AEvent.cpp 8.99 KB
Newer Older
1 2 3 4 5 6 7 8 9
/*
 * AEvent.cpp
 *
 *  Created on: Dec 28, 2016
 *      Author: daria
 */

#include "AEvent.h"

10
AEvent::AEvent() : fNPoints(1024) {	//fNPoints is number of points in one event, 1024 or 1000
11 12 13 14 15 16

	Init();
	Reset();

}

17 18 19 20 21 22
AEvent::AEvent(const Int_t npoints) : fNPoints(npoints) {

	Init();
	Reset();
}

23 24
AEvent::~AEvent() {
	// TODO Auto-generated destructor stub
25 26
	delete fGraphSignal;
	delete fGraphCFD;
27
	delete fInputEvent;
28 29 30 31 32 33 34 35 36 37 38 39 40
}


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();

41
	for(Int_t j = 0; j < fNPoints; j++) {
42 43 44 45
		fAmpPos[j] = amp[j]*(-1.);
		fTime[j] = time[j];
	}

46
	fZeroLevel = FindZeroLevel();
47
	for(Int_t j = 0; j < fNPoints; j++) {
48
		fAmpPos[j] = fAmpPos[j] - fZeroLevel;
49 50
	}

51
	SetMaxAmplitudes();
52

53
	SetGraphs();
54
	FindFrontProperties();
55
	SetLED();
Vratislav Chudoba's avatar
Vratislav Chudoba committed
56
//	SetGraphs();
57
	SetCFD();
58
	SetChargeCFD();
59
	SetChargeLED();
60
	SetChargeTF();
61

62 63
	SmoothGraphs();

64 65 66 67 68 69
	return;

}

void AEvent::Reset() {

70
	for (Int_t i = 0; i < fNPoints; i++) {
71 72
		fAmpPos[i] = 0;
		fTime[i] = 0;
73
		fAmpCFD[i] = 0;
74
	}
75
	fTimeLED = -100.;
76
	fEdgeSlope=0.;
77
	fEdgeXi=0.;
78
	fEdgeSlope=-100.;
79 80
	fTime10=0.;
	fTime90=0.;
81
	fTimeMid=0.;
82 83
	fAmpMax = 0.;
	fTimeAmpMax = 0.;
84
	fTimeCFD = -100.;
85
	fZeroLevel = 0.;
86 87
	fChargeCFD = -10.;
	fChargeLED = -10.;
88
	fTimeFront = -100.;
89 90 91 92 93 94 95 96 97 98 99 100 101
}

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

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

}

void AEvent::Init() {

102 103 104 105
	fAmpPos.Set(fNPoints);
	fTime.Set(fNPoints);
	fAmpCFD.Set(fNPoints);

106 107
	fGraphSignal = new TGraph();
	fGraphCFD = new TGraph();
108
	fGraphSmooth = new TGraph();
109 110
	fInputEvent = 0;

111 112 113
	fCFratio = 0.;
	fCFtimeDelay = 0.;

114 115 116
	fNoiseRangeMin = 0.;
	fNoiseRangeMax = 1.;

117 118 119 120
}

void AEvent::SetGraphs() {

121
	fGraphSignal->Set(fNPoints);
122 123

	for (Int_t i=0; i<fNPoints; i++) {
124
		fGraphSignal->SetPoint(i, fTime[i], fAmpPos[i]);
125 126 127 128
	}

	return;
}
129

130 131 132 133
void AEvent::SmoothGraphs() {

	//smoothing graph

134
	fGraphSmooth->Set(fNPoints - fWinSize/2);
135

136 137
	//Int_t winSize = 5;	 		//number of smoothing points
	Int_t winMidSize = fWinSize / 2;	
138
	Double_t tmin, tmax, meanTime, meanAmp, sumAmp;	
139 140

	for(Int_t i = winMidSize; i < fNPoints - winMidSize; ++i) {
141
   		sumAmp = 0;
142 143 144 145 146 147 148
		tmin = 0;
		tmax = 0;
		meanTime = 0;
		meanAmp = 0;
    		for(Int_t j = i - winMidSize; j <= (i + winMidSize); ++j) {
			if (j == i - winMidSize) { tmin = fTime[j]; }
			if (j == i + winMidSize) { tmax = fTime[j]; }
149
      			sumAmp += fAmpPos[j];
150 151 152 153
    		}
		meanTime = (tmax - tmin)*0.5 + tmin;
		//cout<<"mean time "<<meant<<endl;

154
    		meanAmp = sumAmp / fWinSize;
155 156 157 158 159 160 161 162 163
		//cout<<"mean amp "<<fAmpPos[i]<<endl;

		fGraphSmooth->SetPoint(i, meanTime, meanAmp);
		
	}	

	return;
}

164
void AEvent::SetCFD() {
165

Muzalevsky I.A's avatar
Muzalevsky I.A committed
166
	Double_t time = 0;
167
	Double_t mytime = fCFtimeDelay;
168 169 170 171
	fGraphCFD->Set(fNPoints);

	//working variables
	Double_t maxCFD = 0., minCFD = 0.;
Muzalevsky I.A's avatar
Muzalevsky I.A committed
172
	Double_t TmaxCFD = 0., TminCFD = 0.;	
173 174
	Double_t ampCFD;
	const Double_t timeStep = 0.1;
175 176 177
	Int_t i = 0; //for graph 
 
	//while goes by the graph with the step of timeStep
178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197
	while( mytime < (200. - fCFtimeDelay) ) {

		ampCFD = fGraphSignal->Eval(mytime)*fCFratio*(-1) + fGraphSignal->Eval(mytime - fCFtimeDelay);
		fGraphCFD->SetPoint(i, mytime, ampCFD);

		//point for max CFD amplitude
		if( ampCFD > maxCFD) {
			maxCFD = ampCFD;
			TmaxCFD = mytime;
		}

		//point for min CFD amplitude
		if( ampCFD < minCFD) {
			minCFD = ampCFD;
			TminCFD = mytime;
		}

		i++;
		mytime = mytime + timeStep;
	}
198

199
	//looking for the first point with the closest values to 0 and writing to fTimeCFD
Muzalevsky I.A's avatar
Muzalevsky I.A committed
200
	time = TminCFD;
201
	while( (fGraphCFD->Eval(time) <= 0) && (time <= TmaxCFD) /*&& (time >= TminCFD)*/ ) {
Muzalevsky I.A's avatar
Muzalevsky I.A committed
202 203 204 205
		fTimeCFD = time;
		time = time + timeStep;
	}

Muzalevsky I.A's avatar
Muzalevsky I.A committed
206
}
Muzalevsky I.A's avatar
Muzalevsky I.A committed
207

208 209
void AEvent::FindFrontProperties() {

210 211 212 213 214
	//in percents
	const Double_t minHeight = 0.1;
	const Double_t maxHeight = 0.9;

	const Double_t timeStep = 0.05;	//in ns
215
	Double_t time = 0;			//in ns
216
	Double_t mytime = 0.;
217

218
	if (!fGraphSignal) {
219
		Warning("AEvent::FindFrontProperties", "Graph was not set");
220 221 222
		return;
	}

223
	//TODO search of minimum should be done from the lower edge on the time axis
224

225
	while (fGraphSignal->Eval(time) <= maxHeight*fAmpMax && time<200.) {
226
		fTime90 = time;
227 228 229 230 231 232
		time = time + timeStep;
	};

	time = fTime90;
	while( fGraphSignal->Eval(time) >= minHeight*fAmpMax && time>0) {
		fTime10 = time;
233
		time = time - timeStep;
234
	}
235

236
	TF1 *fit1 = new TF1("fit1","[1]*x+[0]");	//function for one parameter fitting in the range of pmin-pmax
237
	fit1->SetRange(fTime10,fTime90);
238

239
	fGraphSignal->Fit(fit1,"RQN","goff");
240

241
	fEdgeSlope = fit1->GetParameter(1);
242
	fEdgeXi = fit1->GetChisquare();
243

244 245
	fTimeMid = (fTime90 -fTime10)*0.5 + fTime10; 	//time point between fTime90 and fTime10

246 247 248 249 250 251 252 253 254 255 256 257 258 259 260 261 262 263
	//adding point where fit function crosses zero
	Double_t a = 0, b = 0;
	TF1 *line = new TF1("line","[1]*x + [0]");
	a = fit1->GetParameter(1);
	b = fit1->GetParameter(0);
	line->SetParameter(0,b);
	line->SetParameter(1,a);	
	//cout<<"par 0 "<<b<<endl;
	//cout<<"par 1 "<<a<<endl;

	if( a!= 0. && b!= 0. ) {	//in case of fit data is empty
		while(line->Eval(mytime) <= 0 && mytime <= 200.) {	
			//cout<< "mytime "<<mytime<<endl;
			fTimeFront = mytime;
			mytime = mytime + timeStep;
		}
	}

264 265
	delete fit1;
}
266

267
Double_t AEvent::FindZeroLevel() {
268 269 270

	SetGraphs();
	Double_t correction = 0;
271
	TF1 *fit1 = new TF1("fit1","[0]");	//function for one parameter fitting in the range of pmin-pmax
272
	fit1->SetRange(fNoiseRangeMin,fNoiseRangeMax);
273 274 275 276 277

	if (!fGraphSignal) {
		Warning("AEvent::FindZeroLevel", "Graph was not set");
		return 0;
	}
278

279 280
	fGraphSignal->Fit(fit1,"RQN","goff");
	correction = fit1->GetParameter(0);
281

282 283
	delete fit1;
	return correction;
284
}
285

286
void AEvent::SetChargeCFD(Int_t tmin, Int_t tmax) { // tmin = -3, tmax = 17
287
	
288 289 290 291
	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);
292

293
	/*for(Int_t i = 0; i < fNPoints; i++) {
294
		if( fTime[i] > (fTimeCFD + tmin) && fTime[i] < (fTimeCFD + tmax) ) {
295 296
			integral = integral + fAmpPos[i];
		}
297 298 299 300 301 302 303 304 305 306
	}*/

	Int_t imin = 0, imax = 0;

	Int_t i = 0;
	while ( fTime[i] < (fTimeCFD + tmin) && (i < (fGraphSignal->GetN()-1)) ) { imin = i; i++; }
	while ( fTime[i] < (fTimeCFD + tmax) && (i < (fGraphSignal->GetN()-1)) ) { imax = i; i++; }

	integral = fGraphSignal->Integral(imin, imax);

307
	fChargeCFD = integral*time_sig/res;
308 309 310 311 312

	return;

}

313 314 315 316 317 318 319 320 321 322 323 324 325 326 327 328 329
void AEvent::SetChargeLED(Int_t tmin, Int_t tmax) { // tmin = -3, tmax = 17
	
	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] > (fTimeLED + tmin) && fTime[i] < (fTimeLED + tmax) ) {
			integral = integral + fAmpPos[i];
		}
	}*/

	Int_t imin = 0, imax = 0;

	Int_t i = 0;
	while ( fTime[i] < (fTimeLED + tmin) && (i < (fGraphSignal->GetN()-1)) ) { imin = i; i++; }
330
//	i = 0;
331 332 333 334 335 336 337 338 339 340
	while ( fTime[i] < (fTimeLED + tmax) && (i < (fGraphSignal->GetN()-1)) ) { imax = i; i++; }

	integral = fGraphSignal->Integral(imin, imax);

	fChargeLED = integral*time_sig/res;

	return;

}

341 342 343 344 345 346 347 348 349 350 351 352 353 354 355 356 357 358 359 360 361 362
void AEvent::SetChargeTF(Int_t tmin, Int_t tmax) { // tmin = -3, tmax = 17
	
	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);

	Int_t imin = 0, imax = 0;

	Int_t i = 0;
	while ( fTime[i] < (fTimeFront + tmin) && (i < (fGraphSignal->GetN()-1)) ) { imin = i; i++; }
//	i = 0;
	while ( fTime[i] < (fTimeFront + tmax) && (i < (fGraphSignal->GetN()-1)) ) { imax = i; i++; }

	integral = fGraphSignal->Integral(imin, imax);

	fChargeTF = integral*time_sig/res;

	return;

}

Muzalevsky I.A's avatar
Muzalevsky I.A committed
363
Double_t AEvent::GetfCFD() {
364
		return fTimeCFD;
Muzalevsky I.A's avatar
Muzalevsky I.A committed
365 366
}

Muzalevsky I.A's avatar
Muzalevsky I.A committed
367 368 369 370
Double_t AEvent::GetfLED() {
		return fTimeLED;
}

Muzalevsky I.A's avatar
Muzalevsky I.A committed
371 372 373
Double_t AEvent::GetOnefTime(Int_t i) {
		return fTime[i];
}
374

Muzalevsky I.A's avatar
Muzalevsky I.A committed
375 376
Double_t AEvent::GetOnefAmpPos(Int_t i) {
		return fAmpPos[i];
377
}
378 379

Double_t AEvent::GetT_10() {
380
		return fTime10;
381 382 383
}

Double_t AEvent::GetT_90() {
384
		return fTime90;
385 386 387
}

Double_t AEvent::GetEdgeSlope() {
388 389
		return fEdgeSlope;
}
390

391 392 393 394
Double_t AEvent::GetEdgeXi() {
		return fEdgeXi;
}

395 396 397 398 399 400 401 402 403 404 405 406 407
void AEvent::SetMaxAmplitudes() {
	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;
408

409
}
410 411 412 413

void AEvent::SetLED(Double_t threshold) {
	
	Double_t time = 0;
414 415
	const Double_t timeStep = 0.05;
	while( time < fTimeAmpMax && fGraphSignal->Eval(time) <= threshold ) {
416 417 418
		fTimeLED = time;
		time = time + timeStep;
	}
419 420
	//fTimeLED = time; найти номера точек которые лежат на 3 нс раньше и на 20 нс позже чем точка с временем timeled (искать точки в пределах условных)
	// сделать через функцию getpoint и цикл по точкам от 
421 422

}