modified some base classes
This commit is contained in:
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3a0dba08da
commit
6fad708ee2
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@ -15,6 +15,8 @@
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struct Array{
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bool enable;
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double detPerpDist; /// distance from axis
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double detWidth; /// width
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double detLength; /// length
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@ -85,11 +87,7 @@ public:
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double elumPos1, elumPos2; /// imaginary elum, only sensitive to light recoil
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//===================1st array
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Array array1;
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//==================2nd array
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bool use2ndArray;
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Array array2;
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Array array[2];
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double zMin, zMax; /// range of detectors
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bool isCoincidentWithRecoil;
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@ -129,9 +127,7 @@ inline bool DetGeo::LoadDetectorGeo(TMacro * macro, bool verbose){
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TList * haha = macro->GetListOfLines();
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int numLine = (haha)->GetSize();
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array1.pos.clear();
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array2.pos.clear();
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use2ndArray = false;
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for( int i = 0; i < 2 ; i++) array[i].pos.clear();
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int detFlag = 0;
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int detLine = 0;
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@ -170,45 +166,35 @@ inline bool DetGeo::LoadDetectorGeo(TMacro * macro, bool verbose){
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if ( detLine == 10 ) elumPos2 = atof(str[0].c_str());
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}
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if( detFlag == 1){
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if ( detLine == 0 ) array1.detPerpDist = atof(str[0].c_str());
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if ( detLine == 1 ) array1.detWidth = atof(str[0].c_str());
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if ( detLine == 2 ) array1.detLength = atof(str[0].c_str());
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if ( detLine == 3 ) array1.blocker = atof(str[0].c_str());
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if ( detLine == 4 ) array1.firstPos = atof(str[0].c_str());
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if ( detLine == 5 ) array1.eSigma = atof(str[0].c_str());
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if ( detLine == 6 ) array1.zSigma = atof(str[0].c_str());
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if ( detLine == 7 ) array1.detFaceOut = str[0] == "Out" ? true : false;
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if ( detLine == 8 ) array1.mDet = atoi(str[0].c_str());
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if ( detLine >= 9 ) array1.pos.push_back(atof(str[0].c_str()));
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}
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if( detFlag == 2){
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if ( detLine == 0 ) use2ndArray = str[0] == "true" ? true : false;
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if ( detLine == 1 ) array2.detPerpDist = atof(str[0].c_str());
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if ( detLine == 2 ) array2.detWidth = atof(str[0].c_str());
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if ( detLine == 3 ) array2.detLength = atof(str[0].c_str());
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if ( detLine == 4 ) array2.blocker = atof(str[0].c_str());
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if ( detLine == 5 ) array2.firstPos = atof(str[0].c_str());
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if ( detLine == 6 ) array2.eSigma = atof(str[0].c_str());
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if ( detLine == 7 ) array2.zSigma = atof(str[0].c_str());
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if ( detLine == 8 ) array2.detFaceOut = str[0] == "Out" ? true : false;
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if ( detLine == 9 ) array2.mDet = atoi(str[0].c_str());
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if ( detLine >= 10 ) array2.pos.push_back(atof(str[0].c_str()));
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if( detFlag > 0){
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unsigned short ID = detFlag - 1;
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if ( detLine == 0 ) array[ID].enable = str[0] == "true" ? true : false;
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if ( detLine == 1 ) array[ID].detPerpDist = atof(str[0].c_str());
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if ( detLine == 2 ) array[ID].detWidth = atof(str[0].c_str());
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if ( detLine == 3 ) array[ID].detLength = atof(str[0].c_str());
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if ( detLine == 4 ) array[ID].blocker = atof(str[0].c_str());
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if ( detLine == 5 ) array[ID].firstPos = atof(str[0].c_str());
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if ( detLine == 6 ) array[ID].eSigma = atof(str[0].c_str());
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if ( detLine == 7 ) array[ID].zSigma = atof(str[0].c_str());
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if ( detLine == 8 ) array[ID].detFaceOut = str[0] == "Out" ? true : false;
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if ( detLine == 9 ) array[ID].mDet = atoi(str[0].c_str());
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if ( detLine >= 10 ) array[ID].pos.push_back(atof(str[0].c_str()));
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}
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detLine ++;
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}
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array1.DeduceAbsolutePos();
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array2.DeduceAbsolutePos();
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zMin = 99999;
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zMax = -99999;
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zMin = array1.zMin;
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zMax = array1.zMax;
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if( use2ndArray) {
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zMax = TMath::Min(array1.zMax, array2.zMax);
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zMin = TMath::Min(array1.zMin, array2.zMin);
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for( int i = 0; i < 2; i ++ ){
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array[i].DeduceAbsolutePos();
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if (array[i].enable ) {
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double zmax = TMath::Max(array[i].zMin, array[i].zMax);
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double zmin = TMath::Min(array[i].zMin, array[i].zMax);
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if( zmax > zMax ) zMax = zmax;
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if( zmin < zMin ) zMin = zmin;
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}
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}
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if( verbose ) Print(false);
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@ -226,12 +212,13 @@ inline void DetGeo::Print(bool printAll) const{
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}
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printf(" Recoil detector pos: %8.2f mm, radius: %6.2f - %6.2f mm \n", recoilPos, recoilInnerRadius, recoilOuterRadius);
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printf("------------------------------------- Detector Position \n");
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array1.PrintArray();
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for( int i = 0; i < 2 ; i++){
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if( printAll || array[i].enable ) {
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printf("-----------------------------------%d-th Detector Position \n", i);
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array[i].PrintArray();
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}
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if( printAll || use2ndArray){
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printf("--------------------------------- 2nd Detector Position \n");
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array2.PrintArray();
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}
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if( elumPos1 != 0 || elumPos2 != 0 || recoilPos1 != 0 || recoilPos2 != 0){
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@ -63,14 +63,14 @@ public:
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float targetThickness; ///targetThickness_in_cm
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std::string beamStoppingPowerFile; ///stopping_power_for_beam
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Recoil recoil1, recoil2;
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Recoil recoil[2];
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int numEvents; ///number_of_Event_being_generated
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bool isRedo; ///isReDo
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void SetReactionSimple(int beamA, int beamZ,
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int targetA, int targetZ,
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int recoilA, int recoilZ, float beamEnergy_AMeV);
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int recoilA, int recoilZ, float beamEnergy_AMeV, unsigned short ID);
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bool LoadReactionConfig(TString fileName);
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bool LoadReactionConfig(TMacro * macro);
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@ -83,17 +83,17 @@ private:
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inline void ReactionConfig::SetReactionSimple(int beamA, int beamZ,
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int targetA, int targetZ,
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int recoilA, int recoilZ, float beamEnergy_AMeV){
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int recoilA, int recoilZ, float beamEnergy_AMeV, unsigned short ID){
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this->beamA = beamA;
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this->beamZ = beamZ;
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this->targetA = targetA;
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this->targetZ = targetZ;
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this->recoil1.lightA = recoilA;
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this->recoil1.lightZ = recoilZ;
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recoil1.heavyA = this->beamA + this->targetA - recoil1.lightA;
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recoil1.heavyZ = this->beamZ + this->targetZ - recoil1.lightZ;
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this->recoil[ID].lightA = recoilA;
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this->recoil[ID].lightZ = recoilZ;
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recoil[ID].heavyA = this->beamA + this->targetA - recoil[ID].lightA;
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recoil[ID].heavyZ = this->beamZ + this->targetZ - recoil[ID].lightZ;
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beamEnergy = beamEnergy_AMeV;
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beamEnergySigma = 0;
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@ -168,27 +168,16 @@ inline bool ReactionConfig::LoadReactionConfig(TMacro * macro){
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if( recoilLine == 16 ) isRedo = str[0].compare("true" ) == 0 ? true : false;
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}
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if( recoilFlag == 1 ){
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if( recoilFlag > 0 ){
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if( recoilLine == 0 ) recoil1.lightA = atoi(str[0].c_str());
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if( recoilLine == 1 ) recoil1.lightZ = atoi(str[0].c_str());
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if( recoilLine == 2 ) recoil1.lightStoppingPowerFile = str[0];
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if( recoilLine == 3 ) recoil1.heavyStoppingPowerFile = str[0];
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if( recoilLine == 4 ) recoil1.isDecay = str[0].compare("true") == 0 ? true : false;
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if( recoilLine == 5 ) recoil1.decayA = atoi(str[0].c_str());
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if( recoilLine == 6 ) recoil1.decayZ = atoi(str[0].c_str());
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}
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if( recoilFlag == 2 ){
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if( recoilLine == 0 ) recoil2.lightA = atoi(str[0].c_str());
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if( recoilLine == 1 ) recoil2.lightZ = atoi(str[0].c_str());
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if( recoilLine == 2 ) recoil2.lightStoppingPowerFile = str[0];
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if( recoilLine == 3 ) recoil2.heavyStoppingPowerFile = str[0];
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if( recoilLine == 4 ) recoil2.isDecay = str[0].compare("true") == 0 ? true : false;
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if( recoilLine == 5 ) recoil2.decayA = atoi(str[0].c_str());
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if( recoilLine == 6 ) recoil2.decayZ = atoi(str[0].c_str());
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unsigned ID = recoilFlag - 1;
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if( recoilLine == 0 ) recoil[ID].lightA = atoi(str[0].c_str());
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if( recoilLine == 1 ) recoil[ID].lightZ = atoi(str[0].c_str());
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if( recoilLine == 2 ) recoil[ID].lightStoppingPowerFile = str[0];
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if( recoilLine == 3 ) recoil[ID].heavyStoppingPowerFile = str[0];
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if( recoilLine == 4 ) recoil[ID].isDecay = str[0].compare("true") == 0 ? true : false;
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if( recoilLine == 5 ) recoil[ID].decayA = atoi(str[0].c_str());
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if( recoilLine == 6 ) recoil[ID].decayZ = atoi(str[0].c_str());
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}
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@ -196,12 +185,10 @@ inline bool ReactionConfig::LoadReactionConfig(TMacro * macro){
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}
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recoil1.heavyA = beamA + targetA - recoil1.lightA;
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recoil1.heavyZ = beamZ + targetZ - recoil1.lightZ;
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recoil2.heavyA = beamA + targetA - recoil2.lightA;
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recoil2.heavyZ = beamZ + targetZ - recoil2.lightZ;
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for( int i = 0; i < 2; i++){
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recoil[i].heavyA = beamA + targetA - recoil[i].lightA;
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recoil[i].heavyZ = beamZ + targetZ - recoil[i].lightZ;
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}
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return true;
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}
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@ -227,9 +214,9 @@ inline void ReactionConfig::Print() const{
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printf(" beam stopping file : %s \n", beamStoppingPowerFile.c_str());
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}
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printf("------------------------------ Recoil-1\n"); recoil1.Print();
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printf("------------------------------ Recoil-2\n"); recoil2.Print();
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for( int i = 0; i < 2; i ++ ){
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printf("------------------------------ Recoil-%d\n", i); recoil[i].Print();
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}
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printf("=====================================================\n");
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@ -54,8 +54,24 @@ struct trajectory{
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printf(" detID : %d \n", detID);
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}
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};
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void Clear(){
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theta = TMath::QuietNaN();
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phi = TMath::QuietNaN();
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vt = TMath::QuietNaN();
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vp = TMath::QuietNaN();
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rho = TMath::QuietNaN();
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z0 = TMath::QuietNaN();
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t0 = TMath::QuietNaN();
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x = TMath::QuietNaN();
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y = TMath::QuietNaN();
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z = TMath::QuietNaN();
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effLoop = TMath::QuietNaN();
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detID = -1;
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detRowID = -1;
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loop = -1;
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}
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};
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class HELIOS{
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public:
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@ -65,37 +81,23 @@ public:
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void SetCoincidentWithRecoil(bool TorF){ this->isCoincidentWithRecoil = TorF;}
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bool GetCoincidentWithRecoil(){return this->isCoincidentWithRecoil;}
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bool SetDetectorGeometry(std::string filename);
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bool SetDetectorGeometry(std::string filename, unsigned short ID);
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void SetBeamPosition(double x, double y) { xOff = x; yOff = y;}
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void OverrideMagneticField(double BField){ this->detGeo.Bfield = BField; this->detGeo.BfieldSign = BField > 0 ? 1: -1;}
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void OverrideMagneticFieldDirection(double BfieldThetaInDeg){ this->detGeo.BfieldTheta = BfieldThetaInDeg;}
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void OverrideFirstPos(double firstPos){
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overrideFirstPos = true;
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printf("------ Overriding FirstPosition to : %8.2f mm \n", firstPos);
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this->array.firstPos = firstPos;
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}
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void OverrideDetectorDistance(double perpDist){
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overrideDetDistance = true;
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printf("------ Overriding Detector Distance to : %8.2f mm \n", perpDist);
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this->array.detPerpDist = perpDist;
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}
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void OverrideMagneticField(double BField);
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void OverrideMagneticFieldDirection(double BfieldThetaInDeg);
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void OverrideFirstPos(double firstPos);
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void OverrideDetectorDistance(double perpDist);
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void OverrideDetectorFacing(bool isOutside);
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void SetDetectorOutside(bool isOutside){
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this->array.detFaceOut = isOutside;
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printf(" Detectors are facing %s\n", array.detFaceOut ? "outside": "inside" );
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}
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int DetAcceptance();
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int CalArrayHit(TLorentzVector Pb, int Zb, bool debug = false);
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int CalRecoilHit(TLorentzVector PB, int ZB);
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//int CalHit(TLorentzVector Pb, int Zb, TLorentzVector PB, int ZB, double xOff = 0, double yOff = 0 ); // return 0 for no hit, 1 for hit
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void CalTrajectoryPara(TLorentzVector P, int Z, bool isLightRecoil);
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int CheckDetAcceptance();
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int CalArrayHit(TLorentzVector Pb, bool debug = false);
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int CalRecoilHit(TLorentzVector PB);
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void CalTrajectoryPara(TLorentzVector P, bool isLightRecoil);
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int GetNumberOfDetectorsInSamePos(){return array.mDet;}
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double GetEnergy(){return e;}
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double GetDetX(){return detX;} // position in each detector, range from -1, 1
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double GetEnergy()const {return e;}
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double GetDetX() const {return detX;} // position in each detector, range from -1, 1
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/// clockwise rotation for B-field along the z-axis, sign = 1.
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double XPos(double Zpos, double theta, double phi, double rho, int sign){
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double GetRecoilYPos(double ZPos){ return TMath::IsNaN(ZPos) ? TMath::QuietNaN() : YPos( ZPos, orbitB.theta, orbitB.phi, orbitB.rho, detGeo.BfieldSign); }
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double GetRecoilR(double ZPos) { return TMath::IsNaN(ZPos) ? TMath::QuietNaN() : RPos( ZPos, orbitB.theta, orbitB.phi, orbitB.rho, detGeo.BfieldSign); }
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double GetBField() {return detGeo.Bfield;}
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double GetDetRadius() {return array.detPerpDist;}
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void PrintGeometry() const;
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trajectory GetTrajectory_b() {return orbitb;}
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trajectory GetTrajectory_B() {return orbitB;}
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double GetBField() const {return detGeo.Bfield;}
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double GetDetRadius() const {return array.detPerpDist;}
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DetGeo GetDetectorGeometry() {return detGeo;}
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trajectory GetTrajectory_b() const {return orbitb;}
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trajectory GetTrajectory_B() const {return orbitB;}
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DetGeo GetDetectorGeometry() const {return detGeo;}
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TString GetHitMessage() const {return hitMessage;}
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TString GetAcceptanceMessage() const {return accMessage;}
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private:
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void ClearTrajectory(trajectory t){
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t.theta = TMath::QuietNaN();
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t.phi = TMath::QuietNaN();
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t.vt = TMath::QuietNaN();
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t.vp = TMath::QuietNaN();
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t.rho = TMath::QuietNaN();
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t.z0 = TMath::QuietNaN();
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t.t0 = TMath::QuietNaN();
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t.x = TMath::QuietNaN();
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t.y = TMath::QuietNaN();
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t.z = TMath::QuietNaN();
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t.effLoop = TMath::QuietNaN();
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t.detID = -1;
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t.detRowID = -1;
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t.loop = -1;
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}
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DetGeo detGeo;
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Array array;
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@ -178,8 +165,8 @@ private:
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HELIOS::HELIOS(){
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ClearTrajectory(orbitb);
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ClearTrajectory(orbitB);
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orbitb.Clear();
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orbitB.Clear();
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e = TMath::QuietNaN();
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eB = TMath::QuietNaN();
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@ -204,19 +191,40 @@ HELIOS::~HELIOS(){
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}
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bool HELIOS::SetDetectorGeometry(std::string filename){
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if( detGeo.LoadDetectorGeo(filename)) {
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if( detGeo.use2ndArray ){
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array = detGeo.array2;
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}else{
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array = detGeo.array1;
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void HELIOS::OverrideMagneticField(double BField){
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this->detGeo.Bfield = BField;
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this->detGeo.BfieldSign = BField > 0 ? 1: -1;
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}
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isCoincidentWithRecoil = detGeo.isCoincidentWithRecoil;
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void HELIOS::OverrideMagneticFieldDirection(double BfieldThetaInDeg){
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this->detGeo.BfieldTheta = BfieldThetaInDeg;
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}
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void HELIOS::OverrideFirstPos(double firstPos){
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overrideFirstPos = true;
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printf("------ Overriding FirstPosition to : %8.2f mm \n", firstPos);
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this->array.firstPos = firstPos;
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}
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void HELIOS::OverrideDetectorDistance(double perpDist){
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overrideDetDistance = true;
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printf("------ Overriding Detector Distance to : %8.2f mm \n", perpDist);
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this->array.detPerpDist = perpDist;
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}
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void HELIOS::OverrideDetectorFacing(bool isOutside){
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this->array.detFaceOut = isOutside;
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printf(" Detectors are facing %s\n", array.detFaceOut ? "outside": "inside" );
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}
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bool HELIOS::SetDetectorGeometry(std::string filename, unsigned short ID){
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||||
|
||||
if( detGeo.LoadDetectorGeo(filename, false)) {
|
||||
|
||||
array = detGeo.array[ID];
|
||||
isCoincidentWithRecoil = detGeo.isCoincidentWithRecoil;
|
||||
isDetReady = true;
|
||||
|
||||
}else{
|
||||
printf("cannot read file %s.\n", filename.c_str());
|
||||
isDetReady = false;
|
||||
|
@ -225,7 +233,31 @@ bool HELIOS::SetDetectorGeometry(std::string filename){
|
|||
return isDetReady;
|
||||
}
|
||||
|
||||
int HELIOS::DetAcceptance(){
|
||||
void HELIOS::PrintGeometry() const{
|
||||
|
||||
printf("=====================================================\n");
|
||||
printf(" B-field: %8.2f T, Theta : %6.2f deg \n", detGeo.Bfield, detGeo.BfieldTheta);
|
||||
if( detGeo.BfieldTheta != 0.0 ) {
|
||||
printf(" +---- field angle != 0 is not supported!!! \n");
|
||||
}
|
||||
printf(" Recoil detector pos: %8.2f mm, radius: %6.2f - %6.2f mm \n", detGeo.recoilPos, detGeo.recoilInnerRadius, detGeo.recoilOuterRadius);
|
||||
|
||||
printf("----------------------------------- Detector Position \n");
|
||||
array.PrintArray();
|
||||
|
||||
if( detGeo.elumPos1 != 0 || detGeo.elumPos2 != 0 || detGeo.recoilPos1 != 0 || detGeo.recoilPos2 != 0){
|
||||
printf("=================================== Auxillary/Imaginary Detectors\n");
|
||||
}
|
||||
if( detGeo.elumPos1 != 0 ) printf(" Elum 1 pos.: %f mm \n", detGeo.elumPos1);
|
||||
if( detGeo.elumPos2 != 0 ) printf(" Elum 2 pos.: %f mm \n", detGeo.elumPos2);
|
||||
if( detGeo.recoilPos1 != 0 ) printf(" Recoil 1 pos.: %f mm \n", detGeo.recoilPos1);
|
||||
if( detGeo.recoilPos2 != 0 ) printf(" Recoil 2 pos.: %f mm \n", detGeo.recoilPos2);
|
||||
printf("=====================================================\n");
|
||||
|
||||
|
||||
}
|
||||
|
||||
int HELIOS::CheckDetAcceptance(){
|
||||
|
||||
//CalArrayHit and CalRecoilHit must be done before.
|
||||
|
||||
|
@ -329,12 +361,12 @@ int HELIOS::DetAcceptance(){
|
|||
return -20; // for unknown reason
|
||||
}
|
||||
|
||||
void HELIOS::CalTrajectoryPara(TLorentzVector P, int Z, bool isLightRecoil){
|
||||
void HELIOS::CalTrajectoryPara(TLorentzVector P, bool isLightRecoil){
|
||||
|
||||
if( isLightRecoil ){
|
||||
orbitb.theta = P.Theta();
|
||||
orbitb.phi = P.Phi();
|
||||
orbitb.rho = P.Pt() / abs(detGeo.Bfield) / Z / c * 1000; //mm
|
||||
orbitb.rho = P.Pt() / abs(detGeo.Bfield) / P.GetUniqueID() / c * 1000; //mm
|
||||
orbitb.vt = P.Beta() * TMath::Sin(P.Theta()) * c ; // mm / nano-second
|
||||
orbitb.vp = P.Beta() * TMath::Cos(P.Theta()) * c ; // mm / nano-second
|
||||
orbitb.t0 = TMath::TwoPi() * orbitb.rho / orbitb.vt; // nano-second
|
||||
|
@ -346,7 +378,7 @@ void HELIOS::CalTrajectoryPara(TLorentzVector P, int Z, bool isLightRecoil){
|
|||
}else{
|
||||
orbitB.theta = P.Theta();
|
||||
orbitB.phi = P.Phi();
|
||||
orbitB.rho = P.Pt() / abs(detGeo.Bfield) / Z / c * 1000; //mm
|
||||
orbitB.rho = P.Pt() / abs(detGeo.Bfield) / P.GetUniqueID() / c * 1000; //mm
|
||||
orbitB.vt = P.Beta() * TMath::Sin(P.Theta()) * c ; // mm / nano-second
|
||||
orbitB.vp = P.Beta() * TMath::Cos(P.Theta()) * c ; // mm / nano-second
|
||||
orbitB.t0 = TMath::TwoPi() * orbitB.rho / orbitB.vt; // nano-second
|
||||
|
@ -357,13 +389,13 @@ void HELIOS::CalTrajectoryPara(TLorentzVector P, int Z, bool isLightRecoil){
|
|||
}
|
||||
}
|
||||
|
||||
int HELIOS::CalArrayHit(TLorentzVector Pb, int Zb, bool debug){
|
||||
int HELIOS::CalArrayHit(TLorentzVector Pb, bool debug){
|
||||
|
||||
e = Pb.E() - Pb.M();
|
||||
detX = TMath::QuietNaN();
|
||||
rhoHit = TMath::QuietNaN();
|
||||
|
||||
CalTrajectoryPara(Pb, Zb, true);
|
||||
CalTrajectoryPara(Pb, true);
|
||||
|
||||
int targetLoop = 1;
|
||||
int inOut = array.detFaceOut == true ? 1: 0; //1 = from Outside, 0 = from inside
|
||||
|
@ -470,9 +502,9 @@ int HELIOS::CalArrayHit(TLorentzVector Pb, int Zb, bool debug){
|
|||
return 1; // return 1 when OK
|
||||
}
|
||||
|
||||
int HELIOS::CalRecoilHit(TLorentzVector PB, int ZB){
|
||||
int HELIOS::CalRecoilHit(TLorentzVector PB){
|
||||
|
||||
CalTrajectoryPara(PB, ZB, false);
|
||||
CalTrajectoryPara(PB, false);
|
||||
|
||||
orbitB.z = detGeo.recoilPos;
|
||||
orbitB.x = GetRecoilXPos(detGeo.recoilPos) ;
|
||||
|
|
|
@ -30,9 +30,9 @@ public:
|
|||
targetA, targetZ,
|
||||
recoilA, recoilZ, beamEnergy_AMeV);
|
||||
}
|
||||
TransferReaction(string configFile){
|
||||
TransferReaction(string configFile, unsigned short ID = 0){
|
||||
Inititization();
|
||||
SetReactionFromFile(configFile);
|
||||
SetReactionFromFile(configFile, ID);
|
||||
}
|
||||
|
||||
~TransferReaction();
|
||||
|
@ -49,7 +49,7 @@ public:
|
|||
|
||||
void SetExA(double Ex);
|
||||
void SetExB(double Ex);
|
||||
void SetReactionFromFile(string configFile);
|
||||
void SetReactionFromFile(string configFile, unsigned short ID = 0);
|
||||
|
||||
TString GetReactionName();
|
||||
TString GetReactionName_Latex();
|
||||
|
@ -70,7 +70,8 @@ public:
|
|||
TLorentzVector GetPb(){return Pb;}
|
||||
TLorentzVector GetPB(){return PB;}
|
||||
|
||||
void PrintFourVectors();
|
||||
void PrintFourVectors() const;
|
||||
void PrintReaction() const;
|
||||
|
||||
void CalReactionConstant();
|
||||
|
||||
|
@ -85,6 +86,7 @@ public:
|
|||
|
||||
private:
|
||||
|
||||
Recoil recoil;
|
||||
ReactionConfig config;
|
||||
|
||||
string nameA, namea, nameb, nameB;
|
||||
|
@ -161,8 +163,8 @@ void TransferReaction::Seta(int A, int Z){
|
|||
void TransferReaction::Setb(int A, int Z){
|
||||
Isotope temp (A, Z);
|
||||
mb = temp.Mass;
|
||||
config.recoil1.lightA = A;
|
||||
config.recoil1.lightZ = Z;
|
||||
recoil.lightA = A;
|
||||
recoil.lightZ = Z;
|
||||
nameb = temp.Name;
|
||||
isReady = false;
|
||||
isBSet = false;
|
||||
|
@ -170,8 +172,8 @@ void TransferReaction::Setb(int A, int Z){
|
|||
void TransferReaction::SetB(int A, int Z){
|
||||
Isotope temp (A, Z);
|
||||
mB = temp.Mass;
|
||||
config.recoil1.heavyA = A;
|
||||
config.recoil1.heavyZ = Z;
|
||||
recoil.heavyA = A;
|
||||
recoil.heavyZ = Z;
|
||||
nameB = temp.Name;
|
||||
isReady = false;
|
||||
isBSet = true;
|
||||
|
@ -191,12 +193,14 @@ void TransferReaction::SetReactionSimple(int beamA, int beamZ,
|
|||
|
||||
config.SetReactionSimple(beamA, beamZ,
|
||||
targetA, targetZ,
|
||||
recoilA, recoilZ, beamEnergy_AMeV);
|
||||
recoilA, recoilZ, beamEnergy_AMeV, 0);
|
||||
|
||||
recoil = config.recoil[0];
|
||||
|
||||
SetA(config.beamA, config.beamZ);
|
||||
Seta(config.targetA, config.targetZ);
|
||||
Setb(config.recoil1.lightA, config.recoil1.lightZ);
|
||||
SetB(config.recoil1.heavyA, config.recoil1.heavyZ);
|
||||
Setb(recoil.lightA, recoil.lightZ);
|
||||
SetB(recoil.heavyA, recoil.heavyZ);
|
||||
SetIncidentEnergyAngle(config.beamEnergy, 0, 0);
|
||||
|
||||
CalReactionConstant();
|
||||
|
@ -213,14 +217,17 @@ void TransferReaction::SetExB(double Ex){
|
|||
isReady = false;
|
||||
}
|
||||
|
||||
void TransferReaction::SetReactionFromFile(string configFile){
|
||||
void TransferReaction::SetReactionFromFile(string configFile, unsigned short ID){
|
||||
|
||||
if( config.LoadReactionConfig(configFile) ){
|
||||
|
||||
SetA(config.beamA, config.beamZ);
|
||||
Seta(config.targetA, config.targetZ);
|
||||
Setb(config.recoil1.lightA, config.recoil1.lightZ);
|
||||
SetB(config.recoil1.heavyA, config.recoil1.heavyZ);
|
||||
|
||||
recoil = config.recoil[ID];
|
||||
|
||||
Setb(recoil.lightA, recoil.lightZ);
|
||||
SetB(recoil.heavyA, recoil.heavyZ);
|
||||
SetIncidentEnergyAngle(config.beamEnergy, 0, 0);
|
||||
|
||||
CalReactionConstant();
|
||||
|
@ -260,9 +267,9 @@ TString TransferReaction::GetReactionName_Latex(){
|
|||
|
||||
void TransferReaction::CalReactionConstant(){
|
||||
if( !isBSet){
|
||||
config.recoil1.heavyA = config.beamA + config.targetA - config.recoil1.lightA;
|
||||
config.recoil1.heavyZ = config.beamZ + config.targetZ - config.recoil1.lightZ;
|
||||
Isotope temp (config.recoil1.heavyA, config.recoil1.heavyZ);
|
||||
recoil.heavyA = config.beamA + config.targetA - recoil.lightA;
|
||||
recoil.heavyZ = config.beamZ + config.targetZ - recoil.lightZ;
|
||||
Isotope temp (recoil.heavyA, recoil.heavyZ);
|
||||
mB = temp.Mass;
|
||||
isBSet = true;
|
||||
}
|
||||
|
@ -279,10 +286,15 @@ void TransferReaction::CalReactionConstant(){
|
|||
|
||||
Pa.SetXYZM(0,0,0,ma);
|
||||
|
||||
PA.SetUniqueID(config.beamZ);
|
||||
Pa.SetUniqueID(config.targetZ);
|
||||
Pb.SetUniqueID(recoil.lightZ);
|
||||
PB.SetUniqueID(recoil.heavyZ);
|
||||
|
||||
isReady = true;
|
||||
}
|
||||
|
||||
void TransferReaction::PrintFourVectors(){
|
||||
void TransferReaction::PrintFourVectors() const {
|
||||
|
||||
printf("A : %10.2f %10.2f %10.2f %10.2f\n", PA.E(), PA.Px(), PA.Py(), PA.Pz());
|
||||
printf("a : %10.2f %10.2f %10.2f %10.2f\n", Pa.E(), Pa.Px(), Pa.Py(), Pa.Pz());
|
||||
|
@ -297,6 +309,25 @@ void TransferReaction::PrintFourVectors(){
|
|||
|
||||
}
|
||||
|
||||
void TransferReaction::PrintReaction() const {
|
||||
|
||||
printf("=====================================================\n");
|
||||
printf("------------------------------ Beam\n");
|
||||
printf(" beam : A = %3d, Z = %2d, Ex = %.2f MeV\n", config.beamA, config.beamZ, config.beamEx);
|
||||
printf(" beam Energy : %.2f +- %.2f MeV/u, dE/E = %5.2f %%\n", config.beamEnergy, config.beamEnergySigma, config.beamEnergySigma/config.beamEnergy);
|
||||
printf(" Angle : %.2f +- %.2f mrad\n", config.beamAngle, config.beamAngleSigma);
|
||||
printf(" offset : (x,y) = (%.2f, %.2f) mmm \n", config.beamX, config.beamY);
|
||||
|
||||
printf("------------------------------ Target\n");
|
||||
printf(" target : A = %3d, Z = %2d \n", config.targetA, config.targetZ);
|
||||
|
||||
printf("------------------------------ Recoil\n");
|
||||
printf(" light : A = %3d, Z = %2d \n", recoil.lightA, recoil.lightZ);
|
||||
printf(" heavy : A = %3d, Z = %2d \n", recoil.heavyA, recoil.heavyZ);
|
||||
printf("=====================================================\n");
|
||||
|
||||
}
|
||||
|
||||
void TransferReaction::Event(double thetaCM_rad, double phiCM_rad){
|
||||
|
||||
if( isReady == false ){
|
||||
|
@ -355,7 +386,7 @@ std::pair<double, double> TransferReaction::CalExThetaCM(double e, double z, dou
|
|||
double mass = mb;
|
||||
double massB = mB;
|
||||
double y = e + mass;
|
||||
double slope = 299.792458 * config.recoil1.lightZ * abs(Bfield) / TMath::TwoPi() * beta / 1000.; // MeV/mm;
|
||||
double slope = 299.792458 * recoil.lightZ * abs(Bfield) / TMath::TwoPi() * beta / 1000.; // MeV/mm;
|
||||
double alpha = slope/beta;
|
||||
double G = alpha * gamma * beta * perpDist ;
|
||||
double Z = alpha * gamma * beta * z;
|
||||
|
|
|
@ -13,6 +13,7 @@ false //is_coincident_with_recoil
|
|||
0.00 //Elum_2_position_[mm]_when_Elum=0_disable_tree_branch
|
||||
|
||||
#===============1st_Array
|
||||
true ////is_this_array_exist_or_use_for_Simulation
|
||||
11.5 //distance_from_axis_[mm]
|
||||
10.0 //width_of_detector_[mm]
|
||||
50 //length_of_detector_[mm]
|
||||
|
@ -30,12 +31,12 @@ Out //detector_facing_Out_or_In
|
|||
294.0
|
||||
|
||||
#===============2nd_Array
|
||||
false //is_2nd_array_exist_is_use_for_Simulation
|
||||
true //is_this_array_exist_or_use_for_Simulation
|
||||
11.5 //distance_from_axis_[mm]
|
||||
10.0 //width_of_detector_[mm]
|
||||
50 //length_of_detector_[mm]
|
||||
0 //blocker_length_[mm]
|
||||
121 //first_position_-_for_upstream_[mm]
|
||||
500 //first_position_-_for_upstream_[mm]
|
||||
0.03 //energy_resolution_of_PSD_array_[MeV]
|
||||
1.00 //position_resolution_of_PSD_array_[mm]
|
||||
Out //detector_facing_Out_or_In
|
||||
|
|
Loading…
Reference in New Issue
Block a user