mirror of
https://github.com/gwm17/Mask.git
synced 2024-11-22 18:28:51 -05:00
Add better edge sampling of resonance excitations. Add new CoupledThreeStepSystem for angular correlations as well as optional correlation analysis in RootPlot
This commit is contained in:
parent
cf22fb6384
commit
d68f5de383
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@ -20,6 +20,12 @@ SabreArray::SabreArray() :
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m_degradedDetectors[2] = false;
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m_degradedDetectors[2] = false;
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m_degradedDetectors[3] = false;
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m_degradedDetectors[3] = false;
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m_degradedDetectors[4] = true;
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m_degradedDetectors[4] = true;
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//No degraded detectors
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// m_degradedDetectors[0] = false;
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// m_degradedDetectors[1] = false;
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// m_degradedDetectors[2] = false;
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// m_degradedDetectors[3] = false;
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// m_degradedDetectors[4] = false;
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//Choose who to look at right now. Usually switch on or off degraded/non-degraded.
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//Choose who to look at right now. Usually switch on or off degraded/non-degraded.
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m_activeDetectors[0] = false;
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m_activeDetectors[0] = false;
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@ -79,7 +79,7 @@ namespace Mask {
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//Renormalize distribution such that total prob is 1.0.
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//Renormalize distribution such that total prob is 1.0.
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//Test branching ratio to see if we "make" a decay particle,
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//Test branching ratio to see if we "make" a decay particle,
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//then use re-normalized distribution to pick an angle.
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//then use re-normalized distribution to pick an angle.
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if(m_constants[0] < 0.5)
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if(m_constants[0] != 0.5)
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{
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{
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double norm = 0.5/m_constants[0];
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double norm = 0.5/m_constants[0];
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for(auto& value : m_constants)
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for(auto& value : m_constants)
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@ -115,4 +115,14 @@ namespace Mask {
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return costheta;
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return costheta;
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}
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}
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double AngularDistribution::GetProbability(double cosTheta)
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{
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double prob = 0.0;
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for (std::size_t i=0; i<m_constants.size(); i++)
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{
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prob += m_constants[i] * P_l(i*2, cosTheta);
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}
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return prob;
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}
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}
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}
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@ -17,6 +17,7 @@ namespace Mask {
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double GetRandomCosTheta();
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double GetRandomCosTheta();
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int GetL() { return m_L; }
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int GetL() { return m_L; }
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double GetBranchingRatio() { return m_branchingRatio; }
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double GetBranchingRatio() { return m_branchingRatio; }
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double GetProbability(double cosTheta);
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private:
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private:
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bool IsIsotropic() { return m_isIsotropic; }
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bool IsIsotropic() { return m_isIsotropic; }
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@ -55,6 +55,8 @@ target_sources(Mask PRIVATE
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FileWriter.cpp
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FileWriter.cpp
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FileReader.h
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FileReader.h
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FileReader.cpp
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FileReader.cpp
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CoupledThreeStepSystem.h
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CoupledThreeStepSystem.cpp
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)
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)
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set(THREADS_PREFER_PTHREAD_FLAG On)
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set(THREADS_PREFER_PTHREAD_FLAG On)
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210
src/Mask/CoupledThreeStepSystem.cpp
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210
src/Mask/CoupledThreeStepSystem.cpp
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#include "CoupledThreeStepSystem.h"
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#include "Math/Boost.h"
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#include "Math/Vector3D.h"
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#include "Math/RotationY.h"
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#include "Math/RotationZ.h"
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namespace Mask {
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CoupledThreeStepSystem::CoupledThreeStepSystem(const std::vector<StepParameters>& params) :
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ReactionSystem()
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{
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m_nuclei.resize(8);
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Init(params);
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}
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CoupledThreeStepSystem::~CoupledThreeStepSystem() {}
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void CoupledThreeStepSystem::Init(const std::vector<StepParameters>& params)
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{
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if(params.size() != 3 || params[0].rxnType != RxnType::Reaction || params[1].rxnType != RxnType::Decay ||
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params[2].rxnType != RxnType::Decay || params[0].Z.size() != 3 || params[0].A.size() != 3 || params[1].Z.size() != 2 ||
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params[1].A.size() != 2 || params[2].Z.size() != 2 || params[2].A.size() != 2)
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{
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m_isValid = false;
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std::cerr << "Invalid parameters at ThreeStepSystem::Init(), does not match ThreeStep signature!" << std::endl;
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return;
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}
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const StepParameters& step1Params = params[0];
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const StepParameters& step2Params = params[1];
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const StepParameters& step3Params = params[2];
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//Setup nuclei
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int zr = step1Params.Z[0] + step1Params.Z[1] - step1Params.Z[2];
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int ar = step1Params.A[0] + step1Params.A[1] - step1Params.A[2];
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if(zr != step2Params.Z[0] || ar != step2Params.A[0])
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{
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m_isValid = false;
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std::cerr << "Invalid parameters at ThreeStepSystem::Init(), step one and step two are not sequential! Step one recoil (Z,A): ("
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<< zr << "," << ar << ") Step two target (Z,A): (" << step2Params.Z[0] << "," << step2Params.A[0] << ")" <<std::endl;
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return;
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}
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int zb2 = step2Params.Z[0] - step2Params.Z[1];
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int ab2 = step2Params.A[0] - step2Params.A[1];
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if(zb2 != step3Params.Z[0] || ab2 != step3Params.A[0])
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{
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m_isValid = false;
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std::cerr << "Invalid parameters at ThreeStepSystem::Init(), step two and step three are not sequential! Step two heavy (Z,A): ("
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<< zb2 << "," << ab2 << ") Step three target (Z,A): (" << step3Params.Z[0] << "," << step3Params.A[0] << ")" <<std::endl;
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return;
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}
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int zb4 = step3Params.Z[0] - step3Params.Z[1];
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int ab4 = step3Params.A[0] - step3Params.A[1];
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m_nuclei[0] = CreateNucleus(step1Params.Z[0], step1Params.A[0]); //target
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m_nuclei[1] = CreateNucleus(step1Params.Z[1], step1Params.A[1]); //projectile
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m_nuclei[2] = CreateNucleus(step1Params.Z[2], step1Params.A[2]); //ejectile
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m_nuclei[3] = CreateNucleus(zr, ar); //residual
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m_nuclei[4] = CreateNucleus(step2Params.Z[1], step2Params.A[1]); //breakup1
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m_nuclei[5] = CreateNucleus(zb2, ab2); //breakup2
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m_nuclei[6] = CreateNucleus(step3Params.Z[1], step3Params.A[1]); //breakup3
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m_nuclei[7] = CreateNucleus(zb4, ab4); //breakup4
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m_step1.BindNuclei(&(m_nuclei[0]), &(m_nuclei[1]), &(m_nuclei[2]), &(m_nuclei[3]));
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m_step2.BindNuclei(&(m_nuclei[3]), nullptr, &(m_nuclei[4]), &(m_nuclei[5]));
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m_step3.BindNuclei(&(m_nuclei[5]), nullptr, &(m_nuclei[6]), &(m_nuclei[7]));
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SetSystemEquation();
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//Step one sampling parameters
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AddBeamDistribution(step1Params.meanBeamEnergy, step1Params.sigmaBeamEnergy);
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m_step1.SetEjectileThetaType(step1Params.thetaType);
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AddThetaRange(step1Params.thetaMin, step1Params.thetaMax);
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AddPhiRange(step1Params.phiMin, step1Params.phiMax);
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AddExcitationDistribution(step1Params.meanResidualEx, step1Params.sigmaResidualEx);
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//Step two sampling parameters
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AddPhiRange(step2Params.phiMin, step2Params.phiMax);
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AddDecayAngularDistribution(step2Params.angularDistFile);
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AddExcitationDistribution(step2Params.meanResidualEx, step2Params.sigmaResidualEx);
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//Step three sampling parameters
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AddPhiRange(step3Params.phiMin, step3Params.phiMax);
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AddDecayAngularDistribution(step3Params.angularDistFile);
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AddExcitationDistribution(step3Params.meanResidualEx, step3Params.sigmaResidualEx);
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}
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void CoupledThreeStepSystem::SetLayeredTarget(const LayeredTarget& target)
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{
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m_target = target;
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m_rxnLayer = m_target.FindLayerContaining(m_nuclei[0].Z, m_nuclei[0].A);
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if(m_rxnLayer != m_target.GetNumberOfLayers())
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{
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m_step1.SetLayeredTarget(&m_target);
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m_step2.SetLayeredTarget(&m_target);
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m_step3.SetLayeredTarget(&m_target);
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m_step1.SetRxnLayer(m_rxnLayer);
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m_step2.SetRxnLayer(m_rxnLayer);
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m_step3.SetRxnLayer(m_rxnLayer);
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m_isTargetSet = true;
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}
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else
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throw ReactionLayerException();
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}
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void CoupledThreeStepSystem::SetSystemEquation()
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{
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std::stringstream stream;
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stream << m_nuclei[0].isotopicSymbol << "("
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<< m_nuclei[1].isotopicSymbol << ", "
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<< m_nuclei[2].isotopicSymbol << ")"
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<< m_nuclei[3].isotopicSymbol << "->"
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<< m_nuclei[4].isotopicSymbol << "+"
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<< m_nuclei[5].isotopicSymbol << "->"
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<< m_nuclei[6].isotopicSymbol << "+"
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<< m_nuclei[7].isotopicSymbol;
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m_sysEquation = stream.str();
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}
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CoupledThreeStepParameters CoupledThreeStepSystem::SampleParameters()
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{
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CoupledThreeStepParameters params;
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std::mt19937& gen = RandomGenerator::GetInstance().GetGenerator();
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params.beamEnergy = m_beamDistributions[0](gen);
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params.rxnTheta = std::acos((m_thetaRanges[0])(gen));
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params.rxnPhi = m_phiRanges[0](gen);
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params.cosdecay1Theta = m_decayAngularDistributions[0].GetRandomCosTheta();
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params.cosRelativeAngle = m_decayAngularDistributions[1].GetRandomCosTheta();
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params.decay1Theta = std::acos(params.cosdecay1Theta);
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params.decay1Phi = m_phiRanges[1](gen);
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params.residEx = m_exDistributions[0](gen);
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params.decay1Ex = m_exDistributions[1](gen);
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params.decay2Ex = m_exDistributions[2](gen);
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params.rxnDepth = (m_rxnDepthDist(gen));
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return params;
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}
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//Called after running step2
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void CoupledThreeStepSystem::SampleCoupling(CoupledThreeStepParameters& params)
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{
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ROOT::Math::Boost boost(m_nuclei[5].vec4.BoostToCM());
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ROOT::Math::PxPyPzEVector a1Vec = (boost * m_nuclei[4].vec4);
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ROOT::Math::XYZVector a1PVec(a1Vec.Px(), a1Vec.Py(), a1Vec.Pz());
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ROOT::Math::PxPyPzEVector a2Vec;
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ROOT::Math::XYZVector a2PVec;
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ROOT::Math::RotationZ zRot;
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ROOT::Math::RotationY yRot;
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a1PVec *= 1.0/a1Vec.P();
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zRot.SetAngle(a1PVec.Phi());
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yRot.SetAngle(a1PVec.Theta());
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double relAngle = std::acos(params.cosRelativeAngle);
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ROOT::Math::XYZVector a1PVecAligned = yRot.Inverse() * (zRot.Inverse() * a1PVec);
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a2PVec.SetXYZ(
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std::sin(relAngle),
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0.0,
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std::cos(relAngle)
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);
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a2PVec = zRot * (yRot * a2PVec);
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params.decay2Theta = a2PVec.Theta();
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params.decay2Phi = a2PVec.Phi();
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}
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void CoupledThreeStepSystem::RunSystem()
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{
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CoupledThreeStepParameters params;
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do
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{
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params = SampleParameters();
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}
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while(!(m_step1.CheckReactionThreshold(params.beamEnergy, params.residEx)
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&& m_step2.CheckDecayThreshold(params.residEx, params.decay1Ex)
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&& m_step3.CheckDecayThreshold(params.decay1Ex, params.decay2Ex)));
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m_step1.SetReactionDepth(params.rxnDepth);
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m_step1.SetBeamKE(params.beamEnergy);
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m_step1.SetPolarRxnAngle(params.rxnTheta);
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m_step1.SetAzimRxnAngle(params.rxnPhi);
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m_step1.SetExcitation(params.residEx);
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m_step2.SetReactionDepth(params.rxnDepth);
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m_step2.SetPolarRxnAngle(params.decay1Theta);
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m_step2.SetAzimRxnAngle(params.decay1Phi);
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m_step2.SetExcitation(params.decay1Ex);
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m_step3.SetReactionDepth(params.rxnDepth);
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m_step3.SetExcitation(params.decay2Ex);
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m_step1.Calculate();
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if(params.cosdecay1Theta == -10)
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{
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m_nuclei[4].vec4.SetPxPyPzE(0., 0., 0., m_nuclei[4].groundStateMass);
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m_nuclei[5].vec4.SetPxPyPzE(0., 0., 0., m_nuclei[5].groundStateMass);
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m_nuclei[6].vec4.SetPxPyPzE(0., 0., 0., m_nuclei[6].groundStateMass);
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m_nuclei[7].vec4.SetPxPyPzE(0., 0., 0., m_nuclei[7].groundStateMass);
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return;
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}
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m_step2.Calculate();
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m_step3.SetResidualEnergyLoss(true);
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SampleCoupling(params); //must be called here as frame needs to be set
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m_step3.SetPolarRxnAngle(params.decay2Theta);
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m_step3.SetAzimRxnAngle(params.decay2Phi);
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m_step3.Calculate();
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}
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}
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46
src/Mask/CoupledThreeStepSystem.h
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46
src/Mask/CoupledThreeStepSystem.h
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#ifndef COUPLEDTHREESTEPSYSTEM_H
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#define COUPLEDTHREESTEPSYSTEM_H
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#include "ReactionSystem.h"
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#include "AngularDistribution.h"
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namespace Mask {
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struct CoupledThreeStepParameters
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{
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double beamEnergy = 0.;
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double rxnTheta = 0.;
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double rxnPhi = 0.;
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double cosdecay1Theta = 0.;
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double cosRelativeAngle = 0.;
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double decay1Theta = 0.;
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double decay1Phi = 0.;
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double decay2Theta = 0.;
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double decay2Phi = 0.;
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double residEx = 0.;
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double decay1Ex = 0.;
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double decay2Ex = 0.;
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double rxnDepth = 0.;
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};
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class CoupledThreeStepSystem : public ReactionSystem
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{
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public:
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CoupledThreeStepSystem(const std::vector<StepParameters>& params);
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~CoupledThreeStepSystem();
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virtual void SetLayeredTarget(const LayeredTarget& target) override;
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virtual void RunSystem() override;
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protected:
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void Init(const std::vector<StepParameters>& params);
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void SetSystemEquation() override;
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CoupledThreeStepParameters SampleParameters();
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void SampleCoupling(CoupledThreeStepParameters& params);
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Reaction m_step1, m_step2, m_step3;
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};
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}
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#endif
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@ -256,6 +256,27 @@ namespace Mask {
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}
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}
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}
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}
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bool Reaction::CheckReactionThreshold(double beamEnergy, double residEx)
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{
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double Q = m_target->groundStateMass + m_projectile->groundStateMass -
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(m_ejectile->groundStateMass + m_residual->groundStateMass + residEx);
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double Ethresh = -Q*(m_ejectile->groundStateMass+m_residual->groundStateMass) /
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(m_ejectile->groundStateMass + m_residual->groundStateMass - m_projectile->groundStateMass);
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||||||
|
if (beamEnergy < Ethresh)
|
||||||
|
return false;
|
||||||
|
else
|
||||||
|
return true;
|
||||||
|
}
|
||||||
|
|
||||||
|
bool Reaction::CheckDecayThreshold(double targetEx, double residEx)
|
||||||
|
{
|
||||||
|
double Q = m_target->groundStateMass + targetEx -
|
||||||
|
(m_ejectile->groundStateMass + m_residual->groundStateMass + residEx);
|
||||||
|
if ( Q < 0.0)
|
||||||
|
return false;
|
||||||
|
else
|
||||||
|
return true;
|
||||||
|
}
|
||||||
}
|
}
|
||||||
|
|
||||||
|
|
||||||
|
|
|
@ -42,6 +42,9 @@ namespace Mask {
|
||||||
void SetRxnLayer(std::size_t layer) { m_rxnLayer = layer; };
|
void SetRxnLayer(std::size_t layer) { m_rxnLayer = layer; };
|
||||||
void SetResidualEnergyLoss(bool isEloss) { m_isResidEloss = isEloss; };
|
void SetResidualEnergyLoss(bool isEloss) { m_isResidEloss = isEloss; };
|
||||||
|
|
||||||
|
bool CheckReactionThreshold(double beamEnergy, double residualEx);
|
||||||
|
bool CheckDecayThreshold(double targetEx, double residualEx);
|
||||||
|
|
||||||
bool IsDecay() const { return m_isDecay; };
|
bool IsDecay() const { return m_isDecay; };
|
||||||
|
|
||||||
std::size_t GetRxnLayer() const { return m_rxnLayer; };
|
std::size_t GetRxnLayer() const { return m_rxnLayer; };
|
||||||
|
|
|
@ -2,6 +2,11 @@
|
||||||
#include "RandomGenerator.h"
|
#include "RandomGenerator.h"
|
||||||
#include "KinematicsExceptions.h"
|
#include "KinematicsExceptions.h"
|
||||||
|
|
||||||
|
#include "Math/Boost.h"
|
||||||
|
#include "Math/Vector3D.h"
|
||||||
|
#include "Math/RotationZ.h"
|
||||||
|
#include "Math/RotationY.h"
|
||||||
|
|
||||||
namespace Mask {
|
namespace Mask {
|
||||||
|
|
||||||
ThreeStepSystem::ThreeStepSystem(const std::vector<StepParameters>& params) :
|
ThreeStepSystem::ThreeStepSystem(const std::vector<StepParameters>& params) :
|
||||||
|
@ -115,43 +120,57 @@ namespace Mask {
|
||||||
m_sysEquation = stream.str();
|
m_sysEquation = stream.str();
|
||||||
}
|
}
|
||||||
|
|
||||||
|
ThreeStepParameters ThreeStepSystem::SampleParameters()
|
||||||
|
{
|
||||||
|
ThreeStepParameters params;
|
||||||
|
std::mt19937& gen = RandomGenerator::GetInstance().GetGenerator();
|
||||||
|
params.beamEnergy = m_beamDistributions[0](gen);
|
||||||
|
params.rxnTheta = std::acos((m_thetaRanges[0])(gen));
|
||||||
|
params.rxnPhi = m_phiRanges[0](gen);
|
||||||
|
params.cosdecay1Theta = m_decayAngularDistributions[0].GetRandomCosTheta();
|
||||||
|
params.decay1Theta = std::acos(params.cosdecay1Theta);
|
||||||
|
params.decay1Phi = m_phiRanges[1](gen);
|
||||||
|
params.cosdecay2Theta = m_decayAngularDistributions[1].GetRandomCosTheta();
|
||||||
|
params.decay2Theta = std::acos(params.cosdecay2Theta);
|
||||||
|
params.decay2Phi = m_phiRanges[1](gen);
|
||||||
|
params.residEx = m_exDistributions[0](gen);
|
||||||
|
params.decay1Ex = m_exDistributions[1](gen);
|
||||||
|
params.decay2Ex = m_exDistributions[2](gen);
|
||||||
|
params.rxnDepth = (m_rxnDepthDist(gen));
|
||||||
|
return params;
|
||||||
|
}
|
||||||
|
|
||||||
void ThreeStepSystem::RunSystem()
|
void ThreeStepSystem::RunSystem()
|
||||||
{
|
{
|
||||||
//Sample parameters
|
ThreeStepParameters params;
|
||||||
std::mt19937& gen = RandomGenerator::GetInstance().GetGenerator();
|
do
|
||||||
double bke = m_beamDistributions[0](gen);
|
{
|
||||||
double rxnTheta = std::acos((m_thetaRanges[0])(gen));
|
params = SampleParameters();
|
||||||
double rxnPhi = m_phiRanges[0](gen);
|
}
|
||||||
double decay1costheta = m_decayAngularDistributions[0].GetRandomCosTheta();
|
while(!(m_step1.CheckReactionThreshold(params.beamEnergy, params.residEx)
|
||||||
double decay1Theta = std::acos(decay1costheta);
|
&& m_step2.CheckDecayThreshold(params.residEx, params.decay1Ex)
|
||||||
double decay1Phi = m_phiRanges[1](gen);
|
&& m_step3.CheckDecayThreshold(params.decay1Ex, params.decay2Ex)));
|
||||||
double decay2costheta = m_decayAngularDistributions[1].GetRandomCosTheta();
|
|
||||||
double decay2Theta = std::acos(decay2costheta);
|
|
||||||
double decay2Phi = m_phiRanges[2](gen);
|
|
||||||
double residEx = m_exDistributions[0](gen);
|
|
||||||
double decay1Ex = m_exDistributions[1](gen);
|
|
||||||
double decay2Ex = m_exDistributions[2](gen);
|
|
||||||
double rxnDepth = (m_rxnDepthDist(gen));
|
|
||||||
|
|
||||||
m_step1.SetReactionDepth(rxnDepth);
|
m_step1.SetReactionDepth(params.rxnDepth);
|
||||||
m_step1.SetBeamKE(bke);
|
m_step1.SetBeamKE(params.beamEnergy);
|
||||||
m_step1.SetPolarRxnAngle(rxnTheta);
|
m_step1.SetPolarRxnAngle(params.rxnTheta);
|
||||||
m_step1.SetAzimRxnAngle(rxnPhi);
|
m_step1.SetAzimRxnAngle(params.rxnPhi);
|
||||||
m_step1.SetExcitation(residEx);
|
m_step1.SetExcitation(params.residEx);
|
||||||
|
|
||||||
m_step2.SetReactionDepth(rxnDepth);
|
m_step2.SetReactionDepth(params.rxnDepth);
|
||||||
m_step2.SetPolarRxnAngle(decay1Theta);
|
m_step2.SetPolarRxnAngle(params.decay1Theta);
|
||||||
m_step2.SetAzimRxnAngle(decay1Phi);
|
m_step2.SetAzimRxnAngle(params.decay1Phi);
|
||||||
m_step2.SetExcitation(decay1Ex);
|
m_step2.SetExcitation(params.decay1Ex);
|
||||||
|
|
||||||
m_step3.SetReactionDepth(rxnDepth);
|
m_step3.SetReactionDepth(params.rxnDepth);
|
||||||
m_step3.SetPolarRxnAngle(decay2Theta);
|
m_step3.SetPolarRxnAngle(params.decay2Theta);
|
||||||
m_step3.SetAzimRxnAngle(decay2Phi);
|
m_step3.SetAzimRxnAngle(params.decay2Phi);
|
||||||
m_step3.SetExcitation(decay2Ex);
|
m_step3.SetResidualEnergyLoss(true);
|
||||||
|
m_step3.SetExcitation(params.decay2Ex);
|
||||||
|
|
||||||
m_step1.Calculate();
|
m_step1.Calculate();
|
||||||
|
|
||||||
if(decay1costheta == -10)
|
if(params.cosdecay1Theta == -10)
|
||||||
{
|
{
|
||||||
m_nuclei[4].vec4.SetPxPyPzE(0., 0., 0., m_nuclei[4].groundStateMass);
|
m_nuclei[4].vec4.SetPxPyPzE(0., 0., 0., m_nuclei[4].groundStateMass);
|
||||||
m_nuclei[5].vec4.SetPxPyPzE(0., 0., 0., m_nuclei[5].groundStateMass);
|
m_nuclei[5].vec4.SetPxPyPzE(0., 0., 0., m_nuclei[5].groundStateMass);
|
||||||
|
@ -161,15 +180,13 @@ namespace Mask {
|
||||||
}
|
}
|
||||||
m_step2.Calculate();
|
m_step2.Calculate();
|
||||||
|
|
||||||
if(decay2costheta == -10)
|
if(params.cosdecay2Theta == -10)
|
||||||
{
|
{
|
||||||
m_nuclei[6].vec4.SetPxPyPzE(0., 0., 0., m_nuclei[6].groundStateMass);
|
m_nuclei[6].vec4.SetPxPyPzE(0., 0., 0., m_nuclei[6].groundStateMass);
|
||||||
m_nuclei[7].vec4.SetPxPyPzE(0., 0., 0., m_nuclei[7].groundStateMass);
|
m_nuclei[7].vec4.SetPxPyPzE(0., 0., 0., m_nuclei[7].groundStateMass);
|
||||||
return;
|
return;
|
||||||
}
|
}
|
||||||
m_step3.SetResidualEnergyLoss(true);
|
|
||||||
m_step3.Calculate();
|
m_step3.Calculate();
|
||||||
|
|
||||||
}
|
}
|
||||||
|
|
||||||
}
|
}
|
|
@ -6,6 +6,23 @@
|
||||||
|
|
||||||
namespace Mask {
|
namespace Mask {
|
||||||
|
|
||||||
|
struct ThreeStepParameters
|
||||||
|
{
|
||||||
|
double beamEnergy = 0.;
|
||||||
|
double rxnTheta = 0.;
|
||||||
|
double rxnPhi = 0.;
|
||||||
|
double cosdecay1Theta = 0.;
|
||||||
|
double cosdecay2Theta = 0.;
|
||||||
|
double decay1Theta = 0.;
|
||||||
|
double decay1Phi = 0.;
|
||||||
|
double decay2Theta = 0.;
|
||||||
|
double decay2Phi = 0.;
|
||||||
|
double residEx = 0.;
|
||||||
|
double decay1Ex = 0.;
|
||||||
|
double decay2Ex = 0.;
|
||||||
|
double rxnDepth = 0.;
|
||||||
|
};
|
||||||
|
|
||||||
class ThreeStepSystem : public ReactionSystem
|
class ThreeStepSystem : public ReactionSystem
|
||||||
{
|
{
|
||||||
public:
|
public:
|
||||||
|
@ -18,6 +35,7 @@ namespace Mask {
|
||||||
protected:
|
protected:
|
||||||
void Init(const std::vector<StepParameters>& params);
|
void Init(const std::vector<StepParameters>& params);
|
||||||
void SetSystemEquation() override;
|
void SetSystemEquation() override;
|
||||||
|
ThreeStepParameters SampleParameters();
|
||||||
|
|
||||||
Reaction m_step1, m_step2, m_step3;
|
Reaction m_step1, m_step2, m_step3;
|
||||||
|
|
||||||
|
|
|
@ -93,34 +93,58 @@ namespace Mask {
|
||||||
m_sysEquation = stream.str();
|
m_sysEquation = stream.str();
|
||||||
}
|
}
|
||||||
|
|
||||||
|
TwoStepParameters TwoStepSystem::SampleParameters()
|
||||||
|
{
|
||||||
|
TwoStepParameters params;
|
||||||
|
std::mt19937& gen = RandomGenerator::GetInstance().GetGenerator();
|
||||||
|
params.beamEnergy = (m_beamDistributions[0])(gen);
|
||||||
|
params.rxnTheta = std::acos((m_thetaRanges[0])(gen));
|
||||||
|
params.rxnPhi = (m_phiRanges[0])(gen);
|
||||||
|
params.cosdecay1Theta = m_decayAngularDistributions[0].GetRandomCosTheta();
|
||||||
|
params.decay1Theta = std::acos(params.cosdecay1Theta);
|
||||||
|
params.decay1Phi = m_phiRanges[1](gen);
|
||||||
|
params.residEx = (m_exDistributions[0])(gen);
|
||||||
|
params.decay2Ex = m_exDistributions[1](gen);
|
||||||
|
params.rxnDepth = (m_rxnDepthDist(gen));
|
||||||
|
return params;
|
||||||
|
}
|
||||||
|
|
||||||
void TwoStepSystem::RunSystem()
|
void TwoStepSystem::RunSystem()
|
||||||
{
|
{
|
||||||
//Sample parameters
|
//Sample parameters
|
||||||
std::mt19937& gen = RandomGenerator::GetInstance().GetGenerator();
|
// std::mt19937& gen = RandomGenerator::GetInstance().GetGenerator();
|
||||||
double bke = (m_beamDistributions[0])(gen);
|
// double bke = (m_beamDistributions[0])(gen);
|
||||||
double rxnTheta = std::acos((m_thetaRanges[0])(gen));
|
// double rxnTheta = std::acos((m_thetaRanges[0])(gen));
|
||||||
double rxnPhi = (m_phiRanges[0])(gen);
|
// double rxnPhi = (m_phiRanges[0])(gen);
|
||||||
double decay1costheta = m_decayAngularDistributions[0].GetRandomCosTheta();
|
// double decay1costheta = m_decayAngularDistributions[0].GetRandomCosTheta();
|
||||||
double decay1Theta = std::acos(decay1costheta);
|
// double decay1Theta = std::acos(decay1costheta);
|
||||||
double decay1Phi = m_phiRanges[1](gen);
|
// double decay1Phi = m_phiRanges[1](gen);
|
||||||
double residEx = (m_exDistributions[0])(gen);
|
// double residEx = (m_exDistributions[0])(gen);
|
||||||
double decay2Ex = m_exDistributions[1](gen);
|
// double decay2Ex = m_exDistributions[1](gen);
|
||||||
double rxnDepth = (m_rxnDepthDist(gen));
|
// double rxnDepth = (m_rxnDepthDist(gen));
|
||||||
|
|
||||||
m_step1.SetReactionDepth(rxnDepth);
|
TwoStepParameters params;
|
||||||
m_step1.SetBeamKE(bke);
|
do
|
||||||
m_step1.SetPolarRxnAngle(rxnTheta);
|
{
|
||||||
m_step1.SetAzimRxnAngle(rxnPhi);
|
params = SampleParameters();
|
||||||
m_step1.SetExcitation(residEx);
|
}
|
||||||
|
while(!(m_step1.CheckReactionThreshold(params.beamEnergy, params.residEx)
|
||||||
|
&& m_step2.CheckDecayThreshold(params.residEx, params.decay2Ex)));
|
||||||
|
|
||||||
m_step2.SetReactionDepth(rxnDepth);
|
m_step1.SetReactionDepth(params.rxnDepth);
|
||||||
m_step2.SetPolarRxnAngle(decay1Theta);
|
m_step1.SetBeamKE(params.beamEnergy);
|
||||||
m_step2.SetAzimRxnAngle(decay1Phi);
|
m_step1.SetPolarRxnAngle(params.rxnTheta);
|
||||||
m_step2.SetExcitation(decay2Ex);
|
m_step1.SetAzimRxnAngle(params.rxnPhi);
|
||||||
|
m_step1.SetExcitation(params.residEx);
|
||||||
|
|
||||||
|
m_step2.SetReactionDepth(params.rxnDepth);
|
||||||
|
m_step2.SetPolarRxnAngle(params.decay1Theta);
|
||||||
|
m_step2.SetAzimRxnAngle(params.decay1Phi);
|
||||||
|
m_step2.SetExcitation(params.decay2Ex);
|
||||||
|
|
||||||
m_step1.Calculate();
|
m_step1.Calculate();
|
||||||
|
|
||||||
if(decay1costheta == -10)
|
if(params.cosdecay1Theta == -10)
|
||||||
{
|
{
|
||||||
m_nuclei[4].vec4.SetPxPyPzE(0., 0., 0., m_nuclei[4].groundStateMass);
|
m_nuclei[4].vec4.SetPxPyPzE(0., 0., 0., m_nuclei[4].groundStateMass);
|
||||||
m_nuclei[5].vec4.SetPxPyPzE(0., 0., 0., m_nuclei[5].groundStateMass);
|
m_nuclei[5].vec4.SetPxPyPzE(0., 0., 0., m_nuclei[5].groundStateMass);
|
||||||
|
|
|
@ -6,6 +6,19 @@
|
||||||
|
|
||||||
namespace Mask {
|
namespace Mask {
|
||||||
|
|
||||||
|
struct TwoStepParameters
|
||||||
|
{
|
||||||
|
double beamEnergy = 0.;
|
||||||
|
double rxnTheta = 0.;
|
||||||
|
double rxnPhi = 0.;
|
||||||
|
double cosdecay1Theta = 0.;
|
||||||
|
double decay1Theta = 0.;
|
||||||
|
double decay1Phi = 0.;
|
||||||
|
double residEx = 0.;
|
||||||
|
double decay2Ex = 0.;
|
||||||
|
double rxnDepth = 0.;
|
||||||
|
};
|
||||||
|
|
||||||
class TwoStepSystem : public ReactionSystem
|
class TwoStepSystem : public ReactionSystem
|
||||||
{
|
{
|
||||||
public:
|
public:
|
||||||
|
@ -18,6 +31,7 @@ namespace Mask {
|
||||||
private:
|
private:
|
||||||
void Init(const std::vector<StepParameters>& params);
|
void Init(const std::vector<StepParameters>& params);
|
||||||
void SetSystemEquation() override;
|
void SetSystemEquation() override;
|
||||||
|
TwoStepParameters SampleParameters();
|
||||||
|
|
||||||
Reaction m_step1, m_step2;
|
Reaction m_step1, m_step2;
|
||||||
};
|
};
|
||||||
|
|
|
@ -1,7 +1,8 @@
|
||||||
#include "RootPlotter.h"
|
#include "RootPlotter.h"
|
||||||
#include <TFile.h>
|
#include <TFile.h>
|
||||||
#include <TTree.h>
|
#include <TTree.h>
|
||||||
#include <TVector3.h>
|
#include <Math/Vector3D.h>
|
||||||
|
#include "Math/Boost.h"
|
||||||
|
|
||||||
#include <iostream>
|
#include <iostream>
|
||||||
|
|
||||||
|
@ -10,7 +11,8 @@ static double FullPhi(double phi)
|
||||||
return phi < 0.0 ? 2.0*M_PI + phi : phi;
|
return phi < 0.0 ? 2.0*M_PI + phi : phi;
|
||||||
}
|
}
|
||||||
|
|
||||||
RootPlotter::RootPlotter()
|
RootPlotter::RootPlotter() :
|
||||||
|
m_target({5},{9},{1}, 74.0)
|
||||||
{
|
{
|
||||||
TH1::AddDirectory(kFALSE);
|
TH1::AddDirectory(kFALSE);
|
||||||
}
|
}
|
||||||
|
@ -42,10 +44,16 @@ void RootPlotter::Run(const std::string& inputname, const std::string& outputnam
|
||||||
std::cout<<"\rPercent of data processed: "<<flushCount*flushFrac*100<<"%"<<std::flush;
|
std::cout<<"\rPercent of data processed: "<<flushCount*flushFrac*100<<"%"<<std::flush;
|
||||||
}
|
}
|
||||||
tree->GetEntry(i);
|
tree->GetEntry(i);
|
||||||
for(Mask::Nucleus& nuc : *(dataHandle))
|
// for(Mask::Nucleus& nuc : *(dataHandle))
|
||||||
|
// {
|
||||||
|
// FillData(nuc);
|
||||||
|
// }
|
||||||
|
for(int i=0; i<dataHandle->size(); i++)
|
||||||
{
|
{
|
||||||
FillData(nuc);
|
FillData(dataHandle->at(i), i);
|
||||||
}
|
}
|
||||||
|
//Don't leave this in!
|
||||||
|
//Correlations(*dataHandle);
|
||||||
}
|
}
|
||||||
std::cout<<std::endl;
|
std::cout<<std::endl;
|
||||||
input->Close();
|
input->Close();
|
||||||
|
@ -57,34 +65,35 @@ void RootPlotter::Run(const std::string& inputname, const std::string& outputnam
|
||||||
output->Close();
|
output->Close();
|
||||||
}
|
}
|
||||||
|
|
||||||
void RootPlotter::FillData(const Mask::Nucleus& nuc)
|
void RootPlotter::FillData(const Mask::Nucleus& nuc, int i)
|
||||||
{
|
{
|
||||||
std::string mod = "detected";
|
std::string mod = "_detected";
|
||||||
|
std::string num = "_" + std::to_string(i);
|
||||||
|
|
||||||
std::string sym = nuc.isotopicSymbol;
|
std::string sym = nuc.isotopicSymbol;
|
||||||
std::string ke_vs_th_name = sym + "_ke_vs_theta";
|
std::string ke_vs_th_name = sym + num + "_ke_vs_theta";
|
||||||
std::string ke_vs_th_title = ke_vs_th_name + ";#theta_{lab} (degrees);Kinetic Energy (MeV)";
|
std::string ke_vs_th_title = ke_vs_th_name + ";#theta_{lab} (degrees);Kinetic Energy (MeV)";
|
||||||
std::string ke_vs_th_name_det = sym + mod + "_ke_vs_theta";
|
std::string ke_vs_th_name_det = sym + num + mod + "_ke_vs_theta";
|
||||||
std::string ke_vs_th_title_det = ke_vs_th_name + ";#theta_{lab} (degrees);Kinetic Energy (MeV)";
|
std::string ke_vs_th_title_det = ke_vs_th_name + ";#theta_{lab} (degrees);Kinetic Energy (MeV)";
|
||||||
std::string ke_vs_ph_name = sym + "_ke_vs_phi";
|
std::string ke_vs_ph_name = sym + num + "_ke_vs_phi";
|
||||||
std::string ke_vs_ph_title = ke_vs_ph_name + ";#phi_{lab} (degrees);Kinetic Energy (MeV)";
|
std::string ke_vs_ph_title = ke_vs_ph_name + ";#phi_{lab} (degrees);Kinetic Energy (MeV)";
|
||||||
std::string ke_vs_ph_name_det = sym + mod + "_ke_vs_phi";
|
std::string ke_vs_ph_name_det = sym + num + mod + "_ke_vs_phi";
|
||||||
std::string ke_vs_ph_title_det = ke_vs_ph_name + ";#phi_{lab} (degrees);Kinetic Energy (MeV)";
|
std::string ke_vs_ph_title_det = ke_vs_ph_name + ";#phi_{lab} (degrees);Kinetic Energy (MeV)";
|
||||||
std::string th_vs_ph_name = sym + "_theta_vs_phi";
|
std::string th_vs_ph_name = sym + num + "_theta_vs_phi";
|
||||||
std::string th_vs_ph_title = th_vs_ph_name + ";#theta_{lab};#phi_{lab}";
|
std::string th_vs_ph_title = th_vs_ph_name + ";#theta_{lab};#phi_{lab}";
|
||||||
std::string th_vs_ph_name_det = sym + mod + "_theta_vs_phi";
|
std::string th_vs_ph_name_det = sym + num + mod + "_theta_vs_phi";
|
||||||
std::string th_vs_ph_title_det = th_vs_ph_name + ";#theta_{lab};#phi_{lab}";
|
std::string th_vs_ph_title_det = th_vs_ph_name + ";#theta_{lab};#phi_{lab}";
|
||||||
std::string ex_name = sym + "_ex";
|
std::string ex_name = sym + num + "_ex";
|
||||||
std::string ex_title = ex_name + ";E_{ex} (MeV);counts";
|
std::string ex_title = ex_name + ";E_{ex} (MeV);counts";
|
||||||
std::string ex_name_det = sym + mod + "_ex";
|
std::string ex_name_det = sym + num + mod + "_ex";
|
||||||
std::string ex_title_det = ex_name + ";E_{ex} (MeV);counts";
|
std::string ex_title_det = ex_name + ";E_{ex} (MeV);counts";
|
||||||
std::string angdist_name = sym +"_angDist";
|
std::string angdist_name = sym + num + "_angDist";
|
||||||
std::string angdist_title = angdist_name+";cos#right(#theta_{CM}#left);counts";
|
std::string angdist_title = angdist_name+";cos#right(#theta_{CM}#left);counts";
|
||||||
std::string angdist_name_det = sym + mod +"_angDist";
|
std::string angdist_name_det = sym + num + mod +"_angDist";
|
||||||
std::string angdist_title_det = angdist_name+";cos#right(#theta_{CM}#left);counts";
|
std::string angdist_title_det = angdist_name+";cos#right(#theta_{CM}#left);counts";
|
||||||
std::string hist_ke_th_name = sym + "_hist_ke_vs_theta";
|
std::string hist_ke_th_name = sym + num + "_hist_ke_vs_theta";
|
||||||
std::string hist_ke_th_title = hist_ke_th_name + ";#theta_{lab};Kinetic Energy (MeV)";
|
std::string hist_ke_th_title = hist_ke_th_name + ";#theta_{lab};Kinetic Energy (MeV)";
|
||||||
std::string hist_ke_th_name_det = sym + mod + "_hist_ke_vs_theta";
|
std::string hist_ke_th_name_det = sym + num + mod + "_hist_ke_vs_theta";
|
||||||
std::string hist_ke_th_title_det = hist_ke_th_name + ";#theta_{lab};Kinetic Energy (MeV)";
|
std::string hist_ke_th_title_det = hist_ke_th_name + ";#theta_{lab};Kinetic Energy (MeV)";
|
||||||
|
|
||||||
MyFill(ke_vs_th_name, ke_vs_th_title, nuc.vec4.Theta()*s_rad2deg, nuc.GetKE(), 2);
|
MyFill(ke_vs_th_name, ke_vs_th_title, nuc.vec4.Theta()*s_rad2deg, nuc.GetKE(), 2);
|
||||||
|
@ -105,6 +114,93 @@ void RootPlotter::FillData(const Mask::Nucleus& nuc)
|
||||||
|
|
||||||
}
|
}
|
||||||
|
|
||||||
|
//Correlation analysis for coupled step reactions, will need to be customized
|
||||||
|
//for a given reaction. By default it is off.
|
||||||
|
void RootPlotter::Correlations(const std::vector<Mask::Nucleus>& event)
|
||||||
|
{
|
||||||
|
static constexpr double lowerBoundEx = -2.7;
|
||||||
|
static constexpr double upperBoundEx = 2.7;
|
||||||
|
static constexpr double targetDepth = 0.5;
|
||||||
|
const Mask::Nucleus& secondary = event[6];
|
||||||
|
const Mask::Nucleus& primary = event[4];
|
||||||
|
const Mask::Nucleus& parent = event[3];
|
||||||
|
const Mask::Nucleus& li = event[5];
|
||||||
|
if(secondary.vec4.P() == 0.0 || primary.vec4.P() == 0.0)
|
||||||
|
{
|
||||||
|
return;
|
||||||
|
}
|
||||||
|
ROOT::Math::Boost boostParent(parent.vec4.BoostToCM());
|
||||||
|
ROOT::Math::Boost boostIntermediate(li.vec4.BoostToCM());
|
||||||
|
ROOT::Math::PxPyPzEVector a2Vec = (secondary.vec4);
|
||||||
|
ROOT::Math::PxPyPzEVector a1Vec = (primary.vec4);
|
||||||
|
|
||||||
|
double a2KE = secondary.GetKE() + m_target.GetReverseEnergyLossFractionalDepth(secondary.Z, secondary.A, secondary.GetKE(), a2Vec.Theta(), targetDepth);
|
||||||
|
double a2P = std::sqrt(a2KE * (a2KE + 2.0 * secondary.groundStateMass));
|
||||||
|
a2Vec.SetPxPyPzE(
|
||||||
|
a2P * std::sin(a2Vec.Theta()) * std::cos(a2Vec.Phi()),
|
||||||
|
a2P * std::sin(a2Vec.Theta()) * std::sin(a2Vec.Phi()),
|
||||||
|
a2P * std::cos(a2Vec.Theta()),
|
||||||
|
a2KE + secondary.groundStateMass
|
||||||
|
);
|
||||||
|
|
||||||
|
double a1KE = primary.GetKE() + m_target.GetReverseEnergyLossFractionalDepth(primary.Z, primary.A, primary.GetKE(), a1Vec.Theta(), targetDepth);
|
||||||
|
double a1P = std::sqrt(a1KE * (a1KE + 2.0 * primary.groundStateMass));
|
||||||
|
a1Vec.SetPxPyPzE(
|
||||||
|
a1P * std::sin(a1Vec.Theta()) * std::cos(a1Vec.Phi()),
|
||||||
|
a1P * std::sin(a1Vec.Theta()) * std::sin(a1Vec.Phi()),
|
||||||
|
a1P * std::cos(a1Vec.Theta()),
|
||||||
|
a1KE + primary.groundStateMass
|
||||||
|
);
|
||||||
|
|
||||||
|
ROOT::Math::XYZVector a1PVec;
|
||||||
|
ROOT::Math::XYZVector a2PVec;
|
||||||
|
|
||||||
|
ROOT::Math::PxPyPzEVector boostedIntA1Vec = boostIntermediate * a1Vec;
|
||||||
|
ROOT::Math::PxPyPzEVector boostedIntA2Vec = boostIntermediate * a2Vec;
|
||||||
|
ROOT::Math::PxPyPzEVector boostedParA2Vec = boostParent * a2Vec;
|
||||||
|
a1PVec.SetXYZ(boostedIntA1Vec.Px(), boostedIntA1Vec.Py(), boostedIntA1Vec.Pz());
|
||||||
|
a2PVec.SetXYZ(boostedIntA2Vec.Px(), boostedIntA2Vec.Py(), boostedIntA2Vec.Pz());
|
||||||
|
double relCosThetaCM = a1PVec.Dot(a2PVec) / (a1PVec.R() * a2PVec.R());
|
||||||
|
|
||||||
|
ROOT::Math::PxPyPzEVector badLi = parent.vec4 - a2Vec;
|
||||||
|
double secondaryExcitation = badLi.M() - li.groundStateMass;
|
||||||
|
|
||||||
|
MyFill("seoncdaryEx","secondaryEx",1000,-5.0,5.0,secondaryExcitation);
|
||||||
|
MyFill("primaryEx","primaryEx",1000,-5.0,5.0,li.GetExcitationEnergy());
|
||||||
|
MyFill("relativeDist_full","relativeDist_full",20,-1.0,1.0, relCosThetaCM);
|
||||||
|
MyFill("primaryDist_full","primaryDist_full",20,-1.0,1.0,std::cos(primary.thetaCM));
|
||||||
|
MyFill("seondaryDist_full","seconaryDist_full",20,-1.0,1.0,std::cos(boostedParA2Vec.Theta()));
|
||||||
|
MyFill("secondaryDist_fullOwn","seondaryDist_fullOwn",20,-1.0,1.0,std::cos(secondary.thetaCM));
|
||||||
|
|
||||||
|
bool isPrimary = false;
|
||||||
|
bool isSecondary = false;
|
||||||
|
if(primary.isDetected)
|
||||||
|
{
|
||||||
|
MyFill("primaryExMatched","primaryExMatched",1000,-5.0,5.0,li.GetExcitationEnergy());
|
||||||
|
MyFill("primaryDist","primaryDist",20,-1.0,1.0,std::cos(primary.thetaCM));
|
||||||
|
isPrimary = true;
|
||||||
|
}
|
||||||
|
if( secondary.isDetected && secondaryExcitation > lowerBoundEx && secondaryExcitation < upperBoundEx )
|
||||||
|
{
|
||||||
|
MyFill("secondaryDist","secondaryDist",20,-1.0,1.0,std::cos(boostedParA2Vec.Theta()));
|
||||||
|
MyFill("secondaryExMatched","secondaryExMatched",1000,-5.0,5.0,secondaryExcitation);
|
||||||
|
isSecondary = true;
|
||||||
|
}
|
||||||
|
|
||||||
|
if(isSecondary && isPrimary)
|
||||||
|
{
|
||||||
|
return;
|
||||||
|
}
|
||||||
|
else if (isSecondary)
|
||||||
|
{
|
||||||
|
MyFill("completeDist","completeDist",20,-1.0,1.0,std::cos(boostedParA2Vec.Theta()));
|
||||||
|
}
|
||||||
|
else if (isPrimary)
|
||||||
|
{
|
||||||
|
MyFill("completeDist","completeDist",20,-1.0,1.0,std::cos(primary.thetaCM));
|
||||||
|
}
|
||||||
|
}
|
||||||
|
|
||||||
void RootPlotter::MyFill(const std::string& name, const std::string& title, int bins, float min, float max, double val)
|
void RootPlotter::MyFill(const std::string& name, const std::string& title, int bins, float min, float max, double val)
|
||||||
{
|
{
|
||||||
auto iter = m_map.find(name);
|
auto iter = m_map.find(name);
|
||||||
|
|
|
@ -6,6 +6,7 @@
|
||||||
#include <unordered_map>
|
#include <unordered_map>
|
||||||
|
|
||||||
#include "Nucleus.h"
|
#include "Nucleus.h"
|
||||||
|
#include "Target.h"
|
||||||
|
|
||||||
#include <TH1.h>
|
#include <TH1.h>
|
||||||
#include <TH2.h>
|
#include <TH2.h>
|
||||||
|
@ -20,7 +21,8 @@ public:
|
||||||
void Run(const std::string& inputname, const std::string& outputname);
|
void Run(const std::string& inputname, const std::string& outputname);
|
||||||
|
|
||||||
private:
|
private:
|
||||||
void FillData(const Mask::Nucleus& nuc);
|
void FillData(const Mask::Nucleus& nuc, int i);
|
||||||
|
void Correlations(const std::vector<Mask::Nucleus>& event);
|
||||||
void MyFill(const std::string& name, const std::string& title, int bins, float min, float max, double val);
|
void MyFill(const std::string& name, const std::string& title, int bins, float min, float max, double val);
|
||||||
void MyFill(const std::string& name, const std::string& title, int binsx, float minx, float maxx, int binsy, float miny, float maxy,
|
void MyFill(const std::string& name, const std::string& title, int binsx, float minx, float maxx, int binsy, float miny, float maxy,
|
||||||
double valx, double valy);
|
double valx, double valy);
|
||||||
|
@ -29,6 +31,7 @@ private:
|
||||||
std::unordered_map<std::string, std::shared_ptr<TObject>> m_map;
|
std::unordered_map<std::string, std::shared_ptr<TObject>> m_map;
|
||||||
|
|
||||||
static constexpr double s_rad2deg = 180.0/M_PI;
|
static constexpr double s_rad2deg = 180.0/M_PI;
|
||||||
|
Mask::Target m_target;
|
||||||
};
|
};
|
||||||
|
|
||||||
#endif
|
#endif
|
Loading…
Reference in New Issue
Block a user