source: trunk/MagicSoft/Simulation/Detector/include-MFadc/MFadc.hxx@ 10107

Last change on this file since 10107 was 6714, checked in by moralejo, 20 years ago
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1#ifndef __MFadc__
2#define __MFadc__
3//
4// class MFadc
5//
6// implemented by Harald Kornmayer
7//
8// This is a class to simulate the FADC.
9// It assumes a special response of the PMT for one single Photo-electron.
10//
11//
12//
13#include <sstream>
14#include <math.h>
15
16#include "TObject.h"
17#include "TRandom.h"
18
19#include "Mdefine.h"
20
21#include "MTriggerDefine.h"
22#include "MFadcDefine.h"
23
24class MMcEvt;
25
26//==========
27// MFadc
28//
29// The simulation of the Flash ADC system for the MAGIC teleskop is done with
30// this class.
31// So all methods concerning the FADC System should be done inside this
32// class.
33//
34// The Idea is to (in)put the data of the photo electrons into the class and
35// generate the response (output) of the FADC to that input. Response means
36// in this sense the ADC values of the different time slices for all pixels
37//
38// The pixelisation is done by the camera program of Jose Carlos.
39//
40// This class is closly connected to the MTrigger classs. So some of the
41// values defined in MTriggerDefine.h are also used by this class.
42//
43// But a lot of other stuff is defined in MFadcDefine.h.
44//
45//
46
47
48class MFadc {
49 private:
50 Int_t numpix;
51 Int_t fInnerPixelsNum; // number of inner (small) pixels.
52 //
53 // then for all pixels the shape of all the analog signals
54 //
55 Bool_t used[CAMERA_PIXELS] ; // a boolean to indicated if the pixels is used in this event
56 Float_t pedestal[CAMERA_PIXELS] ; // Pedestal of FADCs
57
58 Int_t fSlices_mFadc; // Number of simulated FADC slices. Larger than the actual number of slices
59 // that will be written, since we have to account for possible delays in the
60 // trigger
61
62 Int_t fResponseSlicesFadc;
63
64 //
65 // Float_t sig[CAMERA_PIXELS][] ;
66 // the analog signal for pixels, in bins of width
67 // equal to the FADC slice: (default 50/15 ns), but with a
68 // total of fSlices_mFadc bins (default 48).
69 //
70 Float_t *sig[CAMERA_PIXELS];
71 Float_t *sig_LG[CAMERA_PIXELS];
72
73 Float_t *noise;
74 Float_t *noise_outer;
75 Float_t *digital_noise;
76
77 Float_t *output[CAMERA_PIXELS]; // the analog signal for pixels that is read after a trigger
78 // occurs (high gain).
79
80 Float_t *output_lowgain[CAMERA_PIXELS]; // analog signal, low gain.
81
82 Float_t high2low_gain;
83
84 //
85 // first the data for the response function
86 //
87 Int_t shape_resp; // index shape of the phe_response function
88 // = 0 --> Gaussian
89 // = 1 --> Pulpo set-up
90 Float_t fwhm_resp; // fwhm of the phe_response function (in ns)
91 Float_t integ_resp; // area below curve of the phe_response function (in counts * ns)
92 Float_t *sing_resp; // the shape of the phe_response function
93 Float_t *sing_resp_lowgain; // phe response for the low gain
94
95 Float_t fFadcSlicesPerNanosec; // Number of FADC slices per nanosecond, that is, the
96 // sampling frequency of the FADC.
97
98 Int_t fFadcSlices; // Number of FADC slices that will be written on the output
99 // file (same number for high and low gain)
100
101 //
102 // We may end up with a different reponse for the outer pixels
103 //
104 Int_t shape_resp_outer ; // index shape of the phe_response function
105 // = 0 --> Gaussian
106 // = 1 --> Pulpo set-up
107 Float_t fwhm_resp_outer ; // fwhm of the phe_response function (in ns)
108 Float_t integ_resp_outer; // area below curve of the phe_response function (in counts * ns)
109 Float_t *sing_resp_outer; // the shape of the phe_response function
110 Float_t *sing_resp_outer_lowgain; // phe response for the low gain
111
112 Int_t fGainSwitchAmp; // Height of the high gain signal (in ADC counts) at which we decide
113 // to fill the low gain with a scaled down version of the pulse in the
114 // high gain. Else we put in the continuation of the high gain.
115 // By default it is now 120 ADC counts (see constructor).
116
117 Int_t fShiftFromSwitch2LowGain;
118 // Distance in FADC slices from the slice in which the amplitude
119 // fGainSwitchAmp is reached to were the switch to low gain will happen.
120 // By default it is now 13 slices (see constructor)
121
122 Float_t fHi2LoGainPeak;
123 // Distance in FADC slices from the signal peak in the high gain to the signal peak in
124 // the low gain. By default we set now 16 slices (see constructor).
125
126 //
127 // RandomGenerator for the Electronic Noise
128 //
129
130 TRandom *GenElec ;
131
132 Float_t fadc_time_offset; // Time offset to adjust the delay between trigger
133 // and the peak position in the FADC of the signal
134 // in the trigger pixels.
135
136 Float_t fPulseParameters[7]; // Parameters for the parametrization of the real pulse shape
137 Float_t fPulseParametersLG[7]; // The same for low gain
138
139public:
140
141 MFadc(Int_t pix = 577,
142 Int_t shape = 0,
143 Float_t ampl = MFADC_RESPONSE_INTEGRAL,
144 Float_t fwhm = MFADC_RESPONSE_FWHM,
145 Int_t shapeout = 0,
146 Float_t amplout = MFADC_RESPONSE_INTEGRAL,
147 Float_t fwhmout = MFADC_RESPONSE_FWHM,
148 Float_t trig_delay = 0.,
149 Float_t fadc_slices_per_ns = FADC_SLICES_PER_NSEC,
150 Int_t fadc_slices_written = FADC_SLICES,
151 Int_t gainswitchamp = 120,
152 Int_t shiftfromswitch2lowgain = 13,
153 Float_t hi2logainpeak = 16.5);
154
155 void SetSeed(UInt_t seed) {GenElec->SetSeed(seed);}
156
157 void Reset() ;
158
159 void Fill( Int_t, Float_t, Float_t, Int_t ) ;
160
161 void Fill( Int_t, Float_t, Float_t ) ;
162
163 void FillOuter( Int_t, Float_t, Float_t ) ;
164
165 void AddSignal( Int_t iPix, Float_t *res);
166
167 void SetPedestals( Int_t ped);
168
169 void SetPedestals( Float_t *ped);
170
171 void SetShape( Int_t inner, Int_t outer){
172 shape_resp=inner;
173 shape_resp_outer=outer;
174 }
175
176 void SetFwhm( Float_t fwhm){
177 fwhm_resp=fwhm;
178 }
179
180 void SetInteg( Float_t x){
181 integ_resp=x;
182 }
183
184 void SetFwhmOuter( Float_t fwhm){
185 fwhm_resp_outer=fwhm;
186 }
187
188 void SetIntegOuter( Float_t x){
189 integ_resp_outer=x;
190 }
191
192
193 void Pedestals();
194
195 void SetElecNoise(Float_t value1=2.0, Float_t value2=2.0, UInt_t ninpix=CAMERA_PIXELS);
196
197 void ElecNoise();
198
199 void SetDigitalNoise(Float_t value=2.0);
200
201 void DigitalNoise() ;
202
203 void Scan() ;
204
205 void Scan(Float_t time) ;
206
207 void GetResponse( Float_t *resp ) ;
208
209 void GetPedestals( Float_t *offset);
210
211 Float_t GetPedestalNoise (Int_t pix, Int_t ishigh);
212
213 Float_t AddNoiseInSlices( Int_t pix, Int_t ishigh, Int_t n_slices);
214
215 void TriggeredFadc(Float_t time);
216
217 void ShowSignal ( MMcEvt *McEvt , Float_t ) ;
218
219 UChar_t GetFadcSignal(Int_t pixel, Int_t slice);
220
221 UChar_t GetFadcLowGainSignal(Int_t pixel, Int_t slice);
222
223 void SetHigh2LowGain(Float_t h2l) {high2low_gain=h2l;}
224
225 Int_t GetShape() {
226 return shape_resp;
227 }
228
229 Float_t GetIntegral() {
230 return integ_resp ;
231 }
232
233 Float_t GetFwhm() {
234 return fwhm_resp ;
235 }
236
237 Float_t GetIntegralOuter() {
238 return integ_resp_outer ;
239 }
240
241 Float_t GetFwhmOuter() {
242 return fwhm_resp_outer ;
243 }
244
245 Float_t GetFadcSlicesPerNanosec() {
246 return fFadcSlicesPerNanosec;
247 }
248
249 Int_t GetResponseSlicesFadc() {
250 return fResponseSlicesFadc;
251 }
252
253 Bool_t IsPixelUsed(UInt_t p){
254 return used[p];
255 }
256
257} ;
258
259
260#endif
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