kGUniform?" |Constant Field!":""));
+ if (opts.Contains("a")) {
+ AliInfo(Form("Machine B fields for %s beam (%.0f GeV): QGrad: %.4f Dipole: %.4f",
+ fBeamType==kBeamTypeAA ? "A-A":(fBeamType==kBeamTypepp ? "p-p":"OFF"),
+ fBeamEnergy,fQuadGradient,fDipoleField));
+ AliInfo(Form("Uses %s of %s",GetParamName(),GetDataFileName()));
+ }
}
git://git.uio.no / u / mrichter / AliRoot.git / blobdiff