AEvent.cpp

/*
 * AEvent.cpp
 *
 *  Created on: Dec 28, 2016
 *      Author: daria
 */

#include "AEvent.h"

AEvent::AEvent() : fNPoints(1024) {	//fNPoints is number of points in one event, 1024 or 1000

	Init();
	Reset();

}

AEvent::AEvent(const Int_t npoints) : fNPoints(npoints) {

	Init();
	Reset();
}

AEvent::~AEvent() {
	// TODO Auto-generated destructor stub
	delete fGraphSignal;
	delete fGraphCFD;
	delete fInputEvent;
}

void AEvent::SetRawDataFile(const char* inprawfile, const char* treename) {

	TString iFileName = inprawfile;
	TFile *fraw = new TFile(iFileName.Data());
	if ( !fraw->IsOpen() ) {
		Error("SetRawDataFile", "File %s was not opened and won't be processed", iFileName.Data());
	}
	TTree *traw = (TTree*)fraw->Get(treename);
	if (!traw) {
		Error("SetRawDataFile", "Tree %s was not found in file %s", treename, iFileName.Data());
	}
}

void AEvent::ProcessEvent() {

	if (fInputEvent == NULL) {
		Warning("AEvent::ProcessEvent", "Input event wasn't set. Function won't be processed.");
		return;
	}

	const Double_t *amp = fInputEvent->GetAmp();
	const Double_t *time = fInputEvent->GetTime();

	for(Int_t j = 0; j < fNPoints; j++) {
		fAmpPos[j] = amp[j]*(-1.);
		fTime[j] = time[j];
	}

	fZeroLevel = FindZeroLevel();
	for(Int_t j = 0; j < fNPoints; j++) {
		fAmpPos[j] = fAmpPos[j] - fZeroLevel;
	}

	Double_t maxAmp = 0.;
	Double_t maxAmpT = 0.;

	maxAmp = fAmpPos[0];
	for(Int_t j=0; j < fNPoints; j++) {
		if(fAmpPos[j] > maxAmp) {
			maxAmp = fAmpPos[j];
			maxAmpT = fTime[j];
		}
	}
	fAmpMax = maxAmp;
	fTimeAmpMax = maxAmpT;

	SetGraphs();

	SetCFD();
	SetChargeCFD();

	return;

}

void AEvent::Reset() {

	for (Int_t i = 0; i < fNPoints; i++) {
		fAmpPos[i] = 0;
		fTime[i] = 0;
		fAmpCFD[i] = 0;
	}

	fAmpMax = 0.;
	fTimeAmpMax = 0.;
	fTimeCFD = 0.;
	fZeroLevel = 0.;
	fChargeCFD = 0.;
}

void AEvent::SetInputEvent(RawEvent** event) {

	if (event == 0) {
		Warning("AEvent::SetInputEvent", "Input event was set as 0.");
	}
	fInputEvent = *event;

}

void AEvent::Init() {

	fAmpPos.Set(fNPoints);
	fTime.Set(fNPoints);
	fAmpCFD.Set(fNPoints);

	fGraphSignal = new TGraph();
	fGraphCFD = new TGraph();
	fInputEvent = 0;

	fCFratio = 0.;
	fCFtimeDelay = 0.;

	fNoiseRangeMin = 0.;
	fNoiseRangeMax = 1.;

}

void AEvent::SetGraphs() {

	fGraphSignal->Set(fNPoints);

	for (Int_t i=0; i<fNPoints; i++) {
		fGraphSignal->SetPoint(i, fTime[i], fAmpPos[i]);
	}

	return;
}

void AEvent::SetCFD() {

	Double_t level = 100.;	//is necessary to find cfd amplitude value closest to zero

	fGraphCFD->Set(fNPoints);

	//working variables
	Double_t maxCFD = 0., minCFD = 0.;
	Int_t imax = 0, imin = 0;

	for (Int_t i=0; i<fNPoints; i++) {

		//CFD method
		if(i>fCFtimeDelay) {
			fAmpCFD[i] = fAmpPos[i]*fCFratio*(-1);
			fAmpCFD[i] = fAmpCFD[i] + fAmpPos[i - fCFtimeDelay];
			fGraphCFD->SetPoint(i, fTime[i], fAmpCFD[i]);
		}

		//point for max CFD amplitude
		if(fAmpCFD[i] > maxCFD) {
			maxCFD = fAmpCFD[i];
			imax = i;
		}

		//point for min CFD amplitude
		if(fAmpCFD[i] < minCFD) {
			minCFD = fAmpCFD[i];
			imin = i;
		}

	}

	//finding "zero" of CFD amplitude
	for(Int_t j = imin; j < imax; j++) {   
		if(abs(fAmpCFD[j]) < level) {
			level = abs(fAmpCFD[j]);
			fTimeCFD = fTime[j];
		}
	}
}

Double_t AEvent::FindZeroLevel() {

	SetGraphs();
	Double_t correction = 0;
	TF1 *fit1 = new TF1("fit1","[0]");	//function for one parameter fitting in the range of pmin-pmax
	fit1->SetRange(fNoiseRangeMin,fNoiseRangeMax);

	if (!fGraphSignal) {
		Warning("AEvent::FindZeroLevel", "Graph was not set");
		return 0;
	}

	fGraphSignal->Fit(fit1,"RQN","goff");
	correction = fit1->GetParameter(0);

	delete fit1;
	return correction;
}

void AEvent::SetChargeCFD(Int_t tmin, Int_t tmax) {
	
	Double_t integral = 0.;					//voltage
	Double_t time_sig = 0;					//approximate signal duration in seconds
	const Double_t res = 50.; 				//resistance 50 Om
	time_sig = (double)(-tmin + tmax)*(1e-9);

	for(Int_t i = 0; i < fNPoints; i++) {
		if( fTime[i] > (fTimeCFD + tmin) && fTime[i] < (fTimeCFD + tmax) ) {
			integral = integral + fAmpPos[i];
		}
	}
	fChargeCFD = integral*time_sig/res;
//	cout<<fCharge<<endl;
//	printf("\nIntegral is %f , charge is %lf \n", integral, fCharge);

	return;

}

Double_t AEvent::GetfCFD() {
		return fTimeCFD;
}

Double_t AEvent::GetOnefTime(Int_t i) {
		return fTime[i];
}

Double_t AEvent::GetOnefAmpPos(Int_t i) {
		return fAmpPos[i];
}