#include "TRandom.h" // ROOT random number generators, gRandom #include "TFile.h" // ROOT file I/O #include "TTree.h" // ROOT tree storage #include "TH1.h" // 1D histograms #include "TH2.h" // 2D histograms #include "TStyle.h" // ROOT plotting style controls #include "TCanvas.h" // ROOT canvas drawing #include "TBenchmark.h" // timing measurement #include "TGraph.h" // for energy loss interpolation #include #include "TApplication.h" // ROOT app loop #include "ClassTransfer.h" // Reaction kinematics and MC event generation #include "ClassAnasen.h" // ANASEN detector model classes (SX3, PW, etc.) //======== Generate light particle based on reaction // calculate real and reconstructed tracks and Q-value uncertainty // Function to load energy loss table from file TGraph* LoadELoss(const char* filename) { TGraph* g = new TGraph(filename, "%lg %lg"); return g; } int main(int argc, char **argv){ printf("=========================================\n"); printf("=== ANASEN Monte Carlo ===\n"); printf("=========================================\n"); // number of events can be overridden from command line int numEvent = 1000000; if( argc >= 2 ) numEvent = atoi(argv[1]); // load energy loss tables (assume units: E in MeV, dE/dx in MeV/(mg/cm²), density in mg/cm³) TGraph* elossLight = LoadELoss("../ELoss/Eloss_alpha"); // for light particle (alpha) TGraph* elossHeavy = LoadELoss("../ELoss/Eloss_p"); // for heavy particle (proton) double density = 2.7; // example for aluminum target, adjust as needed // Reaction setup: projectile + target configuration, energy, and product IDs TransferReaction transfer; transfer.SetA(24,12, 0); // e.g., 24Mg (Z=12) with 0 excitation transfer.SetIncidentEnergyAngle(10, 0, 0); // 10 MeV beam, 0 polar and azimuthal angle transfer.Seta( 4, 2); // identify reaction product a in internal indexing transfer.Setb( 1, 1); // identify reaction product b // TODO add alpha source or alternative reaction channel selection // Excited state lists (target and projectile/excited products) std::vector ExAList = {0}; std::vector ExList = {0, 1, 2}; // define vertex position uniform distribution ranges (mm) double vertexXRange[2] = { -5, 5}; // mm double vertexYRange[2] = { -5, 5}; double vertexZRange[2] = { -100, 100}; // detector resolution / uncertainty parameters double sigmaSX3_W = -1; // mm, if < 0 use mid-point (no spread in SX3 horizontal dimension) double sigmaSX3_L = 3; // mm, vertical spread for SX3 double sigmaPW_A = 0; // normalized anode uncertainty term (0-1) double sigmaPW_C = 0; // normalized cathode uncertainty term (0-1) // status printout printf("------------ Vertex :\n"); printf("X : %7.2f - %7.2f mm\n", vertexXRange[0], vertexXRange[1]); printf("Y : %7.2f - %7.2f mm\n", vertexYRange[0], vertexYRange[1]); printf("Z : %7.2f - %7.2f mm\n", vertexZRange[0], vertexZRange[1]); printf("------------ Uncertainty :\n"); printf(" SX3 horizontal : %.1f\n", sigmaSX3_W); printf(" SX3 vertical : %.1f\n", sigmaSX3_L); printf(" Anode : %.1f mm\n", sigmaPW_A); printf(" Cathode : %.1f mm\n", sigmaPW_C); printf(" num_eve : %d \n",numEvent); // calculates energy/momentum/kinematics constants for transfer reaction transfer.CalReactionConstant(); int nExA = ExAList.size(); int nEx = ExList.size(); // optional visualization control: pass "vis" as 3rd arg bool enableVis = (argc >= 3 && strcmp(argv[2], "vis") == 0); TApplication *app = nullptr; if(enableVis){ app = new TApplication("anasenVis", &argc, argv); } // create detector representation in memory ANASEN * anasen = new ANASEN(); // top-level detector object SX3 * sx3 = anasen->GetSX3(); // silicon array part PW * pw = anasen->GetPW(); // proportional wire chamber part // output file + tree TString saveFileName = "SimAnasen1.root"; printf("\e[32m#################################### building Tree in %s\e[0m\n", saveFileName.Data()); TFile * saveFile = new TFile(saveFileName, "recreate"); TTree * tree = new TTree("tree", "tree"); TTree* tree2 = tree->CloneTree(0); // for 2D histograms or alternative data structure if needed // beam and CM variables saved in tree double KEA; tree->Branch("beamKEA", &KEA, "beamKEA/D"); double thetaCM, phiCM; tree->Branch("thetaCM", &thetaCM, "thetaCM/D"); tree->Branch("phiCM", &phiCM, "phiCM/D"); // outgoing particles in lab frame (light/heavy) double thetab, phib, Tb; double thetaB, phiB, TB; tree->Branch("thetab", &thetab, "thetab/D"); tree->Branch("phib", &phib, "phib/D"); tree->Branch("Tb", &Tb, "Tb/D"); tree->Branch("thetaB", &thetaB, "thetaB/D"); tree->Branch("phiB", &phiB, "phiB/D"); tree->Branch("TB", &TB, "TB/D"); // excitation state identifiers int ExAID; double ExA; tree->Branch("ExAID", &ExAID, "ExAID/I"); tree->Branch("ExA", &ExA, "ExA/D"); int ExID; double Ex; tree->Branch("ExID", &ExID, "ExID/I"); tree->Branch("Ex", &Ex, "Ex/D"); // true vertex position in target volume double vertexX, vertexY, vertexZ; tree->Branch("vX", &vertexX, "VertexX/D"); tree->Branch("vY", &vertexY, "VertexY/D"); tree->Branch("vZ", &vertexZ, "VertexZ/D"); // reconstructed SX3 hit position double sx3X, sx3Y, sx3Z; tree->Branch("sx3X", &sx3X, "sx3X/D"); tree->Branch("sx3Y", &sx3Y, "sx3Y/D"); tree->Branch("sx3Z", &sx3Z, "sx3Z/D"); // PW nearest and next nearest wires int anodeID[2], cathodeID[2]; tree->Branch("aID", anodeID, "anodeID/I"); tree->Branch("cID", cathodeID, "cathodeID/I"); // distances to nearest wires double anodeDist[2], cathodeDist[2]; tree->Branch("aDist", anodeDist, "anodeDist/D"); tree->Branch("cDist", cathodeDist, "cathodeDist/D"); // SX3 channel assignment and Z fraction (depth) information int sx3ID, sx3Up, sx3Dn, sx3Bk; double sx3ZFrac; tree->Branch("sx3ID", &sx3ID, "sx3ID/I"); tree->Branch("sx3Up", &sx3Up, "sx3Up/I"); tree->Branch("sx3Dn", &sx3Dn, "sx3Dn/I"); tree->Branch("sx3Bk", &sx3Bk, "sx3Bk/I"); tree->Branch("sx3ZFrac", &sx3ZFrac, "sx3ZFrac/D"); // reconstructed angles from PW track fit, method 1 and 2 double reTheta, rePhi; tree->Branch("reTheta", &reTheta, "reconstucted_theta/D"); tree->Branch("rePhi", &rePhi, "reconstucted_phi/D"); double reTheta1, rePhi1; tree->Branch("reTheta1", &reTheta1, "reconstucted_theta1/D"); tree->Branch("rePhi1", &rePhi1, "reconstucted_phi1/D"); // reconstructed vertex Z from PW fit double z0; tree->Branch("z0", &z0, "reconstucted_Z/D"); //========timer TBenchmark clock; bool shown ; clock.Reset(); clock.Start("timer"); shown = false; //================================= Calculate event loop for( int i = 0; i < numEvent ; i++){ // randomly sample target/projectile excitations ExAID = gRandom->Integer(nExA); ExA = ExAList[ExAID]; transfer.SetExA(ExA); ExID = gRandom->Integer(nEx); Ex = ExList[ExID]; transfer.SetExB(Ex); // recalc kinematic constants for chosen states transfer.CalReactionConstant(); // isotropic CM direction thetaCM = TMath::ACos(2 * gRandom->Rndm() - 1) ; phiCM = (gRandom->Rndm() - 0.5) * TMath::TwoPi(); //==== Calculate reaction kinematics in lab frame TLorentzVector * output = transfer.Event(thetaCM, phiCM); // returns array of outputs TLorentzVector Pb = output[2]; // light particle or product A TLorentzVector PB = output[3]; // heavy particle or product B thetab = Pb.Theta() * TMath::RadToDeg(); thetaB = PB.Theta() * TMath::RadToDeg(); Tb = Pb.E() - Pb.M(); TB = PB.E() - PB.M(); phib = Pb.Phi() * TMath::RadToDeg(); phiB = PB.Phi() * TMath::RadToDeg(); // vertex position in target volume vertexX = (vertexXRange[1]- vertexXRange[0])*gRandom->Rndm() + vertexXRange[0]; vertexY = (vertexYRange[1]- vertexYRange[0])*gRandom->Rndm() + vertexYRange[0]; vertexZ = (vertexZRange[1]- vertexZRange[0])*gRandom->Rndm() + vertexZRange[0]; TVector3 vertex(vertexX, vertexY, vertexZ); // set direction vector from lab angle TVector3 dir(1, 0, 0); dir.SetTheta(thetab * TMath::DegToRad()); dir.SetPhi(phib * TMath::DegToRad()); // run detector response models for PW and SX3 pw->FindWireID(vertex, dir, false); sx3->FindSX3Pos(vertex, dir, false); PWHitInfo hitInfo = pw->GetHitInfo(); // store nearest/next closest wire data anodeID[0] = hitInfo.nearestWire.first; cathodeID[0] = hitInfo.nearestWire.second; anodeID[1] = hitInfo.nextNearestWire.first; cathodeID[1] = hitInfo.nextNearestWire.second; anodeDist[0] = hitInfo.nearestDist.first; cathodeDist[0] = hitInfo.nearestDist.second; anodeDist[1] = hitInfo.nextNearestDist.first; cathodeDist[1] = hitInfo.nextNearestDist.second; // SX3 hit channel info and depth fraction sx3ID = sx3->GetID(); if( sx3ID >= 0 ){ sx3Up = sx3->GetChUp(); sx3Dn = sx3->GetChDn(); sx3Bk = sx3->GetChBk(); sx3ZFrac = sx3->GetZFrac(); // apply intrinsic detector resolution to true SX3 hit position // for no smearing comment out and use GetHitPos(); TVector3 hitPos = sx3->GetHitPosWithSigma(sigmaSX3_W, sigmaSX3_L); sx3X = hitPos.X(); sx3Y = hitPos.Y(); sx3Z = hitPos.Z(); // fill tree with original data before energy loss tree->Fill(); // apply energy loss from vertex to SX3 hit position (for light particle) double dl = (hitPos - vertex).Mag() / 10.0; // path length in cm (positions in mm) double EkinLight = Pb.E() - Pb.M(); double dedxLight = elossLight->Eval(EkinLight); // interpolate dE/dx double dE_light = dedxLight * dl * density / 1000.0; // adjust for units (example scaling) if (dE_light < EkinLight) { Pb.SetE(Pb.E() - dE_light); // update momentum to conserve direction double p_new = TMath::Sqrt(Pb.E()*Pb.E() - Pb.M()*Pb.M()); TVector3 dir_new = Pb.Vect().Unit() * p_new; Pb.SetPxPyPzE(dir_new.X(), dir_new.Y(), dir_new.Z(), Pb.E()); } // update kinetic energy after loss Tb = Pb.E() - Pb.M(); // reconstruct track from PW readings + SX3 hit pw->CalTrack(hitPos, anodeID[0], cathodeID[0], false); reTheta = pw->GetTrackTheta() * TMath::RadToDeg(); rePhi = pw->GetTrackPhi() * TMath::RadToDeg(); // alternative track algorithm with uncertainty parameters pw->CalTrack2(hitPos, hitInfo, sigmaPW_A, sigmaPW_C, false); reTheta1 = pw->GetTrackTheta() * TMath::RadToDeg(); rePhi1 = pw->GetTrackPhi() * TMath::RadToDeg(); z0 = pw->GetZ0(); // fill tree2 with energy loss adjusted data tree2->Fill(); }else{ // no valid SX3 hit: mark clearly invalid sx3Up = -1; sx3Dn = -1; sx3Bk = -1; sx3ZFrac = TMath::QuietNaN(); sx3X = TMath::QuietNaN(); sx3Y = TMath::QuietNaN(); sx3Z = TMath::QuietNaN(); reTheta = TMath::QuietNaN(); rePhi = TMath::QuietNaN(); reTheta1 = TMath::QuietNaN(); rePhi1 = TMath::QuietNaN(); z0 = TMath::QuietNaN(); // fill tree with original data (no energy loss for these events) tree->Fill(); } //#################################################################### Timer // measure elapsed real time and print progress roughly every 10 sec clock.Stop("timer"); Double_t time = clock.GetRealTime("timer"); clock.Start("timer"); if ( !shown ) { if (fmod(time, 10) < 1 ){ printf( "%10d[%2d%%]| %8.2f sec | expect: %5.1f min \n", i, TMath::Nint((i+1)*100./numEvent), time , numEvent*time/(i+1)/60); shown = 1; } } else { if (fmod(time, 10) > 9 ){ shown = 0; } } } // write results to ROOT file and close tree->Write(); tree2->Write(); int count = tree->GetEntries(); int count2 = tree2->GetEntries(); saveFile->Close(); printf("=============== done. saved as %s. tree entries: %d, tree2 entries: %d\n", saveFileName.Data(), count, count2); if(enableVis){ printf("Displaying geometry via ANASEN::DrawAnasen()\n"); anasen->DrawAnasen(); anasen->DrawDeducedTrack(TVector3(sx3X, sx3Y, sx3Z), anodeID[0], cathodeID[0]); if(app){ app->Run(); } } delete anasen; delete elossLight; delete elossHeavy; return 0; }