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have SimChecker.C working. should make it object.

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This commit is contained in:
Ryan@Home 2024-07-05 19:26:51 -04:00
parent 1c140d07fc
commit 052ec49e9e
5 changed files with 615 additions and 33 deletions
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5
.vscode/settings.json vendored
View File

@ -3,6 +3,7 @@
"detectorGeo.txt": "shellscript",
"reactionConfig.txt": "shellscript",
"DWBA": "shellscript",
"SimChecker_Config.txt": "cpp",
"*.C": "cpp"
},
@ -19,10 +20,10 @@
},
{
"tag": "?",
"color": "#0076FF",
"color": "#1FE0CB",
"strikethrough": false,
"backgroundColor": "transparent",
"bold": false,
"bold": true,
"italic": false
},
{

38
Cleopatra/ClassTransfer.h
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@ -10,6 +10,7 @@
#include "TLorentzVector.h"
#include "TMath.h"
#include "TF1.h"
#include "TMacro.h"
//=======================================================
//#######################################################
@ -25,6 +26,7 @@ public:
TransferReaction(){Inititization();};
TransferReaction(ReactionConfig config, unsigned short ID = 0);
TransferReaction(std::string configFile, unsigned short ID = 0);
TransferReaction(TMacro configMarco, unsigned short ID = 0);
TransferReaction(int beamA, int beamZ,
int targetA, int targetZ,
int recoilA, int recoilZ, float beamEnergy_AMeV);
@ -38,6 +40,7 @@ public:
void SetIncidentEnergyAngle(double KEA, double theta, double phi);
void SetReactionFromFile(std::string configFile, unsigned short ID = 0);
void SetReactionFromTMacro(TMacro configMacro, unsigned short ID = 0);
void SetReactionSimple(int beamA, int beamZ,
int targetA, int targetZ,
int recoilA, int recoilZ, float beamEnergy_AMeV);
@ -156,6 +159,11 @@ TransferReaction::TransferReaction(std::string configFile, unsigned short ID){
SetReactionFromFile(configFile, ID);
}
TransferReaction::TransferReaction(TMacro configMarco, unsigned short ID){
Inititization();
SetReactionFromTMacro(configMarco, ID);
}
TransferReaction::TransferReaction(int beamA, int beamZ,
int targetA, int targetZ,
int recoilA, int recoilZ,
@ -305,6 +313,36 @@ void TransferReaction::SetReactionFromFile(std::string configFile, unsigned shor
}
void TransferReaction::SetReactionFromTMacro(TMacro configMacro, unsigned short ID){
if( config.LoadReactionConfig(&configMacro) ){
SetA(config.beamA, config.beamZ);
Seta(config.targetA, config.targetZ);
SetExA(config.beamEx);
if( ID > config.recoil.size() ){
printf("Reaction Config only has %zu recoil settings. input is %u. Abort.\n", config.recoil.size(), ID);
return;
}
recoil = config.recoil[ID];
exList = config.exList[ID];
Setb(recoil.lightA, recoil.lightZ);
SetB(recoil.heavyA, recoil.heavyZ);
SetIncidentEnergyAngle(config.beamEnergy, 0, 0);
CalReactionConstant();
}else{
printf("cannot read TMacro %s.\n", configMacro.GetName());
isReady = false;
}
}
TString TransferReaction::GetReactionName() const{
TString rName;
rName.Form("%s(%s,%s)%s", nameA.c_str(), namea.c_str(), nameb.c_str(), nameB.c_str());

573
Cleopatra/SimChecker.C Normal file
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@ -0,0 +1,573 @@
#include <TFile.h>
#include <TTree.h>
#include <TCanvas.h>
#include <TROOT.h>
#include <TObjArray.h>
#include <TStyle.h>
#include <TH2F.h>
#include <TH1F.h>
#include <TF1.h>
#include <TArc.h>
#include <TMath.h>
#include <TLine.h>
#include <TSpectrum.h>
#include <TGraph.h>
#include <TLegend.h>
#include <TLatex.h>
#include <TMacro.h>
#include <TObjArray.h>
#include <fstream>
#include <TCutG.h>
#include "../Armory/AnalysisLib.h"
#include "../Armory/ClassDetGeo.h"
#include "../Armory/ClassReactionConfig.h"
#include "../Cleopatra/ClassIsotope.h"
#include "../Cleopatra/ClassTransfer.h"
enum plotID { pEZ, /// 0
pRecoilXY, /// 1
pRecoilXY1, /// 2
pRecoilXY2, /// 3
pRecoilRZ, /// 4
pRecoilRTR, /// 5
pTDiffZ, /// 6
pThetaCM, /// 7
pThetaCM_Z, /// 8
pExCal, /// 9
pRecoilRThetaCM, /// 10
pArrayXY, /// 11
pInfo, /// 12
pHitID, /// 13
pElum1XY, /// 14
pEElum1R, /// 15
pElum1RThetaCM, /// 16
pEmpty }; /// 17
plotID StringToPlotID(TString str);
void SimChecker(TString filename = "transfer.root",
TString configFile = "../working/SimChecker_Config.txt",
Int_t padSize = 500,
bool outputCanvas = false){
printf("=================================================================\n");
printf("==================== Simulate Checker ==================\n");
printf("=================================================================\n");
TFile * file = new TFile(filename, "read");
TTree * tree = (TTree*) file->Get("tree");
//*================= Get reactions and Ex
TMacro * ListOfReactions = (TMacro *) file->FindObjectAny("ListOfReactions");
const short numReact = ListOfReactions->GetListOfLines()->GetEntries();
printf(">>>>> %d reactions found.\n", numReact);
std::string reactionList[numReact];
for( int i = 0; i < numReact; i++ ){
std::string haha = ListOfReactions->GetListOfLines()->At(i)->GetName();
std::vector<std::string> kaka = AnalysisLib::SplitStr(haha, "|");
reactionList[i]= kaka[1];
}
ExcitedEnergies reactEx[numReact]; //2-D array [i][j] = i-reaction, j-Ex
TMacro * AllExList = (TMacro *) file->FindObjectAny("AllExList");
TMacro * ExID_ReactID_List = (TMacro *) file->FindObjectAny("ExID_ReactID_List");
const short numEx = ExID_ReactID_List->GetListOfLines()->GetEntries()-1;
for( int i = 1; i <= numEx; i++){
std::string haha = ExID_ReactID_List->GetListOfLines()->At(i)->GetName();
std::vector<std::string> kaka = AnalysisLib::SplitStr(haha, " ");
std::string dudu = AllExList->GetListOfLines()->At(i)->GetName();
std::vector<std::string> dada = AnalysisLib::SplitStr(dudu, " ");
short rID = atoi(kaka[1].c_str());
reactEx[rID].Add(atof(dada[0].c_str()),
atof(dada[1].c_str()),
atof(dada[2].c_str()),
atof(dada[3].c_str()));
}
for( int i = 0; i < numReact; i++ ){
printf("=========== %s\n", reactionList[i].c_str());
reactEx[i].Print();
}
//*================== detGeoID
TMacro * detGeotxt = (TMacro *) file->FindObjectAny("detGeo");
DetGeo detGeo(detGeotxt);
detGeo.Print(true);
//*================== Get EZ-curve
TObjArray * ezList = (TObjArray *) file->FindObjectAny("EZCurve");
//*================== Get thetaCM = 0
TObjArray * thetaCM0List = (TObjArray *) file->FindObjectAny("thetaCM_Z");
//^################################################ Find e-range, z-range
double zRange[numReact][2];
double eMax[numReact];
int count = 0;
for( int i = 0; i < numReact; i++ ){
zRange[i][0] = detGeo.array[i].zMin-50;
zRange[i][1] = detGeo.array[i].zMax+50;
eMax[i] = -1;
for( size_t j = 0; j < reactEx[i].ExList.size() ; j ++){
TGraph * func = (TGraph *) ezList->At(count);
double aaa = func->Eval(zRange[i][1]);
// printf(" xxxxxxxxxxxx %d, %d | %d %.3f\n", i, j, count, aaa);
if( aaa > eMax[i] ) eMax[i] = aaa;
count++;
}
eMax[i] = TMath::Ceil( eMax[i] * 1.1 );
}
// for( int i = 0; i < numReact; i++ ){
// printf(" %d | eMax : %.2f, zRange : %.2f, %.2f \n", i, eMax[i], zRange[i][0], zRange[i][1]);
// }
// //^################################################
TMacro * config = new TMacro(configFile);
int numLine = config->GetListOfLines()->GetSize();
TString gate;
std::vector<plotID> padPlotID;
float elumMax = 60;
float thetaCMMax = 60; //TODO add thetaCM curves in transfer, so that it can be determinated automatically
int rowCount = 0;
int colCount = 0;
bool startCanvasConfig = false;
bool startGateConfig = false;
bool startExtra = false;
for( int i = 0; i < numLine ; i++){
std::string haha = config->GetListOfLines()->At(i)->GetName();
std::vector<std::string> dudu = AnalysisLib::SplitStr(haha, ",");
TString lala = haha;
lala.Remove(3);
if( (lala == " " || lala == "// " || lala == "//=") && dudu.size() == 0) continue;
if( lala == "//#" ) break;
if( lala == "//*" ) {
startCanvasConfig = true;
// rowCount ++;
continue;
}
if( lala == "//^" ) {
startCanvasConfig = false;
startGateConfig = true;
continue;
}
if( lala == "//@" ) {
startGateConfig = false;
startExtra = true;
}
if( startCanvasConfig ){
rowCount ++;
// printf("|%s|\n", haha.c_str());
if( dudu.size() > colCount ) colCount = dudu.size();
for( size_t k = 0; k < dudu.size() ; k++){
padPlotID.push_back(StringToPlotID(dudu[k]));
}
}
if( startGateConfig ){
gate = haha;
}
if( startExtra ){
if( dudu[0] == "elum_Max" ) elumMax = atof(dudu[2].c_str());
if( dudu[0] == "thetaCM_Max" ) thetaCMMax = atof(dudu[2].c_str());
}
}
int Div[2] = {colCount, rowCount};
gStyle->SetOptStat("");
gStyle->SetStatY(0.9);
gStyle->SetStatX(0.9);
gStyle->SetStatW(0.4);
gStyle->SetStatH(0.2);
gStyle->SetLabelSize(0.05, "XY");
gStyle->SetTitleFontSize(0.1);
printf(" Canvas division | col : %d, row : %d \n", colCount, rowCount);
count = 0;
for( int i = 0; i < rowCount; i++){
for( int j = 0; j < colCount; j++){
printf("%6d", padPlotID[count]);
count++;
}
printf("\n");
}
printf("Gate : %s \n", gate.Data());
printf("elum Max : %.2f mm\n", elumMax);
printf("thetaCM Max : %.2f deg\n", thetaCMMax);
printf("#####################################################\n");
// //^################################################
Int_t size[2] = {padSize,padSize}; ///x,y, single Canvas size
TCanvas * cCheck[numReact];
TH2F * hez[numReact];
TH2F * hArrayXY[numReact];
TH2F * hRecoilXY[numReact];
TH2F * hElum1XY[numReact];
TH1F ** hThetaCM[numReact];
TH1F * hExCal[numReact];
TH1F * hHit[numReact];
for( int i = 0; i < numReact; i++ ){
TString gateThis = gate + Form(" && rID == %d", i);
cCheck[i] = new TCanvas(Form("cCheck-%d", i), Form("Simulation Checker (%d)", i), 200 * i , 200 * i, size[0]*Div[0], size[1]*Div[1]);
if(cCheck[i]->GetShowEditor() ) cCheck[i]->ToggleEditor();
if(cCheck[i]->GetShowToolBar() )cCheck[i]->ToggleToolBar();
cCheck[i]->Divide(Div[0],Div[1]);
for( int j = 1; j <= Div[0]*Div[1]; j ++){
cCheck[i]->cd(j);
if( padPlotID[i-1] == pThetaCM ) {
cCheck[i]->cd(j)->SetGrid(0,0);
cCheck[i]->cd(j)->SetLogy();
}
plotID pID = padPlotID[j-1];
///########################################
if( pID == pEZ){
hez[i] = new TH2F(Form("hez%d", i),
Form("e-z [gated] @ %5.0f mm; z [mm]; e [MeV]", detGeo.array[i].firstPos),
200, zRange[i][0], zRange[i][1],
200, 0, eMax[i]);
tree->Draw(Form("e:z>>hez%d", i), gateThis , "colz");
}
if( pID == pRecoilXY ){
hRecoilXY[i] = new TH2F(Form("hRecoilXY%d",i),
Form("RecoilXY [gated] @ %4.0f mm; X [mm]; Y [mm]", detGeo.aux[i].detPos ),
200, -detGeo.aux[i].outerRadius, detGeo.aux[i].outerRadius,
200, -detGeo.aux[i].outerRadius, detGeo.aux[i].outerRadius);
tree->Draw(Form("yRecoil:xRecoil>>hRecoilXY%d", i), gateThis, "colz");
TArc * detArc1 = new TArc(0,0, detGeo.aux[i].outerRadius);
detArc1->SetLineColor(kBlue-8);
detArc1->SetFillStyle(0);
detArc1->Draw("same");
TArc * detArc2 = new TArc(0,0, detGeo.aux[i].innerRadius);
detArc2->SetLineColor(kBlue-8);
detArc2->SetFillStyle(0);
detArc2->Draw("same");
// if( reactionConfig.beamX != 0. || reactionConfig.beamY != 0. ){
// TArc * arc = new TArc(reactionConfig.beamX, reactionConfig.beamY, 1);
// arc->SetLineColor(2);
// detArc1->SetFillStyle(0);
// arc->Draw("same");
// }
}
/*
if( pID == pRecoilXY1 ){
TH2F * hRecoilXY1 = new TH2F("hRecoilXY1", Form("RecoilXY-1 [gated] @ %4.0f mm; X [mm]; Y [mm]", detGeo.aux[detGeoID].detPos1 ),
400, -detGeo.aux[detGeoID].outerRadius, detGeo.aux[detGeoID].outerRadius,
400, -detGeo.aux[detGeoID].outerRadius, detGeo.aux[detGeoID].outerRadius);
tree->Draw("yRecoil1:xRecoil1>>hRecoilXY1", gate, "colz");
}
if( pID == pRecoilXY2 ){
TH2F * hRecoilXY2 = new TH2F("hRecoilXY2", Form("RecoilXY-2 [gated] @ %4.0f mm; X [mm]; Y [mm]", detGeo.aux[detGeoID].detPos2 ),
400, -detGeo.aux[detGeoID].outerRadius, detGeo.aux[detGeoID].outerRadius,
400, -detGeo.aux[detGeoID].outerRadius, detGeo.aux[detGeoID].outerRadius);
tree->Draw("yRecoil2:xRecoil2>>hRecoilXY2", gate, "colz");
}
if( pID == pRecoilRZ ){
TH2F * hRecoilRZ = new TH2F("hRecoilRZ", "RecoilR - Z [gated]; z [mm]; RecoilR [mm]", zRange[0], zRange[1], zRange[2], 400,0, detGeo.aux[detGeoID].outerRadius);
tree->Draw("rhoRecoil:z>>hRecoilRZ", gate, "colz");
}
if( pID == pRecoilRTR ){
FindRange("TB", gate, tree, recoilERange);
TH2F * hRecoilRTR = new TH2F("hRecoilRTR", "RecoilR - recoilE [gated]; recoil Energy [MeV]; RecoilR [mm]", 500, recoilERange[0], recoilERange[1], 500, 0, detGeo.aux[detGeoID].outerRadius);
tree->Draw("rhoRecoil:TB>>hRecoilRTR", gate, "colz");
}
if( pID == pTDiffZ ){
double tDiffRange [2];
FindRange("t-tB", gate, tree, tDiffRange);
TH2F * hTDiffZ = new TH2F("hTDiffZ", "time(Array) - time(Recoil) vs Z [gated]; z [mm]; time diff [ns]", zRange[0], zRange[1], zRange[2], 500, tDiffRange[0], tDiffRange[1]);
tree->Draw("t - tB : z >> hTDiffZ", gate, "colz");
}
*/
if( pID == pThetaCM ){
int numExTemp = reactEx[i].ExList.size();
hThetaCM[i] = new TH1F *[numExTemp];
TLegend * legend = new TLegend(0.8,0.2,0.99,0.8);
double maxCount = 0;
for( int h = 0; h < numExTemp; h++){
hThetaCM[i][h] = new TH1F(Form("hThetaCM%d-%d", i, h), Form("thetaCM [gated] (ExID=%d); thetaCM [deg]; count", h), 200, 0, thetaCMMax);
hThetaCM[i][h]->SetLineColor(h+1);
hThetaCM[i][h]->SetFillColor(h+1);
hThetaCM[i][h]->SetFillStyle(3000+h);
tree->Draw(Form("thetaCM>>hThetaCM%d-%d", i, h), gateThis + Form("&& ExID==%d", h), "");
legend->AddEntry(hThetaCM[i][h], Form("Ex=%5.1f MeV", reactEx[i].ExList[h].Ex));
double max = hThetaCM[i][h]->GetMaximum();
if( max > maxCount ) maxCount = max;
}
for( int h = 0; h < numExTemp; h++){
hThetaCM[i][h]->GetYaxis()->SetRangeUser(1, maxCount * 1.2);
if( h == 0 ) {
hThetaCM[i][h]->Draw();
}else{
hThetaCM[i][h]->Draw("same");
}
}
legend->Draw();
}
/*
if( pID == pThetaCM_Z ){
TH2F *hThetaCM_Z = new TH2F("hThetaCM_Z","ThetaCM vs Z ; Z [mm]; thetaCM [deg]",zRange[0], zRange[1], zRange[2], 200, thetaCMRange[0], thetaCMRange[1]);
tree->Draw("thetaCM:z>>hThetaCM_Z",gate,"col");
if( shownKELines){
for( int i = 0; i < numEx ; i++){
txList->At(i)->Draw("same");
}
}
}
*/
if( pID == pExCal ){
double exMin = 9999;
double exMax = -1;
for( size_t k = 0 ; k < reactEx[i].ExList.size(); k++){
double kuku = reactEx[i].ExList[k].Ex;
if( kuku > exMax ) exMax = kuku;
if( kuku < exMin ) exMin = kuku;
}
double exPadding = (exMax - exMin) < 1 ? 1 : (exMax - exMin) * 0.3;
exMin = exMin - exPadding ;
exMax = exMax + exPadding ;
hExCal[i] = new TH1F(Form("hExCal%d",i),
Form("calculated Ex [gated]; Ex [MeV]; count / %.2f keV", (exMax-exMin)/400.*1000),
400, exMin, exMax);
tree->Draw(Form("ExCal>>hExCal%d", i), gateThis, "");
// Isotope hRecoil(recoil.heavyA, recoil.heavyZ);
// double Sn = hRecoil.CalSp(0,1);
// double Sp = hRecoil.CalSp(1,0);
// double Sa = hRecoil.CalSp2(4,2);
// double S2n = hRecoil.CalSp(0, 2);
// printf("Heavy recoil: %s \n", hRecoil.Name.c_str());
// printf("Sn : %f MeV/u \n", Sn);
// printf("Sp : %f MeV/u \n", Sp);
// printf("Sa : %f MeV/u \n", Sa);
// printf("S2n : %f MeV/u \n", S2n);
// double yMax = hExCal->GetMaximum();
// TLine * lineSn = new TLine(Sn, 0, Sn, yMax); lineSn->SetLineColor(2); lineSn->Draw("");
// TLine * lineSp = new TLine(Sp, 0, Sp, yMax); lineSp->SetLineColor(4); lineSp->Draw("same");
// TLine * lineSa = new TLine(Sa, 0, Sa, yMax); lineSa->SetLineColor(6); lineSa->Draw("same");
// TLine * lineS2n = new TLine(S2n, 0, S2n, yMax); lineS2n->SetLineColor(8); lineS2n->Draw("same");
// TLatex * text = new TLatex();
// text->SetTextFont(82);
// text->SetTextSize(0.06);
// text->SetTextColor(2); text->DrawLatex(Sn, yMax*0.9, "S_{n}");
// text->SetTextColor(4); text->DrawLatex(Sp, yMax*0.9, "S_{p}");
// text->SetTextColor(6); text->DrawLatex(Sa, yMax*0.9, "S_{a}");
// text->SetTextColor(8); text->DrawLatex(S2n, yMax*0.9, "S_{2n}");
}
/*
if( pID == pRecoilRThetaCM ){
TH2F * hRecoilRThetaCM = new TH2F("hRecoilRThetaCM", "RecoilR - thetaCM [gated]; thetaCM [deg]; RecoilR [mm]", 400, 0, 60, 400,0, detGeo.aux[detGeoID].outerRadius);
tree->Draw("rhoRecoil:thetaCM>>hRecoilRThetaCM", gate, "colz");
}
*/
if( pID == pArrayXY ){
hArrayXY[i] = new TH2F(Form("hArrayXY%d", i),
"Array-XY [gated]; X [mm]; Y [mm]",
400, -detGeo.array[i].detPerpDist*1.5, detGeo.array[i].detPerpDist*1.5,
400, -detGeo.array[i].detPerpDist*1.5, detGeo.array[i].detPerpDist*1.5);
tree->Draw(Form("yArray:xArray>>hArrayXY%d", i), gateThis, "colz");
}
if( pID == pInfo ){
TLatex text;
text.SetNDC();
text.SetTextFont(82);
text.SetTextSize(0.06);
text.SetTextColor(2);
text.DrawLatex(0., 0.9, reactionList[i].c_str());
text.DrawLatex(0., 0.8, detGeo.Bfield > 0 ? "out of plan" : "into plan");
text.SetTextColor(1);
text.DrawLatex(0., 0.7, "gate:");
text.SetTextColor(2);
//check gate text length, if > 30, break by "&&"
int ll = gate.Length();
if( ll > 30 ) {
std::vector<std::string> strList = AnalysisLib::SplitStr( (std::string) gate.Data(), "&&");
for( int i = 0; i < strList.size(); i++){
text.DrawLatex(0., 0.6 - 0.05*i, (TString) strList[i]);
}
}else{
text.DrawLatex(0., 0.6, gate);
}
// if( reactionConfig.beamX != 0.0 || reactionConfig.beamY != 0.0 ){
// text.DrawLatex(0.0, 0.1, Form("Bema pos: (%4.1f, %4.1f) mm", reactionConfig.beamX, reactionConfig.beamY));
// }
}
if( pID == pElum1XY ){
hElum1XY[i] = new TH2F(Form("hElum1XY%d", i),
Form("Elum-1 XY [gated] @ %.0f mm ; X [mm]; Y [mm]", detGeo.aux[i].elumPos1),
400, -elumMax, elumMax,
400, -elumMax, elumMax);
tree->Draw(Form("yElum1:xElum1>>hElum1XY%d", i), gateThis, "colz");
double count = hElum1XY[i]->GetEntries();
if( count < 2000. ) {
hElum1XY[i]->SetMarkerStyle(7);
if( count < 500. ) hElum1XY[i]->SetMarkerStyle(3);
hElum1XY[i]->Draw("scat");
}
}
/*
if( pID == pEElum1R ){
TH2F * hEElum1Rho = new TH2F("hEElum1Rho", "Elum-1 E-R [gated]; R[mm]; Energy[MeV]", 400, 0, elumRange, 400, eRange[0], eRange[1]);
tree->Draw("Tb:rhoElum1>>hEElum1Rho", gate, "colz");
}
if( pID == pElum1RThetaCM){
int angBin = 400;
TH2F * hElum1RThetaCM = new TH2F("hElum1RThetaCM", "Elum-1 rho vs ThetaCM [gated]; thatCM [deg]; Elum- rho [mm]", angBin, thetaCMRange[0], thetaCMRange[1], 400, 0, elumRange);
tree->Draw("rhoElum1:thetaCM>>hElum1RThetaCM", gate, "colz");
TH1F * htemp = (TH1F *) hElum1RThetaCM->ProjectionX("htemp");
double rel = (thetaCMRange[1] - thetaCMRange[0])*1.0/angBin;
printf("angular resolution : %f deg \n", rel);
vector<double> xList;
double old_y = 0;
for( int i = 1; i <= angBin; i++){
double y = htemp->GetBinContent(i);
if( old_y == 0 && y > 0) xList.push_back(htemp->GetBinCenter(i));
if( old_y > 0 && y == 0 ) xList.push_back(htemp->GetBinCenter(i));
old_y = y;
}
printf("list of gaps :\n");
for( int i = 0; i < (int) xList.size(); i+=2){
printf("%d | %.3f - %.3f deg\n", i, xList[i], xList[i+1]);
}
TF1 f1("f1", "sin(x)");
double acceptance = 0;
double err1 = 0;
double err2 = 0;
for( int i = 0; i < (int) xList.size(); i += 2 ){
acceptance += f1.Integral(xList[i] * TMath::DegToRad(), xList[i+1] * TMath::DegToRad() ) * TMath::TwoPi();
err1 += f1.Integral((xList[i]-rel) * TMath::DegToRad(), (xList[i+1] + rel) * TMath::DegToRad() ) * TMath::TwoPi();
err2 += f1.Integral((xList[i]+rel) * TMath::DegToRad(), (xList[i+1] - rel) * TMath::DegToRad() ) * TMath::TwoPi();
}
printf("acceptance = %f sr +- %f \n", acceptance, (err1-err2)/2);
TLatex text;
text.SetTextFont(82);
text.SetTextSize(0.06);
text.SetTextColor(2);
text.SetTextAngle(90);
for( int i = 0; i < (int) xList.size(); i++){
text.DrawLatex(xList[i], elumRange/2, Form("%.2f", xList[i]));
}
text.SetNDC();
text.SetTextAngle(0);
text.DrawLatex(0.15, 0.15, Form("accp. = %.2f(%.2f) msr", acceptance * 1000., (err1-err2)*1000./2));
}
*/
if( pID == pHitID ){
printf("=======================meaning of Hit ID\n");
printf(" 1 = light recoil hit array & heavy recoil hit recoil\n");
printf(" 0 = no detector\n");
printf(" -1 = light recoil go opposite side of array\n");
printf(" -2 = light recoil hit > det width\n");
printf(" -3 = light recoil hit > array \n");
printf(" -4 = light recoil hit blocker \n");
printf(" -10 = light recoil orbit radius too big \n");
printf(" -11 = light recoil orbit radius too small\n");
printf(" -12 = when reocol at the same side of array, light recoil blocked by recoil detector\n");
printf(" -13 = more than 3 loops\n");
printf(" -14 = heavy recoil did not hit recoil \n");
printf(" -15 = cannot find hit on array\n");
printf(" -20 = unknown\n");
printf("===========================================\n");
hHit[i] = new TH1F(Form("hHit%d", i), "hit; hit-ID; count", 13, -11, 2);
tree->Draw(Form("hit>>hHit%d", i), "", "");
}
}///===== end of pad loop
}///===== end of reaction loop
}
plotID StringToPlotID(TString str){
if( str == "pEZ") return plotID::pEZ; ///0
if( str == "pRecoilXY") return plotID::pRecoilXY; /// 1
if( str == "pRecoilXY1" ) return plotID::pRecoilXY1; /// 2
if( str == "pRecoilXY2" ) return plotID::pRecoilXY2; /// 3
if( str == "pRecoilRZ" ) return plotID::pRecoilRZ; /// 4
if( str == "pRecoilRTR" ) return plotID::pRecoilRTR; /// 5
if( str == "pTDiffZ" ) return plotID::pTDiffZ; /// 6
if( str == "pThetaCM" ) return plotID::pThetaCM; /// 7
if( str == "pThetaCM_Z" ) return plotID::pThetaCM_Z; /// 8
if( str == "pExCal" ) return plotID::pExCal; /// 9
if( str == "pRecoilRThetaCM" ) return plotID::pRecoilRThetaCM; /// 10
if( str == "pArrayXY" ) return plotID::pArrayXY; /// 11
if( str == "pInfo" ) return plotID::pInfo; /// 12
if( str == "pHitID" ) return plotID::pHitID; /// 13
if( str == "pElum1XY" ) return plotID::pElum1XY; /// 14
if( str == "pEElum1R" ) return plotID::pEElum1R; /// 14
if( str == "pElum1RThetaCM" ) return plotID::pElum1RThetaCM; /// 15
if( str == "pEmpty" ) return plotID::pEmpty ; /// 16
return plotID::pEmpty;
}

30
working/Check_Simulation_Config.txt
View File

@ -1,30 +0,0 @@
/////enum plotID { pEZ, /// 0
///// pRecoilXY, /// 1
///// pRecoilXY1, /// 2
///// pRecoilXY2, /// 3
///// pRecoilRZ, /// 4
///// pRecoilRTR, /// 5
///// pTDiffZ, /// 6
///// pThetaCM, /// 7
///// pThetaCM_Z, /// 8
///// pExCal, /// 9
///// pRecoilRThetaCM, /// 10
///// pArrayXY, /// 11
///// pInfo, /// 12
///// pHitID, /// 13
///// pElum1XY, /// 14
///// pEElum1R, /// 15
///// pElum1RThetaCM, /// 16
///// pEmpty }; /// 17
/////=============================================== User Config
{pEZ, pExCal, pThetaCM, pRecoilRZ, break, pThetaCM_Z, pRecoilXY, pInfo, pArrayXY} //Canvas config
hit == 1 && loop <= 1 && thetaCM > 10
60 //elum range
{0,50} //thetaCM range
true //shownKELines
false //isOverRideEx
{-0.5, 4.0} // over-rdied Ex range
///============================== example of gate
hit == 1 && loop <= 1 && thetaCM > 10 && detRowID == 0
hit == 1 && loop <= 1
15 < rhoElum1 && rhoElum1 < 50 && rhoElum2 > 60

2
working/detectorGeo.txt
View File

@ -28,7 +28,7 @@ Out //detector_facing_Out_or_In
294.0
#===============2nd_Array + Recoil
false //is_this_array_exist_or_use_for_Simulation
true //is_this_array_exist_or_use_for_Simulation
1000 //recoil_position_+_for_downstream_[mm]
10.0 //inner_radius_of_recoil_detector_[mm]
40.2 //outter_radius_of_recoil_detector_[mm]