1 | ////!////////////////////////////////////////////////////////////////////
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2 | //
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3 | // camera
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4 | //
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5 | // @file camera.cxx
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6 | // @title Camera simulation
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7 | // @subtitle Code for the simulation of the camera phase
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8 | // @desc Code for the simulation of the camera of CT1 and MAGIC
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9 | // @author J C Gonzalez, O Blanch, A Moralejo
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10 | // @email moralejo@pd.infn.it
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11 | // @email gonzalez@mppmu.mpg.de
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12 | // @email blanch@ifae.es
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13 | // @date Thu May 7 16:24:22 1998
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14 | //
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15 |
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16 | //=-----------------------------------------------------------
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17 | //!@section Source code of |camera.cxx|.
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18 |
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19 | //=-----------------------------------------------------------
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20 | //!@subsection Includes and Global variables definition.
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21 |
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22 | //!@{
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23 |
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24 | // includes for ROOT
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25 | // BEWARE: the order matters!
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26 |
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27 | #include "TROOT.h"
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28 |
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29 | #include "TRandom.h"
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30 | #include "TApplication.h"
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31 |
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32 | #include "TFile.h"
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33 | #include "TTree.h"
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34 | #include "TBranch.h"
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35 | #include "TCanvas.h"
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36 |
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37 | #include "TArrayC.h"
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38 | #include "TObjArray.h"
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39 |
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40 | #include "MTrigger.hxx"
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41 | #include "MFadc.hxx"
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42 | #include "MLons.hxx"
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43 |
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44 | #include "MRawRunHeader.h"
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45 | #include "MRawEvtData.h"
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46 | #include "MRawEvtHeader.h"
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47 | #include "MRawCrateArray.h"
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48 | #include "MRawCrateData.h"
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49 | #include "MMcEvt.hxx"
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50 | #include "MMcEvtBasic.h"
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51 | #include "MMcTrig.hxx"
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52 | #include "MMcRunHeader.hxx"
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53 | #include "MMcConfigRunHeader.h"
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54 | #include "MMcCorsikaRunHeader.h"
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55 | #include "MMcTrigHeader.hxx"
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56 | #include "MMcFadcHeader.hxx"
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57 | #include "MGeomCamMagic.h"
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58 | #include "MGeomCamMagic919.h"
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59 | #include "MGeomCamMagicHG.h"
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60 | #include "MGeomCamECO1000.h"
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61 | #include "MGeomCamECO1000HG.h"
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62 | #include "MGeomCamCT1.h"
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63 | #include "MGeomCamCT1Daniel.h"
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64 | #include "MGeomPix.h"
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65 | #include "MGeomCorsikaCT.h"
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66 | #include "MTriggerPattern.h"
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67 |
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68 | /*!@"
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69 |
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70 | All the defines are located in the file |camera.h|.
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71 |
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72 | @"*/
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73 |
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74 | #include "camera.h"
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75 |
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76 | //!@}
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77 |
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78 | /*!@"
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79 |
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80 | The following set of flags are used in time of compilation. They do
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81 | not affect directly the behaviour of the program at run-time
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82 | (though, of course, if you disconnected the option for
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83 | implementation of the Trigger logic, you will not be able to use any
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84 | trigger at all. The 'default' values mean default in the sense of
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85 | what you got from the server when you obtained this program.
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86 |
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87 | @"*/
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88 |
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89 | //!@{
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90 |
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91 | // flag for debugging (default: OFF )
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92 | #define __DEBUG__
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93 | #undef __DEBUG__
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94 |
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95 |
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96 | //!@}
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97 |
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98 | //=-----------------------------------------------------------
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99 | //!@subsection Definition of global variables.
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100 |
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101 | /*!@"
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102 |
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103 | Now we define some global variables with data about the telescope,
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104 | such as "focal distance", number of pixels/mirrors,
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105 | "size of the camera", and so on.
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106 |
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107 | @"*/
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108 |
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109 | /*!@"
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110 |
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111 | Depending on the telescope we are using (CT1 or MAGIC), the
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112 | information stored in the definition file is different.
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113 | The variable |ct_Type| has the value 0 when we use
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114 | CT1, and 1 when we use MAGIC.
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115 |
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116 | @"*/
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117 |
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118 | /*!@"
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119 |
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120 | And this is the information about the whole telescope.
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121 |
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122 | @"*/
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123 |
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124 | //!@{
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125 |
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126 | // parameters of the CT (from the CT definition file)
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127 |
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128 | //@: Number of pixels
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129 | static int ct_NPixels;
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130 |
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131 | //@: Number of CT
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132 | static int ct_Number;
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133 |
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134 | //@: list of showers to be skipped
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135 | static int *Skip;
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136 |
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137 | //@: number of showers to be skipped
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138 | static int nSkip=0;
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139 |
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140 | //@: flag: TRUE: data come from STDIN; FALSE: from file
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141 | static int Data_From_STDIN = FALSE;
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142 |
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143 | //@: flag: TRUE: write the event headers of all events to output;
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144 | //@: FALSE: only triggered showers
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145 | static int Write_All_Event_Headers = TRUE;
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146 |
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147 | static int Write_McEvt = TRUE;
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148 | static int Write_McTrig = TRUE;
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149 | static int Write_McFADC = TRUE;
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150 | static int Write_RawEvt = FALSE;
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151 |
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152 | //@: flag: TRUE: selection on the energy
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153 | static int Select_Energy = TRUE;
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154 |
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155 | //@: Lower edge of the selected energy range (in GeV)
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156 | static float Select_Energy_le = 0.0;
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157 |
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158 | //@: Upper edge of the selected energy range (in GeV)
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159 | static float Select_Energy_ue = 100000.0;
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160 |
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161 | //@: flag: TRUE: show all fadc singnal in the screen; FALSE: don't
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162 | static int FADC_Scan = FALSE;
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163 |
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164 | //@: flag: TRUE: show all trigger signal in the screen; FALSE: don't
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165 | static int Trigger_Scan = FALSE;
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166 |
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167 | //@: flag: TRUE: loop trigger analysis over several thresholds, multiplicities and topologies; FALSE: a single trigger configuration
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168 | static int Trigger_Loop = FALSE;
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169 |
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170 | //@: flag: TRUE: Different threshold for each pixel ; FALSE: same threshold for all pixels
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171 | static int Individual_Thres_Pixel = FALSE;
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172 |
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173 | //@: Properties of the trigger
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174 | static float Trigger_gate_length = 6.0;
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175 | static float Trigger_response_ampl = 1.0;
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176 | static float Trigger_response_fwhm = 2.0;
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177 | static float Trigger_overlaping_time= 0.25;
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178 | static float Trigger_noise= 0.3;
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179 |
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180 | //@: Properties of the FADC
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181 | static Int_t FADC_shape = 0;
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182 | static float FADC_response_integ = MFADC_RESPONSE_INTEGRAL;
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183 | static float FADC_response_fwhm = MFADC_RESPONSE_FWHM;
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184 | static Int_t FADC_shape_out = 0;
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185 | static float FADC_resp_integ_out = MFADC_RESPONSE_INTEGRAL;
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186 | static float FADC_resp_fwhm_out = MFADC_RESPONSE_FWHM;
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187 | static float FADC_slices_per_ns = FADC_SLICES_PER_NSEC;
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188 | static Int_t FADC_slices_written = FADC_SLICES;
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189 | static float FADC_noise_inner = 2.0;
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190 | static float FADC_noise_outer = 2.0;
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191 | static float DIGITAL_noise = 0.0;
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192 | static float FADC_high2low = HIGH2LOWGAIN;
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193 |
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194 | //@: Trigger conditions for a single trigger mode
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195 | static float **qThreshold;
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196 | static int Trigger_multiplicity[MAX_NUMBER_OF_CTS];
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197 | static int Trigger_topology[MAX_NUMBER_OF_CTS];
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198 |
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199 | //@: Upper and lower edges of the trigger loop
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200 | static float Trigger_loop_lthres = 2.0;
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201 | static float Trigger_loop_uthres = 10.0;
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202 | static float Trigger_loop_sthres = 1.0;
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203 | static int Trigger_loop_lmult = 2;
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204 | static int Trigger_loop_umult = 10;
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205 | static int Trigger_loop_ltop = 0;
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206 | static int Trigger_loop_utop = 2;
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207 |
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208 | //@: Direction of each shower
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209 | static float Zenith = 0.0;
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210 | static float Azimutal = 90.0;
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211 |
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212 | //@: Mispointing Simulation
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213 | static int missPointing = 0;
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214 | static float missP_x = 0.0;
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215 | static float missP_y = 0.0;
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216 |
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217 | //@: Point Spread Function Added
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218 | static float Spot_x=0.0;
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219 | static float Spot_y=0.0;
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220 | static float Spotsigma=0.0;
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221 |
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222 | //@: PMT time jitter
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223 | static float pmt_jitter;
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224 |
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225 |
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226 | //!@}
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227 |
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228 | /*!@"
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229 |
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230 | The following double-pointer is a 2-dimensional table with information
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231 | about each pixel. The routine read_pixels will generate
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232 | the information for filling it using igen_pixel_coordinates().
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233 |
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234 | @"*/
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235 |
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236 | //!@{
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237 | // Pointer to a tables/Arrays with information about the pixels
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238 | // and data stored on them with information about the pixels
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239 |
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240 |
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241 | //@: contents of the pixels (ph.e.)
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242 | static float *fnpix;
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243 |
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244 |
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245 | //!@}
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246 |
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247 | /*!@"
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248 |
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249 | The following double-pointer is a 2-dimensional table with the
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250 | Quantum Efficiency @$QE@$ of each pixel in the camera, as a function
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251 | of the wavelength @$\lambda@$. The routine |read_pixels()| will read
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252 | also this information from the file |qe.dat|.
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253 |
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254 | @"*/
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255 |
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256 | //!@{
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257 | // Pointer to a table with QE, number of datapoints, and wavelengths
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258 |
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259 | //@: table of QE
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260 | static float ****QE;
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261 |
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262 | //@: number of datapoints for the QE curve
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263 | static int pointsQE[MAX_NUMBER_OF_CTS];
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264 |
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265 | //@: table of QE
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266 | static float *QElambda;
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267 |
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268 | //@: table of lightguide = WC; WC_outer for outer pixels.
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269 | static float **WC;
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270 | static float **WC_outer;
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271 |
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272 | //@: number of datapoints for the WC curve
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273 | static int pointsWC;
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274 |
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275 | //!@}
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276 |
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277 | /*!@"
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278 |
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279 | The following double-pointer is a 2-dimensional table with information
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280 | about each mirror in the dish. The routine |read_ct_file()| will read
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281 | this information from the CT definition file.
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282 |
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283 | @"*/
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284 |
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285 | /*!@"
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286 |
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287 | We define a table into where random numbers will be stored.
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288 | The routines used for random number generation are provided by
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289 | |RANLIB| (taken from NETLIB, |www.netlib.org|), and by
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290 | the routine |double drand48(void)| (prototype defined in
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291 | |stdlib.h|) through the macro |RandomNumber| defined in
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292 | |camera.h|.
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293 |
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294 | @"*/
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295 |
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296 |
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297 | //!@}
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298 |
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299 | extern char FileName[];
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300 | // switch on starfield rotation
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301 | static int Starfield_rotate = TRUE;
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302 |
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303 | //=-----------------------------------------------------------
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304 | // @subsection Main program.
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305 |
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306 | //!@{
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307 |
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308 | //++++++++++++++++++++++++++++++++++++++++
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309 | // MAIN PROGRAM
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310 | //----------------------------------------
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311 |
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312 | int main(int argc, char **argv)
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313 | {
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314 |
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315 | //!@' @#### Definition of variables.
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316 | //@'
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317 |
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318 | char **inname_CT; //@< array of names for each CT input file
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319 | char starfieldname[256]; //@< starfield input file name
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320 | char qe_filename[256]; //@< qe input file name
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321 |
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322 | char datname[256]; //@< data (ASCII) output file name
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323 |
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324 | char rootname[256] ; //@< ROOT file name
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325 | char rootname_loop[256] ; //@< ROOT file name
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326 |
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327 | char parname[256]; //@< parameters file name
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328 |
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329 | char nsbpathname[256]; //@< directory with the dataabse for th NSB
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330 | char nsbpath_outer[256]; //@< directory with the dataabse for outer pixels
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331 |
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332 | char flag[SIZE_OF_FLAGS + 1]; //@< flags in the .rfl file
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333 | char flag_new[SIZE_OF_FLAGS + 1]; //@< New flag for the run header in the .rfl file
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334 | char **GeometryName; //@< Name of MGeomCam for each CT
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335 | int GeometryCamera[MAX_NUMBER_OF_CTS]; //@< Identification of MGeomCam for each CT
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336 | int TriggerPixels[MAX_NUMBER_OF_CTS]; //@< Number of pixels in the trigger region for each CT
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337 |
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338 | int reflector_file_version=0; //@< vrsion of he reflector file
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339 |
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340 | FILE *inputfile[MAX_NUMBER_OF_CTS]; //@< stream for the input file
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341 |
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342 | ofstream datafile; //@< stream for the data file
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343 |
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344 | MCRunHeader mcrunh; //@< Run Header class (MC)
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345 | MCEventHeader mcevth[MAX_NUMBER_OF_CTS]; //@< Event Header class (MC)
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346 | MCEventHeader_2 mcevth_2[MAX_NUMBER_OF_CTS]; //@< Event Header class (MC) for reflector > 0.6
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347 | MCCphoton cphoton; //@< Cherenkov Photon class (MC)
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348 |
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349 | int inumphe; //@< number of photoelectrons in an event from showers
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350 | int inumphe_CT[MAX_NUMBER_OF_CTS]; //@< number of photoelectrons in an event from showers
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351 | float inumphensb[MAX_NUMBER_OF_CTS]; //@< number of photoelectrons in an event from nsb
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352 |
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353 | float arrtmin_ns; //@ arrival time of the first photoelectron
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354 | float arrtmax_ns; //@ arrival time of the last photoelectron
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355 |
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356 | float thetaCT[MAX_NUMBER_OF_CTS], phiCT[MAX_NUMBER_OF_CTS]; //@< theta and phi of telescopes
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357 |
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358 | //@: Coordinates of telescopes in Corsika's coordinate system
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359 | float CTx[MAX_NUMBER_OF_CTS];
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360 | float CTy[MAX_NUMBER_OF_CTS];
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361 | float CTz[MAX_NUMBER_OF_CTS];
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362 |
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363 | float mirror_frac[MAX_NUMBER_OF_CTS];
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364 |
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365 | float thetashw, phishw; //@< parameters of a given shower
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366 | float coreX, coreY; //@< core position
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367 | float impactD[MAX_NUMBER_OF_CTS]; //@< impact parameter
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368 | float l1, m1, n1; //@< auxiliary variables
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369 | float factorqe_NSB[MAX_NUMBER_OF_CTS]; //@< factor on the NSB depending of QE
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370 |
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371 | int nshow=0; //@< partial number of shower in a given run
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372 | int ntshow=0; //@< total number of showers
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373 | int ncph[MAX_NUMBER_OF_CTS]; //@< partial number of photons in a given run
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374 | int ntcph[MAX_NUMBER_OF_CTS]; //@< total number of photons
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375 |
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376 | int ibr, j, k; //@< simple counters
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377 |
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378 | int addElecNoise; //@< Will we add ElecNoise?
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379 |
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380 | float riseDiskThres;
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381 | float secureDiskThres;
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382 |
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383 | int simulateNSB; //@< Will we simulate NSB?
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384 | int nphe2NSB; //@< From how many phe will we simulate NSB?
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385 | float meanNSB; //@< diffuse NSB mean value (phe per ns per central pixel)
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386 | float **diffnsb_phepns;
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387 | //@< diffuse NSB values for each pixel derived from meanNSB
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388 |
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389 | float **nsbrate_phepns; //@< non-diffuse nsb
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390 | //@< photoelectron rates
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391 | float **nsb_phepns;
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392 | //@< NSB values for each pixel
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393 |
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394 | float **nsb_phepns_rotated;
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395 | //@< NSB values for each pixel after rotation
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396 |
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397 | Float_t nsb_trigresp[TRIGGER_TIME_SLICES]; //@< array to write the trigger
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398 | //@< response from the database
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399 | Float_t *nsb_fadcresp; //@< array to write the fadc
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400 | //@< response from the database
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401 | Byte_t trigger_map[((Int_t)(CAMERA_PIXELS/8))+1]; //@< Pixels on when the
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402 | //@< camera triggers
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403 | Float_t fadc_elecnoise[CAMERA_PIXELS]; //@< Electronic noise for each pixel
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404 | Float_t fadc_diginoise[CAMERA_PIXELS]; //@< Digital noise for each pixel
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405 | Float_t fadc_pedestals[CAMERA_PIXELS]; //@< array for fadc pedestals values
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406 | Float_t fadc_sigma[CAMERA_PIXELS]; //@< array for fadc pedestals sigma
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407 | Float_t fadc_sigma_low[CAMERA_PIXELS]; //@< array for fadc pedestals sigma
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408 |
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409 | float ext[iNUMWAVEBANDS] = { //@< average atmospheric extinction in each waveband
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410 | EXTWAVEBAND1,
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411 | EXTWAVEBAND2,
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412 | EXTWAVEBAND3,
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413 | EXTWAVEBAND4,
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414 | EXTWAVEBAND5
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415 | };
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416 | float zenfactor=1.0; // correction factor calculated from the extinction
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417 |
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418 | int nstoredevents = 0;
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419 | int flagstoring = 0;
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420 |
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421 | int ntrigger[MAX_NUMBER_OF_CTS]; //@< number of triggers in the whole file
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422 | int btrigger = 0; //@< trigger flag
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423 | int ithrescount; //@< counter for loop over threshold trigger
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424 | float fthrescount; //@< value for loop over threshold trigger
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425 | int imulticount; //@< counter for loop over multiplicity trigger
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426 | int itopocount; //@< counter for loop over topology trigger
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427 | int isorttopo[3]; //@< sorting the topologies
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428 | int icontrigger; //@< number of trigger conditions to be analised
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429 |
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430 | float fpixelthres[CAMERA_PIXELS]; //@< Threshold values
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431 |
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432 | TArrayC *fadcValues; //@< the analog Fadc High gain signal for pixels
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433 | TArrayC *fadcValuesLow; //@< the analog Fadc Low gain signal for pixels
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434 |
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435 | int still_in_loop = FALSE;
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436 |
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437 | //@< Variables to fill the McRunHeader
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438 | Int_t sfRaH = 5;
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439 | Int_t sfRaM = 34;
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440 | Int_t sfRaS = 32;
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441 | Int_t sfDeD = 22;
|
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442 | Int_t sfDeM = 00;
|
---|
443 | Int_t sfDeS = 52;
|
---|
444 | Float_t shthetamax = 0.0;
|
---|
445 | Float_t shthetamin = 0.0;
|
---|
446 | Float_t shphimax = 0.0;
|
---|
447 | Float_t shphimin = 0.0;
|
---|
448 | UInt_t corsika = 5200 ;
|
---|
449 | Float_t maxpimpact = 0.0;
|
---|
450 |
|
---|
451 | // Star Field Rotation variables
|
---|
452 | Float_t zenith = 0.0;
|
---|
453 | Float_t azimutal = 90.0;
|
---|
454 | Float_t rho , C3 , C2 , C1;
|
---|
455 |
|
---|
456 | //!@' @#### Definition of variables for |getopt()|.
|
---|
457 | //@'
|
---|
458 |
|
---|
459 | int ch, errflg = 0; //@< used by getopt
|
---|
460 |
|
---|
461 | //!@' @#### Initialisation of some variables
|
---|
462 | //@'
|
---|
463 |
|
---|
464 | inname_CT = new char *[MAX_NUMBER_OF_CTS];
|
---|
465 | GeometryName = new char *[MAX_NUMBER_OF_CTS];
|
---|
466 | diffnsb_phepns = new float *[MAX_NUMBER_OF_CTS];
|
---|
467 | nsb_phepns = new float *[MAX_NUMBER_OF_CTS];
|
---|
468 | nsb_phepns_rotated = new float *[MAX_NUMBER_OF_CTS];
|
---|
469 |
|
---|
470 | for(int i=0;i<MAX_NUMBER_OF_CTS;i++)
|
---|
471 | {
|
---|
472 | inname_CT[i] = new char[256];
|
---|
473 | GeometryName[i] = new char[50];
|
---|
474 | diffnsb_phepns[i] = new float[iMAXNUMPIX];
|
---|
475 | nsb_phepns[i] = new float[iMAXNUMPIX];
|
---|
476 | nsb_phepns_rotated[i] = new float[iMAXNUMPIX];
|
---|
477 | CTx[i] = 0.; CTy[i] = 0.; CTz[i] = 0.;
|
---|
478 | }
|
---|
479 |
|
---|
480 | nsbrate_phepns = new float *[iMAXNUMPIX];
|
---|
481 | for(int i=0;i<iMAXNUMPIX;i++)
|
---|
482 | nsbrate_phepns[i] = new float[iNUMWAVEBANDS];
|
---|
483 |
|
---|
484 | qThreshold = new float *[MAX_NUMBER_OF_CTS];
|
---|
485 | for(int i=0;i<MAX_NUMBER_OF_CTS;i++)
|
---|
486 | qThreshold[i] = new float [CAMERA_PIXELS];
|
---|
487 |
|
---|
488 | for(int i=0;i<iMAXNUMPIX;i++){
|
---|
489 | for(int ict=0;ict<MAX_NUMBER_OF_CTS;ict++){
|
---|
490 | nsb_phepns[ict][i]=0;
|
---|
491 | nsb_phepns_rotated[ict][i]=0;
|
---|
492 | }
|
---|
493 | for(j=0;j<iNUMWAVEBANDS;j++)
|
---|
494 | nsbrate_phepns[i][j]=0.0; //@< Starlight rates initialised at 0.0
|
---|
495 | }
|
---|
496 | for(int i=0;i<MAX_NUMBER_OF_CTS;i++)
|
---|
497 | ntcph[i]=0;
|
---|
498 | /*!@'
|
---|
499 |
|
---|
500 | @#### Beginning of the program.
|
---|
501 |
|
---|
502 | We start with the main program. First we (could) make some
|
---|
503 | presentation, and follows the reading of the parameters file (now
|
---|
504 | from the |stdin|), the reading of the CT parameters file, and the
|
---|
505 | creation of the output file, where the processed data will be
|
---|
506 | stored.
|
---|
507 |
|
---|
508 | */
|
---|
509 |
|
---|
510 | //++
|
---|
511 | // START
|
---|
512 | //--
|
---|
513 |
|
---|
514 | // make unbuffered output
|
---|
515 |
|
---|
516 | // cout.setf ( ios::stdio );
|
---|
517 |
|
---|
518 | // parse command line options (see reflector.h)
|
---|
519 |
|
---|
520 | parname[0] = '\0';
|
---|
521 |
|
---|
522 | optarg = NULL;
|
---|
523 | while ( !errflg && ((ch = getopt(argc, argv, COMMAND_LINE_OPTIONS)) != -1) )
|
---|
524 | switch (ch) {
|
---|
525 | case 'f':
|
---|
526 | strcpy(parname, optarg);
|
---|
527 | break;
|
---|
528 | case 'h':
|
---|
529 | usage();
|
---|
530 | break;
|
---|
531 | default :
|
---|
532 | errflg++;
|
---|
533 | }
|
---|
534 |
|
---|
535 | // show help if error
|
---|
536 |
|
---|
537 | if ( errflg>0 )
|
---|
538 | usage();
|
---|
539 |
|
---|
540 | // make some sort of presentation
|
---|
541 |
|
---|
542 | present();
|
---|
543 |
|
---|
544 | // read parameters file
|
---|
545 |
|
---|
546 | if ( strlen(parname) < 1 )
|
---|
547 | readparam(NULL);
|
---|
548 | else
|
---|
549 | readparam(parname);
|
---|
550 |
|
---|
551 | // read data from file or from STDIN?
|
---|
552 |
|
---|
553 | Data_From_STDIN = get_data_from_stdin();
|
---|
554 |
|
---|
555 | // get number of telescopes and camera geometries
|
---|
556 |
|
---|
557 | ct_Number=get_ct_number();
|
---|
558 | if (ct_Number > MAX_NUMBER_OF_CTS)
|
---|
559 | {
|
---|
560 | error( SIGNATURE, "Number of telescopes is larger than maximum allowed (%i). Stoping camera program ...", MAX_NUMBER_OF_CTS);
|
---|
561 | exit(1);
|
---|
562 | }
|
---|
563 |
|
---|
564 | for(int ict=0;ict<ct_Number;ict++){
|
---|
565 | ntrigger[ict]=0;
|
---|
566 | GeometryCamera[ict]=get_ct_geometry(ict);
|
---|
567 |
|
---|
568 | //
|
---|
569 | // Get telescope coordinates (if supplied) from input card (units cm).
|
---|
570 | //
|
---|
571 | CTx[ict] = get_telescope_location_cm(ict,0);
|
---|
572 | CTy[ict] = get_telescope_location_cm(ict,1);
|
---|
573 | CTz[ict] = get_telescope_location_cm(ict,2);
|
---|
574 |
|
---|
575 | //
|
---|
576 | // Get fraction of operative mirror:
|
---|
577 | //
|
---|
578 | mirror_frac[ict] = get_mirror_fraction(ict);
|
---|
579 | }
|
---|
580 |
|
---|
581 | // structure holding the camera definition
|
---|
582 |
|
---|
583 | TObjArray camgeom;
|
---|
584 |
|
---|
585 | for (int i=0; i<ct_Number;i++){
|
---|
586 | switch(GeometryCamera[i]){
|
---|
587 | case 1: camgeom[i]=new MGeomCamMagic;
|
---|
588 | strcpy(GeometryName[i],"MGeomCamMagic");
|
---|
589 | TriggerPixels[i]=TRIGGER_PIXELS_1;
|
---|
590 | break;
|
---|
591 | case 2: camgeom[i]=new MGeomCamMagic919;
|
---|
592 | strcpy(GeometryName[i],"MGeomCamMagic919");
|
---|
593 | TriggerPixels[i]=TRIGGER_PIXELS_2;
|
---|
594 | break;
|
---|
595 | case 3: camgeom[i]=new MGeomCamMagicHG;
|
---|
596 | strcpy(GeometryName[i],"MGeomCamMagicHG");
|
---|
597 | TriggerPixels[i]=TRIGGER_PIXELS_3;
|
---|
598 | break;
|
---|
599 | case 5: camgeom[i]=new MGeomCamECO1000;
|
---|
600 | strcpy(GeometryName[i],"MGeomCamECO1000");
|
---|
601 | TriggerPixels[i]=TRIGGER_PIXELS_5;
|
---|
602 | break;
|
---|
603 | case 6: camgeom[i]=new MGeomCamECO1000HG;
|
---|
604 | strcpy(GeometryName[i],"MGeomCamECO1000HG");
|
---|
605 | TriggerPixels[i]=TRIGGER_PIXELS_6;
|
---|
606 | break;
|
---|
607 | case 8: camgeom[i]=new MGeomCamCT1;
|
---|
608 | strcpy(GeometryName[i],"MGeomCamCT1");
|
---|
609 | TriggerPixels[i]=TRIGGER_PIXELS_8;
|
---|
610 | break;
|
---|
611 | case 9: camgeom[i]=new MGeomCamCT1Daniel;
|
---|
612 | strcpy(GeometryName[i],"MGeomCamCT1Daniel");
|
---|
613 | TriggerPixels[i]=TRIGGER_PIXELS_9;
|
---|
614 | break;
|
---|
615 | default:
|
---|
616 | error( SIGNATURE, "Camera geometry %i is not defined. Stoping camera program ...", GeometryCamera[i]);
|
---|
617 | exit(1);
|
---|
618 | break;
|
---|
619 | }
|
---|
620 | }
|
---|
621 |
|
---|
622 | ct_NPixels=0;
|
---|
623 |
|
---|
624 | for(int ict=0;ict<ct_Number;ict++)
|
---|
625 | ct_NPixels=(((MGeomCam*)(camgeom.UncheckedAt(ict)))->GetNumPixels()>(UInt_t)ct_NPixels)?
|
---|
626 | (Int_t)((MGeomCam*)(camgeom.UncheckedAt(ict)))->GetNumPixels():
|
---|
627 | ct_NPixels;
|
---|
628 |
|
---|
629 | // read WC and QE files
|
---|
630 |
|
---|
631 | // FIX ME !
|
---|
632 | // Currently the PMT N of any camera with same average QE has the same QE.
|
---|
633 |
|
---|
634 | QE = new float *** [ct_Number];
|
---|
635 | for(int ict=0;ict<ct_Number;ict++){
|
---|
636 | strcpy( qe_filename, get_qe_filename(ict));
|
---|
637 | read_QE(qe_filename,ict);
|
---|
638 | }
|
---|
639 |
|
---|
640 | read_WC();
|
---|
641 |
|
---|
642 | // write all images, even those without trigger?
|
---|
643 |
|
---|
644 | Write_All_Event_Headers = get_write_all_event_headers();
|
---|
645 |
|
---|
646 | Write_McEvt = get_write_McEvt() ;
|
---|
647 | Write_McTrig = get_write_McTrig() ;
|
---|
648 | Write_McFADC = get_write_McFadc() ;
|
---|
649 | Write_RawEvt = get_write_RawEvt() ;
|
---|
650 |
|
---|
651 | FADC_Scan = get_FADC_Scan();
|
---|
652 | Trigger_Scan = get_Trigger_Scan();
|
---|
653 |
|
---|
654 | Individual_Thres_Pixel = get_indi_thres_pixel();
|
---|
655 |
|
---|
656 | get_secure_threhold(&riseDiskThres,&secureDiskThres);
|
---|
657 |
|
---|
658 | get_FADC_properties
|
---|
659 | (&FADC_shape, &FADC_response_integ, &FADC_response_fwhm,
|
---|
660 | &FADC_shape_out, &FADC_resp_integ_out, &FADC_resp_fwhm_out,
|
---|
661 | &FADC_slices_per_ns, &FADC_slices_written);
|
---|
662 |
|
---|
663 | // Allocate memory for the NSB contribution to the FADC signal:
|
---|
664 | nsb_fadcresp = new Float_t[(Int_t)(FADC_slices_per_ns*TOTAL_TRIGGER_TIME)];
|
---|
665 |
|
---|
666 | FADC_high2low=get_High_to_Low();
|
---|
667 |
|
---|
668 | // FIXME --- trigger properties may depend on the Camera geometry
|
---|
669 |
|
---|
670 | get_Trigger_properties( &Trigger_gate_length, &Trigger_overlaping_time, &Trigger_response_ampl, &Trigger_response_fwhm);
|
---|
671 |
|
---|
672 | Trigger_Loop = get_Trigger_Loop(&Trigger_loop_lthres, &Trigger_loop_uthres, &Trigger_loop_sthres, &Trigger_loop_lmult, &Trigger_loop_umult, &Trigger_loop_ltop, &Trigger_loop_utop);
|
---|
673 |
|
---|
674 | icontrigger =((int)((Trigger_loop_uthres-Trigger_loop_lthres)
|
---|
675 | /Trigger_loop_sthres)+1)*
|
---|
676 | (Trigger_loop_umult-Trigger_loop_lmult+1)*
|
---|
677 | (Trigger_loop_utop-Trigger_loop_ltop+1);
|
---|
678 |
|
---|
679 | // Trigger loop operation is not implemented for Multi telescopes
|
---|
680 |
|
---|
681 | if ( Trigger_Loop && ct_Number > 1 ){
|
---|
682 | cout<<"ERROR : camera::main : Trigger loop option is not";
|
---|
683 | cout<<" implemented for Multi Telescopes option. "<<icontrigger<<
|
---|
684 | " "<<ct_Number<<endl;
|
---|
685 | exit(1);
|
---|
686 | }
|
---|
687 |
|
---|
688 | if (!Trigger_Loop){
|
---|
689 | get_Trigger_Single (qThreshold,
|
---|
690 | &Trigger_multiplicity[0],
|
---|
691 | &Trigger_topology[0]);
|
---|
692 | icontrigger=1;
|
---|
693 | }
|
---|
694 | else
|
---|
695 | get_threshold(qThreshold[0]);
|
---|
696 |
|
---|
697 | // get filenames
|
---|
698 |
|
---|
699 | if (! is_calibration_run())
|
---|
700 | for(int ict=0;ict<ct_Number;ict++)
|
---|
701 | {
|
---|
702 | strcpy( inname_CT[ict], get_input_filename(ict) );
|
---|
703 | if (strlen(inname_CT[ict]) == 0)
|
---|
704 | {
|
---|
705 | printf("\nError: missing input file name for CT id = %d. Exiting.\n\n", ict);
|
---|
706 | exit(1);
|
---|
707 | }
|
---|
708 | }
|
---|
709 |
|
---|
710 | strcpy( starfieldname, get_starfield_filename() );
|
---|
711 | strcpy( datname, get_data_filename() );
|
---|
712 | strcpy( rootname, get_root_filename() );
|
---|
713 | strcpy( rootname_loop, get_loop_filename() );
|
---|
714 | strcpy( nsbpathname, get_nsb_directory() );
|
---|
715 | strcpy( nsbpath_outer, get_nsb_directory_outer() );
|
---|
716 |
|
---|
717 | // get different parameters of the simulation
|
---|
718 |
|
---|
719 | addElecNoise = add_elec_noise(&FADC_noise_inner, &FADC_noise_outer, &DIGITAL_noise, &Trigger_noise);
|
---|
720 | simulateNSB = get_nsb( &meanNSB, &nphe2NSB );
|
---|
721 | missPointing = get_misspointing(&missP_x,&missP_y);
|
---|
722 | Spotsigma = get_sigma_xy_cm_spot(&Spot_x,&Spot_y);
|
---|
723 | pmt_jitter = get_pmt_jitter_ns();
|
---|
724 |
|
---|
725 |
|
---|
726 | // get selections on the parameters
|
---|
727 |
|
---|
728 | Select_Energy = get_select_energy( &Select_Energy_le, &Select_Energy_ue);
|
---|
729 |
|
---|
730 | //Parameters for starfield rotation
|
---|
731 |
|
---|
732 | Starfield_rotate = get_starfield_rotate();
|
---|
733 |
|
---|
734 | // log filenames information
|
---|
735 | for(Int_t ict=0;ict<ct_Number;ict++){
|
---|
736 |
|
---|
737 | log(SIGNATURE,"\t%s : %i\n\t%20s:\t%s\n",
|
---|
738 | "------- TELESCOPE ",ict+1,
|
---|
739 | "Geometry ", GeometryName[ict]);
|
---|
740 | strcpy( qe_filename, get_qe_filename(ict));
|
---|
741 |
|
---|
742 | printf("Telescope coordinates (cm): %.1f %.1f %.1f\n", CTx[ict], CTy[ict], CTz[ict]);
|
---|
743 |
|
---|
744 | // Look to factor for NSB respect to emi_coat PMTs
|
---|
745 | if(strstr(qe_filename,"qe-emi-coat.RFL.dat") != 0)
|
---|
746 | factorqe_NSB[ict]=EMICOAT_NSB;
|
---|
747 | else if(strstr(qe_filename,"qe-emi.RFL.dat") != 0)
|
---|
748 | factorqe_NSB[ict]=EMI_NSB;
|
---|
749 | else if(strstr(qe_filename, "qe-intevac_hpd.RFL.dat") != 0)
|
---|
750 | factorqe_NSB[ict]=HPD_INTEVAC_NSB;
|
---|
751 | else if(strstr(qe_filename, "qe-hamamatsu_hpd.RFL.dat") != 0)
|
---|
752 | factorqe_NSB[ict]=HPD_HAMAMATSU_NSB;
|
---|
753 | else{
|
---|
754 | log(SIGNATURE,"\n\nWARNING!! : the factor for the diffuse NSB for this QE file (%s) is not known to the camera simulation. The number of phe(ns stated in the inputcard will be used.\n\n",qe_filename);
|
---|
755 | factorqe_NSB[ict]=1.0;
|
---|
756 | }
|
---|
757 | log(SIGNATURE,
|
---|
758 | "%s:\n\t%20s:\t%s\n\t%20s:\t%s\n\t%20s\n\t%20s:\t%s\n\t%20s:\t%s\n\t%20s:\t%s\n\t%20s:\t%s\n\t%20s:\t%s\n",
|
---|
759 | "Filenames",
|
---|
760 | "In", inname_CT[ict],
|
---|
761 | "Stars", starfieldname,
|
---|
762 | "NSB database","(inner pixels)", nsbpathname,
|
---|
763 | "(outer pixels)", nsbpath_outer,
|
---|
764 | "QE", qe_filename,
|
---|
765 | "Data", datname,
|
---|
766 | "ROOT", rootname
|
---|
767 | );
|
---|
768 |
|
---|
769 | // log parameters information
|
---|
770 |
|
---|
771 | log(SIGNATURE,
|
---|
772 | "%s:\n\t%20s: %f: %s\n\t%20s: %f\n\t%20s: %f\n",
|
---|
773 | "Parameters",
|
---|
774 | "NSB (phes/ ns 0.1*0.1 deg^2 239 m^2)", meanNSB*factorqe_NSB[ict], ONoff(simulateNSB),
|
---|
775 | "Pedestals = ", get_FADC_pedestal(),
|
---|
776 | "High to Low gain = ", FADC_high2low
|
---|
777 | );
|
---|
778 |
|
---|
779 | // log Trigger information
|
---|
780 |
|
---|
781 | if (Trigger_Loop) {
|
---|
782 | log(SIGNATURE,
|
---|
783 | "%s:\n\t%20s: from %5.2f to %5.2f by %5.2f step\n\t%20s: %i - %i\n\t%20s: %i - %i\n\t%20s\n",
|
---|
784 | "Trigger Loop mode",
|
---|
785 | "Threshold",Trigger_loop_lthres,Trigger_loop_uthres,Trigger_loop_sthres,
|
---|
786 | "Multiplicity",Trigger_loop_lmult,Trigger_loop_umult,
|
---|
787 | "Topology",Trigger_loop_ltop,Trigger_loop_utop,
|
---|
788 | rootname_loop);
|
---|
789 | }
|
---|
790 | else if (Individual_Thres_Pixel == FALSE){
|
---|
791 | log(SIGNATURE,
|
---|
792 | "%s:\n\t%20s: %f\n\t%20s: %i\n\t%20s: %i\n",
|
---|
793 | "Single Trigger mode",
|
---|
794 | "Threshold",qThreshold[ict][0],
|
---|
795 | "Multiplicity",Trigger_multiplicity[ict],
|
---|
796 | "Topology",Trigger_topology[ict]);
|
---|
797 | }
|
---|
798 | else{
|
---|
799 | log(SIGNATURE,
|
---|
800 | "%s:\n\t%20s: %s\n\t%20s: %i\n\t%20s: %i\n",
|
---|
801 | "Single Trigger mode",
|
---|
802 | "Threshold","Different for each pixel",
|
---|
803 | "Multiplicity",Trigger_multiplicity[ict],
|
---|
804 | "Topology",Trigger_topology[ict]);
|
---|
805 | }
|
---|
806 | log(SIGNATURE,"\t%s\n",
|
---|
807 | "END TELESCOPE --------");
|
---|
808 | }
|
---|
809 | // log flags information
|
---|
810 |
|
---|
811 | log(SIGNATURE,
|
---|
812 | "%s:\n\t%23s: %s\n\t%23s: %s\n\t%23s: %s\n\t%23s: %s\n\t\t %s %3.2f,\n\t\t %s %3.2f (%s), %3.2f (%s) \n\t\t + %3.2f (%s)\n\n",
|
---|
813 | "Flags",
|
---|
814 | "Data_From_STDIN", ONoff(Data_From_STDIN),
|
---|
815 | "Write_All_Event_Headers", ONoff(Write_All_Event_Headers),
|
---|
816 | "Rotate Starfield", ONoff(Starfield_rotate),
|
---|
817 | "Electronic Noise", ONoff(addElecNoise),
|
---|
818 | "Trigger noise (amplitude relative to that of single phe): ",
|
---|
819 | Trigger_noise,
|
---|
820 | "FADC noise (ADC counts): ", FADC_noise_inner, "inner p.",
|
---|
821 | FADC_noise_outer, "outer p.",
|
---|
822 | DIGITAL_noise, "added digital noise at FADC"
|
---|
823 | );
|
---|
824 |
|
---|
825 | if (! apply_gain_fluctuations())
|
---|
826 | {
|
---|
827 | log(SIGNATURE, "PMT gain fluctuations for the signal phes have been switched OFF");
|
---|
828 | log(SIGNATURE, "in the input card.\n\n");
|
---|
829 | }
|
---|
830 | if (! apply_noise_gain_fluctuations())
|
---|
831 | {
|
---|
832 | log(SIGNATURE, "PMT gain fluctuations for the NSB phes have been switched OFF\n");
|
---|
833 | log(SIGNATURE, "in the input card.\n\n");
|
---|
834 | }
|
---|
835 |
|
---|
836 | if ( apply_gain_fluctuations() && !apply_noise_gain_fluctuations())
|
---|
837 | {
|
---|
838 | log(SIGNATURE, "Warning: you switched off PMT gain fluctuations for the NSB\n");
|
---|
839 | log(SIGNATURE, "photoelectrons, but not for the signal photoelectrons.\n\n");
|
---|
840 | }
|
---|
841 | else if ( !apply_gain_fluctuations() && apply_noise_gain_fluctuations())
|
---|
842 | {
|
---|
843 | log(SIGNATURE, "Warning: you switched off PMT gain fluctuations for the signal\n");
|
---|
844 | log(SIGNATURE, "photoelectrons, but not for the NSB photoelectrons.\n");
|
---|
845 | }
|
---|
846 |
|
---|
847 |
|
---|
848 | // log flags information
|
---|
849 |
|
---|
850 | log(SIGNATURE,
|
---|
851 | "%s:\n\t%20s: %s\n\t%20s: %s\n\t%20s: %s\n\t%20s: %s\n",
|
---|
852 | "Root output",
|
---|
853 | "Write_McEvt", ONoff(Write_McEvt),
|
---|
854 | "Write_McTrig", ONoff(Write_McTrig),
|
---|
855 | "Write_McFADC", ONoff(Write_McFADC),
|
---|
856 | "Write_RawEvt", ONoff(Write_RawEvt));
|
---|
857 |
|
---|
858 | // log selections
|
---|
859 |
|
---|
860 | log(SIGNATURE,
|
---|
861 | "%s:\n\t%20s: %s (%f:%f)\n",
|
---|
862 | "Selections:",
|
---|
863 | "Energy", ONoff(Select_Energy), Select_Energy_le, Select_Energy_ue);
|
---|
864 |
|
---|
865 | // Definition and initialization of array to save trigger statistics
|
---|
866 |
|
---|
867 | int ***ntriggerloop;
|
---|
868 |
|
---|
869 | ntriggerloop= new int ** [(int)((Trigger_loop_uthres-Trigger_loop_lthres)
|
---|
870 | /Trigger_loop_sthres)+1];
|
---|
871 | for (ithrescount=0, fthrescount=Trigger_loop_lthres;fthrescount<=Trigger_loop_uthres;fthrescount+=Trigger_loop_sthres, ithrescount++){
|
---|
872 | ntriggerloop[ithrescount]= new int * [Trigger_loop_umult-Trigger_loop_lmult+1];
|
---|
873 | for (imulticount=0;imulticount<=Trigger_loop_umult-Trigger_loop_lmult;imulticount++){
|
---|
874 | ntriggerloop[ithrescount][imulticount]= new int [Trigger_loop_utop-Trigger_loop_ltop+1];
|
---|
875 | for(itopocount=0;itopocount<=Trigger_loop_utop-Trigger_loop_ltop;itopocount++){
|
---|
876 | ntriggerloop[ithrescount][imulticount][itopocount]=0;
|
---|
877 | }
|
---|
878 | }
|
---|
879 | }
|
---|
880 |
|
---|
881 | // We should be careful that topologies are sort from
|
---|
882 | // the less to the more restrictive one.
|
---|
883 |
|
---|
884 | if (Trigger_loop_utop==Trigger_loop_ltop)
|
---|
885 | for(int is=0; is<3;is++)
|
---|
886 | isorttopo[is]=is;
|
---|
887 | else {
|
---|
888 | isorttopo[0]=1;
|
---|
889 | isorttopo[1]=0;
|
---|
890 | isorttopo[2]=2;
|
---|
891 | }
|
---|
892 |
|
---|
893 | // get list of showers to evt. skip
|
---|
894 |
|
---|
895 | nSkip = get_nskip_showers();
|
---|
896 |
|
---|
897 | if (nSkip > 0) {
|
---|
898 | Skip = new int[ nSkip ];
|
---|
899 | get_skip_showers( Skip );
|
---|
900 |
|
---|
901 | log(SIGNATURE, "There are some showers to skip:\n");
|
---|
902 | for (int i=0; i<nSkip; ++i)
|
---|
903 | log(SIGNATURE, "\tshower # %d\n", Skip[i]);
|
---|
904 | }
|
---|
905 |
|
---|
906 |
|
---|
907 | // read parameters from the ct.def file
|
---|
908 |
|
---|
909 | //read_ct_file();
|
---|
910 |
|
---|
911 | Int_t Lev0, Lev1;
|
---|
912 | Int_t Lev0MT[MAX_NUMBER_OF_CTS], Lev1MT[MAX_NUMBER_OF_CTS];
|
---|
913 |
|
---|
914 | fadcValues = new TArrayC(FADC_slices_written);
|
---|
915 | fadcValuesLow = new TArrayC(FADC_slices_written);
|
---|
916 |
|
---|
917 | // number of pixels for parameters
|
---|
918 |
|
---|
919 | // Switched off writing TObject
|
---|
920 |
|
---|
921 | MArray::Class()->IgnoreTObjectStreamer();
|
---|
922 | MParContainer::Class()->IgnoreTObjectStreamer();
|
---|
923 |
|
---|
924 | // initialise ROOT
|
---|
925 |
|
---|
926 | TROOT simple("simple", "MAGIC Telescope Monte Carlo");
|
---|
927 |
|
---|
928 | // initialise instance of Trigger and FADC classes
|
---|
929 |
|
---|
930 | MTrigger **Trigger_CT;
|
---|
931 | Trigger_CT = new MTrigger *[ct_Number];
|
---|
932 |
|
---|
933 | for (int i=0; i<ct_Number;i++){
|
---|
934 | Trigger_CT[i] = new MTrigger(TriggerPixels[i],
|
---|
935 | ((MGeomCam*)(camgeom.UncheckedAt(i))),
|
---|
936 | Trigger_gate_length,
|
---|
937 | Trigger_overlaping_time,
|
---|
938 | Trigger_response_ampl,
|
---|
939 | Trigger_response_fwhm, i); //@< A instance of the Class MTrigger
|
---|
940 | Trigger_CT[i]->SetSeed(UInt_t(i+get_seeds(0)));
|
---|
941 |
|
---|
942 | if ( ! apply_gain_fluctuations())
|
---|
943 | Trigger_CT[i]->SetGainFluctuations(kFALSE);
|
---|
944 | }
|
---|
945 |
|
---|
946 | for (int ict=0; ict<ct_Number;ict++){
|
---|
947 | // Generate database for trigger electronic noise
|
---|
948 | if (addElecNoise)
|
---|
949 | Trigger_CT[ict]->SetElecNoise(Trigger_noise) ;
|
---|
950 |
|
---|
951 | // Set Right Discriminator threshold, taking into account trigger pixels
|
---|
952 | Trigger_CT[ict]->CheckThreshold(&qThreshold[ict][0],GeometryCamera[ict]);
|
---|
953 | }
|
---|
954 | // Set flag in pixel 0 (not used for trigger) that indicates if secure pixel
|
---|
955 | // is active: secureDiskThres*10000+riseDiskThres
|
---|
956 |
|
---|
957 | for (int ict=0; ict<ct_Number;ict++){
|
---|
958 | if(riseDiskThres>0.0)
|
---|
959 | qThreshold[ict][0]=((UInt_t)secureDiskThres*100)*100+riseDiskThres;
|
---|
960 | else
|
---|
961 | qThreshold[ict][0]=0.0;
|
---|
962 | }
|
---|
963 | // Initialise McTrig information class if we want to save trigger informtion
|
---|
964 |
|
---|
965 | MMcTrig **McTrig = NULL;
|
---|
966 | MMcTrigHeader **HeaderTrig = NULL;
|
---|
967 | MMcFadcHeader **HeaderFadc = NULL;
|
---|
968 |
|
---|
969 | int numberBranches;
|
---|
970 |
|
---|
971 | if (!Trigger_Loop)
|
---|
972 | numberBranches=ct_Number;
|
---|
973 | else
|
---|
974 | numberBranches=icontrigger;
|
---|
975 |
|
---|
976 | if (Write_McTrig){
|
---|
977 |
|
---|
978 | McTrig = new MMcTrig * [numberBranches];
|
---|
979 |
|
---|
980 | for (int i=0;i<numberBranches;i++) {
|
---|
981 | McTrig[i] = new MMcTrig();
|
---|
982 | }
|
---|
983 |
|
---|
984 | HeaderTrig = new MMcTrigHeader * [numberBranches];
|
---|
985 |
|
---|
986 | for (int i=0;i<numberBranches;i++) {
|
---|
987 | HeaderTrig[i] = new MMcTrigHeader();
|
---|
988 | }
|
---|
989 | }
|
---|
990 |
|
---|
991 | if (Write_McFADC){
|
---|
992 |
|
---|
993 | HeaderFadc = new MMcFadcHeader * [numberBranches];
|
---|
994 |
|
---|
995 | for (int i=0;i<numberBranches;i++) {
|
---|
996 | HeaderFadc[i] = new MMcFadcHeader();
|
---|
997 | }
|
---|
998 | }
|
---|
999 |
|
---|
1000 | float *fadc_jitter = new float[ct_Number];
|
---|
1001 | for (int i=0; i<ct_Number;i++)
|
---|
1002 | fadc_jitter[i] = 0.;
|
---|
1003 |
|
---|
1004 | MFadc **Fadc_CT;
|
---|
1005 | Fadc_CT = new MFadc *[ct_Number];
|
---|
1006 |
|
---|
1007 | for (int i=0; i<ct_Number;i++)
|
---|
1008 | Fadc_CT[i] =
|
---|
1009 | new MFadc(((MGeomCam*)(camgeom.UncheckedAt(i)))->GetNumPixels(),
|
---|
1010 | FADC_shape,
|
---|
1011 | FADC_response_integ,FADC_response_fwhm,
|
---|
1012 | FADC_shape_out,
|
---|
1013 | FADC_resp_integ_out,FADC_resp_fwhm_out,
|
---|
1014 | get_trig_delay(),
|
---|
1015 | FADC_slices_per_ns,
|
---|
1016 | FADC_slices_written); //@< A instance of the Class MFadc
|
---|
1017 |
|
---|
1018 |
|
---|
1019 | //!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
|
---|
1020 | //
|
---|
1021 | // Set the FADC pedestals for that run
|
---|
1022 | // Some modifications
|
---|
1023 | // mut be done to simulate a more realistic distribution of the pedestals.
|
---|
1024 | // This simualtion is done int the SetPedestals methode inside the
|
---|
1025 | // class MFadc
|
---|
1026 | // Currentlly a input_pedestal array is declared with the pedestals.
|
---|
1027 | // Thy can also be set randomly following a flat distribution.
|
---|
1028 | //
|
---|
1029 | /////////////////////////////////////////////////////////////////////
|
---|
1030 |
|
---|
1031 | Float_t input_pedestals[ct_NPixels];
|
---|
1032 |
|
---|
1033 | for(int i=0;i<ct_NPixels;i++)
|
---|
1034 | input_pedestals[i]=get_FADC_pedestal();
|
---|
1035 | for (int ict=0; ict<ct_Number;ict++){
|
---|
1036 |
|
---|
1037 | Fadc_CT[ict]->SetPedestals(input_pedestals);
|
---|
1038 | Fadc_CT[ict]->SetHigh2LowGain(FADC_high2low);
|
---|
1039 |
|
---|
1040 | // Generate database for the Fadc electronic noise
|
---|
1041 |
|
---|
1042 | if (!addElecNoise)
|
---|
1043 | continue;
|
---|
1044 |
|
---|
1045 | MGeomCam *camg = (MGeomCam*)(camgeom.UncheckedAt(ict));
|
---|
1046 | UInt_t n_inner_pixels; // Number of inner(small) pixels
|
---|
1047 | for (n_inner_pixels = 0; n_inner_pixels < camg->GetNumPixels();
|
---|
1048 | n_inner_pixels ++)
|
---|
1049 | {
|
---|
1050 | if (camg->GetPixRatio(n_inner_pixels) < 1.)
|
---|
1051 | break;
|
---|
1052 | }
|
---|
1053 | Fadc_CT[ict]->SetElecNoise(FADC_noise_inner, FADC_noise_outer,
|
---|
1054 | n_inner_pixels);
|
---|
1055 | Fadc_CT[ict]->SetDigitalNoise(DIGITAL_noise);
|
---|
1056 | }
|
---|
1057 |
|
---|
1058 | // Prepare the raw data output
|
---|
1059 |
|
---|
1060 | // Header Tree
|
---|
1061 | MGeomCam **camdummy = new MGeomCam * [ct_Number];
|
---|
1062 | for (int ict=0; ict<ct_Number;ict++){
|
---|
1063 | camdummy[ict]= ((MGeomCam*)(camgeom.UncheckedAt(ict)));
|
---|
1064 | }
|
---|
1065 | MRawRunHeader *RunHeader= new MRawRunHeader();
|
---|
1066 | MMcRunHeader *McRunHeader = new MMcRunHeader();
|
---|
1067 | MMcCorsikaRunHeader *McCorsikaRunHeader = new MMcCorsikaRunHeader("","",ct_Number);
|
---|
1068 |
|
---|
1069 |
|
---|
1070 | for (int i = 0; i < ct_Number; i++)
|
---|
1071 | McCorsikaRunHeader->FillCT(CTx[i], CTy[i], CTz[i], -1., -1., -1., -1., i);
|
---|
1072 |
|
---|
1073 |
|
---|
1074 | MMcConfigRunHeader **McConfigRunHeader = NULL;
|
---|
1075 | McConfigRunHeader = new MMcConfigRunHeader * [numberBranches];
|
---|
1076 | for (int i=0;i<numberBranches;i++) {
|
---|
1077 | McConfigRunHeader[i] = new MMcConfigRunHeader();
|
---|
1078 | }
|
---|
1079 |
|
---|
1080 | // Header branch
|
---|
1081 |
|
---|
1082 | MRawEvtHeader **EvtHeader = NULL;
|
---|
1083 |
|
---|
1084 | if (Write_RawEvt) {
|
---|
1085 | EvtHeader = new MRawEvtHeader * [numberBranches];
|
---|
1086 |
|
---|
1087 | for (int i=0;i<numberBranches;i++) {
|
---|
1088 | EvtHeader[i] = new MRawEvtHeader();
|
---|
1089 | }
|
---|
1090 |
|
---|
1091 | }
|
---|
1092 |
|
---|
1093 | // Data branch
|
---|
1094 |
|
---|
1095 | MRawEvtData **EvtData = NULL; // Data branch
|
---|
1096 |
|
---|
1097 | if (Write_RawEvt) {
|
---|
1098 | EvtData = new MRawEvtData * [numberBranches];
|
---|
1099 |
|
---|
1100 | for (int i=0;i<numberBranches;i++) {
|
---|
1101 | EvtData[i] = new MRawEvtData();
|
---|
1102 | EvtData[i]->InitRead(RunHeader); // We need the RunHeader to read
|
---|
1103 | // number of pixels
|
---|
1104 | }
|
---|
1105 | }
|
---|
1106 |
|
---|
1107 | MMcEvt **McEvt = NULL;
|
---|
1108 | MMcEvtBasic **McEvtBasic = NULL;
|
---|
1109 |
|
---|
1110 | if (Write_McEvt)
|
---|
1111 | {
|
---|
1112 | McEvt = new MMcEvt *[ct_Number];
|
---|
1113 | McEvtBasic = new MMcEvtBasic *[ct_Number];
|
---|
1114 | for (int i = 0; i < ct_Number; i++)
|
---|
1115 | {
|
---|
1116 | McEvt[i] = new MMcEvt();
|
---|
1117 | McEvtBasic[i] = new MMcEvtBasic();
|
---|
1118 | }
|
---|
1119 | }
|
---|
1120 | //
|
---|
1121 | // initalize a temporal ROOT file
|
---|
1122 | //
|
---|
1123 |
|
---|
1124 | TFile outfile_temp ( rootname , "RECREATE" );
|
---|
1125 |
|
---|
1126 | // create a Tree for the Header Event
|
---|
1127 | TTree HeaderTree("RunHeaders","Headers of Run");
|
---|
1128 |
|
---|
1129 | // define branches of Header Tree
|
---|
1130 |
|
---|
1131 | char help[4];
|
---|
1132 |
|
---|
1133 | HeaderTree.Branch("MRawRunHeader.","MRawRunHeader",
|
---|
1134 | &RunHeader);
|
---|
1135 |
|
---|
1136 | HeaderTree.Branch("MMcRunHeader.","MMcRunHeader",
|
---|
1137 | &McRunHeader);
|
---|
1138 |
|
---|
1139 | HeaderTree.Branch("MMcCorsikaRunHeader.","MMcCorsikaRunHeader",
|
---|
1140 | &McCorsikaRunHeader);
|
---|
1141 |
|
---|
1142 | if(!Trigger_Loop && Write_McTrig && ct_Number==1){
|
---|
1143 |
|
---|
1144 | HeaderTree.Branch("MMcTrigHeader.","MMcTrigHeader",
|
---|
1145 | &HeaderTrig[0]);
|
---|
1146 | }
|
---|
1147 |
|
---|
1148 | if (ct_Number==1){
|
---|
1149 | // HeaderTree.Branch("MGeomCam.", "MGeomCam", &camdummy[0]);
|
---|
1150 | HeaderTree.Branch("MGeomCam.", GeometryName[0], &camdummy[0]);
|
---|
1151 | HeaderTree.Branch("MMcConfigRunHeader.","MMcConfigRunHeader",
|
---|
1152 | &McConfigRunHeader[0]);
|
---|
1153 | }
|
---|
1154 | else{
|
---|
1155 | char branchname[256];
|
---|
1156 | for (int ict=0; ict<ct_Number;ict++){
|
---|
1157 | sprintf(help,"%i",ict+1);
|
---|
1158 | strcpy (branchname, "MGeomCam;");
|
---|
1159 | strcat (branchname, & help[0]);
|
---|
1160 | strcat (branchname, ".");
|
---|
1161 | HeaderTree.Branch(branchname, GeometryName[ict],
|
---|
1162 | &camdummy[ict]);
|
---|
1163 | }
|
---|
1164 | for(int i=0;i<numberBranches;i++){
|
---|
1165 | sprintf(help,"%i",i+1);
|
---|
1166 | strcpy (branchname, "MMcConfigRunHeader;");
|
---|
1167 | strcat (branchname, & help[0]);
|
---|
1168 | strcat (branchname, ".");
|
---|
1169 | HeaderTree.Branch(branchname,"MMcConfigRunHeader",
|
---|
1170 | &McConfigRunHeader[i]);
|
---|
1171 | }
|
---|
1172 |
|
---|
1173 | }
|
---|
1174 |
|
---|
1175 | if ((Trigger_Loop || ct_Number>1) && Write_McTrig){
|
---|
1176 | ibr=0;
|
---|
1177 | for(char branchname[256];ibr<numberBranches;ibr++){
|
---|
1178 |
|
---|
1179 | sprintf(help,"%i",ibr+1);
|
---|
1180 | strcpy (branchname, "MMcTrigHeader;");
|
---|
1181 | strcat (branchname, & help[0]);
|
---|
1182 | strcat (branchname, ".");
|
---|
1183 | HeaderTree.Branch(branchname,"MMcTrigHeader",
|
---|
1184 | &HeaderTrig[ibr]);
|
---|
1185 | }
|
---|
1186 | }
|
---|
1187 |
|
---|
1188 | if(!Trigger_Loop && Write_McFADC && ct_Number==1){
|
---|
1189 |
|
---|
1190 | HeaderTree.Branch("MMcFadcHeader.","MMcFadcHeader",
|
---|
1191 | &HeaderFadc[0]);
|
---|
1192 | }
|
---|
1193 | if ((Trigger_Loop || ct_Number>1) && Write_McFADC){
|
---|
1194 | ibr=0;
|
---|
1195 | for(char branchname[256];ibr<numberBranches;ibr++){
|
---|
1196 |
|
---|
1197 | sprintf(help,"%i",ibr+1);
|
---|
1198 | strcpy (branchname, "MMcFadcHeader;");
|
---|
1199 | strcat (branchname, & help[0]);
|
---|
1200 | strcat (branchname, ".");
|
---|
1201 |
|
---|
1202 | HeaderTree.Branch(branchname,"MMcFadcHeader",
|
---|
1203 | &HeaderFadc[ibr]);
|
---|
1204 | }
|
---|
1205 | }
|
---|
1206 |
|
---|
1207 | // Fill branches for MRawRunHeader
|
---|
1208 |
|
---|
1209 | RunHeader->SetMagicNumber(MRawRunHeader::kMagicNumber);
|
---|
1210 |
|
---|
1211 | //
|
---|
1212 | // We set as format version 5, the current real data version as of February 2005.
|
---|
1213 | // These data have the peculiarity that the trigger pattern bits
|
---|
1214 | // (MRawEventHeader.fTrigPattern[0]) will be inverted (0 <-> 1) with respect
|
---|
1215 | // to the definitions in Mars/mtrigger/MTriggerPattern. We will account for this
|
---|
1216 | // below when setting the trigger pattern.
|
---|
1217 | //
|
---|
1218 | RunHeader->SetFormatVersion(5);
|
---|
1219 |
|
---|
1220 |
|
---|
1221 | RunHeader->SetSoftVersion((UShort_t) (VERSION*10));
|
---|
1222 | RunHeader->SetRunType(256);
|
---|
1223 | RunHeader->SetRunNumber(0);
|
---|
1224 | RunHeader->SetNumSamples(FADC_slices_written, FADC_slices_written);
|
---|
1225 | RunHeader->SetNumCrates(1);
|
---|
1226 | RunHeader->SetNumPixInCrate(ct_NPixels);
|
---|
1227 |
|
---|
1228 | // Fill branches for MMcTrigHeader
|
---|
1229 |
|
---|
1230 | if(!Trigger_Loop && Write_McTrig && ct_Number==1){
|
---|
1231 |
|
---|
1232 | HeaderTrig[0]->SetTopology((Short_t) Trigger_topology[0]);
|
---|
1233 | HeaderTrig[0]->SetMultiplicity((Short_t) Trigger_multiplicity[0]);
|
---|
1234 | HeaderTrig[0]->SetThreshold(qThreshold[0]);
|
---|
1235 | HeaderTrig[0]->SetAmplitud(Trigger_response_ampl);
|
---|
1236 | HeaderTrig[0]->SetFwhm(Trigger_response_fwhm);
|
---|
1237 | HeaderTrig[0]->SetOverlap(Trigger_overlaping_time);
|
---|
1238 | HeaderTrig[0]->SetGate(Trigger_gate_length);
|
---|
1239 | HeaderTrig[0]->SetElecNoise(Trigger_noise);
|
---|
1240 | HeaderTrig[0]->SetGainFluctuations(Trigger_CT[0]->GetGainFluctuations());
|
---|
1241 | HeaderTrig[0]->SetNoiseGainFluctuations((Bool_t)apply_noise_gain_fluctuations());
|
---|
1242 | }
|
---|
1243 |
|
---|
1244 | if(!Trigger_Loop && Write_McTrig && ct_Number>1){
|
---|
1245 | for(int i=0;i<ct_Number;i++){
|
---|
1246 | HeaderTrig[i]->SetTopology((Short_t) Trigger_topology[i]);
|
---|
1247 | HeaderTrig[i]->SetMultiplicity((Short_t) Trigger_multiplicity[i]);
|
---|
1248 | HeaderTrig[i]->SetThreshold(qThreshold[i]);
|
---|
1249 | HeaderTrig[i]->SetAmplitud(Trigger_response_ampl);
|
---|
1250 | HeaderTrig[i]->SetFwhm(Trigger_response_fwhm);
|
---|
1251 | HeaderTrig[i]->SetOverlap(Trigger_overlaping_time);
|
---|
1252 | HeaderTrig[i]->SetGate(Trigger_gate_length);
|
---|
1253 | HeaderTrig[i]->SetElecNoise(Trigger_noise);
|
---|
1254 | HeaderTrig[i]->SetGainFluctuations(Trigger_CT[i]->GetGainFluctuations());
|
---|
1255 | HeaderTrig[i]->SetNoiseGainFluctuations((Bool_t)apply_noise_gain_fluctuations());
|
---|
1256 | }
|
---|
1257 | }
|
---|
1258 | if(Trigger_Loop && Write_McTrig){
|
---|
1259 |
|
---|
1260 | int iconcount;
|
---|
1261 | for (iconcount=0,ithrescount=0,fthrescount=Trigger_loop_lthres;fthrescount<=Trigger_loop_uthres;ithrescount++,fthrescount+=Trigger_loop_sthres){
|
---|
1262 | for (imulticount=0;imulticount<=Trigger_loop_umult-Trigger_loop_lmult;imulticount++){
|
---|
1263 | for(itopocount=0;itopocount<=Trigger_loop_utop-Trigger_loop_ltop;itopocount++){
|
---|
1264 | HeaderTrig[iconcount]->SetTopology((Short_t) isorttopo[itopocount+Trigger_loop_ltop]);
|
---|
1265 | HeaderTrig[iconcount]->SetMultiplicity((Short_t) imulticount+Trigger_loop_lmult);
|
---|
1266 | for(int i=0;i<ct_NPixels;i++){
|
---|
1267 | fpixelthres[i]=
|
---|
1268 | ((Float_t)(fthrescount)>=qThreshold[0][i])?
|
---|
1269 | (Float_t)(fthrescount):qThreshold[0][i];
|
---|
1270 | }
|
---|
1271 | HeaderTrig[iconcount]->SetThreshold( fpixelthres);
|
---|
1272 | HeaderTrig[iconcount]->SetAmplitud(Trigger_response_ampl);
|
---|
1273 | HeaderTrig[iconcount]->SetFwhm(Trigger_response_fwhm);
|
---|
1274 | HeaderTrig[iconcount]->SetOverlap(Trigger_overlaping_time);
|
---|
1275 | HeaderTrig[iconcount]->SetGate(Trigger_gate_length);
|
---|
1276 | HeaderTrig[iconcount]->SetElecNoise(Trigger_noise);
|
---|
1277 | HeaderTrig[iconcount]->SetGainFluctuations(Trigger_CT[0]->GetGainFluctuations());
|
---|
1278 | HeaderTrig[iconcount]->SetNoiseGainFluctuations((Bool_t)apply_noise_gain_fluctuations());
|
---|
1279 | iconcount++;
|
---|
1280 | }
|
---|
1281 | }
|
---|
1282 | }
|
---|
1283 | }
|
---|
1284 |
|
---|
1285 | // Fill branches for MMcFadcHeader
|
---|
1286 | Fadc_CT[0]->GetPedestals(&fadc_pedestals[0]);
|
---|
1287 |
|
---|
1288 | if(!Trigger_Loop && Write_McFADC && ct_Number==1){
|
---|
1289 |
|
---|
1290 | for(int k = 0; k < ct_NPixels; k++){
|
---|
1291 | if ( ((MGeomCam*)(camgeom.UncheckedAt(0)))->GetPixRatio(k) < 1.)
|
---|
1292 | fadc_elecnoise[k]=FADC_noise_outer; // outer pixels
|
---|
1293 | else
|
---|
1294 | fadc_elecnoise[k]=FADC_noise_inner; // inner pixels
|
---|
1295 |
|
---|
1296 | fadc_diginoise[k]=DIGITAL_noise;
|
---|
1297 | }
|
---|
1298 |
|
---|
1299 | HeaderFadc[0]->SetShape((Float_t)FADC_shape);
|
---|
1300 | HeaderFadc[0]->SetShapeOuter((Float_t)FADC_shape_out);
|
---|
1301 | HeaderFadc[0]->SetAmplitud(FADC_response_integ,
|
---|
1302 | FADC_resp_integ_out);
|
---|
1303 | HeaderFadc[0]->SetFwhm(FADC_response_fwhm,FADC_resp_fwhm_out);
|
---|
1304 | HeaderFadc[0]->SetLow2High(FADC_high2low);
|
---|
1305 | HeaderFadc[0]->SetPedestal(&fadc_pedestals[0],
|
---|
1306 | ((MGeomCam*)(camgeom.UncheckedAt(0)))->GetNumPixels());
|
---|
1307 | HeaderFadc[0]->SetElecNoise(&fadc_elecnoise[0], &fadc_diginoise[0],
|
---|
1308 | ((MGeomCam*)(camgeom.UncheckedAt(0)))->GetNumPixels());
|
---|
1309 |
|
---|
1310 | //
|
---|
1311 | // Fill also the flag indicating whether the PMT gain fluctuations
|
---|
1312 | // were simulated or not:
|
---|
1313 | //
|
---|
1314 | HeaderFadc[0]->SetGainFluctuations(Trigger_CT[0]->GetGainFluctuations());
|
---|
1315 | HeaderFadc[0]->SetNoiseGainFluctuations((Bool_t)apply_noise_gain_fluctuations());
|
---|
1316 |
|
---|
1317 | }
|
---|
1318 |
|
---|
1319 | if(!Trigger_Loop && Write_McFADC && ct_Number>1){
|
---|
1320 | for(int i=0;i<ct_Number;i++){
|
---|
1321 |
|
---|
1322 | for(int k = 0; k < ct_NPixels; k++){
|
---|
1323 | if ( ((MGeomCam*)(camgeom.UncheckedAt(i)))->GetPixRatio(k) < 1.)
|
---|
1324 | fadc_elecnoise[k]=FADC_noise_outer; // outer pixels
|
---|
1325 | else
|
---|
1326 | fadc_elecnoise[k]=FADC_noise_inner; // inner pixels
|
---|
1327 |
|
---|
1328 | fadc_diginoise[k]=DIGITAL_noise;
|
---|
1329 | }
|
---|
1330 |
|
---|
1331 | Fadc_CT[i]->GetPedestals(&fadc_pedestals[0]);
|
---|
1332 | HeaderFadc[i]->SetShape((Float_t)FADC_shape);
|
---|
1333 | HeaderFadc[i]->SetShapeOuter((Float_t)FADC_shape_out);
|
---|
1334 | HeaderFadc[i]->SetAmplitud(FADC_response_integ,
|
---|
1335 | FADC_resp_integ_out);
|
---|
1336 | HeaderFadc[i]->SetFwhm(FADC_response_fwhm,FADC_resp_fwhm_out);
|
---|
1337 | HeaderFadc[i]->SetLow2High(FADC_high2low);
|
---|
1338 | HeaderFadc[i]->SetPedestal(&fadc_pedestals[0],((MGeomCam*)(camgeom.UncheckedAt(i)))->GetNumPixels());
|
---|
1339 | HeaderFadc[i]->SetElecNoise(&fadc_elecnoise[0], &fadc_diginoise[0],
|
---|
1340 | ((MGeomCam*)(camgeom.UncheckedAt(i)))->GetNumPixels());
|
---|
1341 |
|
---|
1342 | //
|
---|
1343 | // Fill also the flag indicating whether the PMT gain fluctuations
|
---|
1344 | // were simulated or not:
|
---|
1345 | //
|
---|
1346 | HeaderFadc[i]->SetGainFluctuations(Trigger_CT[i]->GetGainFluctuations());
|
---|
1347 | HeaderFadc[i]->SetNoiseGainFluctuations((Bool_t)apply_noise_gain_fluctuations());
|
---|
1348 |
|
---|
1349 | }
|
---|
1350 | }
|
---|
1351 |
|
---|
1352 | if(Trigger_Loop && Write_McFADC){
|
---|
1353 |
|
---|
1354 | for(int k = 0; k < ct_NPixels; k++){
|
---|
1355 | if ( ((MGeomCam*)(camgeom.UncheckedAt(0)))->GetPixRatio(k) < 1.)
|
---|
1356 | fadc_elecnoise[k]=FADC_noise_outer; // outer
|
---|
1357 | else
|
---|
1358 | fadc_elecnoise[k]=FADC_noise_inner; // inner
|
---|
1359 |
|
---|
1360 | fadc_diginoise[k]=DIGITAL_noise;
|
---|
1361 | }
|
---|
1362 |
|
---|
1363 | int iconcount;
|
---|
1364 | for (iconcount=0,ithrescount=0,fthrescount=Trigger_loop_lthres;fthrescount<=Trigger_loop_uthres;ithrescount++, fthrescount+=Trigger_loop_sthres){
|
---|
1365 | for (imulticount=0;imulticount<=Trigger_loop_umult-Trigger_loop_lmult;imulticount++){
|
---|
1366 | for(itopocount=0;itopocount<=Trigger_loop_utop-Trigger_loop_ltop;itopocount++){
|
---|
1367 | Fadc_CT[0]->GetPedestals(&fadc_pedestals[0]);
|
---|
1368 | HeaderFadc[iconcount]->SetShape((Float_t)FADC_shape);
|
---|
1369 | HeaderFadc[iconcount]->SetShapeOuter((Float_t)FADC_shape_out);
|
---|
1370 | HeaderFadc[iconcount]->SetAmplitud(FADC_response_integ,
|
---|
1371 | FADC_resp_integ_out);
|
---|
1372 | HeaderFadc[iconcount]->SetFwhm(FADC_response_fwhm,
|
---|
1373 | FADC_resp_fwhm_out);
|
---|
1374 | HeaderFadc[iconcount]->SetLow2High(FADC_high2low);
|
---|
1375 | HeaderFadc[iconcount]->SetPedestal(&fadc_pedestals[0], ct_NPixels);
|
---|
1376 | HeaderFadc[iconcount]->SetElecNoise(&fadc_elecnoise[0],
|
---|
1377 | &fadc_diginoise[0],ct_NPixels);
|
---|
1378 |
|
---|
1379 | HeaderFadc[iconcount]->SetGainFluctuations(Trigger_CT[0]->GetGainFluctuations());
|
---|
1380 | HeaderFadc[iconcount]->SetNoiseGainFluctuations((Bool_t)apply_noise_gain_fluctuations());
|
---|
1381 |
|
---|
1382 | iconcount++;
|
---|
1383 | }
|
---|
1384 | }
|
---|
1385 | }
|
---|
1386 | }
|
---|
1387 |
|
---|
1388 | // UnSet flag in pixel 0 (not used for trigger) that indicates if secure pixel
|
---|
1389 | // is active once it has been stored
|
---|
1390 |
|
---|
1391 | for (int ict=0; ict<ct_Number;ict++){
|
---|
1392 | qThreshold[ict][0]=999999.99;
|
---|
1393 | }
|
---|
1394 |
|
---|
1395 | // create a Tree for the Event data stream
|
---|
1396 | TTree EvtTree("Events","Normal Triggered Events");
|
---|
1397 |
|
---|
1398 | if (Write_McEvt && ct_Number == 1)
|
---|
1399 | {
|
---|
1400 | EvtTree.Branch("MMcEvt.","MMcEvt", &McEvt[0]);
|
---|
1401 | EvtTree.Branch("MMcEvtBasic.","MMcEvtBasic", &McEvtBasic[0]);
|
---|
1402 | }
|
---|
1403 |
|
---|
1404 | if (Write_McEvt && ct_Number!=1)
|
---|
1405 | {
|
---|
1406 | ibr=0;
|
---|
1407 | for(char branchname[256]; ibr < numberBranches; ibr++)
|
---|
1408 | {
|
---|
1409 | sprintf(help,"%i",ibr+1);
|
---|
1410 | strcpy (branchname, "MMcEvt;");
|
---|
1411 | strcat (branchname, & help[0]);
|
---|
1412 | strcat (branchname, ".");
|
---|
1413 | EvtTree.Branch(branchname,"MMcEvt",
|
---|
1414 | &McEvt[ibr]);
|
---|
1415 | }
|
---|
1416 | for(char branchname[256]; ibr < numberBranches; ibr++)
|
---|
1417 | {
|
---|
1418 | sprintf(help,"%i",ibr+1);
|
---|
1419 | strcpy (branchname, "MMcEvtBasic;");
|
---|
1420 | strcat (branchname, & help[0]);
|
---|
1421 | strcat (branchname, ".");
|
---|
1422 | EvtTree.Branch(branchname,"MMcEvtBasic",
|
---|
1423 | &McEvtBasic[ibr]);
|
---|
1424 | }
|
---|
1425 | }
|
---|
1426 |
|
---|
1427 | if(!Trigger_Loop && ct_Number==1){
|
---|
1428 |
|
---|
1429 | if (Write_RawEvt){
|
---|
1430 | EvtTree.Branch("MRawEvtHeader.","MRawEvtHeader",
|
---|
1431 | &EvtHeader[0]);
|
---|
1432 | EvtTree.Branch("MRawEvtData.","MRawEvtData",
|
---|
1433 | &EvtData[0]);
|
---|
1434 | }
|
---|
1435 | if (Write_McTrig){
|
---|
1436 | EvtTree.Branch("MMcTrig.","MMcTrig",
|
---|
1437 | &McTrig[0]);
|
---|
1438 | }
|
---|
1439 | }
|
---|
1440 | else{
|
---|
1441 |
|
---|
1442 | if (Write_McTrig){
|
---|
1443 | ibr=0;
|
---|
1444 | for(char branchname[256];ibr<numberBranches;ibr++){
|
---|
1445 |
|
---|
1446 | sprintf(help,"%i",ibr+1);
|
---|
1447 | strcpy (branchname, "MMcTrig;");
|
---|
1448 | strcat (branchname, & help[0]);
|
---|
1449 | strcat (branchname, ".");
|
---|
1450 | EvtTree.Branch(branchname,"MMcTrig",
|
---|
1451 | &McTrig[ibr]);
|
---|
1452 | }
|
---|
1453 | }
|
---|
1454 | }
|
---|
1455 |
|
---|
1456 | if ((Trigger_Loop || ct_Number>1) && Write_RawEvt){
|
---|
1457 | ibr=0;
|
---|
1458 | for(char branchname[256];ibr<numberBranches;ibr++){
|
---|
1459 |
|
---|
1460 | sprintf(help,"%i",ibr+1);
|
---|
1461 | strcpy (branchname, "MRawEvtHeader;");
|
---|
1462 | strcat (branchname, & help[0]);
|
---|
1463 | strcat (branchname, ".");
|
---|
1464 | EvtTree.Branch(branchname,"MRawEvtHeader",
|
---|
1465 | &EvtHeader[ibr]);
|
---|
1466 | }
|
---|
1467 | ibr=0;
|
---|
1468 | for(char branchname[256];ibr<numberBranches;ibr++){
|
---|
1469 |
|
---|
1470 | sprintf(help,"%i",ibr+1);
|
---|
1471 | strcpy (branchname, "MRawEvtData;");
|
---|
1472 | strcat (branchname, & help[0]);
|
---|
1473 | strcat (branchname, ".");
|
---|
1474 | EvtTree.Branch(branchname,"MRawEvtData",
|
---|
1475 | &EvtData[ibr]);
|
---|
1476 | }
|
---|
1477 | }
|
---|
1478 |
|
---|
1479 |
|
---|
1480 | TApplication theAppTrigger("App", &argc, argv);
|
---|
1481 |
|
---|
1482 | if(FADC_Scan){
|
---|
1483 | if (gROOT->IsBatch()) {
|
---|
1484 | fprintf(stderr, "%s: cannot run in batch mode\n", argv[0]);
|
---|
1485 | // return 1;
|
---|
1486 | }
|
---|
1487 | }
|
---|
1488 | if(FADC_Scan){
|
---|
1489 | //TApplication theAppFadc("App", &argc, argv);
|
---|
1490 |
|
---|
1491 | if (gROOT->IsBatch()) {
|
---|
1492 | fprintf(stderr, "%s: cannot run in batch mode\n", argv[0]);
|
---|
1493 | // return 1;
|
---|
1494 | }
|
---|
1495 | }
|
---|
1496 |
|
---|
1497 | // prepare the NSB simulation
|
---|
1498 |
|
---|
1499 | // Instance of the Mlons class
|
---|
1500 |
|
---|
1501 | MLons lons(0, Trigger_response_ampl, Trigger_response_fwhm,
|
---|
1502 | FADC_shape, FADC_response_integ, FADC_response_fwhm,
|
---|
1503 | FADC_slices_per_ns, apply_noise_gain_fluctuations());
|
---|
1504 |
|
---|
1505 | lons.SetSeed(((UInt_t)(get_seeds(1)*get_seeds(1)*get_seeds(0))));
|
---|
1506 |
|
---|
1507 | lons.SetPath(nsbpathname);
|
---|
1508 |
|
---|
1509 | // Instance of the Mlons class
|
---|
1510 | MLons lons_outer(0, Trigger_response_ampl, Trigger_response_fwhm,
|
---|
1511 | FADC_shape_out,FADC_resp_integ_out,FADC_resp_fwhm_out,
|
---|
1512 | FADC_slices_per_ns, apply_noise_gain_fluctuations());
|
---|
1513 |
|
---|
1514 | lons_outer.SetSeed(((UInt_t)(get_seeds(1)*get_seeds(0)*get_seeds(0))));
|
---|
1515 |
|
---|
1516 | lons_outer.SetPath(nsbpath_outer);
|
---|
1517 |
|
---|
1518 | if( simulateNSB){
|
---|
1519 |
|
---|
1520 | //
|
---|
1521 | // Calculate the non-diffuse NSB photoelectron rates
|
---|
1522 | //
|
---|
1523 |
|
---|
1524 | //
|
---|
1525 | // FIXME! --- star NSB different for each camera?
|
---|
1526 | // Then we will have to use mirror_frac[ict]
|
---|
1527 | //
|
---|
1528 | log(SIGNATURE,"Produce NSB rates from Star Field...\n");
|
---|
1529 |
|
---|
1530 | k = produce_nsbrates( starfieldname,
|
---|
1531 | ((MGeomCam*)(camgeom.UncheckedAt(0))),
|
---|
1532 | nsbrate_phepns,
|
---|
1533 | 0,
|
---|
1534 | mirror_frac[0]);
|
---|
1535 |
|
---|
1536 | //
|
---|
1537 | // Call to "produce_nsbrates" above accounts ONLY for
|
---|
1538 | // non-diffuse NSB (i.e. from stars). NOTE: produce_nsbrates already
|
---|
1539 | // accounts for the possibly different light collection efficiencies
|
---|
1540 | // of inner and outer pixels, through a call (see function) to
|
---|
1541 | // "produce_phes". The output array nsbrate_phepns contains only the
|
---|
1542 | // rates due to individual stars in the FOV, and not diffuse NSB light!
|
---|
1543 | //
|
---|
1544 |
|
---|
1545 | if (k != 0){
|
---|
1546 | cout << "Error when reading starfield... \nExiting.\n";
|
---|
1547 | exit(1);
|
---|
1548 | }
|
---|
1549 |
|
---|
1550 | // calculate diffuse rate correcting for the pixel size and telescope
|
---|
1551 |
|
---|
1552 | float factorNSB_ct;
|
---|
1553 | for(int ict=0;ict<ct_Number;ict++){
|
---|
1554 |
|
---|
1555 | // First we set the factor due to the mirror size with respect to the normal
|
---|
1556 | // MAGIC mirror geometry.
|
---|
1557 |
|
---|
1558 | switch(GeometryCamera[ict]){
|
---|
1559 | case 1:
|
---|
1560 | case 2:
|
---|
1561 | case 3:
|
---|
1562 | case 4:
|
---|
1563 | factorNSB_ct=1.0;
|
---|
1564 | break;
|
---|
1565 | case 5:
|
---|
1566 | case 6:
|
---|
1567 | case 7:
|
---|
1568 | factorNSB_ct=1000.0/239.0;
|
---|
1569 | break;
|
---|
1570 | case 8:
|
---|
1571 | case 9:
|
---|
1572 | default:
|
---|
1573 | factorNSB_ct=1.0;
|
---|
1574 | break;
|
---|
1575 | }
|
---|
1576 |
|
---|
1577 | factorNSB_ct = factorNSB_ct /
|
---|
1578 | ((*((MGeomCam*)(camgeom.UncheckedAt(ict)))).GetCameraDist()*1000*
|
---|
1579 | (*((MGeomCam*)(camgeom.UncheckedAt(ict)))).GetCameraDist()*1000*
|
---|
1580 | PIXEL_SIZE*PIXEL_SIZE); // [mm^-2]
|
---|
1581 |
|
---|
1582 | for(UInt_t ui=0;
|
---|
1583 | ui<((MGeomCam*)(camgeom.UncheckedAt(ict)))->GetNumPixels(); ui++){
|
---|
1584 | const Float_t size=
|
---|
1585 | (*((MGeomCam*)(camgeom.UncheckedAt(ict))))[ui].GetD();
|
---|
1586 | // Returns distance [mm] between two paralel sides of pixel
|
---|
1587 |
|
---|
1588 |
|
---|
1589 | Float_t diffusensb = meanNSB*mirror_frac[ict];
|
---|
1590 |
|
---|
1591 | //
|
---|
1592 | // If pixel is outer pixel:
|
---|
1593 | //
|
---|
1594 | if ( ((MGeomCam*)(camgeom.UncheckedAt(ict)))->GetPixRatio(ui) < 1. )
|
---|
1595 | diffusensb *= WC_outer[1][90] / WC[1][90];
|
---|
1596 | //
|
---|
1597 | // FIXME! Correction above is for (possibly) different light collection efficiencies of
|
---|
1598 | // inner and outer pixels. For the moment we assume the angular dependence of the light
|
---|
1599 | // collection is the same and hence use simply the ratio of efficiencies for light impinging
|
---|
1600 | // perpendicular to the camera plane (index 90 stands for 90 degrees)
|
---|
1601 | //
|
---|
1602 |
|
---|
1603 | diffnsb_phepns[ict][ui] = (Int_t(diffusensb*factorNSB_ct*100*size*size+0.5))/(100.0)*factorqe_NSB[ict];
|
---|
1604 | }
|
---|
1605 | }
|
---|
1606 |
|
---|
1607 | // calculate nsb rate including diffuse and starlight
|
---|
1608 | // we also include the extinction effect
|
---|
1609 | for(int ict=0;ict<ct_Number;ict++){
|
---|
1610 | for(j=0;j<iNUMWAVEBANDS;j++){
|
---|
1611 | // calculate the effect of the atmospheric extinction (for stars!)
|
---|
1612 |
|
---|
1613 | zenfactor = pow(10., -0.4 * ext[j] );
|
---|
1614 |
|
---|
1615 | for(UInt_t ui=0; ui<((MGeomCam*)(camgeom.UncheckedAt(ict)))->GetNumPixels();ui++)
|
---|
1616 | {
|
---|
1617 | nsb_phepns[ict][ui]+=diffnsb_phepns[ict][ui]/iNUMWAVEBANDS +
|
---|
1618 | zenfactor * nsbrate_phepns[ui][j];
|
---|
1619 | nsb_phepns_rotated[ict][ui]=nsb_phepns[ict][ui];
|
---|
1620 | }
|
---|
1621 | }
|
---|
1622 | }
|
---|
1623 | }
|
---|
1624 |
|
---|
1625 |
|
---|
1626 | //!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
|
---|
1627 | //
|
---|
1628 | // Now 500 empty events with the condition in which the camera is run
|
---|
1629 | // are simulated. In this way one gets an estimation of the
|
---|
1630 | // fluctuations of the pedestal of each FADC channel.
|
---|
1631 | // This computation is done assuming any noise that affects
|
---|
1632 | // the FADC but there is no rotation of the Star Field (otherwise it
|
---|
1633 | // should be done for each event). So it is valid if no starfield
|
---|
1634 | // rotation is used.
|
---|
1635 | //
|
---|
1636 | // Changed 20/03/2004, AM: now we no longer calculate the individual
|
---|
1637 | // FADC slice RMS. Due to correlations in the noise of neighboring
|
---|
1638 | // slides, it follows that RMS(sum_n_slices) != sqrt(n)*RMS(single_slice)
|
---|
1639 | //
|
---|
1640 | // In the analysis in Mars, however, the RMS of the fluctuations of the
|
---|
1641 | // signal (resulting from the integration of n slices) is estimated as
|
---|
1642 | // sqrt(n) * MMcFadcHeader.fPedesSigmaHigh, where the latter value,
|
---|
1643 | // stored in the camera output, is calculated in the next lines of code.
|
---|
1644 | // We have then made the following, as is being done also in real data:
|
---|
1645 | // calculate the RMS of the distribution of the sum of 14 slices, then
|
---|
1646 | // the stored value is
|
---|
1647 | // MMcFadcHeader.fPedesSigmaHigh = RMS(sum_14_slices)/sqrt(14), and the
|
---|
1648 | // same for the low gain. It can be seen that the RMS of the sum of n
|
---|
1649 | // slices, with n not too low (n>=6 or so), is more or less:
|
---|
1650 | // RMS(sum_n_slices) ~ sqrt(n) * RMS(sum_14_slices)/sqrt(14)
|
---|
1651 | //
|
---|
1652 | // The reason to sum 14 slices (and not 15) comes from the fact that in
|
---|
1653 | // real data there is a FADC clock noise affecting differently odd and
|
---|
1654 | // even FADC slices, so always an even number of them is added up so that
|
---|
1655 | // this cancels out. So we do the calculation in the same way as in real
|
---|
1656 | // data.
|
---|
1657 | //
|
---|
1658 | //!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
|
---|
1659 |
|
---|
1660 | Int_t empty_events = 500;
|
---|
1661 | Int_t n_slices = 14;
|
---|
1662 |
|
---|
1663 | for(int ict=0;ict<ct_Number;ict++){
|
---|
1664 | for(UInt_t ui=0;
|
---|
1665 | ui<((MGeomCam*)(camgeom.UncheckedAt(ict)))->GetNumPixels();
|
---|
1666 | ui++){
|
---|
1667 | fadc_sigma[ui]=0.0;
|
---|
1668 | fadc_sigma_low[ui]=0.0;
|
---|
1669 | }
|
---|
1670 | for(int ie=0; ie < empty_events; ie++){
|
---|
1671 | Fadc_CT[ict]->Reset();
|
---|
1672 | if (addElecNoise){
|
---|
1673 | Fadc_CT[ict]->ElecNoise() ;
|
---|
1674 | }
|
---|
1675 | if(simulateNSB)
|
---|
1676 | {
|
---|
1677 | for(UInt_t ui=0;
|
---|
1678 | ui<((MGeomCam*)(camgeom.UncheckedAt(ict)))->GetNumPixels();
|
---|
1679 | ui++)
|
---|
1680 | {
|
---|
1681 | if(nsb_phepns[ict][ui]>0.0)
|
---|
1682 | {
|
---|
1683 | if((*((MGeomCam*)(camgeom.UncheckedAt(ict))))[ui].GetD() >
|
---|
1684 | (*((MGeomCam*)(camgeom.UncheckedAt(ict))))[0].GetD())
|
---|
1685 | {
|
---|
1686 |
|
---|
1687 | k = lons_outer.GetResponse(nsb_phepns[ict][ui],0.01,
|
---|
1688 | & nsb_trigresp[0],
|
---|
1689 | & nsb_fadcresp[0]);
|
---|
1690 | }
|
---|
1691 | else
|
---|
1692 | {
|
---|
1693 | k = lons.GetResponse(nsb_phepns[ict][ui],0.01,
|
---|
1694 | & nsb_trigresp[0],& nsb_fadcresp[0]);
|
---|
1695 | }
|
---|
1696 |
|
---|
1697 | if(k==0)
|
---|
1698 | {
|
---|
1699 | cout << "Exiting.\n";
|
---|
1700 | exit(1);
|
---|
1701 | }
|
---|
1702 | Fadc_CT[ict]->AddSignal(ui,nsb_fadcresp);
|
---|
1703 | }
|
---|
1704 | }
|
---|
1705 | }
|
---|
1706 | Fadc_CT[ict]->Pedestals();
|
---|
1707 |
|
---|
1708 | for(UInt_t ui=0;
|
---|
1709 | ui<((MGeomCam*)(camgeom.UncheckedAt(ict)))->GetNumPixels();
|
---|
1710 | ui++)
|
---|
1711 | {
|
---|
1712 | //
|
---|
1713 | // We add up n_slices FADC slices (pedestal subtracted), then
|
---|
1714 | // calculate the sigma_n-1 of this sum for the number of generated
|
---|
1715 | // noise events (=empty_events).
|
---|
1716 | //
|
---|
1717 | Float_t sumslices = Fadc_CT[ict]->AddNoiseInSlices(ui,1,n_slices);
|
---|
1718 | fadc_sigma[ui] += sumslices*sumslices;
|
---|
1719 |
|
---|
1720 | // Now the low gain:
|
---|
1721 | sumslices = Fadc_CT[ict]->AddNoiseInSlices(ui,0,n_slices);
|
---|
1722 | fadc_sigma_low[ui]+= sumslices*sumslices;
|
---|
1723 | }
|
---|
1724 | }
|
---|
1725 |
|
---|
1726 | for(UInt_t ui=0;
|
---|
1727 | ui<((MGeomCam*)(camgeom.UncheckedAt(ict)))->GetNumPixels();
|
---|
1728 | ui++)
|
---|
1729 | {
|
---|
1730 | Float_t s_high = fadc_sigma[ui] / (Float_t)(empty_events-1) /
|
---|
1731 | (Float_t)(n_slices);
|
---|
1732 | fadc_sigma[ui] = sqrt(s_high);
|
---|
1733 |
|
---|
1734 | Float_t s_low = fadc_sigma_low[ui] / (Float_t)(empty_events-1) /
|
---|
1735 | (Float_t)(n_slices);
|
---|
1736 | fadc_sigma_low[ui] = sqrt(s_low);
|
---|
1737 | }
|
---|
1738 |
|
---|
1739 | HeaderFadc[ict]->SetPedestalSigma(&fadc_sigma_low[0],&fadc_sigma[0],
|
---|
1740 | ((MGeomCam*)(camgeom.UncheckedAt(ict)))
|
---|
1741 | ->GetNumPixels());
|
---|
1742 | }
|
---|
1743 |
|
---|
1744 |
|
---|
1745 | if (is_calibration_run())
|
---|
1746 | {
|
---|
1747 | DoCalibration(Fadc_CT, Trigger_CT, camgeom, nsb_trigresp, nsb_fadcresp,
|
---|
1748 | &lons, &lons_outer, nsb_phepns, addElecNoise,
|
---|
1749 | &EvtTree, EvtHeader, McEvt, EvtData);
|
---|
1750 |
|
---|
1751 | HeaderTree.Fill() ;
|
---|
1752 |
|
---|
1753 | outfile_temp.Write();
|
---|
1754 | outfile_temp.Close();
|
---|
1755 |
|
---|
1756 | cout << endl << "Calibration run finished!" << endl << endl;
|
---|
1757 |
|
---|
1758 | return (0);
|
---|
1759 | }
|
---|
1760 |
|
---|
1761 | //
|
---|
1762 | // Read the reflector file with the Cherenkov data
|
---|
1763 | //
|
---|
1764 |
|
---|
1765 | // select input file
|
---|
1766 |
|
---|
1767 | if ( Data_From_STDIN )
|
---|
1768 | inputfile[0] = stdin;
|
---|
1769 |
|
---|
1770 | else
|
---|
1771 | {
|
---|
1772 | for(int ict = 0; ict < ct_Number; ict++)
|
---|
1773 | {
|
---|
1774 | log( SIGNATURE, "Opening input \"rfl\" file %s\n", inname_CT[ict] );
|
---|
1775 | inputfile[ict] = fopen( inname_CT[ict], "r" );
|
---|
1776 |
|
---|
1777 | if ( inputfile[ict] == NULL )
|
---|
1778 | error( SIGNATURE, "Cannot open input file: %s\n", inname_CT[ict] );
|
---|
1779 | }
|
---|
1780 | }
|
---|
1781 |
|
---|
1782 | // get signature, and check it
|
---|
1783 |
|
---|
1784 | for(int ict=0;ict<ct_Number;ict++)
|
---|
1785 | {
|
---|
1786 | if((reflector_file_version=check_reflector_file( inputfile[ict] ))==FALSE)
|
---|
1787 | exit(1);
|
---|
1788 | }
|
---|
1789 |
|
---|
1790 | // open data file
|
---|
1791 |
|
---|
1792 | log( SIGNATURE, "Opening data \"dat\" file %s\n", datname );
|
---|
1793 | datafile.open( datname );
|
---|
1794 |
|
---|
1795 | if ( datafile.bad() )
|
---|
1796 | error( SIGNATURE, "Cannot open data file: %s\n", datname );
|
---|
1797 |
|
---|
1798 | // initializes flag
|
---|
1799 |
|
---|
1800 | strcpy( flag, " \0" );
|
---|
1801 | strcpy( flag_new, " \0" );
|
---|
1802 |
|
---|
1803 | // allocate space for PMTs numbers of pixels
|
---|
1804 |
|
---|
1805 | fnpix = new float [ct_NPixels];
|
---|
1806 |
|
---|
1807 |
|
---|
1808 | //!@' @#### Main loop.
|
---|
1809 | //@'
|
---|
1810 |
|
---|
1811 | // get flag
|
---|
1812 |
|
---|
1813 | for(int ict=0;ict<ct_Number;ict++)
|
---|
1814 | fread( flag, SIZE_OF_FLAGS, 1, inputfile[ict] );
|
---|
1815 |
|
---|
1816 |
|
---|
1817 | // loop over the file
|
---|
1818 |
|
---|
1819 | still_in_loop = TRUE;
|
---|
1820 |
|
---|
1821 | // FIXME --- check if not eof for all input reflector files
|
---|
1822 |
|
---|
1823 | while (
|
---|
1824 | ((! Data_From_STDIN) && ( !feof(inputfile[0]) ))
|
---|
1825 | ||
|
---|
1826 | (Data_From_STDIN && still_in_loop)
|
---|
1827 | ) {
|
---|
1828 |
|
---|
1829 | // reading .rfl files
|
---|
1830 | if(!isA( flag, FLAG_START_OF_RUN )){
|
---|
1831 |
|
---|
1832 | // We break the main loop
|
---|
1833 | cout<<"Warning: Expected start of run flag, but found:"<<flag<<endl;
|
---|
1834 | cout<<" We break the main loop"<<endl;
|
---|
1835 | break;
|
---|
1836 | }
|
---|
1837 | else { // found start of run
|
---|
1838 |
|
---|
1839 | for(int ict=0;ict<ct_Number;ict++) {
|
---|
1840 |
|
---|
1841 | fread( flag_new, 4, 1, inputfile[ict] );
|
---|
1842 |
|
---|
1843 | if(!isA( flag_new, FLAG_START_OF_HEADER)){
|
---|
1844 |
|
---|
1845 | // We break the main loop
|
---|
1846 | cout<<"Warning: Expected start of run header flag, but found:"<<flag_new<<endl;
|
---|
1847 | cout<<" We break the main loop"<<endl;
|
---|
1848 | break;
|
---|
1849 | }
|
---|
1850 |
|
---|
1851 | // fread((char*)&mcrunh,(SIZE_OF_MCRUNHEADER)*sizeof(float), 1, inputfile[ict] );
|
---|
1852 | // AM, changed reading method, 02/2004:
|
---|
1853 |
|
---|
1854 | mcrunh.read(inputfile[ict]);
|
---|
1855 |
|
---|
1856 | }
|
---|
1857 |
|
---|
1858 | nshow=0;
|
---|
1859 |
|
---|
1860 | for(int ict=0;ict<ct_Number;ict++){
|
---|
1861 | fread( flag, SIZE_OF_FLAGS, 1, inputfile[ict] );
|
---|
1862 | }
|
---|
1863 | while( isA( flag, FLAG_START_OF_EVENT )){ // while there is a next event
|
---|
1864 | for(int ict=0;ict<ct_Number;ict++) {
|
---|
1865 | fread( flag_new, 4, 1, inputfile[ict] );
|
---|
1866 | if(!isA( flag_new, FLAG_EVENT_HEADER)){
|
---|
1867 |
|
---|
1868 | // We break while events loop
|
---|
1869 | cout<<"Warning: Expected start of event header flag, but found:"<<flag_new<<" "<<ict<<endl;
|
---|
1870 | cout<<" We break the while events loop"<<endl;
|
---|
1871 | break;
|
---|
1872 | }
|
---|
1873 | }
|
---|
1874 |
|
---|
1875 |
|
---|
1876 | //
|
---|
1877 | // Clear Trigger and Fadc
|
---|
1878 | //
|
---|
1879 | for(int ict=0;ict<ct_Number;ict++) {
|
---|
1880 | Trigger_CT[ict]->Reset() ;
|
---|
1881 | Trigger_CT[ict]->ClearFirst();
|
---|
1882 | Trigger_CT[ict]->ClearZero();
|
---|
1883 | Fadc_CT[ict]->Reset() ;
|
---|
1884 | }
|
---|
1885 |
|
---|
1886 | ++nshow;
|
---|
1887 | if((nshow+ntshow+1)%100 == 1)
|
---|
1888 | log(SIGNATURE, "Event %d(+%d)\n", nshow, ntshow);
|
---|
1889 |
|
---|
1890 | // get MCEventHeader
|
---|
1891 | if (reflector_file_version<6){
|
---|
1892 | for(int ict=0;ict<ct_Number;ict++)
|
---|
1893 | {
|
---|
1894 | mcevth[ict].read(inputfile[ict]);
|
---|
1895 | }
|
---|
1896 |
|
---|
1897 | }
|
---|
1898 | else{
|
---|
1899 | for(int ict=0;ict<ct_Number;ict++)
|
---|
1900 | {
|
---|
1901 | mcevth_2[ict].read(inputfile[ict]);
|
---|
1902 | }
|
---|
1903 | }
|
---|
1904 |
|
---|
1905 | //
|
---|
1906 | // AM March 2004 simplified impact parameter calculation,
|
---|
1907 | // and allowed for correct estimate also for telescopes not
|
---|
1908 | // placed at Corsika's origin of coordinates (0.,0.).
|
---|
1909 | // FIXME: telescope coordinates still set by the user in the
|
---|
1910 | // input card, since they are not available in the reflector
|
---|
1911 | // file!
|
---|
1912 | //
|
---|
1913 | // Calculate impact parameter as distance between telescope
|
---|
1914 | // location and shower axis. In the previous implementation,
|
---|
1915 | // the definition was the distance between telescope axis and
|
---|
1916 | // shower axis, but this has less physical meaning in general.
|
---|
1917 | // Light yield depends above all on distance to shower axis!
|
---|
1918 | // Of course for shower axis paralel to telescope the old and
|
---|
1919 | // the new definitions of impact parameter agree.
|
---|
1920 | //
|
---|
1921 |
|
---|
1922 |
|
---|
1923 | // read the direction of the incoming shower
|
---|
1924 | // It is done only for one telescope since it is suposed
|
---|
1925 | // to be the same shower for all of them
|
---|
1926 | if (reflector_file_version<6){
|
---|
1927 | thetashw = mcevth[0].get_theta();
|
---|
1928 | phishw = mcevth[0].get_phi();
|
---|
1929 | }
|
---|
1930 | else{
|
---|
1931 | thetashw = mcevth_2[0].get_theta();
|
---|
1932 | phishw = mcevth_2[0].get_phi();
|
---|
1933 | }
|
---|
1934 | Zenith=thetashw; Azimutal=phishw;
|
---|
1935 |
|
---|
1936 | // calculate vector for shower
|
---|
1937 |
|
---|
1938 | l1 = sin(thetashw)*cos(phishw);
|
---|
1939 | m1 = sin(thetashw)*sin(phishw);
|
---|
1940 | n1 = cos(thetashw);
|
---|
1941 |
|
---|
1942 | //
|
---|
1943 | // Note, A.M.:
|
---|
1944 | // Attention! "core vector from mcevth*.get_core
|
---|
1945 | // is the vector from the core to the telescope!
|
---|
1946 | //
|
---|
1947 | Float_t core2ct_x;
|
---|
1948 | Float_t core2ct_y;
|
---|
1949 |
|
---|
1950 | if (reflector_file_version<6)
|
---|
1951 | mcevth[0].get_core(&core2ct_x, &core2ct_y);
|
---|
1952 | else
|
---|
1953 | mcevth_2[0].get_core(&core2ct_x, &core2ct_y);
|
---|
1954 |
|
---|
1955 | //
|
---|
1956 | // Then true core position in Corsika's system is:
|
---|
1957 | //
|
---|
1958 |
|
---|
1959 | coreX = CTx[0] - core2ct_x;
|
---|
1960 | coreY = CTy[0] - core2ct_y;
|
---|
1961 |
|
---|
1962 | //
|
---|
1963 | // FIXME: This may not work fine for CTs at z != 0 !!
|
---|
1964 | //
|
---|
1965 | for(int ict=0;ict<ct_Number;ict++)
|
---|
1966 | impactD[ict] = dist_r_P( CTx[ict], CTy[ict], CTz[ict],
|
---|
1967 | l1, m1, n1, coreX, coreY, 0. );
|
---|
1968 |
|
---|
1969 |
|
---|
1970 | // energy cut
|
---|
1971 |
|
---|
1972 | if ( Select_Energy ) {
|
---|
1973 | if (reflector_file_version<6)
|
---|
1974 | if (( mcevth[0].get_energy() < Select_Energy_le ) ||
|
---|
1975 | ( mcevth[0].get_energy() > Select_Energy_ue )) {
|
---|
1976 | log(SIGNATURE, "select_energy: shower rejected.\n");
|
---|
1977 | continue;
|
---|
1978 | }
|
---|
1979 | else
|
---|
1980 | if (( mcevth_2[0].get_energy() < Select_Energy_le ) ||
|
---|
1981 | ( mcevth_2[0].get_energy() > Select_Energy_ue )) {
|
---|
1982 | log(SIGNATURE, "select_energy: shower rejected.\n");
|
---|
1983 | continue;
|
---|
1984 | }
|
---|
1985 | }
|
---|
1986 |
|
---|
1987 | inumphe=0;
|
---|
1988 |
|
---|
1989 | for(int ict=0;ict<ct_Number;ict++){
|
---|
1990 |
|
---|
1991 | // Read first and last time and put inumphe_CT[0] to 0
|
---|
1992 |
|
---|
1993 | if (reflector_file_version<6)
|
---|
1994 | mcevth[ict].get_times(&arrtmin_ns,&arrtmax_ns);
|
---|
1995 | else
|
---|
1996 | mcevth_2[ict].get_times(&arrtmin_ns,&arrtmax_ns);
|
---|
1997 |
|
---|
1998 | inumphe_CT[ict]=0;
|
---|
1999 |
|
---|
2000 |
|
---|
2001 | // Obtain the FADC jitter of 1 FADC slice. This is a time to be added to the
|
---|
2002 | // time of all photons in an event, before digitalization of the signal. It is
|
---|
2003 | // therefore the same time shift for all pixels in a CT.
|
---|
2004 |
|
---|
2005 | fadc_jitter[ict] =
|
---|
2006 | (1./Fadc_CT[ict]->GetFadcSlicesPerNanosec()) * RandomNumber; //ns
|
---|
2007 |
|
---|
2008 | // read the photons and produce the photoelectrons
|
---|
2009 |
|
---|
2010 | k = produce_phes( inputfile[ict],
|
---|
2011 | ((MGeomCam*)(camgeom.UncheckedAt(ict))),
|
---|
2012 | WAVEBANDBOUND1,
|
---|
2013 | WAVEBANDBOUND6,
|
---|
2014 | Trigger_CT[ict], // will be changed by the function!
|
---|
2015 | Fadc_CT[ict], // will be changed by the function!
|
---|
2016 | &inumphe_CT[ict], // important for later: the size of photoe[]
|
---|
2017 | fnpix, // will be changed by the function!
|
---|
2018 | &ncph[ict], // will be changed by the function!
|
---|
2019 | &arrtmin_ns, // will be changed by the function!
|
---|
2020 | &arrtmax_ns, // will be changed by the function!
|
---|
2021 | ict,
|
---|
2022 | mirror_frac[ict],
|
---|
2023 | fadc_jitter[ict]);
|
---|
2024 |
|
---|
2025 | inumphe = (inumphe < inumphe_CT[ict])? inumphe_CT[ict] : inumphe;
|
---|
2026 | // inumphe will be the maximum number of phe in any of the telescopes
|
---|
2027 |
|
---|
2028 |
|
---|
2029 | if( k != 0 ){ // non-zero return value means error
|
---|
2030 | cout << "Exiting.\n";
|
---|
2031 | exit(1);
|
---|
2032 | }
|
---|
2033 | }
|
---|
2034 |
|
---|
2035 | // NSB simulation
|
---|
2036 |
|
---|
2037 | if(simulateNSB && inumphe >= nphe2NSB)
|
---|
2038 | {
|
---|
2039 |
|
---|
2040 | if(Starfield_rotate){
|
---|
2041 |
|
---|
2042 | // Introduction rho angle
|
---|
2043 |
|
---|
2044 | zenith = thetashw;
|
---|
2045 | azimutal = phishw;
|
---|
2046 | C1 = 0.48 * sin(zenith) - 0.87 * cos(zenith) * cos(azimutal);
|
---|
2047 | C3 = (0.87 * cos(zenith) - 0.48 * sin(zenith) * cos(azimutal));
|
---|
2048 | C2 = sqrt( sin(zenith) * sin(zenith) * sin(azimutal) * sin(azimutal) +
|
---|
2049 | C3 * C3 );
|
---|
2050 | rho = acos( C1/C2 );
|
---|
2051 |
|
---|
2052 | if ( sin(azimutal) < 0)
|
---|
2053 | rho = 2 * 3.14159 - rho;
|
---|
2054 | else
|
---|
2055 | rho = rho;
|
---|
2056 |
|
---|
2057 | rho = rho*180/3.14159;
|
---|
2058 |
|
---|
2059 | // Rotation of the NSB
|
---|
2060 | // FIXME --- We should rotate for all cameras. Is it always the same rho?
|
---|
2061 | for(int ict=0;ict<ct_Number;ict++)
|
---|
2062 | k = size_rotated(&nsb_phepns_rotated[ict][0],
|
---|
2063 | nsb_phepns[ict],
|
---|
2064 | rho);
|
---|
2065 | }
|
---|
2066 |
|
---|
2067 | // Fill trigger and fadc response in the trigger class from the database
|
---|
2068 | for(int ict=0;ict<ct_Number;ict++)
|
---|
2069 | {
|
---|
2070 | for(UInt_t ui=0;
|
---|
2071 | ui<((MGeomCam*)(camgeom.UncheckedAt(ict)))->GetNumPixels();
|
---|
2072 | ui++)
|
---|
2073 | {
|
---|
2074 | if(nsb_phepns_rotated[ict][ui]>0.0)
|
---|
2075 | {
|
---|
2076 | if((*((MGeomCam*)(camgeom.UncheckedAt(ict))))[ui].GetD() >
|
---|
2077 | (*((MGeomCam*)(camgeom.UncheckedAt(ict))))[0].GetD())
|
---|
2078 | {
|
---|
2079 | k=lons_outer.GetResponse(nsb_phepns_rotated[ict][ui],0.01,
|
---|
2080 | & nsb_trigresp[0],
|
---|
2081 | & nsb_fadcresp[0]);
|
---|
2082 | }
|
---|
2083 | else
|
---|
2084 | {
|
---|
2085 | k=lons.GetResponse(nsb_phepns_rotated[ict][ui],0.01,
|
---|
2086 | & nsb_trigresp[0],& nsb_fadcresp[0]);
|
---|
2087 | }
|
---|
2088 | if(k==0)
|
---|
2089 | {
|
---|
2090 | cout << "Exiting.\n";
|
---|
2091 | exit(1);
|
---|
2092 | }
|
---|
2093 | Trigger_CT[ict]->AddNSB(ui,nsb_trigresp);
|
---|
2094 | Fadc_CT[ict]->AddSignal(ui,nsb_fadcresp);
|
---|
2095 | }
|
---|
2096 | }
|
---|
2097 | }
|
---|
2098 |
|
---|
2099 | }// end if(simulateNSB && inumphe >= nphe2NSB) ...
|
---|
2100 |
|
---|
2101 |
|
---|
2102 | for(int ict=0;ict<ct_Number;ict++)
|
---|
2103 | {
|
---|
2104 | inumphensb[ict]=0;
|
---|
2105 |
|
---|
2106 | for (UInt_t ui=0;
|
---|
2107 | ui < ((MGeomCam*)(camgeom.UncheckedAt(ict)))->GetNumPixels();
|
---|
2108 | ui++)
|
---|
2109 | inumphensb[ict]+=nsb_phepns[ict][ui]*TOTAL_TRIGGER_TIME;
|
---|
2110 |
|
---|
2111 | ntcph[ict]+=ncph[ict];
|
---|
2112 | if ((nshow+ntshow+1)%100 == 1){
|
---|
2113 | log(SIGNATURE, "End of this event: %d cphs(+%d). . .\n",
|
---|
2114 | ncph[ict], ntcph[ict]);
|
---|
2115 |
|
---|
2116 | cout << "Total number of phes in CT "<<ict<<": "
|
---|
2117 | << inumphe_CT[ict]<<" (+ ";
|
---|
2118 | cout<<inumphensb[ict]<<" mean expected number from NSB)"<<endl;
|
---|
2119 | }
|
---|
2120 | }
|
---|
2121 |
|
---|
2122 | // skip it ?
|
---|
2123 |
|
---|
2124 | int i;
|
---|
2125 | for (i=0; i<nSkip; ++i ) {
|
---|
2126 | if (Skip[i] == (nshow+ntshow)) {
|
---|
2127 | i = -1;
|
---|
2128 | break;
|
---|
2129 | }
|
---|
2130 | }
|
---|
2131 |
|
---|
2132 | // if after the previous loop, the exit value of i is -1
|
---|
2133 | // then the shower number is in the list of showers to be
|
---|
2134 | // skipped
|
---|
2135 |
|
---|
2136 | if (i == -1) {
|
---|
2137 | log(SIGNATURE, "\t\tskipped!\n");
|
---|
2138 | continue;
|
---|
2139 | }
|
---|
2140 |
|
---|
2141 | //++++++++++++++++++++++++++++++++++++++++++++++++++
|
---|
2142 | // at this point we have a camera full of
|
---|
2143 | // ph.e.s
|
---|
2144 | // we should first apply the trigger condition,
|
---|
2145 | // and if there's trigger, then clean the image,
|
---|
2146 | // calculate the islands statistics and the
|
---|
2147 | // other parameters of the image (Hillas' parameters
|
---|
2148 | // and so on).
|
---|
2149 | //--------------------------------------------------
|
---|
2150 |
|
---|
2151 | // TRIGGER HERE
|
---|
2152 |
|
---|
2153 | // We should simulate the AC coupling behaviour:
|
---|
2154 | // For the FADC it is only done for the NSB while producing
|
---|
2155 | // the StarResponse database.
|
---|
2156 | // For the trigger is done in the Trigger.Diskriminate(), which
|
---|
2157 | // is called later (it should be separated to speed up the program)
|
---|
2158 | //
|
---|
2159 |
|
---|
2160 | // now the noise of the electronic
|
---|
2161 | // (preamps, optical transmission,..) is introduced.
|
---|
2162 | // This is done inside the class MTrigger by the method ElecNoise.
|
---|
2163 | //
|
---|
2164 |
|
---|
2165 | for(int ict=0;ict<ct_Number;ict++)
|
---|
2166 | {
|
---|
2167 | if (addElecNoise && inumphe >= nphe2NSB)
|
---|
2168 | {
|
---|
2169 | Trigger_CT[ict]->ElecNoise(Trigger_noise);
|
---|
2170 | Fadc_CT[ict]->ElecNoise();
|
---|
2171 | }
|
---|
2172 | }
|
---|
2173 |
|
---|
2174 | // now a shift in the fadc signal due to the pedestals is
|
---|
2175 | // introduced
|
---|
2176 | // This is done inside the class MFadc by the method Pedestals
|
---|
2177 |
|
---|
2178 | for(int ict=0;ict<ct_Number;ict++)
|
---|
2179 | Fadc_CT[ict]->Pedestals();
|
---|
2180 |
|
---|
2181 |
|
---|
2182 | // We study several trigger conditons
|
---|
2183 | if(Trigger_Loop)
|
---|
2184 | {
|
---|
2185 | // Set to zero the flag to know if some conditon has triggered
|
---|
2186 | btrigger=0;
|
---|
2187 | flagstoring = 0;
|
---|
2188 |
|
---|
2189 | // Loop over trigger threshold
|
---|
2190 | int iconcount;
|
---|
2191 | for (iconcount=0, ithrescount=0, fthrescount=Trigger_loop_lthres;
|
---|
2192 | fthrescount <= Trigger_loop_uthres;
|
---|
2193 | ithrescount++, fthrescount += Trigger_loop_sthres)
|
---|
2194 | {
|
---|
2195 | for (int i=0;i<ct_NPixels;i++)
|
---|
2196 | {
|
---|
2197 | fpixelthres[i] =
|
---|
2198 | ((Float_t)(fthrescount)>=qThreshold[0][i])?
|
---|
2199 | (Float_t)(fthrescount):qThreshold[0][i];
|
---|
2200 |
|
---|
2201 | // Rise the discrimnator threshold to avoid huge rates
|
---|
2202 |
|
---|
2203 | if(riseDiskThres>0.0 && simulateNSB && inumphe >= nphe2NSB)
|
---|
2204 | for(int ii=0;ii<ct_NPixels;ii++)
|
---|
2205 | if( nsb_phepns_rotated[0][ii]>riseDiskThres)
|
---|
2206 | fpixelthres[ii]=secureDiskThres;
|
---|
2207 | }
|
---|
2208 | Trigger_CT[0]->SetThreshold(fpixelthres);
|
---|
2209 |
|
---|
2210 | Trigger_CT[0]->Diskriminate();
|
---|
2211 |
|
---|
2212 | //
|
---|
2213 | // look if in all the signals in the trigger signal branch
|
---|
2214 | // is a possible Trigger. Therefore we habe to diskriminate all
|
---|
2215 | // the simulated analog signals (Method Diskriminate in class
|
---|
2216 | // MTrigger). We look simultanously for the moments at which
|
---|
2217 | // there are more than TRIGGER_MULTI pixels above the
|
---|
2218 | // CHANNEL_THRESHOLD.
|
---|
2219 | //
|
---|
2220 |
|
---|
2221 | // Set trigger flags to zero
|
---|
2222 | Lev0=0;
|
---|
2223 | Lev1=0;
|
---|
2224 |
|
---|
2225 | // loop over multiplicity of trigger configuration
|
---|
2226 | for (imulticount = Trigger_loop_lmult;
|
---|
2227 | imulticount <= Trigger_loop_umult;
|
---|
2228 | imulticount++)
|
---|
2229 | {
|
---|
2230 | Trigger_CT[0]->SetMultiplicity(imulticount);
|
---|
2231 | Trigger_CT[0]->ClearZero();
|
---|
2232 |
|
---|
2233 | Lev0=(Short_t) Trigger_CT[0]->ZeroLevel();
|
---|
2234 | if (Lev0>0 || Write_All_Event_Headers || btrigger)
|
---|
2235 | {
|
---|
2236 |
|
---|
2237 | // loop over topologies
|
---|
2238 | for(itopocount=Trigger_loop_ltop;
|
---|
2239 | itopocount<=Trigger_loop_utop;
|
---|
2240 | itopocount++)
|
---|
2241 | {
|
---|
2242 | Lev1=0;
|
---|
2243 |
|
---|
2244 | if(itopocount==0 && imulticount>7)
|
---|
2245 | continue;
|
---|
2246 |
|
---|
2247 | //COBB if(itopocount==2 && imulticount<3) continue;
|
---|
2248 | // It only makes to look for a different topology
|
---|
2249 | // if there are 3 or more N pixels.
|
---|
2250 | if(imulticount<3)
|
---|
2251 | Trigger_CT[0]->SetTopology(1);
|
---|
2252 | else
|
---|
2253 | {
|
---|
2254 | // We should be careful that topologies are sort from
|
---|
2255 | // the less to the more restrictive one.
|
---|
2256 | Trigger_CT[0]->SetTopology(isorttopo[itopocount]);
|
---|
2257 | }
|
---|
2258 | Trigger_CT[0]->ClearFirst();
|
---|
2259 |
|
---|
2260 | //
|
---|
2261 | // Start the First Level Trigger simulation
|
---|
2262 | //
|
---|
2263 | if(Lev0!=0)
|
---|
2264 | Lev1=Trigger_CT[0]->FirstLevel();
|
---|
2265 | if(Lev1>0) {
|
---|
2266 | btrigger= 1;
|
---|
2267 | ntriggerloop[ithrescount]
|
---|
2268 | [imulticount-Trigger_loop_lmult]
|
---|
2269 | [itopocount-Trigger_loop_ltop]++;
|
---|
2270 | }
|
---|
2271 |
|
---|
2272 | Lev0=1;
|
---|
2273 | Int_t NumImages = Lev1;
|
---|
2274 | if(Lev1==0 && (Write_All_Event_Headers || btrigger))
|
---|
2275 | {
|
---|
2276 | btrigger= 1;
|
---|
2277 | NumImages=1;
|
---|
2278 | Lev0=0;
|
---|
2279 | }
|
---|
2280 |
|
---|
2281 | for (Int_t ii=0;ii<NumImages;ii++)
|
---|
2282 | {
|
---|
2283 | if (Write_McTrig)
|
---|
2284 | {
|
---|
2285 | McTrig[iconcount]->SetFirstLevel ((ii+1)*Lev0);
|
---|
2286 | McTrig[iconcount]->
|
---|
2287 | SetTime(Trigger_CT[0]->GetFirstLevelTime(ii),ii+1);
|
---|
2288 | Trigger_CT[0]->GetMapDiskriminator(trigger_map);
|
---|
2289 | McTrig[iconcount]->SetMapPixels(trigger_map,ii);
|
---|
2290 | }
|
---|
2291 | //
|
---|
2292 | // fill inside the class fadc the member output
|
---|
2293 | //
|
---|
2294 |
|
---|
2295 | Fadc_CT[0]->TriggeredFadc(Trigger_CT[0]->
|
---|
2296 | GetFirstLevelTime(ii));
|
---|
2297 |
|
---|
2298 | if( Write_RawEvt )
|
---|
2299 | {
|
---|
2300 | //
|
---|
2301 | // Fill the header of this event
|
---|
2302 | //
|
---|
2303 |
|
---|
2304 | EvtHeader[iconcount]->
|
---|
2305 | FillHeader( (UInt_t) (ntshow + nshow),0);
|
---|
2306 |
|
---|
2307 | // Set trigger pattern. WARNING: the trigger pattern of real
|
---|
2308 | // data is inverted for the MRawRunHeader.fFormatVersion=5
|
---|
2309 | // which is the one we now set in the camera outputs. Hence
|
---|
2310 | /// we use the binary inversion operator "~" below:
|
---|
2311 |
|
---|
2312 | EvtHeader[iconcount]->
|
---|
2313 | SetTriggerPattern((UInt_t)~MTriggerPattern::kTriggerLvl1);
|
---|
2314 |
|
---|
2315 | // fill pixel information
|
---|
2316 | if (Lev1){
|
---|
2317 | if (addElecNoise) Fadc_CT[0]->DigitalNoise();
|
---|
2318 | for(UInt_t i=0;
|
---|
2319 | i<((MGeomCam*)(camgeom.UncheckedAt(0)))
|
---|
2320 | ->GetNumPixels();i++){
|
---|
2321 | //
|
---|
2322 | // AM 15 01 2004: commented out "continue"
|
---|
2323 | // statement, so that also pixels with no
|
---|
2324 | // C-photons will be written to the output
|
---|
2325 | // in case the camera is run with no noise.
|
---|
2326 | // if(!Fadc_CT[0]->IsPixelUsed(i)) continue;
|
---|
2327 |
|
---|
2328 | for (j=0;j<FADC_slices_written;j++){
|
---|
2329 | fadcValues->AddAt(Fadc_CT[0]->
|
---|
2330 | GetFadcSignal(i,j),j);
|
---|
2331 | fadcValuesLow->AddAt(Fadc_CT[0]->
|
---|
2332 | GetFadcLowGainSignal(i,j),j);
|
---|
2333 | }
|
---|
2334 | EvtData[iconcount]->AddPixel(i,fadcValues,0);
|
---|
2335 | EvtData[iconcount]->AddPixel(i,fadcValuesLow,kTRUE);
|
---|
2336 | }
|
---|
2337 | }
|
---|
2338 | }
|
---|
2339 | }
|
---|
2340 | //
|
---|
2341 | // Increase counter of analised trigger conditions
|
---|
2342 | //
|
---|
2343 | iconcount++;
|
---|
2344 | }
|
---|
2345 | }
|
---|
2346 | else{
|
---|
2347 | break;
|
---|
2348 | }
|
---|
2349 | }
|
---|
2350 | if (!btrigger) break;
|
---|
2351 | }
|
---|
2352 | if (btrigger){
|
---|
2353 |
|
---|
2354 | //
|
---|
2355 | // fill the MMcEvt with all information
|
---|
2356 | //
|
---|
2357 |
|
---|
2358 | if(!flagstoring)
|
---|
2359 | nstoredevents++;
|
---|
2360 | flagstoring = 1;
|
---|
2361 |
|
---|
2362 | if (Write_McEvt) {
|
---|
2363 | Float_t ftime, ltime;
|
---|
2364 | if (reflector_file_version<6){
|
---|
2365 | mcevth[0].get_times(&ftime, <ime);
|
---|
2366 |
|
---|
2367 | McEvtBasic[0]->Fill((MMcEvt::ParticleId_t) mcevth[0].get_primary(),
|
---|
2368 | mcevth[0].get_energy(), impactD[0],
|
---|
2369 | phiCT[0], thetaCT[0]);
|
---|
2370 |
|
---|
2371 | McEvt[0]->Fill( 0,
|
---|
2372 | (UShort_t) mcevth[0].get_primary() ,
|
---|
2373 | mcevth[0].get_energy(),
|
---|
2374 | -1.0,
|
---|
2375 | -1.0,
|
---|
2376 | -1.0,
|
---|
2377 | mcevth[0].get_theta(),
|
---|
2378 | mcevth[0].get_phi(),
|
---|
2379 | mcevth[0].get_core(),
|
---|
2380 | coreX,
|
---|
2381 | coreY,
|
---|
2382 | impactD[0],
|
---|
2383 | phiCT[0],
|
---|
2384 | thetaCT[0],
|
---|
2385 | ftime,
|
---|
2386 | ltime,
|
---|
2387 | 0,
|
---|
2388 | 0,
|
---|
2389 | 0,
|
---|
2390 | 0,
|
---|
2391 | 0,
|
---|
2392 | 0,
|
---|
2393 | 0,
|
---|
2394 | (UInt_t)mcevth[0].get_CORSIKA(),
|
---|
2395 | (UInt_t)mcevth[0].get_AtmAbs(),
|
---|
2396 | (UInt_t)(mcevth[0].get_MirrAbs()+
|
---|
2397 | mcevth[0].get_OutOfMirr()+
|
---|
2398 | mcevth[0].get_BlackSpot()),
|
---|
2399 | (UInt_t) ncph[0],
|
---|
2400 | (UInt_t) inumphe_CT[0],
|
---|
2401 | (UInt_t) inumphensb[0]+inumphe_CT[0],
|
---|
2402 | -1.0,
|
---|
2403 | -1.0,
|
---|
2404 | -1.0,
|
---|
2405 | fadc_jitter[0]);
|
---|
2406 | }
|
---|
2407 | else{
|
---|
2408 | Float_t Nmax, t0, tmax, a, b, c, chi2;
|
---|
2409 | mcevth_2[0].get_times(&ftime, <ime);
|
---|
2410 | chi2=mcevth_2[0].get_NKGfit(&Nmax, &t0, &tmax, &a, &b, &c);
|
---|
2411 |
|
---|
2412 | McEvtBasic[0]->Fill((MMcEvt::ParticleId_t) mcevth_2[0].get_primary(),
|
---|
2413 | mcevth_2[0].get_energy(), impactD[0],
|
---|
2414 | mcevth_2[0].get_phi_CT(),
|
---|
2415 | mcevth_2[0].get_theta_CT());
|
---|
2416 |
|
---|
2417 | McEvt[0]->Fill((UInt_t) mcevth_2[0].get_evt_number(),
|
---|
2418 | (UShort_t) mcevth_2[0].get_primary() ,
|
---|
2419 | mcevth_2[0].get_energy(),
|
---|
2420 | mcevth_2[0].get_thick0(),
|
---|
2421 | mcevth_2[0].get_first_target(),
|
---|
2422 | mcevth_2[0].get_z_first_int(),
|
---|
2423 | mcevth_2[0].get_theta(),
|
---|
2424 | mcevth_2[0].get_phi(),
|
---|
2425 | mcevth_2[0].get_core(),
|
---|
2426 | coreX,
|
---|
2427 | coreY,
|
---|
2428 | impactD[0],
|
---|
2429 | mcevth_2[0].get_phi_CT(),
|
---|
2430 | mcevth_2[0].get_theta_CT(),
|
---|
2431 | ftime,
|
---|
2432 | ltime,
|
---|
2433 | Nmax,
|
---|
2434 | t0,
|
---|
2435 | tmax,
|
---|
2436 | a,
|
---|
2437 | b,
|
---|
2438 | c,
|
---|
2439 | chi2,
|
---|
2440 | (UInt_t)mcevth_2[0].get_CORSIKA(),
|
---|
2441 | (UInt_t)mcevth_2[0].get_AtmAbs(),
|
---|
2442 | (UInt_t)(mcevth_2[0].get_MirrAbs()+
|
---|
2443 | mcevth_2[0].get_OutOfMirr()+
|
---|
2444 | mcevth_2[0].get_BlackSpot()),
|
---|
2445 | (UInt_t) ncph[0],
|
---|
2446 | (UInt_t) inumphe_CT[0],
|
---|
2447 | (UInt_t) inumphensb[0]+inumphe_CT[0],
|
---|
2448 | mcevth_2[0].get_ElecFraction(),
|
---|
2449 | mcevth_2[0].get_MuonFraction(),
|
---|
2450 | mcevth_2[0].get_OtherFraction(),
|
---|
2451 | fadc_jitter[0]);
|
---|
2452 | }
|
---|
2453 | }
|
---|
2454 | // Fill the Tree with the current leaves of each branch
|
---|
2455 | i=EvtTree.Fill() ;
|
---|
2456 |
|
---|
2457 | // Clear the branches
|
---|
2458 | if(Write_McTrig){
|
---|
2459 | for(int i=0;i<numberBranches;i++){
|
---|
2460 | McTrig[i]->Clear() ;
|
---|
2461 | }
|
---|
2462 | }
|
---|
2463 | if( Write_RawEvt ){
|
---|
2464 | for(int i=0;i<numberBranches;i++){
|
---|
2465 | EvtHeader[i]->Clear() ;
|
---|
2466 | EvtData[i]->ResetPixels (0, 0);
|
---|
2467 | }
|
---|
2468 | }
|
---|
2469 | if (Write_McEvt)
|
---|
2470 | {
|
---|
2471 | McEvt[0]->Clear();
|
---|
2472 | McEvtBasic[0]->Clear();
|
---|
2473 | }
|
---|
2474 | }
|
---|
2475 | }
|
---|
2476 |
|
---|
2477 | // We study a single trigger condition
|
---|
2478 | else {
|
---|
2479 |
|
---|
2480 | // Set to zero the flag to know if some conditon has triggered
|
---|
2481 | btrigger=0;
|
---|
2482 | flagstoring = 0;
|
---|
2483 |
|
---|
2484 | for(int ict = 0; ict < ct_Number; ict++)
|
---|
2485 | {
|
---|
2486 |
|
---|
2487 | // Setting trigger conditions
|
---|
2488 | Trigger_CT[ict]->SetMultiplicity(Trigger_multiplicity[ict]);
|
---|
2489 | Trigger_CT[ict]->SetTopology(Trigger_topology[ict]);
|
---|
2490 | for (int i=0;i<ct_NPixels;i++)
|
---|
2491 | fpixelthres[i]=qThreshold[ict][i];
|
---|
2492 |
|
---|
2493 | // Rise the discrimnator threshold to avoid huge rates
|
---|
2494 | if(riseDiskThres>0.0 && simulateNSB && inumphe >= nphe2NSB)
|
---|
2495 | for(int ii=0;ii<ct_NPixels;ii++)
|
---|
2496 | {
|
---|
2497 | if( nsb_phepns_rotated[ict][ii]>riseDiskThres)
|
---|
2498 | fpixelthres[ii]=secureDiskThres;
|
---|
2499 | }
|
---|
2500 |
|
---|
2501 | Trigger_CT[ict]->SetThreshold(fpixelthres);
|
---|
2502 |
|
---|
2503 | Trigger_CT[ict]->Diskriminate() ;
|
---|
2504 |
|
---|
2505 | //
|
---|
2506 | // Look if in all the signals in the trigger signal branch
|
---|
2507 | // is a possible Trigger. Therefore we have to discriminate all
|
---|
2508 | // the simulated analog signals (Method Diskriminate in class
|
---|
2509 | // MTrigger). We look simultaneously for the moments at which
|
---|
2510 | // there are more than TRIGGER_MULTI pixels above the
|
---|
2511 | // CHANNEL_THRESHOLD.
|
---|
2512 | //
|
---|
2513 |
|
---|
2514 | Lev0MT[ict] = (Short_t) Trigger_CT[ict]->ZeroLevel() ;
|
---|
2515 |
|
---|
2516 | Lev1MT[ict] = 0 ;
|
---|
2517 |
|
---|
2518 | //
|
---|
2519 | // Start the First Level Trigger simulation
|
---|
2520 | //
|
---|
2521 |
|
---|
2522 | if ( Lev0MT[ict] > 0 /*|| Write_All_Event_Headers*/)
|
---|
2523 | Lev1MT[ict]= Trigger_CT[ict]->FirstLevel();
|
---|
2524 |
|
---|
2525 | if (Lev1MT[ict]>0)
|
---|
2526 | ++ntrigger[ict];
|
---|
2527 |
|
---|
2528 | }
|
---|
2529 |
|
---|
2530 | Int_t NumImages = 0;
|
---|
2531 | Int_t CT_triggered=0;
|
---|
2532 | for(int ict=0;ict<ct_Number;ict++)
|
---|
2533 | {
|
---|
2534 | if(NumImages==0 && Lev1MT[ict]>0)
|
---|
2535 | CT_triggered=ict;
|
---|
2536 | NumImages = (NumImages>=Lev1MT[ict]) ? NumImages : 1;
|
---|
2537 | Lev0MT[ict]=1;
|
---|
2538 |
|
---|
2539 | if (Lev1MT[ict]==0 && Write_All_Event_Headers)
|
---|
2540 | {
|
---|
2541 | NumImages=1;
|
---|
2542 | Lev0MT[ict]=0;
|
---|
2543 | }
|
---|
2544 | }
|
---|
2545 |
|
---|
2546 | for(int ict=0;ict<ct_Number;ict++){
|
---|
2547 | for(Int_t ii=0;ii<NumImages;ii++){
|
---|
2548 |
|
---|
2549 | btrigger=1;
|
---|
2550 |
|
---|
2551 | // Loop over different level one triggers
|
---|
2552 |
|
---|
2553 | //
|
---|
2554 | // fill inside class fadc the member output
|
---|
2555 | //
|
---|
2556 | if(Lev1MT[ict]>0)
|
---|
2557 | Fadc_CT[ict]->
|
---|
2558 | TriggeredFadc(Trigger_CT[ict]->GetFirstLevelTime(ii));
|
---|
2559 | else
|
---|
2560 | Fadc_CT[ict]->
|
---|
2561 | TriggeredFadc(Trigger_CT[CT_triggered]->GetFirstLevelTime(ii));
|
---|
2562 |
|
---|
2563 | if(!flagstoring)
|
---|
2564 | nstoredevents++;
|
---|
2565 | flagstoring = 1;
|
---|
2566 |
|
---|
2567 | if (Write_McTrig){
|
---|
2568 | McTrig[ict]->SetFirstLevel (Lev1MT[ict]);
|
---|
2569 | McTrig[ict]
|
---|
2570 | ->SetTime(Trigger_CT[ict]->GetFirstLevelTime(ii),ii+1);
|
---|
2571 | Trigger_CT[ict]->GetMapDiskriminator(trigger_map);
|
---|
2572 | McTrig[ict]->SetMapPixels(trigger_map,ii);
|
---|
2573 | }
|
---|
2574 |
|
---|
2575 | // Fill Evt information
|
---|
2576 |
|
---|
2577 | if (Write_RawEvt){
|
---|
2578 |
|
---|
2579 | //
|
---|
2580 | // Fill the header of this event
|
---|
2581 | //
|
---|
2582 |
|
---|
2583 | EvtHeader[ict]
|
---|
2584 | ->FillHeader ( (UInt_t) (ntshow + nshow) , 0 ) ;
|
---|
2585 |
|
---|
2586 |
|
---|
2587 | // Set trigger pattern. WARNING: the trigger pattern of real
|
---|
2588 | // data is inverted for the MRawRunHeader.fFormatVersion=5
|
---|
2589 | // which is the one we now set in the camera outputs. Hence
|
---|
2590 | /// we use the binary inversion operator "~" below:
|
---|
2591 | EvtHeader[ict]->SetTriggerPattern((UInt_t)~MTriggerPattern::kTriggerLvl1);
|
---|
2592 |
|
---|
2593 | // Fill pixel information
|
---|
2594 | // AM 17/2/2005: added condition on inumphe. Noise is not generated for
|
---|
2595 | // events with less than phe2NSB photoelectrons, and then it is better not
|
---|
2596 | // to write the images of those events to the output, so that we avoid them
|
---|
2597 | // to be processed (with no noise) later in the chain.
|
---|
2598 |
|
---|
2599 | if (Lev1MT[ict] && inumphe >= nphe2NSB)
|
---|
2600 | {
|
---|
2601 | if (addElecNoise)
|
---|
2602 | Fadc_CT[ict]->DigitalNoise();
|
---|
2603 | for(UInt_t i=0;
|
---|
2604 | i<((MGeomCam*)(camgeom.UncheckedAt(ict)))->GetNumPixels();
|
---|
2605 | i++){
|
---|
2606 | //
|
---|
2607 | // AM 15 01 2004 Commented out "continue" statement, so that also pixels
|
---|
2608 | // containing no C-photons will be written to the output in case of running
|
---|
2609 | // camera with no noise added to the signal.
|
---|
2610 | // if(!Fadc_CT[ict]->IsPixelUsed(i)) continue;
|
---|
2611 | //
|
---|
2612 | for (j = 0; j < FADC_slices_written; j++)
|
---|
2613 | {
|
---|
2614 | fadcValues->AddAt(Fadc_CT[ict]->GetFadcSignal(i,j),j);
|
---|
2615 | fadcValuesLow->AddAt(Fadc_CT[ict]->GetFadcLowGainSignal(i,j),j);
|
---|
2616 | }
|
---|
2617 | EvtData[ict]->AddPixel(i,fadcValues,0);
|
---|
2618 | EvtData[ict]->AddPixel(i,fadcValuesLow,kTRUE);
|
---|
2619 | }
|
---|
2620 | }
|
---|
2621 | }
|
---|
2622 | }
|
---|
2623 | //
|
---|
2624 | // if a first level trigger occurred, then
|
---|
2625 | // 1. do some other stuff (not implemented)
|
---|
2626 | // 2. start the gui tool
|
---|
2627 |
|
---|
2628 | if(FADC_Scan){
|
---|
2629 | if ( Lev0MT[ict] > 0 ) {
|
---|
2630 | Fadc_CT[ict]->ShowSignal( McEvt[ict], (Float_t) 60. ) ;
|
---|
2631 | }
|
---|
2632 | }
|
---|
2633 |
|
---|
2634 | if(Trigger_Scan){
|
---|
2635 | if ( Lev0MT[ict] > 0 ) {
|
---|
2636 | Trigger_CT[ict]->ShowSignal(McEvt[ict]) ;
|
---|
2637 | }
|
---|
2638 | }
|
---|
2639 |
|
---|
2640 | } // end CT loop
|
---|
2641 |
|
---|
2642 | // If there is trigger in some telescope or we store all showers
|
---|
2643 | if(btrigger){
|
---|
2644 | if (Write_McEvt){
|
---|
2645 | //
|
---|
2646 | // fill the MMcEvt with all information
|
---|
2647 | //
|
---|
2648 |
|
---|
2649 | for (int ict=0;ict<ct_Number;ict++){
|
---|
2650 | Float_t ftime, ltime;
|
---|
2651 | if (reflector_file_version<6){
|
---|
2652 | mcevth[ict].get_times(&ftime, <ime);
|
---|
2653 |
|
---|
2654 | McEvtBasic[ict]->Fill((MMcEvt::ParticleId_t) mcevth[0].get_primary(),
|
---|
2655 | mcevth[ict].get_energy(), impactD[ict],
|
---|
2656 | phiCT[ict], thetaCT[ict]);
|
---|
2657 |
|
---|
2658 | McEvt[ict]->Fill( 0,
|
---|
2659 | (UShort_t) mcevth[0].get_primary() ,
|
---|
2660 | mcevth[ict].get_energy(),
|
---|
2661 | -1.0,
|
---|
2662 | -1.0,
|
---|
2663 | -1.0,
|
---|
2664 | mcevth[ict].get_theta(),
|
---|
2665 | mcevth[ict].get_phi(),
|
---|
2666 | mcevth[ict].get_core(),
|
---|
2667 | coreX,
|
---|
2668 | coreY,
|
---|
2669 | impactD[ict],
|
---|
2670 | phiCT[ict],
|
---|
2671 | thetaCT[ict],
|
---|
2672 | ftime,
|
---|
2673 | ltime,
|
---|
2674 | 0,
|
---|
2675 | 0,
|
---|
2676 | 0,
|
---|
2677 | 0,
|
---|
2678 | 0,
|
---|
2679 | 0,
|
---|
2680 | 0,
|
---|
2681 | (UInt_t)mcevth[ict].get_CORSIKA(),
|
---|
2682 | (UInt_t)mcevth[ict].get_AtmAbs(),
|
---|
2683 | (UInt_t)(mcevth[ict].get_MirrAbs()+mcevth[0].get_OutOfMirr()+mcevth[0].get_BlackSpot()),
|
---|
2684 | (UInt_t) ncph[ict],
|
---|
2685 | (UInt_t) inumphe_CT[ict],
|
---|
2686 | (UInt_t) inumphensb[ict]+inumphe_CT[ict],
|
---|
2687 | -1.0,
|
---|
2688 | -1.0,
|
---|
2689 | -1.0,
|
---|
2690 | fadc_jitter[ict]);
|
---|
2691 | }
|
---|
2692 | else{
|
---|
2693 | Float_t Nmax, t0, tmax, a, b, c, chi2;
|
---|
2694 | mcevth_2[ict].get_times(&ftime, <ime);
|
---|
2695 | chi2=mcevth_2[ict].get_NKGfit(&Nmax, &t0, &tmax, &a, &b, &c);
|
---|
2696 |
|
---|
2697 | McEvtBasic[ict]->Fill((MMcEvt::ParticleId_t)mcevth_2[ict].get_primary(),
|
---|
2698 | mcevth_2[ict].get_energy(), impactD[ict],
|
---|
2699 | mcevth_2[ict].get_phi_CT(),
|
---|
2700 | mcevth_2[ict].get_theta_CT());
|
---|
2701 |
|
---|
2702 |
|
---|
2703 | McEvt[ict]->Fill( (UInt_t) mcevth_2[ict].get_evt_number(),
|
---|
2704 | (UShort_t) mcevth_2[ict].get_primary() ,
|
---|
2705 | mcevth_2[ict].get_energy(),
|
---|
2706 | mcevth_2[ict].get_thick0(),
|
---|
2707 | mcevth_2[ict].get_first_target(),
|
---|
2708 | mcevth_2[ict].get_z_first_int(),
|
---|
2709 | mcevth_2[ict].get_theta(),
|
---|
2710 | mcevth_2[ict].get_phi(),
|
---|
2711 | mcevth_2[ict].get_core(),
|
---|
2712 | coreX,
|
---|
2713 | coreY,
|
---|
2714 | impactD[ict],
|
---|
2715 | mcevth_2[ict].get_phi_CT(),
|
---|
2716 | mcevth_2[ict].get_theta_CT(),
|
---|
2717 | ftime,
|
---|
2718 | ltime,
|
---|
2719 | Nmax,
|
---|
2720 | t0,
|
---|
2721 | tmax,
|
---|
2722 | a,
|
---|
2723 | b,
|
---|
2724 | c,
|
---|
2725 | chi2,
|
---|
2726 | (UInt_t)mcevth_2[ict].get_CORSIKA(),
|
---|
2727 | (UInt_t)mcevth_2[ict].get_AtmAbs(),
|
---|
2728 | (UInt_t) (mcevth_2[ict].get_MirrAbs()+mcevth_2[ict].get_OutOfMirr()+mcevth_2[ict].get_BlackSpot()),
|
---|
2729 | (UInt_t) ncph[ict],
|
---|
2730 | (UInt_t) inumphe_CT[ict],
|
---|
2731 | (UInt_t) inumphensb[ict]+inumphe_CT[ict],
|
---|
2732 | mcevth_2[ict].get_ElecFraction(),
|
---|
2733 | mcevth_2[ict].get_MuonFraction(),
|
---|
2734 | mcevth_2[ict].get_OtherFraction(),
|
---|
2735 | fadc_jitter[ict]);
|
---|
2736 | }
|
---|
2737 | }
|
---|
2738 | }
|
---|
2739 | // We do not count photons out of the camera.
|
---|
2740 |
|
---|
2741 |
|
---|
2742 | //
|
---|
2743 | // write it out to the file outfile
|
---|
2744 | //
|
---|
2745 |
|
---|
2746 | EvtTree.Fill() ;
|
---|
2747 | }
|
---|
2748 |
|
---|
2749 | // clear all
|
---|
2750 | for(int ict=0;ict<ct_Number;ict++){
|
---|
2751 | if (Write_RawEvt) EvtHeader[ict]->Clear() ;
|
---|
2752 | if (Write_RawEvt) EvtData[ict]->ResetPixels(0,0);
|
---|
2753 | if (Write_McTrig) McTrig[ict]->Clear() ;
|
---|
2754 | if (Write_McEvt)
|
---|
2755 | {
|
---|
2756 | McEvt[ict]->Clear() ;
|
---|
2757 | McEvtBasic[ict]->Clear();
|
---|
2758 | }
|
---|
2759 | }
|
---|
2760 | }
|
---|
2761 |
|
---|
2762 | #ifdef __DEBUG__
|
---|
2763 | printf("\n");
|
---|
2764 |
|
---|
2765 | for ( ici=0; ici<PIX_ARRAY_SIDE; ++ici ) {
|
---|
2766 |
|
---|
2767 | for ( icj=0; icj<PIX_ARRAY_SIDE; ++icj ) {
|
---|
2768 |
|
---|
2769 | if ( (int)pixels[ici][icj][PIXNUM] > -1 ) {
|
---|
2770 |
|
---|
2771 | if ( fnpix[(int)pixels[ici][icj][PIXNUM]] > 0. ) {
|
---|
2772 |
|
---|
2773 | printf ("@@ %4d %4d %10f %10f %4f (%4d %4d)\n", nshow,
|
---|
2774 | (int)pixels[ici][icj][PIXNUM],
|
---|
2775 | pixels[ici][icj][PIXX],
|
---|
2776 | pixels[ici][icj][PIXY],
|
---|
2777 | fnpix[(int)pixels[ici][icj][PIXNUM]], ici, icj);
|
---|
2778 |
|
---|
2779 | }
|
---|
2780 | }
|
---|
2781 | }
|
---|
2782 | }
|
---|
2783 |
|
---|
2784 | for (int i=0;
|
---|
2785 | i<((MGeomCam*)(camgeom.UncheckedAt(0)))->GetNumPixels(); ++i) {
|
---|
2786 | printf("%d (%d): ", i, npixneig[i]);
|
---|
2787 | for (j=0; j<npixneig[i]; ++i)
|
---|
2788 | printf(" %d", pixneig[i][j]);
|
---|
2789 | printf("\n");
|
---|
2790 | }
|
---|
2791 |
|
---|
2792 | #endif // __DEBUG__
|
---|
2793 |
|
---|
2794 |
|
---|
2795 | // We search the maximum impact parameter fo the simualted showers
|
---|
2796 | maxpimpact=maxpimpact<impactD[0]?impactD[0]:maxpimpact;
|
---|
2797 |
|
---|
2798 | // look for the next event
|
---|
2799 |
|
---|
2800 | for(int ict=0;ict<ct_Number;ict++)
|
---|
2801 | fread( flag, SIZE_OF_FLAGS, 1, inputfile[ict] );
|
---|
2802 |
|
---|
2803 | } // end while there is a next event
|
---|
2804 |
|
---|
2805 | if( !isA( flag, FLAG_END_OF_RUN )){
|
---|
2806 | error( SIGNATURE, "Expected end of run flag, but found: %s\n", flag );
|
---|
2807 | break;
|
---|
2808 | }
|
---|
2809 | else { // found end of run
|
---|
2810 | ntshow += nshow;
|
---|
2811 | log(SIGNATURE, "End of this run with %d events . . .\n", nshow);
|
---|
2812 |
|
---|
2813 | //fread( flag, SIZE_OF_FLAGS, 1, inputfile );
|
---|
2814 | for(int ict=0;ict<ct_Number;ict++)
|
---|
2815 | fread( flag, SIZE_OF_FLAGS, 1, inputfile[ict] );
|
---|
2816 |
|
---|
2817 | if( isA( flag, FLAG_END_OF_FILE ) ){ // end of file
|
---|
2818 | log(SIGNATURE, "End of file . . .\n");
|
---|
2819 | still_in_loop = FALSE;
|
---|
2820 | log(SIGNATURE, "Reading ASCII files at the end of the reflector file. . .\n");
|
---|
2821 | for(int ict=0;ict<ct_Number;ict++){
|
---|
2822 | read_ascii(inputfile[ict], McConfigRunHeader[ict]);
|
---|
2823 | McConfigRunHeader[ict]->SetMissPointingX(missP_x);
|
---|
2824 | McConfigRunHeader[ict]->SetMissPointingY(missP_y);
|
---|
2825 |
|
---|
2826 | McConfigRunHeader[ict]->SetMirrorFraction(mirror_frac[ict]);
|
---|
2827 |
|
---|
2828 | if ( Spotsigma > 0.)
|
---|
2829 | {
|
---|
2830 | Float_t ref_spotsigma = McConfigRunHeader[ict]->GetPointSpread();
|
---|
2831 | Float_t newsigma = sqrt(ref_spotsigma * ref_spotsigma +
|
---|
2832 | Spot_x* Spot_x);
|
---|
2833 | McConfigRunHeader[ict]->SetPointSpreadX(newsigma);
|
---|
2834 | newsigma = sqrt(ref_spotsigma * ref_spotsigma + Spot_y* Spot_y);
|
---|
2835 | McConfigRunHeader[ict]->SetPointSpreadY(newsigma);
|
---|
2836 | }
|
---|
2837 | }
|
---|
2838 | if ((! Data_From_STDIN) && ( !feof(inputfile[0]) )){
|
---|
2839 |
|
---|
2840 | // we have concatenated input files.
|
---|
2841 | // get signature of the next part and check it.
|
---|
2842 |
|
---|
2843 | if((reflector_file_version=check_reflector_file( inputfile[0] ))==FALSE){
|
---|
2844 | log(SIGNATURE, "Next file is not recognised as a reflector file.\n");
|
---|
2845 | log(SIGNATURE, "Stopping ...\n");
|
---|
2846 | break;
|
---|
2847 | }
|
---|
2848 |
|
---|
2849 | }
|
---|
2850 |
|
---|
2851 | for(int ict=0;ict<ct_Number;ict++)
|
---|
2852 | fread( flag, SIZE_OF_FLAGS, 1, inputfile[ict] );
|
---|
2853 |
|
---|
2854 | } // end if found end of file
|
---|
2855 | } // end if found end of run
|
---|
2856 |
|
---|
2857 | } // end if else found start of run
|
---|
2858 | } // end big while loop
|
---|
2859 |
|
---|
2860 | //<@ Finally we should fill the McRunHeader
|
---|
2861 |
|
---|
2862 | Float_t heights[10];
|
---|
2863 | time_t ltime;
|
---|
2864 | Float_t ftime;
|
---|
2865 | Float_t rnum;
|
---|
2866 | Float_t viewcone[2]={0,0};
|
---|
2867 |
|
---|
2868 | get_starfield_center(&sfRaH,&sfRaM,&sfRaS,&sfDeD,&sfDeM,&sfDeS);
|
---|
2869 | if (reflector_file_version<6){
|
---|
2870 | mcevth[0].get_theta_range(&shthetamin, &shthetamax);
|
---|
2871 | mcevth[0].get_phi_range(&shphimin,&shphimax);
|
---|
2872 | mcevth[0].get_theta_range(&shthetamin, &shthetamax);
|
---|
2873 | mcevth[0].get_phi_range(&shphimin,&shphimax);
|
---|
2874 | corsika=UInt_t(mcevth[0].get_VersionPGM()*1000);
|
---|
2875 | for (int i=0; i< 10;i++)
|
---|
2876 | heights[i]=mcevth[0].get_HeightLev (i);
|
---|
2877 | rnum=mcevth[0].get_RunNumber();
|
---|
2878 | }
|
---|
2879 | else{
|
---|
2880 | mcevth_2[0].get_theta_range(&shthetamin, &shthetamax);
|
---|
2881 | mcevth_2[0].get_phi_range(&shphimin,&shphimax);
|
---|
2882 | corsika=UInt_t(mcevth_2[0].get_VersionPGM()*1000);
|
---|
2883 | for (int i=0; i< 10;i++)
|
---|
2884 | heights[i]=mcevth_2[0].get_HeightLev (i);
|
---|
2885 | rnum=mcevth_2[0].get_RunNumber();
|
---|
2886 | mcevth_2[0].get_viewcone(&viewcone[0],&viewcone[1]);
|
---|
2887 | }
|
---|
2888 |
|
---|
2889 | if(!Trigger_Loop) icontrigger=0;
|
---|
2890 | time (<ime);
|
---|
2891 | ftime = ((Float_t)ltime)/1000;
|
---|
2892 |
|
---|
2893 | if (reflector_file_version<6)
|
---|
2894 | McRunHeader->Fill(rnum,
|
---|
2895 | (UInt_t) 0,
|
---|
2896 | mcevth[0].get_DateRun(),
|
---|
2897 | ftime,
|
---|
2898 | icontrigger,
|
---|
2899 | !Write_All_Event_Headers,
|
---|
2900 | Write_McEvt,
|
---|
2901 | Write_McTrig,
|
---|
2902 | Write_McFADC,
|
---|
2903 | Write_RawEvt,
|
---|
2904 | addElecNoise,
|
---|
2905 | ct_NPixels,
|
---|
2906 | (UInt_t)ntshow,
|
---|
2907 | (UInt_t)nstoredevents,
|
---|
2908 | 0,
|
---|
2909 | sfRaH,
|
---|
2910 | sfRaM,
|
---|
2911 | sfRaS,
|
---|
2912 | sfDeD,
|
---|
2913 | sfDeM,
|
---|
2914 | sfDeS,
|
---|
2915 | meanNSB,
|
---|
2916 | shthetamax,
|
---|
2917 | shthetamin,
|
---|
2918 | shphimax,
|
---|
2919 | shphimin,
|
---|
2920 | maxpimpact,
|
---|
2921 | mcevth[0].get_CWaveLower(),
|
---|
2922 | mcevth[0].get_CWaveUpper(),
|
---|
2923 | mcevth[0].get_slope(),
|
---|
2924 | 1,
|
---|
2925 | heights,
|
---|
2926 | corsika,
|
---|
2927 | (UInt_t)(reflector_file_version*100),
|
---|
2928 | (UInt_t)(VERSION*100),
|
---|
2929 | 0);
|
---|
2930 | else
|
---|
2931 | McRunHeader->Fill(rnum,
|
---|
2932 | (UInt_t) 0,
|
---|
2933 | mcevth_2[0].get_DateRun(),
|
---|
2934 | ftime,
|
---|
2935 | icontrigger,
|
---|
2936 | !Write_All_Event_Headers,
|
---|
2937 | Write_McEvt,
|
---|
2938 | Write_McTrig,
|
---|
2939 | Write_McFADC,
|
---|
2940 | Write_RawEvt,
|
---|
2941 | addElecNoise,
|
---|
2942 | ct_NPixels,
|
---|
2943 | (UInt_t)ntshow,
|
---|
2944 | (UInt_t)nstoredevents,
|
---|
2945 | 0,
|
---|
2946 | sfRaH,
|
---|
2947 | sfRaM,
|
---|
2948 | sfRaS,
|
---|
2949 | sfDeD,
|
---|
2950 | sfDeM,
|
---|
2951 | sfDeS,
|
---|
2952 | meanNSB,
|
---|
2953 | shthetamax,
|
---|
2954 | shthetamin,
|
---|
2955 | shphimax,
|
---|
2956 | shphimin,
|
---|
2957 | maxpimpact,
|
---|
2958 | mcevth_2[0].get_CWaveLower(),
|
---|
2959 | mcevth_2[0].get_CWaveUpper(),
|
---|
2960 | mcevth_2[0].get_slope(),
|
---|
2961 | 1,
|
---|
2962 | heights,
|
---|
2963 | corsika,
|
---|
2964 | (UInt_t)(reflector_file_version*100),
|
---|
2965 | (UInt_t)(VERSION*100),
|
---|
2966 | 0);
|
---|
2967 | // Fill some missing values for MRawRunHeader
|
---|
2968 |
|
---|
2969 | RunHeader->SetRunNumber((UInt_t)rnum);
|
---|
2970 | RunHeader->SetNumEvents(nstoredevents);
|
---|
2971 |
|
---|
2972 | // Fill MMcCorsikaRunHeader
|
---|
2973 |
|
---|
2974 | Float_t constantC[50];
|
---|
2975 | mcrunh.get_constantC(&constantC[0]);
|
---|
2976 | Float_t constantCKA[40];
|
---|
2977 | mcrunh.get_constantCKA(&constantCKA[0]);
|
---|
2978 | Float_t constantCETA[5];
|
---|
2979 | mcrunh.get_constantCETA(&constantCETA[0]);
|
---|
2980 | Float_t constantCSTRBA[11];
|
---|
2981 | mcrunh.get_constantCSTRBA(&constantCSTRBA[0]);
|
---|
2982 | Float_t constantAATM[5];
|
---|
2983 | mcrunh.get_constantAATM(&constantAATM[0]);
|
---|
2984 | Float_t constantBATM[5];
|
---|
2985 | mcrunh.get_constantBATM(&constantBATM[0]);
|
---|
2986 | Float_t constantCATM[5];
|
---|
2987 | mcrunh.get_constantCATM(&constantCATM[0]);
|
---|
2988 | Float_t constantNFL[4];
|
---|
2989 | mcrunh.get_constantNFL(&constantNFL[0]);
|
---|
2990 |
|
---|
2991 | if(reflector_file_version>5)
|
---|
2992 | McCorsikaRunHeader->Fill(rnum,
|
---|
2993 | mcrunh.get_date(),
|
---|
2994 | corsika,
|
---|
2995 | 1,
|
---|
2996 | heights,
|
---|
2997 | mcevth_2[0].get_slope(),
|
---|
2998 | mcrunh.get_ELow(),
|
---|
2999 | mcrunh.get_EUpp(),
|
---|
3000 | mcrunh.get_EGS4(),
|
---|
3001 | mcrunh.get_NKG(),
|
---|
3002 | mcrunh.get_Ecutoffh(),
|
---|
3003 | mcrunh.get_Ecutoffm(),
|
---|
3004 | mcrunh.get_Ecutoffe(),
|
---|
3005 | mcrunh.get_Ecutoffg(),
|
---|
3006 | constantC,
|
---|
3007 | constantCKA,
|
---|
3008 | constantCETA,
|
---|
3009 | constantCSTRBA,
|
---|
3010 | constantAATM,
|
---|
3011 | constantBATM,
|
---|
3012 | constantCATM,
|
---|
3013 | constantNFL,
|
---|
3014 | viewcone,
|
---|
3015 | mcrunh.get_wobble(),
|
---|
3016 | mcrunh.get_atmophere()
|
---|
3017 | );
|
---|
3018 |
|
---|
3019 | // Store qe for each PMT in output file
|
---|
3020 | TArrayF qe_pmt;
|
---|
3021 | TArrayF wav_pmt;
|
---|
3022 |
|
---|
3023 | for(int ict=0;ict<ct_Number;ict++){
|
---|
3024 | McConfigRunHeader[ict]->InitSizePMTs(ct_NPixels);
|
---|
3025 | for(int i=0; i<(Int_t)((MGeomCam*)(camgeom.UncheckedAt(ict)))->GetNumPixels();i++){
|
---|
3026 | McConfigRunHeader[ict]->SetPmtTimeJitter(pmt_jitter);
|
---|
3027 | McConfigRunHeader[ict]->AddPMT(i);
|
---|
3028 | MGeomPMT &pmt = McConfigRunHeader[ict]->GetPMT(i);
|
---|
3029 | qe_pmt.Set(pointsQE[ict],QE[ict][i][1]);
|
---|
3030 | wav_pmt.Set(pointsQE[ict],QElambda);
|
---|
3031 | pmt.SetArraySize(pointsQE[ict]);
|
---|
3032 | pmt.SetPMTContent(i,wav_pmt,qe_pmt);
|
---|
3033 | }
|
---|
3034 |
|
---|
3035 | // Store Light Collection factors in the output file
|
---|
3036 | TArrayF theta_lc;
|
---|
3037 | TArrayF factor_lc;
|
---|
3038 | TArrayF factor_lc_outer;
|
---|
3039 |
|
---|
3040 | theta_lc.Set(pointsWC,WC[0]);
|
---|
3041 | factor_lc.Set(pointsWC,WC[1]);
|
---|
3042 | factor_lc_outer.Set(pointsWC,WC_outer[1]);
|
---|
3043 |
|
---|
3044 | McConfigRunHeader[ict]->SetLightCollection(theta_lc, factor_lc,
|
---|
3045 | factor_lc_outer);
|
---|
3046 |
|
---|
3047 | }
|
---|
3048 |
|
---|
3049 | // Fill the Header Tree with the current leaves of each branch
|
---|
3050 | HeaderTree.Fill() ;
|
---|
3051 |
|
---|
3052 | //++
|
---|
3053 | // put the Event to the root file
|
---|
3054 | //--
|
---|
3055 |
|
---|
3056 | outfile_temp.Write() ;
|
---|
3057 | outfile_temp.Close() ;
|
---|
3058 |
|
---|
3059 | // close input file
|
---|
3060 |
|
---|
3061 | if (Trigger_Loop){
|
---|
3062 | log( SIGNATURE, "%d event(s), with a total of %d C.photons\n",
|
---|
3063 | ntshow, ntcph[0] );
|
---|
3064 | datafile<<ntshow<<" event(s), with a total of "<<ntcph[0]<<" C.photons"<<endl;
|
---|
3065 | log( SIGNATURE, "Trigger Mode. \n");
|
---|
3066 | log( SIGNATURE, "Fraction of triggers: \n");
|
---|
3067 | datafile<<"Fraction of triggers: "<<endl;
|
---|
3068 | for (ithrescount=0, fthrescount=Trigger_loop_lthres;fthrescount<=Trigger_loop_uthres;ithrescount++, fthrescount+=Trigger_loop_sthres){
|
---|
3069 | for (imulticount=Trigger_loop_lmult;imulticount<=Trigger_loop_umult;imulticount++){
|
---|
3070 | for(itopocount=Trigger_loop_ltop;itopocount<=Trigger_loop_utop;itopocount++){
|
---|
3071 | log( SIGNATURE, "Thres %5.1f, Multi %d, Topo %d: %5.1f%% (%d out of %d)\n",
|
---|
3072 | fthrescount,imulticount,isorttopo[itopocount],((float)ntriggerloop[ithrescount][imulticount-Trigger_loop_lmult][itopocount-Trigger_loop_ltop] / ((float)ntshow) * 100.0), ntriggerloop[ithrescount][imulticount-Trigger_loop_lmult][itopocount-Trigger_loop_ltop], ntshow);
|
---|
3073 | datafile<<"Thres "<<fthrescount<<", Multi "<<imulticount<<", Topo"<<isorttopo[itopocount]<<": ";
|
---|
3074 | datafile<<((float)ntriggerloop[ithrescount][imulticount-Trigger_loop_lmult][itopocount-Trigger_loop_ltop] / ((float)ntshow) * 100.0)<<"% ("<<ntriggerloop[ithrescount][imulticount-Trigger_loop_lmult][itopocount-Trigger_loop_ltop]<<" out of "<<ntshow<<")"<<endl;
|
---|
3075 | }
|
---|
3076 | }
|
---|
3077 | }
|
---|
3078 | }
|
---|
3079 | else{
|
---|
3080 | for(int ict=0;ict<ct_Number;ict++){
|
---|
3081 | log( SIGNATURE,
|
---|
3082 | "%d event(s), with a total of %d C.photons in CT %i (%s)\n",
|
---|
3083 | ntshow, ntcph[ict],ict,GeometryName[ict] );
|
---|
3084 | datafile<<ntshow<<" event(s), with a total of "<<ntcph[ict]
|
---|
3085 | <<" C.photons in CT "<<ict<<" ("<<GeometryName[ict]<<")"<<endl;
|
---|
3086 | log( SIGNATURE, "Fraction of triggers: %5.1f%% (%d out of %d)\n",
|
---|
3087 | ((float)ntrigger[ict]) / ((float)ntshow) * 100.0, ntrigger[ict], ntshow);
|
---|
3088 | datafile<<"Fraction of triggers: "<<((float)ntrigger[ict]) / ((float)ntshow) * 100.0<<" ("<<ntrigger[ict]<<" out of "<<ntshow<<" )"<<endl;
|
---|
3089 | }
|
---|
3090 | }
|
---|
3091 |
|
---|
3092 | // close files
|
---|
3093 |
|
---|
3094 | log( SIGNATURE, "Closing files\n" );
|
---|
3095 |
|
---|
3096 | if( ! Data_From_STDIN ){
|
---|
3097 | for(int ict=0;ict<ct_Number;ict++)
|
---|
3098 | fclose( inputfile[ict] );
|
---|
3099 | }
|
---|
3100 | datafile.close();
|
---|
3101 |
|
---|
3102 | // program finished
|
---|
3103 |
|
---|
3104 | log( SIGNATURE, "Done.\n");
|
---|
3105 |
|
---|
3106 | return( 0 );
|
---|
3107 | }
|
---|
3108 | //!@}
|
---|
3109 |
|
---|
3110 | // @T \newpage
|
---|
3111 |
|
---|
3112 | //!@subsection Functions definition.
|
---|
3113 |
|
---|
3114 | //!-----------------------------------------------------------
|
---|
3115 | // @name present
|
---|
3116 | //
|
---|
3117 | // @desc Make some presentation
|
---|
3118 | //
|
---|
3119 | // @date Sat Jun 27 05:58:56 MET DST 1998
|
---|
3120 | //------------------------------------------------------------
|
---|
3121 | // @function
|
---|
3122 |
|
---|
3123 | //!@{
|
---|
3124 | void
|
---|
3125 | present(void)
|
---|
3126 | {
|
---|
3127 | cout << "##################################################\n"
|
---|
3128 | << SIGNATURE << '\n' << '\n'
|
---|
3129 | << "Processor of the reflector output\n"
|
---|
3130 | << "J. C. Gonzalez, Jun 1998\n"
|
---|
3131 | << "O. Blanch, A. Moralejo, 2004\n"
|
---|
3132 | << "##################################################\n\n"
|
---|
3133 | << flush ;
|
---|
3134 | }
|
---|
3135 | //!@}
|
---|
3136 |
|
---|
3137 |
|
---|
3138 | //!-----------------------------------------------------------
|
---|
3139 | // @name usage
|
---|
3140 | //
|
---|
3141 | // @desc show help
|
---|
3142 | //
|
---|
3143 | // @date Tue Dec 15 16:23:30 MET 1998
|
---|
3144 | //------------------------------------------------------------
|
---|
3145 | // @function
|
---|
3146 |
|
---|
3147 | //!@{
|
---|
3148 | void
|
---|
3149 | usage(void)
|
---|
3150 | {
|
---|
3151 | present();
|
---|
3152 | cout << "\nusage ::\n\n"
|
---|
3153 | << "\t camera "
|
---|
3154 | << " [ -@ paramfile ] "
|
---|
3155 | << " [ -h ] "
|
---|
3156 | << "\n\n or \n\n"
|
---|
3157 | << "\t camera < paramfile"
|
---|
3158 | << "\n\n";
|
---|
3159 | exit(0);
|
---|
3160 | }
|
---|
3161 | //!@}
|
---|
3162 |
|
---|
3163 |
|
---|
3164 | //!-----------------------------------------------------------
|
---|
3165 | // @name log
|
---|
3166 | //
|
---|
3167 | // @desc function to send log information
|
---|
3168 | //
|
---|
3169 | // @var funct Name of the caller function
|
---|
3170 | // @var fmt Format to be used (message)
|
---|
3171 | // @var ... Other information to be shown
|
---|
3172 | //
|
---|
3173 | // @date Sat Jun 27 05:58:56 MET DST 1998
|
---|
3174 | //------------------------------------------------------------
|
---|
3175 | // @function
|
---|
3176 |
|
---|
3177 | //!@{
|
---|
3178 | void
|
---|
3179 | log(const char *funct, char *fmt, ...)
|
---|
3180 | {
|
---|
3181 | va_list args;
|
---|
3182 |
|
---|
3183 | // Display the name of the function that called error
|
---|
3184 | printf("[%s]: ", funct);
|
---|
3185 |
|
---|
3186 | // Display the remainder of the message
|
---|
3187 | va_start(args, fmt);
|
---|
3188 | vprintf(fmt, args);
|
---|
3189 | va_end(args);
|
---|
3190 | }
|
---|
3191 | //!@}
|
---|
3192 |
|
---|
3193 |
|
---|
3194 | //!-----------------------------------------------------------
|
---|
3195 | // @name error
|
---|
3196 | //
|
---|
3197 | // @desc function to send an error message, and abort the program
|
---|
3198 | //
|
---|
3199 | // @var funct Name of the caller function
|
---|
3200 | // @var fmt Format to be used (message)
|
---|
3201 | // @var ... Other information to be shown
|
---|
3202 | //
|
---|
3203 | // @date Sat Jun 27 05:58:56 MET DST 1998
|
---|
3204 | //------------------------------------------------------------
|
---|
3205 | // @function
|
---|
3206 |
|
---|
3207 | //!@{
|
---|
3208 | void
|
---|
3209 | error(const char *funct, char *fmt, ...)
|
---|
3210 | {
|
---|
3211 | va_list args;
|
---|
3212 |
|
---|
3213 | // Display the name of the function that called error
|
---|
3214 | fprintf(stdout, "ERROR in %s: ", funct);
|
---|
3215 |
|
---|
3216 | // Display the remainder of the message
|
---|
3217 | va_start(args, fmt);
|
---|
3218 | vfprintf(stdout, fmt, args);
|
---|
3219 | va_end(args);
|
---|
3220 |
|
---|
3221 | perror(funct);
|
---|
3222 |
|
---|
3223 | exit(1);
|
---|
3224 | }
|
---|
3225 | //!@}
|
---|
3226 |
|
---|
3227 |
|
---|
3228 | //!-----------------------------------------------------------
|
---|
3229 | // @name isA
|
---|
3230 | //
|
---|
3231 | // @desc returns TRUE(FALSE), if the flag is(is not) the given
|
---|
3232 | //
|
---|
3233 | // @var s1 String to be searched
|
---|
3234 | // @var flag Flag to compare with string s1
|
---|
3235 | // @return TRUE: both strings match; FALSE: oth.
|
---|
3236 | //
|
---|
3237 | // @date Wed Jul 8 15:25:39 MET DST 1998
|
---|
3238 | //------------------------------------------------------------
|
---|
3239 | // @function
|
---|
3240 |
|
---|
3241 | //!@{
|
---|
3242 | int
|
---|
3243 | isA( char * s1, const char * flag ) {
|
---|
3244 | return ( (strncmp((char *)s1, flag, SIZE_OF_FLAGS)==0) ? 1 : 0 );
|
---|
3245 | }
|
---|
3246 | //!@}
|
---|
3247 |
|
---|
3248 |
|
---|
3249 | //!-----------------------------------------------------------
|
---|
3250 | // @name read_QE
|
---|
3251 | //
|
---|
3252 | // @desc read QE data
|
---|
3253 | //
|
---|
3254 | // @date thu 5 17:59:57 CEST 2002
|
---|
3255 | //------------------------------------------------------------
|
---|
3256 | // @function
|
---|
3257 |
|
---|
3258 | //!@{
|
---|
3259 | void
|
---|
3260 | read_QE(char fname[256], int ict){
|
---|
3261 | ifstream qefile;
|
---|
3262 | char line[LINE_MAX_LENGTH];
|
---|
3263 | int i, j, icount;
|
---|
3264 | float qe;
|
---|
3265 |
|
---|
3266 | //------------------------------------------------------------
|
---|
3267 | // second, pixels' QE
|
---|
3268 |
|
---|
3269 | // try to open the file
|
---|
3270 |
|
---|
3271 | log("read_QE", "Opening the file \"%s\" . . .\n", fname);
|
---|
3272 |
|
---|
3273 | qefile.open( fname );
|
---|
3274 |
|
---|
3275 | // if it is wrong or does not exist, exit
|
---|
3276 |
|
---|
3277 | if ( qefile.bad() )
|
---|
3278 | error( "read_QE", "Cannot open \"%s\". Exiting.\n", fname );
|
---|
3279 |
|
---|
3280 | // read file
|
---|
3281 |
|
---|
3282 | log("read_QE", "Reading data . . .\n");
|
---|
3283 |
|
---|
3284 | i=-1;
|
---|
3285 | icount = 0;
|
---|
3286 |
|
---|
3287 | while ( ! qefile.eof() ) {
|
---|
3288 |
|
---|
3289 | // get line from the file
|
---|
3290 |
|
---|
3291 | qefile.getline(line, LINE_MAX_LENGTH);
|
---|
3292 |
|
---|
3293 | // skip if comment
|
---|
3294 |
|
---|
3295 | if ( *line == '#' )
|
---|
3296 | continue;
|
---|
3297 |
|
---|
3298 | // if it is the first valid value, it is the number of QE data points
|
---|
3299 |
|
---|
3300 | if ( i < 0 ) {
|
---|
3301 |
|
---|
3302 | // get the number of datapoints
|
---|
3303 |
|
---|
3304 | sscanf(line, "%d", &pointsQE[ict]);
|
---|
3305 |
|
---|
3306 | // allocate memory for the table of QEs
|
---|
3307 |
|
---|
3308 | QE[ict] = new float ** [ct_NPixels];
|
---|
3309 |
|
---|
3310 | for ( i=0; i<ct_NPixels; ++i ) {
|
---|
3311 | QE[ict][i] = new float * [2];
|
---|
3312 | QE[ict][i][0] = new float[pointsQE[ict]];
|
---|
3313 | QE[ict][i][1] = new float[pointsQE[ict]];
|
---|
3314 | }
|
---|
3315 |
|
---|
3316 | QElambda = new float [pointsQE[ict]];
|
---|
3317 |
|
---|
3318 | for ( i=0; i<pointsQE[ict]; ++i ) {
|
---|
3319 | qefile.getline(line, LINE_MAX_LENGTH);
|
---|
3320 | sscanf(line, "%f", &QElambda[i]);
|
---|
3321 | }
|
---|
3322 |
|
---|
3323 | i=0;
|
---|
3324 |
|
---|
3325 | continue;
|
---|
3326 | }
|
---|
3327 |
|
---|
3328 | // get the values (num-pixel, num-datapoint, QE-value)
|
---|
3329 |
|
---|
3330 | if( sscanf(line, "%d %d %f", &i, &j, &qe) != 3 )
|
---|
3331 | break;
|
---|
3332 |
|
---|
3333 | if ( (i < ct_NPixels) && (i > -1) &&
|
---|
3334 | ((j-1) < pointsQE[ict]) && ((j-1) > -1) ) {
|
---|
3335 | QE[ict][i][0][j-1] = QElambda[j-1];
|
---|
3336 | QE[ict][i][1][j-1] = qe;
|
---|
3337 | }
|
---|
3338 |
|
---|
3339 | if ( i > ct_NPixels) break;
|
---|
3340 |
|
---|
3341 | icount++;
|
---|
3342 |
|
---|
3343 | }
|
---|
3344 |
|
---|
3345 | if(icount/pointsQE[ict] < ct_NPixels){
|
---|
3346 | error( "read_QE", "The quantum efficiency file is faulty\n (found only %d pixels instead of %d).\n",
|
---|
3347 | icount/pointsQE[ict], ct_NPixels );
|
---|
3348 | }
|
---|
3349 |
|
---|
3350 | // close file
|
---|
3351 |
|
---|
3352 | qefile.close();
|
---|
3353 |
|
---|
3354 | // test QE
|
---|
3355 |
|
---|
3356 | for(icount=0; icount< ct_NPixels; icount++){
|
---|
3357 | for(i=0; i<pointsQE[ict]; i++){
|
---|
3358 | if( QE[ict][icount][0][i] < 100. || QE[ict][icount][0][i] > 1000. ||
|
---|
3359 | QE[ict][icount][1][i] < 0. || QE[ict][icount][1][i] > 100.){
|
---|
3360 | error( "read_QE", "The quantum efficiency file is faulty\n pixel %d, point %d is % f, %f\n",
|
---|
3361 | icount, i, QE[ict][icount][0][i], QE[ict][icount][1][i] );
|
---|
3362 | }
|
---|
3363 | }
|
---|
3364 | }
|
---|
3365 |
|
---|
3366 | // end
|
---|
3367 |
|
---|
3368 | log("read_QE", "Done.\n");
|
---|
3369 | }
|
---|
3370 | //!@}
|
---|
3371 |
|
---|
3372 | //!-----------------------------------------------------------
|
---|
3373 | // @name read_WC
|
---|
3374 | //
|
---|
3375 | // @desc read WC data
|
---|
3376 | //
|
---|
3377 | // @date thu 5 17:59:57 CEST 2002
|
---|
3378 | //------------------------------------------------------------
|
---|
3379 | // @function
|
---|
3380 |
|
---|
3381 | //!@{
|
---|
3382 | void
|
---|
3383 | read_WC(void){
|
---|
3384 | ifstream wcfile;
|
---|
3385 | char line[LINE_MAX_LENGTH];
|
---|
3386 | int i;
|
---|
3387 |
|
---|
3388 | //------------------------------------------------------------
|
---|
3389 | // Read Light Collection data
|
---|
3390 |
|
---|
3391 | // try to open the file
|
---|
3392 |
|
---|
3393 | log("read_WC", "Opening the file \"%s\" . . .\n", WC_FILE);
|
---|
3394 |
|
---|
3395 | wcfile.open( WC_FILE );
|
---|
3396 |
|
---|
3397 | // if it is wrong or does not exist, exit
|
---|
3398 |
|
---|
3399 | if ( wcfile.bad() )
|
---|
3400 | error( "read_WC", "Cannot open \"%s\". Exiting.\n", WC_FILE );
|
---|
3401 |
|
---|
3402 | // read file
|
---|
3403 |
|
---|
3404 | log("read_WC", "Reading data . . .\n");
|
---|
3405 |
|
---|
3406 | // get line from the file
|
---|
3407 |
|
---|
3408 | do
|
---|
3409 | wcfile.getline(line, LINE_MAX_LENGTH);
|
---|
3410 | while (line[0] == '#');
|
---|
3411 |
|
---|
3412 | // get the number of datapoints
|
---|
3413 |
|
---|
3414 | sscanf(line, "%d", &pointsWC);
|
---|
3415 |
|
---|
3416 | // allocate memory for the table of QEs
|
---|
3417 |
|
---|
3418 | WC = new float * [2];
|
---|
3419 | WC[0] = new float[pointsWC];
|
---|
3420 | WC[1] = new float[pointsWC];
|
---|
3421 |
|
---|
3422 | for ( i=0; i<pointsWC; ++i ) {
|
---|
3423 | wcfile.getline(line, LINE_MAX_LENGTH);
|
---|
3424 | sscanf(line, "%f %f", &WC[0][i], &WC[1][i]);
|
---|
3425 | }
|
---|
3426 |
|
---|
3427 | //
|
---|
3428 | // Now read info for outer pixels
|
---|
3429 | //
|
---|
3430 | WC_outer = new float * [2];
|
---|
3431 | WC_outer[0] = new float[pointsWC];
|
---|
3432 | WC_outer[1] = new float[pointsWC];
|
---|
3433 |
|
---|
3434 | do
|
---|
3435 | wcfile.getline(line, LINE_MAX_LENGTH);
|
---|
3436 | while (line[0] == '#');
|
---|
3437 |
|
---|
3438 | if (wcfile.eof())
|
---|
3439 | {
|
---|
3440 | log("read_WC", "ERROR. Missing data for outer pixels in file \"%s\"...\n",WC_FILE);
|
---|
3441 | log("read_WC", "EXITING camera\n");
|
---|
3442 | exit(-1);
|
---|
3443 | }
|
---|
3444 |
|
---|
3445 | sscanf(line, "%f %f", &WC_outer[0][0], &WC_outer[1][0]);
|
---|
3446 | for ( i=1; i<pointsWC; ++i ) {
|
---|
3447 | wcfile.getline(line, LINE_MAX_LENGTH);
|
---|
3448 | sscanf(line, "%f %f", &WC_outer[0][i], &WC_outer[1][i]);
|
---|
3449 | }
|
---|
3450 |
|
---|
3451 | // close file
|
---|
3452 |
|
---|
3453 | wcfile.close();
|
---|
3454 |
|
---|
3455 | // read
|
---|
3456 |
|
---|
3457 | log("read_WC", "Done.\n");
|
---|
3458 | }
|
---|
3459 | //!@}
|
---|
3460 |
|
---|
3461 |
|
---|
3462 | //!-----------------------------------------------------------
|
---|
3463 | // @name read_ascii
|
---|
3464 | //
|
---|
3465 | // @desc read ascii configuration files used by the reflector
|
---|
3466 | //
|
---|
3467 | // @date tue dec 10 17:14:10 CET 2002
|
---|
3468 | //------------------------------------------------------------
|
---|
3469 | // @function
|
---|
3470 |
|
---|
3471 | //!@{
|
---|
3472 | void
|
---|
3473 | read_ascii(FILE *sp, MMcConfigRunHeader *config)
|
---|
3474 | {
|
---|
3475 | Float_t radius = -1.0;
|
---|
3476 | Float_t focal = -1.0;
|
---|
3477 | Float_t point = -1.0;
|
---|
3478 | Float_t spot = -1.0;
|
---|
3479 | Float_t camwidth = -1.0;
|
---|
3480 |
|
---|
3481 | Int_t imir;
|
---|
3482 | Float_t f,sx,sy,x,y,z,thetan,phin,xn,yn,zn;
|
---|
3483 | Float_t dx,dy;
|
---|
3484 | Int_t nummir, numref;
|
---|
3485 | Float_t wav,ref;
|
---|
3486 |
|
---|
3487 | Char_t token[40];
|
---|
3488 | Char_t line[511];
|
---|
3489 | Char_t flag;
|
---|
3490 |
|
---|
3491 | while(1){
|
---|
3492 | if((flag=fgetc(sp))==EOF)
|
---|
3493 | break;
|
---|
3494 | if (flag == '\n') // skip empty lines
|
---|
3495 | continue;
|
---|
3496 |
|
---|
3497 | fgets(&line[1],500,sp);
|
---|
3498 | line[0]=flag;
|
---|
3499 |
|
---|
3500 | if ( strstr(line, "# reflectivity file") == line ) {
|
---|
3501 | while (strstr(line, "# number of datapoints") != line)
|
---|
3502 | fgets(line,500,sp);
|
---|
3503 |
|
---|
3504 | fgets(line,500,sp);
|
---|
3505 | sscanf(line,"%i",&numref);
|
---|
3506 |
|
---|
3507 | TArrayF wavarray(numref);
|
---|
3508 | TArrayF refarray(numref);
|
---|
3509 |
|
---|
3510 | while (strstr(line, "# datapoints") != line)
|
---|
3511 | fgets(line,500,sp);
|
---|
3512 |
|
---|
3513 | for(int i=0; i<numref;i++){
|
---|
3514 | fgets(line,500,sp);
|
---|
3515 | if (line[0] == '#')
|
---|
3516 | {
|
---|
3517 | i--;
|
---|
3518 | continue;
|
---|
3519 | }
|
---|
3520 | sscanf(line,"%f %f",&wav,&ref);
|
---|
3521 | wavarray[i]=wav;
|
---|
3522 | refarray[i]=ref;
|
---|
3523 | }
|
---|
3524 | for (int j=0; j<nummir;j++){
|
---|
3525 |
|
---|
3526 | MGeomMirror &mirror = config->GetMirror(j);
|
---|
3527 | mirror.SetArraySize(numref);
|
---|
3528 | mirror.SetReflectivity(wavarray, refarray);
|
---|
3529 | }
|
---|
3530 | continue;
|
---|
3531 | }
|
---|
3532 | if (line[0]== '#')
|
---|
3533 | continue;
|
---|
3534 | if (strstr(line, "type") == line)
|
---|
3535 | continue;
|
---|
3536 | if (strstr(line, "focal_distance") == line){
|
---|
3537 | sscanf(line,"%s %f",token,&focal);
|
---|
3538 | continue;
|
---|
3539 | }
|
---|
3540 | if (strstr(line, "point_spread") == line){
|
---|
3541 | sscanf(line,"%s %f",token,&point);
|
---|
3542 | continue;
|
---|
3543 | }
|
---|
3544 | if (strstr(line, "black_spot") == line){
|
---|
3545 | sscanf(line,"%s %f",token,&spot);
|
---|
3546 | continue;
|
---|
3547 | }
|
---|
3548 | if (strstr(line, "camera_width") == line){
|
---|
3549 | sscanf(line,"%s %f",token,&camwidth);
|
---|
3550 | continue;
|
---|
3551 | }
|
---|
3552 | //
|
---|
3553 | // Skip obsolete magic.def entries:
|
---|
3554 | //
|
---|
3555 | if (strstr(line, "n_pixels") == line)
|
---|
3556 | continue;
|
---|
3557 | if (strstr(line, "pixel_width") == line)
|
---|
3558 | continue;
|
---|
3559 | if (strstr(line, "n_centralpixels") == line)
|
---|
3560 | continue;
|
---|
3561 | if (strstr(line, "n_gappixels") == line)
|
---|
3562 | continue;
|
---|
3563 |
|
---|
3564 | if (strstr(line, "n_mirrors") == line){
|
---|
3565 | sscanf(line,"%s %i",token,&nummir);
|
---|
3566 | config->InitSizeMirror(nummir);
|
---|
3567 | continue;
|
---|
3568 | }
|
---|
3569 | if (strstr(line, "r_mirror") == line){
|
---|
3570 | sscanf(line,"%s %f",token,&radius);
|
---|
3571 | continue;
|
---|
3572 | }
|
---|
3573 | if (strstr(line, "define_mirrors") == line){
|
---|
3574 | for(int i=0;i<nummir;i++){
|
---|
3575 | fgets(line,500,sp);
|
---|
3576 | sscanf(line,"%i %f %f %f %f %f %f %f %f %f %f %f",
|
---|
3577 | &imir,&f,&sx,&sy,&x,&y,&z,&thetan,&phin,&xn,&yn,&zn);
|
---|
3578 | config->AddMirror(i);
|
---|
3579 | MGeomMirror &mirror = config->GetMirror(i);
|
---|
3580 | mirror.SetMirrorContent(imir,f,sx,sy,x,y,z,thetan,phin,xn,yn,zn);
|
---|
3581 | }
|
---|
3582 | fgets(line,500,sp);
|
---|
3583 |
|
---|
3584 | while ( ! strstr(line, "axis deviation"))
|
---|
3585 | fgets(line,500,sp);
|
---|
3586 |
|
---|
3587 | for(int i=0;i<nummir;i++){
|
---|
3588 | fgets(line,500,sp);
|
---|
3589 | if (line[0] == '#')
|
---|
3590 | {
|
---|
3591 | i--;
|
---|
3592 | continue;
|
---|
3593 | }
|
---|
3594 | sscanf(line,"%f %f",&dx,&dy);
|
---|
3595 | MGeomMirror &mirror = config->GetMirror(i);
|
---|
3596 | mirror.SetMirrorDeviations(dx,dy);
|
---|
3597 | }
|
---|
3598 | continue;
|
---|
3599 | }
|
---|
3600 | }
|
---|
3601 | config->SetMagicDef(radius, focal, point, spot, camwidth);
|
---|
3602 | }
|
---|
3603 |
|
---|
3604 |
|
---|
3605 | //!-----------------------------------------------------------
|
---|
3606 | // @name igen_pixel_coordinates
|
---|
3607 | //
|
---|
3608 | // @desc generate the pixel center coordinates
|
---|
3609 | //
|
---|
3610 | // @var *pcam structure camera containing all the
|
---|
3611 | // camera information
|
---|
3612 | // @return total number of pixels
|
---|
3613 | //
|
---|
3614 | // DP
|
---|
3615 | //
|
---|
3616 | // @date Thu Oct 14 10:41:03 CEST 1999
|
---|
3617 | //------------------------------------------------------------
|
---|
3618 | // @function
|
---|
3619 |
|
---|
3620 | //!@{
|
---|
3621 | /******** igen_pixel_coordinates() *********************************/
|
---|
3622 |
|
---|
3623 | int igen_pixel_coordinates(struct camera *pcam) {
|
---|
3624 | /* generate pixel coordinates, return value is number of pixels */
|
---|
3625 |
|
---|
3626 | int i, itot_inside_ring, iN, in, ipixno, iring_no, ipix_in_ring, isegment;
|
---|
3627 | float fsegment_fract;
|
---|
3628 | double dtsize;
|
---|
3629 | double dhsize;
|
---|
3630 | double dpsize;
|
---|
3631 | double dxfirst_pix;
|
---|
3632 | double dyfirst_pix;
|
---|
3633 | double ddxseg1, ddxseg2, ddxseg3, ddxseg4, ddxseg5;
|
---|
3634 | double ddyseg1, ddyseg2, ddyseg3, ddyseg4, ddyseg5;
|
---|
3635 |
|
---|
3636 |
|
---|
3637 | double dstartx, dstarty; /* for the gap pixels and outer pixels */
|
---|
3638 | int j, nrow;
|
---|
3639 |
|
---|
3640 | dpsize = pcam->dpixdiameter_cm;
|
---|
3641 | dtsize = dpsize * sqrt(3.) / 2.;
|
---|
3642 | dhsize = dpsize / 2.;
|
---|
3643 |
|
---|
3644 | /* Loop over central pixels to generate co-ordinates */
|
---|
3645 |
|
---|
3646 | for(ipixno=1; ipixno <= pcam->inumcentralpixels; ipixno++){
|
---|
3647 |
|
---|
3648 | /* Initialise variables. The central pixel = ipixno 1 in ring iring_no 0 */
|
---|
3649 |
|
---|
3650 | pcam->dpixsizefactor[ipixno-1] = 1.;
|
---|
3651 |
|
---|
3652 | in = 0;
|
---|
3653 |
|
---|
3654 | i = 0;
|
---|
3655 | itot_inside_ring = 0;
|
---|
3656 | iring_no = 0;
|
---|
3657 |
|
---|
3658 | /* Calculate the number of pixels out to and including the ring containing pixel number */
|
---|
3659 | /* ipixno e.g. for pixel number 17 in ring number 2 itot_inside_ring = 19 */
|
---|
3660 |
|
---|
3661 | while (itot_inside_ring == 0){
|
---|
3662 |
|
---|
3663 | iN = 3*(i*(i+1)) + 1;
|
---|
3664 |
|
---|
3665 | if (ipixno <= iN){
|
---|
3666 | iring_no = i;
|
---|
3667 | itot_inside_ring = iN;
|
---|
3668 | }
|
---|
3669 |
|
---|
3670 | i++;
|
---|
3671 | }
|
---|
3672 |
|
---|
3673 |
|
---|
3674 | /* Find the number of pixels which make up ring number iring_no e.g. ipix_in_ring = 6 for ring 1 */
|
---|
3675 |
|
---|
3676 | ipix_in_ring = 0;
|
---|
3677 | for (i = 0; i < iring_no; ++i){
|
---|
3678 |
|
---|
3679 | ipix_in_ring = ipix_in_ring + 6;
|
---|
3680 | }
|
---|
3681 |
|
---|
3682 | /* The camera is viewed as 6 radial segments ("pie slices"). Knowing the number of pixels in its */
|
---|
3683 | /* ring calculate which segment the pixel ipixno is in. Then find how far across this segment it is */
|
---|
3684 | /* as a fraction of the number of pixels in this sixth of the ring (ask SMB). */
|
---|
3685 |
|
---|
3686 | isegment = 0;
|
---|
3687 | fsegment_fract = 0.;
|
---|
3688 | if (iring_no > 0) {
|
---|
3689 |
|
---|
3690 | isegment = (int)((ipixno - itot_inside_ring + ipix_in_ring - 0.5) / iring_no + 1); /* integer division ! numbering starts at 1 */
|
---|
3691 |
|
---|
3692 | fsegment_fract = (ipixno - (itot_inside_ring - ipix_in_ring)) - ((isegment-1)*iring_no) - 1 ;
|
---|
3693 |
|
---|
3694 | }
|
---|
3695 |
|
---|
3696 | /* the first pixel in each ring lies on the positive x axis at a distance dxfirst_pix = iring_no * the */
|
---|
3697 | /* pixel width (flat to flat) dpsize. */
|
---|
3698 |
|
---|
3699 | dxfirst_pix = dpsize*iring_no;
|
---|
3700 | dyfirst_pix = 0.;
|
---|
3701 |
|
---|
3702 | /* the vector between the first and last pixels in a segment n is (ddxsegn, ddysegn) */
|
---|
3703 |
|
---|
3704 | ddxseg1 = - dhsize*iring_no;
|
---|
3705 | ddyseg1 = dtsize*iring_no;
|
---|
3706 | ddxseg2 = -dpsize*iring_no;
|
---|
3707 | ddyseg2 = 0.;
|
---|
3708 | ddxseg3 = ddxseg1;
|
---|
3709 | ddyseg3 = -ddyseg1;
|
---|
3710 | ddxseg4 = -ddxseg1;
|
---|
3711 | ddyseg4 = -ddyseg1;
|
---|
3712 | ddxseg5 = -ddxseg2;
|
---|
3713 | ddyseg5 = 0.;
|
---|
3714 |
|
---|
3715 | /* to find the position of pixel ipixno take the position of the first pixel in the ring and move */
|
---|
3716 | /* anti-clockwise around the ring by adding the segment to segment vectors. */
|
---|
3717 |
|
---|
3718 | switch (isegment) {
|
---|
3719 |
|
---|
3720 | case 0:
|
---|
3721 |
|
---|
3722 | pcam->dxc[ipixno-1] = 0.;
|
---|
3723 | pcam->dyc[ipixno-1] = 0.;
|
---|
3724 |
|
---|
3725 | case 1:
|
---|
3726 | pcam->dxc[ipixno-1] = dxfirst_pix - dhsize*fsegment_fract;
|
---|
3727 | pcam->dyc[ipixno-1] = dyfirst_pix + dtsize*fsegment_fract;
|
---|
3728 |
|
---|
3729 | break;
|
---|
3730 |
|
---|
3731 | case 2:
|
---|
3732 |
|
---|
3733 | pcam->dxc[ipixno-1] = dxfirst_pix + ddxseg1 - dpsize*fsegment_fract;
|
---|
3734 | pcam->dyc[ipixno-1] = dyfirst_pix + ddyseg1 + 0.;
|
---|
3735 |
|
---|
3736 | break;
|
---|
3737 |
|
---|
3738 | case 3:
|
---|
3739 |
|
---|
3740 | pcam->dxc[ipixno-1] = dxfirst_pix + ddxseg1 + ddxseg2 - dhsize*fsegment_fract;
|
---|
3741 | pcam->dyc[ipixno-1] = dyfirst_pix + ddyseg1 + ddyseg2 - dtsize*fsegment_fract;
|
---|
3742 |
|
---|
3743 | break;
|
---|
3744 |
|
---|
3745 | case 4:
|
---|
3746 |
|
---|
3747 | pcam->dxc[ipixno-1] = dxfirst_pix + ddxseg1 + ddxseg2 + ddxseg3 + dhsize*fsegment_fract;
|
---|
3748 | pcam->dyc[ipixno-1] = dyfirst_pix + ddyseg1 + ddyseg2 + ddyseg3 - dtsize*fsegment_fract;
|
---|
3749 |
|
---|
3750 | break;
|
---|
3751 |
|
---|
3752 | case 5:
|
---|
3753 |
|
---|
3754 | pcam->dxc[ipixno-1] = dxfirst_pix + ddxseg1 + ddxseg2 + ddxseg3 + ddxseg4 + dpsize*fsegment_fract;
|
---|
3755 | pcam->dyc[ipixno-1] = dyfirst_pix + ddyseg1 + ddyseg2 + ddyseg3 + ddyseg4 + 0.;
|
---|
3756 |
|
---|
3757 | break;
|
---|
3758 |
|
---|
3759 | case 6:
|
---|
3760 |
|
---|
3761 | pcam->dxc[ipixno-1] = dxfirst_pix + ddxseg1 + ddxseg2 + ddxseg3 + ddxseg4 + ddxseg5 + dhsize*fsegment_fract;
|
---|
3762 | pcam->dyc[ipixno-1] = dyfirst_pix + ddyseg1 + ddyseg2 + ddyseg3 + ddyseg4 + ddyseg5 + dtsize*fsegment_fract;
|
---|
3763 |
|
---|
3764 | break;
|
---|
3765 |
|
---|
3766 | default:
|
---|
3767 |
|
---|
3768 | fprintf(stderr, "ERROR: problem in coordinate generation for pixel %d\n", ipixno);
|
---|
3769 | return(0);
|
---|
3770 |
|
---|
3771 | } /* end switch */
|
---|
3772 |
|
---|
3773 | } /* end for */
|
---|
3774 |
|
---|
3775 | dstartx = pcam->dxc[pcam->inumcentralpixels - 1] + dhsize;
|
---|
3776 | dstarty = pcam->dyc[pcam->inumcentralpixels - 1] + dtsize;
|
---|
3777 |
|
---|
3778 | if(pcam->inumgappixels > 0){ /* generate the positions of the gap pixels */
|
---|
3779 |
|
---|
3780 | j = pcam->inumcentralpixels;
|
---|
3781 |
|
---|
3782 | for(i=0; i<pcam->inumgappixels; i=i+6){
|
---|
3783 | pcam->dxc[j + i ] = dstartx + 2. * (i/6 + 1) * dpsize;
|
---|
3784 | pcam->dyc[j + i ] = dstarty;
|
---|
3785 | pcam->dpixsizefactor[j + i] = 1.;
|
---|
3786 | pcam->dxc[j + i + 1] = pcam->dxc[j + i ] / 2.;
|
---|
3787 | pcam->dyc[j + i + 1] = sqrt(3.) * pcam->dxc[j + i + 1];
|
---|
3788 | pcam->dpixsizefactor[j + i + 1] = 1.;
|
---|
3789 | pcam->dxc[j + i + 2] = - pcam->dxc[j + i + 1];
|
---|
3790 | pcam->dyc[j + i + 2] = pcam->dyc[j + i + 1];
|
---|
3791 | pcam->dpixsizefactor[j + i+ 2] = 1.;
|
---|
3792 | pcam->dxc[j + i + 3] = - pcam->dxc[j + i];
|
---|
3793 | pcam->dyc[j + i + 3] = dstarty;
|
---|
3794 | pcam->dpixsizefactor[j + i+ 3] = 1.;
|
---|
3795 | pcam->dxc[j + i + 4] = pcam->dxc[j + i + 2];
|
---|
3796 | pcam->dyc[j + i + 4] = - pcam->dyc[j + i + 2];
|
---|
3797 | pcam->dpixsizefactor[j + i+ 4] = 1.;
|
---|
3798 | pcam->dxc[j + i + 5] = pcam->dxc[j + i + 1];
|
---|
3799 | pcam->dyc[j + i + 5] = - pcam->dyc[j + i + 1];
|
---|
3800 | pcam->dpixsizefactor[j + i + 5] = 1.;
|
---|
3801 | } /* end for */
|
---|
3802 | } /* end if */
|
---|
3803 |
|
---|
3804 | /* generate positions of the outer pixels */
|
---|
3805 |
|
---|
3806 | if( pcam->inumbigpixels > 0 ){
|
---|
3807 |
|
---|
3808 | j = pcam->inumcentralpixels + pcam->inumgappixels;
|
---|
3809 |
|
---|
3810 | for(i=0; i<pcam->inumbigpixels; i++){
|
---|
3811 | pcam->dpixsizefactor[j + i] = 2.;
|
---|
3812 | }
|
---|
3813 |
|
---|
3814 | in = 0;
|
---|
3815 |
|
---|
3816 | nrow = (int) ceil(dstartx / 2. / dpsize);
|
---|
3817 |
|
---|
3818 | while(in < pcam->inumbigpixels){
|
---|
3819 |
|
---|
3820 | pcam->dxc[j + in] = dstartx + dpsize;
|
---|
3821 | pcam->dyc[j + in] = dstarty + 2 * dpsize / sqrt(3.);
|
---|
3822 | pcam->dxc[j + in + nrow] = dstartx / 2. - dpsize / 2.;
|
---|
3823 | pcam->dyc[j + in + nrow] = sqrt(3.)/2. * dstartx + 2.5 * dpsize/sqrt(3.);
|
---|
3824 | pcam->dxc[j + in + 3 * nrow - 1] = - pcam->dxc[j + in];
|
---|
3825 | pcam->dyc[j + in + 3 * nrow - 1] = pcam->dyc[j + in];
|
---|
3826 | pcam->dxc[j + in + 3 * nrow] = - pcam->dxc[j + in];
|
---|
3827 | pcam->dyc[j + in + 3 * nrow] = - pcam->dyc[j + in];
|
---|
3828 | pcam->dxc[j + in + 5 * nrow - 1] = pcam->dxc[j + in + nrow];
|
---|
3829 | pcam->dyc[j + in + 5 * nrow - 1] = - pcam->dyc[j + in + nrow];
|
---|
3830 | pcam->dxc[j + in + 6 * nrow - 1] = pcam->dxc[j + in];
|
---|
3831 | pcam->dyc[j + in + 6 * nrow - 1] = - pcam->dyc[j + in];
|
---|
3832 | for(i=1; i<nrow; i++){
|
---|
3833 | pcam->dxc[j + in + i] = pcam->dxc[j + in] - i * dpsize;
|
---|
3834 | pcam->dyc[j + in + i] = pcam->dyc[j + in] + i * dpsize * sqrt(3.);
|
---|
3835 | pcam->dxc[j + in + i + nrow] = pcam->dxc[j + in + nrow] - i * 2 * dpsize;
|
---|
3836 | pcam->dyc[j + in + i + nrow] = pcam->dyc[j + in + nrow];
|
---|
3837 | pcam->dxc[j + in + 3 * nrow - 1 - i] = - pcam->dxc[j + in + i];
|
---|
3838 | pcam->dyc[j + in + 3 * nrow - 1- i] = pcam->dyc[j + in + i];
|
---|
3839 | pcam->dxc[j + in + i + 3 * nrow] = - pcam->dxc[j + in + i];
|
---|
3840 | pcam->dyc[j + in + i + 3 * nrow] = - pcam->dyc[j + in + i];
|
---|
3841 | pcam->dxc[j + in + 5 * nrow - 1 - i] = pcam->dxc[j + in + i + nrow];
|
---|
3842 | pcam->dyc[j + in + 5 * nrow - 1 - i] = - pcam->dyc[j + in + i + nrow];
|
---|
3843 | pcam->dxc[j + in + 6 * nrow - 1 - i] = pcam->dxc[j + in + i];
|
---|
3844 | pcam->dyc[j + in + 6 * nrow - 1 - i] = - pcam->dyc[j + in + i];
|
---|
3845 | }
|
---|
3846 | in = in + 6 * nrow;
|
---|
3847 | dstartx = dstartx + 2. * dpsize;
|
---|
3848 | nrow = nrow + 1;
|
---|
3849 | } /* end while */
|
---|
3850 |
|
---|
3851 | } /* end if */
|
---|
3852 |
|
---|
3853 | return(pcam->inumpixels);
|
---|
3854 |
|
---|
3855 | }
|
---|
3856 | //!@}
|
---|
3857 |
|
---|
3858 | //!-----------------------------------------------------------
|
---|
3859 | // @name bpoint_is_in_pix
|
---|
3860 | //
|
---|
3861 | // @desc check if a point (x,y) in camera coordinates is inside a given pixel
|
---|
3862 | //
|
---|
3863 | // @var *pcam structure camera containing all the
|
---|
3864 | // camera information
|
---|
3865 | // @var dx, dy point coordinates in centimeters
|
---|
3866 | // @var ipixnum pixel number (starting at 0)
|
---|
3867 | // @return TRUE if the point is inside the pixel, FALSE otherwise
|
---|
3868 | //
|
---|
3869 | // DP
|
---|
3870 | //
|
---|
3871 | // @date Thu Oct 14 16:59:04 CEST 1999
|
---|
3872 | //------------------------------------------------------------
|
---|
3873 | // @function
|
---|
3874 |
|
---|
3875 | //!@{
|
---|
3876 |
|
---|
3877 | /******** bpoint_is_in_pix() ***************************************/
|
---|
3878 |
|
---|
3879 | #define sqrt13 0.577350269 // = 1./sqrt(3.)
|
---|
3880 | #define sqrt3 1.732050807 // = sqrt(3.)
|
---|
3881 |
|
---|
3882 | int bpoint_is_in_pix(double dx, double dy, MGeomCam *pgeomcam)
|
---|
3883 | {
|
---|
3884 | /* return TRUE if point (dx, dy) is in pixel number ipixnum, else return FALSE (use camera coordinate system) */
|
---|
3885 | /* the pixel is assumed to be a "closed set" */
|
---|
3886 |
|
---|
3887 | /*
|
---|
3888 | a = length of one of the edges of one pixel,
|
---|
3889 | b = half the width of one pixel
|
---|
3890 | */
|
---|
3891 |
|
---|
3892 | const int numN = pgeomcam->GetNumPixels();
|
---|
3893 |
|
---|
3894 | for (int i=0; i<numN; i++)
|
---|
3895 | {
|
---|
3896 | MGeomPix &pixel = (*pgeomcam)[i];
|
---|
3897 | const double b = pixel.GetD()/2;
|
---|
3898 | const double a = pixel.GetD()/sqrt3;
|
---|
3899 |
|
---|
3900 | const double xx = dx - pixel.GetX();
|
---|
3901 | const double yy = dy - pixel.GetY();
|
---|
3902 |
|
---|
3903 | if(((-b <= xx) && (xx <= 0.) && ((-sqrt13 * xx - a) <= yy) && (yy <= ( sqrt13 * xx + a))) ||
|
---|
3904 | ((0. < xx) && (xx <= b ) && (( sqrt13 * xx - a) <= yy) && (yy <= (-sqrt13 * xx + a))) ){
|
---|
3905 |
|
---|
3906 | return i; // inside i
|
---|
3907 | }
|
---|
3908 |
|
---|
3909 | // return -1; // outside
|
---|
3910 | }
|
---|
3911 |
|
---|
3912 | return -1; // outside
|
---|
3913 | }
|
---|
3914 |
|
---|
3915 | //!@}
|
---|
3916 |
|
---|
3917 | //------------------------------------------------------------
|
---|
3918 | // @name dist_r_P
|
---|
3919 | //
|
---|
3920 | // @desc distance straight line r - point P
|
---|
3921 | //
|
---|
3922 | // @date Sat Jun 27 05:58:56 MET DST 1998
|
---|
3923 | // @function @code
|
---|
3924 | //------------------------------------------------------------
|
---|
3925 | // dist_r_P
|
---|
3926 | //
|
---|
3927 | // distance straight line r (x+t*l, y+t*m, z+t*n) to point P(a,b,c)
|
---|
3928 | //
|
---|
3929 | // We assume that vector (l, m, n) is normalized l^2+m^2+n^2 = 1
|
---|
3930 | //------------------------------------------------------------
|
---|
3931 |
|
---|
3932 | float
|
---|
3933 | dist_r_P(float a, float b, float c,
|
---|
3934 | float l, float m, float n,
|
---|
3935 | float x, float y, float z)
|
---|
3936 | {
|
---|
3937 | return (
|
---|
3938 | sqrt((SQR((a-x)*m-(b-y)*l) +
|
---|
3939 | SQR((b-y)*n-(c-z)*m) +
|
---|
3940 | SQR((c-z)*l-(a-x)*n)))
|
---|
3941 | );
|
---|
3942 | }
|
---|
3943 |
|
---|
3944 | //------------------------------------------------------------
|
---|
3945 | // @name check_reflector_file
|
---|
3946 | //
|
---|
3947 | // @desc check if a given reflector file has the right signature
|
---|
3948 | // @desc return TRUE or FALSE
|
---|
3949 | //
|
---|
3950 | // @date Mon Feb 14 16:44:21 CET 2000
|
---|
3951 | // @function @code
|
---|
3952 | //------------------------------------------------------------
|
---|
3953 |
|
---|
3954 | int check_reflector_file(FILE *infile){
|
---|
3955 |
|
---|
3956 | char sign[20]; // auxiliary variable
|
---|
3957 |
|
---|
3958 | strcpy(sign, REFL_SIGNATURE_B);
|
---|
3959 |
|
---|
3960 | fread( (char *)sign, strlen(REFL_SIGNATURE_B), 1, infile);
|
---|
3961 | if (strcmp(sign, REFL_SIGNATURE_A) == 0){
|
---|
3962 | fread( (char *)sign, 1, 1, infile);
|
---|
3963 | return 4;
|
---|
3964 | }
|
---|
3965 | else if (strcmp(sign, REFL_SIGNATURE_B) == 0){
|
---|
3966 | fread( (char *)sign, 1, 1, infile);
|
---|
3967 | return 5;
|
---|
3968 | }
|
---|
3969 | else if (strcmp(sign, REFL_SIGNATURE_C) == 0){
|
---|
3970 | // An empty bin has been removed and therefore we do not need to rezd it.
|
---|
3971 | return 6;
|
---|
3972 | }
|
---|
3973 | else {
|
---|
3974 | cout << "ERROR: Signature of .rfl file is not correct\n";
|
---|
3975 | cout << '"' << sign << '"' << '\n';
|
---|
3976 | cout << "should be: " << REFL_SIGNATURE_A <<" or "<< REFL_SIGNATURE_B <<" or " << REFL_SIGNATURE_C <<" or "<< '\n';
|
---|
3977 | return(FALSE);
|
---|
3978 | }
|
---|
3979 |
|
---|
3980 |
|
---|
3981 | }
|
---|
3982 |
|
---|
3983 | //------------------------------------------------------------
|
---|
3984 | // @name lin_interpol
|
---|
3985 | //
|
---|
3986 | // @desc interpolate linearly between two points returning the
|
---|
3987 | // @desc y-value of the result
|
---|
3988 | //
|
---|
3989 | // @date Thu Feb 17 11:31:32 CET 2000
|
---|
3990 | // @function @code
|
---|
3991 | //------------------------------------------------------------
|
---|
3992 |
|
---|
3993 | float lin_interpol( float x1, float y1, float x2, float y2, float x){
|
---|
3994 |
|
---|
3995 | if( (x2 - x1)<=0. ){ // avoid division by zero, return average
|
---|
3996 | cout << "Warning: lin_interpol was asked to interpolate between two points with x1>=x2.\n";
|
---|
3997 | return((y1+y2)/2.);
|
---|
3998 | }
|
---|
3999 | else{ // note: the check whether x1 < x < x2 is omitted for speed reasons
|
---|
4000 | return((float) (y1 + (y2-y1)/(x2-x1)*(x-x1)) );
|
---|
4001 | }
|
---|
4002 | }
|
---|
4003 |
|
---|
4004 | //------------------------------------------------------------
|
---|
4005 | // @name size_rotated
|
---|
4006 | //
|
---|
4007 | // @desc It rotates the NSB
|
---|
4008 | //
|
---|
4009 | // @date Tue Jan 7 17:09:25 CET 2003
|
---|
4010 | // @function @code
|
---|
4011 | //------------------------------------------------------------
|
---|
4012 |
|
---|
4013 | int size_rotated(
|
---|
4014 | float *rotated,
|
---|
4015 | float *nsb,
|
---|
4016 | float rho)
|
---|
4017 | {
|
---|
4018 | int r=0;
|
---|
4019 | float size_rotated;
|
---|
4020 | float Num_Pixels;
|
---|
4021 | float PixNum=0;
|
---|
4022 | float rho_pixel;
|
---|
4023 | int j=0;
|
---|
4024 | int k=0;
|
---|
4025 |
|
---|
4026 | for(int i=1; i<iMAXNUMPIX;i++){
|
---|
4027 | // Substituir per Int_t radius[iMAXNUMPIX]={0,1,1,1,1,1,1,2,2,2,2, ...}
|
---|
4028 | Num_Pixels=0;
|
---|
4029 | for (int ii=1; ii<17;ii++){
|
---|
4030 | if (Num_Pixels >= i){
|
---|
4031 | r=ii-1;
|
---|
4032 | break;
|
---|
4033 | }
|
---|
4034 |
|
---|
4035 |
|
---|
4036 |
|
---|
4037 | if (ii<12){
|
---|
4038 | Num_Pixels+=ii*6;
|
---|
4039 | PixNum=6*ii;
|
---|
4040 | // size_rotated = (360/PixNum);
|
---|
4041 | //rho_pixel = rho/size_rotated;
|
---|
4042 | }
|
---|
4043 |
|
---|
4044 |
|
---|
4045 | else
|
---|
4046 | {
|
---|
4047 | Num_Pixels+=(ii-6)*6;
|
---|
4048 | PixNum=(ii-6)*6;
|
---|
4049 | // size_rotated = (360/PixNum);
|
---|
4050 | // rho_pixel = rho/size_rotated;
|
---|
4051 | }
|
---|
4052 | }
|
---|
4053 |
|
---|
4054 |
|
---|
4055 |
|
---|
4056 | size_rotated = (360/PixNum);
|
---|
4057 | rho_pixel = rho/size_rotated;
|
---|
4058 |
|
---|
4059 | //Buscar j i k que no canvin de r!!!
|
---|
4060 |
|
---|
4061 | j=i-int(rho_pixel);
|
---|
4062 |
|
---|
4063 | //cout<<"j inicial "<<j<<endl;
|
---|
4064 | int MINPIXinner[13]= {0,1,7,19,37,61,91,127,169,217,271,331,397};
|
---|
4065 | int MINPIXouter[5]={397,433,475,523,578};
|
---|
4066 |
|
---|
4067 | if( r<12 ){
|
---|
4068 | if (j < MINPIXinner[r])
|
---|
4069 | {
|
---|
4070 | j = i+6 * r - int(rho_pixel);
|
---|
4071 | }
|
---|
4072 |
|
---|
4073 | k=j-1;
|
---|
4074 | if (k < MINPIXinner[r])
|
---|
4075 | {
|
---|
4076 | k = MINPIXinner[r+1]-1;
|
---|
4077 | }
|
---|
4078 | }
|
---|
4079 | if( r > 11 && r < 16){
|
---|
4080 | if (j < MINPIXouter[r-12])
|
---|
4081 | {
|
---|
4082 | j = i + (r - 6) * 6 - int(rho_pixel);
|
---|
4083 |
|
---|
4084 | }
|
---|
4085 |
|
---|
4086 | k=j-1;
|
---|
4087 | if ( k < MINPIXouter[r-12])
|
---|
4088 | {
|
---|
4089 | k = MINPIXouter[r-11] - 1;
|
---|
4090 | }
|
---|
4091 | }
|
---|
4092 | rotated[i]= (1 - ((rho_pixel)-floor(rho_pixel))) * nsb[j] + (rho_pixel-floor(rho_pixel)) * nsb[k];
|
---|
4093 | }
|
---|
4094 | return (int(rho_pixel));
|
---|
4095 |
|
---|
4096 | }
|
---|
4097 |
|
---|
4098 |
|
---|
4099 | //------------------------------------------------------------
|
---|
4100 | // @name produce_phes
|
---|
4101 | //
|
---|
4102 | // @desc read the photons of an event, pixelize them and simulate QE
|
---|
4103 | // @desc return various statistics and the array of Photoelectrons
|
---|
4104 | //
|
---|
4105 | // @date Mon Feb 14 16:44:21 CET 2000
|
---|
4106 | // @function @code
|
---|
4107 | //------------------------------------------------------------
|
---|
4108 |
|
---|
4109 | int produce_phes( FILE *sp, // the input file
|
---|
4110 | class MGeomCam *camgeom, // the camera layout
|
---|
4111 | float minwl_nm, // the minimum accepted wavelength
|
---|
4112 | float maxwl_nm, // the maximum accepted wavelength
|
---|
4113 | class MTrigger *trigger, // the generated phes
|
---|
4114 | class MFadc *fadc,
|
---|
4115 | int *itotnphe, // total number of produced photoelectrons
|
---|
4116 | float *nphe, // number of photoelectrons in each pixel
|
---|
4117 | int *incph, // total number of cph within camera
|
---|
4118 | float *tmin_ns, // minimum arrival time of all phes
|
---|
4119 | float *tmax_ns, // maximum arrival time of all phes
|
---|
4120 | int ict, // Telescope that is being analised to get the right QE.
|
---|
4121 | float mirror_fraction, // Fraction of total mirror really present
|
---|
4122 | float fadc_jitter // Random shift (max 1 slice) of pulses in
|
---|
4123 | // FADC, to simulate FADC clock noise.
|
---|
4124 | ){
|
---|
4125 |
|
---|
4126 | static uint i;
|
---|
4127 | static int k, ipixnum;
|
---|
4128 | static float cx, cy, wl, qe;
|
---|
4129 | static float cw;
|
---|
4130 | static MCCphoton photon;
|
---|
4131 | static float **qept;
|
---|
4132 | static char flag[SIZE_OF_FLAGS + 1];
|
---|
4133 | static float radius_mm;
|
---|
4134 | static UInt_t seed = (UInt_t)(get_seeds(0)*get_seeds(1));
|
---|
4135 |
|
---|
4136 | float time;
|
---|
4137 | float *pmtjit;
|
---|
4138 |
|
---|
4139 | pmtjit = new float[camgeom->GetNumPixels()];
|
---|
4140 |
|
---|
4141 | // reset variables
|
---|
4142 |
|
---|
4143 | TRandom random;
|
---|
4144 | random.SetSeed(seed);
|
---|
4145 |
|
---|
4146 | for ( i = 0; i < camgeom->GetNumPixels(); ++i )
|
---|
4147 | {
|
---|
4148 | nphe[i] = 0.0;
|
---|
4149 | //
|
---|
4150 | // PMT time jitter: gaussian, not negative (MTrigger::FillShow does
|
---|
4151 | // not accept negative times!)
|
---|
4152 | //
|
---|
4153 | do
|
---|
4154 | pmtjit[i] = random.Gaus(3.*pmt_jitter, pmt_jitter);
|
---|
4155 | while (pmtjit[i] < 0.);
|
---|
4156 | }
|
---|
4157 |
|
---|
4158 | *itotnphe = 0;
|
---|
4159 | *incph = 0;
|
---|
4160 |
|
---|
4161 | radius_mm = camgeom->GetMaxRadius();
|
---|
4162 |
|
---|
4163 | float C1, C2, C3, rho;
|
---|
4164 |
|
---|
4165 | //- - - - - - - - - - - - - - - - - - - - - - - - -
|
---|
4166 | // read photons and "map" them into the pixels
|
---|
4167 | //--------------------------------------------------
|
---|
4168 |
|
---|
4169 | // initialize CPhoton
|
---|
4170 |
|
---|
4171 | photon.fill(0., 0., 0., 0., 0., 0., 0., 0.);
|
---|
4172 |
|
---|
4173 | // read the photons data
|
---|
4174 |
|
---|
4175 | // loop over the photons
|
---|
4176 |
|
---|
4177 | while (1) {
|
---|
4178 |
|
---|
4179 | photon.read(sp);
|
---|
4180 | photon.get_flag(flag);
|
---|
4181 |
|
---|
4182 | if (isA( flag, FLAG_END_OF_EVENT ))
|
---|
4183 | {
|
---|
4184 | fseek (sp, SIZE_OF_FLAGS-photon.mysize(), SEEK_CUR);
|
---|
4185 | break;
|
---|
4186 | }
|
---|
4187 |
|
---|
4188 | // Check if photon is inside trigger time range
|
---|
4189 |
|
---|
4190 | time = photon.get_t() ;
|
---|
4191 |
|
---|
4192 | if (time-*tmin_ns>TOTAL_TRIGGER_TIME) {
|
---|
4193 | continue;
|
---|
4194 | }
|
---|
4195 |
|
---|
4196 | //
|
---|
4197 | // Account for possibly missing mirrors, or lower reflectivity...
|
---|
4198 | // mirror_fraction is the fraction of the total mirror really
|
---|
4199 | // working.
|
---|
4200 | //
|
---|
4201 | if (mirror_fraction < 1.)
|
---|
4202 | if (RandomNumber > mirror_fraction)
|
---|
4203 | continue;
|
---|
4204 |
|
---|
4205 | //
|
---|
4206 | // Pixelization
|
---|
4207 | //
|
---|
4208 |
|
---|
4209 | cx = photon.get_x();
|
---|
4210 | cy = photon.get_y();
|
---|
4211 |
|
---|
4212 | if (Spotsigma > 0.)
|
---|
4213 | {
|
---|
4214 | cx += random.Gaus(0.,Spot_x);
|
---|
4215 | cy += random.Gaus(0.,Spot_y);
|
---|
4216 | }
|
---|
4217 | if (missPointing > 0.)
|
---|
4218 | {
|
---|
4219 | // We should take intot acount the rotation of the FoV
|
---|
4220 | C1 = 0.48 * sin(Zenith) - 0.87 * cos(Zenith) * cos(Azimutal);
|
---|
4221 | C3 = (0.87 * cos(Zenith) - 0.48 * sin(Zenith) * cos(Azimutal));
|
---|
4222 | C2 = sqrt( sin(Zenith) * sin(Zenith) * sin(Azimutal) * sin(Azimutal) + C3 * C3 );
|
---|
4223 | rho = acos( C1/C2 );
|
---|
4224 | rho=(sin(Azimutal)<0 ? (2 * 3.14159 - rho) : rho);
|
---|
4225 |
|
---|
4226 | rho = rho*180/3.14159;
|
---|
4227 |
|
---|
4228 | cx += (missP_x*cos(rho)-missP_y*sin(rho))/(10*camgeom->GetConvMm2Deg());
|
---|
4229 | cy += (missP_x*sin(rho)+missP_y*cos(rho))/(10*camgeom->GetConvMm2Deg());
|
---|
4230 | }
|
---|
4231 |
|
---|
4232 |
|
---|
4233 | // get wavelength
|
---|
4234 |
|
---|
4235 | wl = photon.get_wl();
|
---|
4236 |
|
---|
4237 | // cout << "wl " << wl << " radius " << sqrt(cx*cx + cy*cy) << "\n";
|
---|
4238 |
|
---|
4239 | // check if photon has valid wavelength and is inside outermost camera radius
|
---|
4240 |
|
---|
4241 | if( (wl > maxwl_nm) || (wl < minwl_nm) || (sqrt(cx*cx + cy*cy)*10 > radius_mm ) ){
|
---|
4242 | continue;
|
---|
4243 |
|
---|
4244 | }
|
---|
4245 |
|
---|
4246 | ipixnum = bpoint_is_in_pix(cx*10, cy*10, camgeom);
|
---|
4247 |
|
---|
4248 | // -1 = the photon is in none of the pixels
|
---|
4249 | // 0 = the phton is in the central pixel, which is not used for trigger
|
---|
4250 | if (ipixnum==-1 || ipixnum==0) {
|
---|
4251 | continue;
|
---|
4252 | }
|
---|
4253 |
|
---|
4254 | // AM changed meaning of incph: before it was all photons read from
|
---|
4255 | // reflector file, now only those within a valid pixel:
|
---|
4256 | //
|
---|
4257 | // increase number of photons
|
---|
4258 | (*incph)++;
|
---|
4259 |
|
---|
4260 | //+++
|
---|
4261 | // QE simulation
|
---|
4262 | //---
|
---|
4263 |
|
---|
4264 | // set pointer to the QE table of the relevant pixel
|
---|
4265 |
|
---|
4266 | qept = (float **)QE[ict][ipixnum];
|
---|
4267 |
|
---|
4268 | // check if wl is inside table; outside the table, QE is assumed to be zero
|
---|
4269 |
|
---|
4270 | if((wl < qept[0][0]) || (wl > qept[0][pointsQE[ict]-1])){
|
---|
4271 | continue;
|
---|
4272 |
|
---|
4273 | }
|
---|
4274 |
|
---|
4275 | // find data point in the QE table (-> k)
|
---|
4276 |
|
---|
4277 | k = 1; // start at 1 because the condition was already tested for 0
|
---|
4278 | while (k < pointsQE[ict]-1 && qept[0][k] < wl){
|
---|
4279 | k++;
|
---|
4280 | }
|
---|
4281 |
|
---|
4282 | // calculate the qe value between 0. and 1.
|
---|
4283 |
|
---|
4284 | qe = lin_interpol(qept[0][k-1], qept[1][k-1], qept[0][k], qept[1][k], wl) / 100.0;
|
---|
4285 |
|
---|
4286 | //
|
---|
4287 | // Apply incident angular correction due to Light Guides, plexiglas,
|
---|
4288 | // 1st dynode collection efficiency, double crossings... etc.
|
---|
4289 | // This information is contained in the file Data/LightCollection.dat
|
---|
4290 | //
|
---|
4291 | cw=photon.get_phi()*180./3.14159265;
|
---|
4292 |
|
---|
4293 | // find data point in the WC table (-> k)
|
---|
4294 |
|
---|
4295 | if ( camgeom->GetPixRatio(ipixnum) < 1.) // => Pixel is outer pixel
|
---|
4296 | {
|
---|
4297 | k = 0;
|
---|
4298 | while (k < pointsWC-1 && WC_outer[0][k] < cw)
|
---|
4299 | k++;
|
---|
4300 | // correct the qe with WC data.
|
---|
4301 | qe = qe*lin_interpol(WC_outer[0][k-1], WC_outer[1][k-1],
|
---|
4302 | WC_outer[0][k], WC_outer[1][k], cw);
|
---|
4303 | }
|
---|
4304 |
|
---|
4305 | else // => Pixel is inner pixel
|
---|
4306 | {
|
---|
4307 | k = 0;
|
---|
4308 | while (k < pointsWC-1 && WC[0][k] < cw)
|
---|
4309 | k++;
|
---|
4310 | // correct the qe with WC data.
|
---|
4311 | qe = qe*lin_interpol(WC[0][k-1], WC[1][k-1], WC[0][k], WC[1][k], cw);
|
---|
4312 | }
|
---|
4313 |
|
---|
4314 |
|
---|
4315 | // if random > quantum efficiency, reject it
|
---|
4316 |
|
---|
4317 | if ( (RandomNumber) > qe ) {
|
---|
4318 | continue;
|
---|
4319 | }
|
---|
4320 |
|
---|
4321 | //+++
|
---|
4322 | // The photon has produced a photo electron
|
---|
4323 | //---
|
---|
4324 |
|
---|
4325 | // cout << " accepted\n";
|
---|
4326 |
|
---|
4327 | // increment the number of photoelectrons in the relevant pixel
|
---|
4328 |
|
---|
4329 | nphe[ipixnum] += 1.0;
|
---|
4330 |
|
---|
4331 | // store the new photoelectron
|
---|
4332 |
|
---|
4333 | fadc->Fill(ipixnum,
|
---|
4334 | (time-*tmin_ns) + pmtjit[ipixnum] + fadc_jitter,
|
---|
4335 | trigger->FillShow(ipixnum, time-*tmin_ns + pmtjit[ipixnum] + fadc_jitter),
|
---|
4336 | !((*camgeom)[ipixnum].GetD()>(*camgeom)[0].GetD()));
|
---|
4337 |
|
---|
4338 | *itotnphe += 1;
|
---|
4339 | }
|
---|
4340 |
|
---|
4341 | seed = random.GetSeed(); // Get seed for next call
|
---|
4342 |
|
---|
4343 | return(0);
|
---|
4344 |
|
---|
4345 | }
|
---|
4346 |
|
---|
4347 |
|
---|
4348 | //------------------------------------------------------------
|
---|
4349 | // @name produce_nsbrates
|
---|
4350 | //
|
---|
4351 | // @desc read the starfield file, call produce_phes on it in,
|
---|
4352 | // @desc different wavebands, calculate the nsbrates
|
---|
4353 | //
|
---|
4354 | // @date Mon Feb 14 16:44:21 CET 2000
|
---|
4355 | // @function @code
|
---|
4356 | //------------------------------------------------------------
|
---|
4357 |
|
---|
4358 | int produce_nsbrates( char *iname, // the starfield input file name
|
---|
4359 | MGeomCam *camgeom, // camera layout
|
---|
4360 | float **rate_phepns,
|
---|
4361 | // the product of this function:
|
---|
4362 | // the NSB rates in phe/ns for each pixel
|
---|
4363 | int ict,
|
---|
4364 | float mirror_fraction)
|
---|
4365 | {
|
---|
4366 | uint i, j; // counters
|
---|
4367 | int k, ii; // counters
|
---|
4368 |
|
---|
4369 | static float wl_nm[iNUMWAVEBANDS + 1] = { WAVEBANDBOUND1,
|
---|
4370 | WAVEBANDBOUND2,
|
---|
4371 | WAVEBANDBOUND3,
|
---|
4372 | WAVEBANDBOUND4,
|
---|
4373 | WAVEBANDBOUND5,
|
---|
4374 | WAVEBANDBOUND6 };
|
---|
4375 |
|
---|
4376 | FILE *infile; // the input file
|
---|
4377 | fpos_t fileposition; // marker on the input file
|
---|
4378 | static char cflag[SIZE_OF_FLAGS + 1]; // auxiliary variable
|
---|
4379 | static MCEventHeader evth; // the event header
|
---|
4380 | static MCEventHeader evth_2; // the event header
|
---|
4381 | static float nphe[iMAXNUMPIX]; // the number of photoelectrons in each pixel
|
---|
4382 | int reflector_file_version;
|
---|
4383 | int itnphe; // total number of produced photoelectrons
|
---|
4384 | int itotnphe; // total number of produced photoelectrons after averaging
|
---|
4385 | int incph; // total number of cph read
|
---|
4386 | float tmin_ns; // minimum arrival time of all phes
|
---|
4387 | float tmax_ns; // maximum arrival time of all phes
|
---|
4388 | float integtime_ns; // integration time from the starfield generator
|
---|
4389 | char flag_new[4];
|
---|
4390 |
|
---|
4391 |
|
---|
4392 | if (strlen(iname) == 0)
|
---|
4393 | {
|
---|
4394 | log( SIGNATURE, "No starfield input file has been provided.\n");
|
---|
4395 | return (0);
|
---|
4396 | }
|
---|
4397 | else // check if the starfield input file exists and open it
|
---|
4398 | {
|
---|
4399 | log(SIGNATURE, "Opening starfield input \"rfl\" file %s\n", iname );
|
---|
4400 | infile = fopen( iname, "r" );
|
---|
4401 |
|
---|
4402 | if ( infile == NULL )
|
---|
4403 | {
|
---|
4404 | log( SIGNATURE, "ERROR! Cannot open starfield input file: %s\n", iname );
|
---|
4405 | exit(-1);
|
---|
4406 | }
|
---|
4407 | }
|
---|
4408 |
|
---|
4409 |
|
---|
4410 | // get signature, and check it
|
---|
4411 |
|
---|
4412 | if((reflector_file_version=check_reflector_file( infile ))==FALSE){
|
---|
4413 | exit(1);
|
---|
4414 | }
|
---|
4415 |
|
---|
4416 | // Instance of MTrigger and MFadc; needed here only as dummies for
|
---|
4417 | // a call to produce_phes (see below).
|
---|
4418 | // 15/09/2004, A. Moralejo, changed "trigger" and "flashadc" to
|
---|
4419 | // pointers, the former static allocation caused memory problems and
|
---|
4420 | // segmentation fault in some systems.
|
---|
4421 |
|
---|
4422 | MTrigger* trigger = new MTrigger(camgeom->GetNumPixels(),camgeom,
|
---|
4423 | Trigger_gate_length,
|
---|
4424 | Trigger_overlaping_time,
|
---|
4425 | Trigger_response_ampl,
|
---|
4426 | Trigger_response_fwhm);
|
---|
4427 |
|
---|
4428 | MFadc* flashadc = new MFadc(camgeom->GetNumPixels(),
|
---|
4429 | FADC_shape,
|
---|
4430 | FADC_response_integ,FADC_response_fwhm,
|
---|
4431 | FADC_shape_out,
|
---|
4432 | FADC_resp_integ_out,FADC_resp_fwhm_out,
|
---|
4433 | get_trig_delay(),
|
---|
4434 | FADC_slices_per_ns,
|
---|
4435 | FADC_slices_written);
|
---|
4436 |
|
---|
4437 | // initialize flag
|
---|
4438 | strcpy( cflag, " \0" );
|
---|
4439 |
|
---|
4440 | // get flag
|
---|
4441 |
|
---|
4442 | fread( cflag, SIZE_OF_FLAGS, 1, infile );
|
---|
4443 |
|
---|
4444 | if ( ! feof(infile)){
|
---|
4445 |
|
---|
4446 | // reading .rfl file
|
---|
4447 |
|
---|
4448 | if(!isA( cflag, FLAG_START_OF_RUN )){
|
---|
4449 | error( SIGNATURE, "Expected start of run flag, but found: %s\n", cflag );
|
---|
4450 | }
|
---|
4451 | else { // found start of run
|
---|
4452 |
|
---|
4453 | if (reflector_file_version > 5){
|
---|
4454 |
|
---|
4455 | fread( flag_new, 4, 1, infile );
|
---|
4456 |
|
---|
4457 | if(!isA( flag_new, FLAG_START_OF_HEADER)){
|
---|
4458 |
|
---|
4459 | // We break the main loop
|
---|
4460 | cout<<"Warning: Expected start of run header flag, but found:"<<flag_new<<endl;
|
---|
4461 | cout<<" We assume no Star Light"<<endl;
|
---|
4462 | return(0);
|
---|
4463 | }
|
---|
4464 |
|
---|
4465 | Float_t flag_temp[SIZE_OF_MCRUNHEADER];
|
---|
4466 |
|
---|
4467 | fread( flag_temp, (SIZE_OF_MCRUNHEADER)*sizeof(float), 1, infile );
|
---|
4468 |
|
---|
4469 | }
|
---|
4470 |
|
---|
4471 | fread( cflag, SIZE_OF_FLAGS, 1, infile );
|
---|
4472 |
|
---|
4473 | if( isA( cflag, FLAG_START_OF_EVENT )){ // there is a event
|
---|
4474 | fread( flag_new, 4, 1, infile );
|
---|
4475 |
|
---|
4476 | if(!isA( flag_new, FLAG_EVENT_HEADER)){
|
---|
4477 |
|
---|
4478 | // We break while events loop
|
---|
4479 | cout<<"Warning: Expected start of event header flag, but found:"<<flag_new<<endl;
|
---|
4480 | cout<<" We assume no light from Stars"<<endl;
|
---|
4481 | return(0);
|
---|
4482 | }
|
---|
4483 |
|
---|
4484 | // get MCEventHeader
|
---|
4485 |
|
---|
4486 | if (reflector_file_version<6)
|
---|
4487 | // fread( (char*)&evth, evth.mysize(), 1, infile );
|
---|
4488 | evth.read(infile);
|
---|
4489 | else
|
---|
4490 | // fread( (char*)&evth_2, evth_2.mysize(), 1, infile );
|
---|
4491 | evth_2.read(infile);
|
---|
4492 |
|
---|
4493 | if (reflector_file_version<6)
|
---|
4494 | integtime_ns = evth.get_energy();
|
---|
4495 | else
|
---|
4496 | integtime_ns = evth_2.get_energy();
|
---|
4497 |
|
---|
4498 | // memorize where we are in the file
|
---|
4499 |
|
---|
4500 | if (fgetpos( infile, &fileposition ) != 0){
|
---|
4501 | error( SIGNATURE, "Cannot position in file ...\n");
|
---|
4502 | }
|
---|
4503 |
|
---|
4504 | // loop over the wavebands
|
---|
4505 |
|
---|
4506 | for(i=0; i<iNUMWAVEBANDS; i++){
|
---|
4507 |
|
---|
4508 | // initialize the rate array
|
---|
4509 |
|
---|
4510 | for(j = 0; j<camgeom->GetNumPixels(); j++){ // loop over pixels
|
---|
4511 | rate_phepns[j][i] = 0.;
|
---|
4512 | }
|
---|
4513 |
|
---|
4514 | itotnphe = 0;
|
---|
4515 |
|
---|
4516 | // read the photons and produce the photoelectrons
|
---|
4517 | // - in order to average over the QE simulation, call the
|
---|
4518 | // production function iNUMNSBPRODCALLS times
|
---|
4519 |
|
---|
4520 | for(ii=0; ii<iNUMNSBPRODCALLS; ii++){
|
---|
4521 |
|
---|
4522 | // position the file pointer to the beginning of the photons
|
---|
4523 |
|
---|
4524 | fsetpos( infile, &fileposition);
|
---|
4525 |
|
---|
4526 | // produce photoelectrons (photons from starfield)
|
---|
4527 |
|
---|
4528 | k = produce_phes( infile,
|
---|
4529 | camgeom,
|
---|
4530 | wl_nm[i],
|
---|
4531 | wl_nm[i+1],
|
---|
4532 | trigger, // this is a dummy here
|
---|
4533 | flashadc, // this is a dummy here
|
---|
4534 | &itnphe,
|
---|
4535 | nphe, // we want this!
|
---|
4536 | &incph,
|
---|
4537 | &tmin_ns,
|
---|
4538 | &tmax_ns,
|
---|
4539 | 0,
|
---|
4540 | mirror_fraction,
|
---|
4541 | 0.);
|
---|
4542 |
|
---|
4543 |
|
---|
4544 | if( k != 0 ){ // non-zero returnvalue means error
|
---|
4545 | cout << "Exiting.\n";
|
---|
4546 | exit(1);
|
---|
4547 | }
|
---|
4548 |
|
---|
4549 | for(j = 0; j<camgeom->GetNumPixels(); j++){ // loop over pixels
|
---|
4550 | rate_phepns[j][i] += nphe[j]/integtime_ns/(float)iNUMNSBPRODCALLS;
|
---|
4551 | }
|
---|
4552 |
|
---|
4553 | itotnphe += itnphe;
|
---|
4554 |
|
---|
4555 | } // end for(ii=0 ...
|
---|
4556 |
|
---|
4557 | fprintf(stdout, "Starfield, %6f - %6f nm: %d photoelectrons for %6f ns integration time\n",
|
---|
4558 | wl_nm[i], wl_nm[i+1], itotnphe/iNUMNSBPRODCALLS, integtime_ns);
|
---|
4559 |
|
---|
4560 | } // end for(i=0 ...
|
---|
4561 |
|
---|
4562 | }
|
---|
4563 | else{
|
---|
4564 | cout << "Starfield file contains no event.\nExiting.\n";
|
---|
4565 | exit(1);
|
---|
4566 | } // end if( isA ... event
|
---|
4567 | } // end if ( isA ... run
|
---|
4568 | }
|
---|
4569 | else{
|
---|
4570 | cout << "Starfield file contains no run.\nExiting.\n";
|
---|
4571 | exit(1);
|
---|
4572 | }
|
---|
4573 |
|
---|
4574 | fclose( infile );
|
---|
4575 |
|
---|
4576 | return(0);
|
---|
4577 | }
|
---|
4578 |
|
---|
4579 |
|
---|
4580 |
|
---|
4581 | //-------------------------------------------------------------
|
---|
4582 | //
|
---|
4583 | // Function DoCalibration. A. Moralejo October 2004
|
---|
4584 | //
|
---|
4585 | // Generates calibration events similar to those in the real
|
---|
4586 | // calibration runs.
|
---|
4587 | //
|
---|
4588 | //-------------------------------------------------------------
|
---|
4589 |
|
---|
4590 | int DoCalibration(MFadc **Fadc_CT, MTrigger **Trigger_CT,
|
---|
4591 | TObjArray camgeom,
|
---|
4592 | float *nsb_trigresp, float *nsb_fadcresp,
|
---|
4593 | MLons *lons, MLons *lons_outer,
|
---|
4594 | float **nsb_phepns, int addElecNoise,
|
---|
4595 | TTree *EvtTree, MRawEvtHeader **EvtHeader,
|
---|
4596 | MMcEvt **McEvt, MRawEvtData** EvtData)
|
---|
4597 | {
|
---|
4598 |
|
---|
4599 | int nevent = 0;
|
---|
4600 | int maxevents;
|
---|
4601 | int lons_return;
|
---|
4602 |
|
---|
4603 | int *ntotphe = new int[ct_Number];
|
---|
4604 | int *ntotphot = new int[ct_Number];
|
---|
4605 | float *nphe_from_nsb = new float[ct_Number];
|
---|
4606 | float *pulsetime = new float[ct_Number];
|
---|
4607 |
|
---|
4608 | float lambda, sigma_lambda, phot_per_pix, sigma_time;
|
---|
4609 | UInt_t *first_pixel, *last_pixel;
|
---|
4610 | int selected_pixel;
|
---|
4611 |
|
---|
4612 | TRandom random;
|
---|
4613 | random.SetSeed((UInt_t)(get_seeds(0)*get_seeds(0)));
|
---|
4614 |
|
---|
4615 | for (int ict = 0; ict < ct_Number; ict++)
|
---|
4616 | pulsetime[ict] = 0.;
|
---|
4617 |
|
---|
4618 | // Get parameters of the calibration:
|
---|
4619 |
|
---|
4620 | get_calibration_properties( &lambda, &sigma_lambda, &phot_per_pix,
|
---|
4621 | &sigma_time, &maxevents, &selected_pixel);
|
---|
4622 |
|
---|
4623 | first_pixel = new UInt_t[ct_Number];
|
---|
4624 | last_pixel = new UInt_t[ct_Number];
|
---|
4625 |
|
---|
4626 | for (int ict = 0; ict < ct_Number; ict++)
|
---|
4627 | {
|
---|
4628 | if (selected_pixel < 0)
|
---|
4629 | {
|
---|
4630 | first_pixel[ict] = 0;
|
---|
4631 | last_pixel[ict] = ((MGeomCam*)(camgeom.UncheckedAt(ict)))->GetNumPixels()-1;
|
---|
4632 | }
|
---|
4633 | else
|
---|
4634 | first_pixel[ict] = last_pixel[ict] = selected_pixel;
|
---|
4635 | }
|
---|
4636 |
|
---|
4637 |
|
---|
4638 | TArrayC *fadcValues; //@< the analog Fadc High gain signal for pixels
|
---|
4639 | TArrayC *fadcValuesLow; //@< the analog Fadc Low gain signal for pixels
|
---|
4640 |
|
---|
4641 | // allocate space for FADC info
|
---|
4642 | fadcValues = new TArrayC(FADC_slices_written);
|
---|
4643 | fadcValuesLow = new TArrayC(FADC_slices_written);
|
---|
4644 |
|
---|
4645 |
|
---|
4646 | // allocate space for PMTs numbers of pixels
|
---|
4647 | float *pheinpix = new float [ct_NPixels];
|
---|
4648 |
|
---|
4649 | for (int calevent = 0; calevent < maxevents; calevent++)
|
---|
4650 | {
|
---|
4651 | //
|
---|
4652 | // Clear Trigger and Fadc
|
---|
4653 | //
|
---|
4654 | for(int ict = 0; ict < ct_Number; ict++)
|
---|
4655 | {
|
---|
4656 | Trigger_CT[ict]->Reset() ;
|
---|
4657 | Trigger_CT[ict]->ClearFirst();
|
---|
4658 | Trigger_CT[ict]->ClearZero();
|
---|
4659 | Fadc_CT[ict]->Reset() ;
|
---|
4660 |
|
---|
4661 | ntotphe[ict] = ntotphot[ict] = 0;
|
---|
4662 | nphe_from_nsb[ict] = 0.;
|
---|
4663 |
|
---|
4664 | }
|
---|
4665 |
|
---|
4666 | nevent++;
|
---|
4667 |
|
---|
4668 | if((nevent+1)%100 == 1)
|
---|
4669 | log(SIGNATURE, "Event %d\n", nevent);
|
---|
4670 |
|
---|
4671 | // Produce the photoelectrons
|
---|
4672 | for(int ict = 0; ict < ct_Number; ict++)
|
---|
4673 | {
|
---|
4674 | // Obtain the FADC jitter of 1 FADC slice. This is a time to be added to the
|
---|
4675 | // time of all photons in an event, before digitalization of the signal. It is
|
---|
4676 | // therefore the same time shift for all pixels in a CT.
|
---|
4677 |
|
---|
4678 | float fadc_jitter =
|
---|
4679 | (1./Fadc_CT[ict]->GetFadcSlicesPerNanosec()) * random.Uniform(0., 1.); //ns
|
---|
4680 |
|
---|
4681 |
|
---|
4682 | produce_calib_phes( (MGeomCam*)(camgeom.UncheckedAt(ict)),
|
---|
4683 | Trigger_CT[ict],
|
---|
4684 | Fadc_CT[ict],
|
---|
4685 | &(ntotphe[ict]),
|
---|
4686 | pheinpix,
|
---|
4687 | &(ntotphot[ict]),
|
---|
4688 | ict,
|
---|
4689 | lambda,
|
---|
4690 | sigma_lambda,
|
---|
4691 | phot_per_pix,
|
---|
4692 | sigma_time,
|
---|
4693 | selected_pixel,
|
---|
4694 | fadc_jitter
|
---|
4695 | );
|
---|
4696 |
|
---|
4697 | pulsetime[ict] = fadc_jitter; // Keep value for writing it to output.
|
---|
4698 | }
|
---|
4699 |
|
---|
4700 | // NSB simulation
|
---|
4701 |
|
---|
4702 | if(lons && lons_outer)
|
---|
4703 | {
|
---|
4704 | // Fill trigger and fadc response in the trigger class from the NSB database
|
---|
4705 |
|
---|
4706 | for (int ict = 0; ict < ct_Number; ict++)
|
---|
4707 | {
|
---|
4708 | for (UInt_t ui = first_pixel[ict]; ui <= last_pixel[ict]; ui++)
|
---|
4709 | {
|
---|
4710 | nphe_from_nsb[ict] += nsb_phepns[ict][ui];
|
---|
4711 |
|
---|
4712 | if (nsb_phepns[ict][ui] > 0.0)
|
---|
4713 | {
|
---|
4714 | if((*((MGeomCam*)(camgeom.UncheckedAt(ict))))[ui].GetD() >
|
---|
4715 | (*((MGeomCam*)(camgeom.UncheckedAt(ict))))[0].GetD())
|
---|
4716 | lons_return = lons_outer->GetResponse(nsb_phepns[ict][ui],0.01,
|
---|
4717 | & nsb_trigresp[0],
|
---|
4718 | & nsb_fadcresp[0]);
|
---|
4719 | else
|
---|
4720 | lons_return = lons->GetResponse(nsb_phepns[ict][ui],0.01,
|
---|
4721 | & nsb_trigresp[0],
|
---|
4722 | & nsb_fadcresp[0]);
|
---|
4723 |
|
---|
4724 | if (lons_return == 0)
|
---|
4725 | {
|
---|
4726 | cout << "Exiting.\n";
|
---|
4727 | exit(1);
|
---|
4728 | }
|
---|
4729 |
|
---|
4730 | Fadc_CT[ict]->AddSignal(ui,nsb_fadcresp);
|
---|
4731 | }
|
---|
4732 | }
|
---|
4733 | }
|
---|
4734 |
|
---|
4735 | }// end if(simulateNSB) ...
|
---|
4736 |
|
---|
4737 |
|
---|
4738 | //++++++++++++++++++++++++++++++++++++++++++++++++++
|
---|
4739 | // at this point we have a camera full of
|
---|
4740 | // ph.e.s
|
---|
4741 | //--------------------------------------------------
|
---|
4742 |
|
---|
4743 | // now the noise of the electronic
|
---|
4744 | // (preamps, optical transmission,..) is introduced.
|
---|
4745 | //
|
---|
4746 |
|
---|
4747 | for (int ict = 0; ict < ct_Number; ict++)
|
---|
4748 | {
|
---|
4749 | if (addElecNoise)
|
---|
4750 | Fadc_CT[ict]->ElecNoise();
|
---|
4751 |
|
---|
4752 | // now a shift in the fadc signal due to the pedestals is
|
---|
4753 | // introduced
|
---|
4754 | // This is done inside the class MFadc by the method Pedestals
|
---|
4755 |
|
---|
4756 | Fadc_CT[ict]->Pedestals();
|
---|
4757 |
|
---|
4758 | // Set the trigger time. The 3 ns are such that the calibration pulses
|
---|
4759 | // appear roughly at the same position as for the case of real data.
|
---|
4760 | // If you want to shift the pulse position, do not change this value here,
|
---|
4761 | // use the option trigger_delay in the input card instead.
|
---|
4762 | // The additional value 3*sigma_time makes that the pulse maximum is, in
|
---|
4763 | // average, in the same position no matter of the time width of the pulse
|
---|
4764 | // (see that, in produce_calib_phes(...), in order to avoid negative times
|
---|
4765 | // we shift the time of the photons by this same amount!)
|
---|
4766 |
|
---|
4767 | Fadc_CT[ict]->TriggeredFadc(3.+3*sigma_time);
|
---|
4768 |
|
---|
4769 | // Add the "digital noise": electronic noise intrinsic to the FADC and which
|
---|
4770 | // therefore is not scaled down in the low gain slices!
|
---|
4771 |
|
---|
4772 | Fadc_CT[ict]->DigitalNoise();
|
---|
4773 |
|
---|
4774 | //
|
---|
4775 | // Fill the event header information
|
---|
4776 | //
|
---|
4777 | EvtHeader[ict]->FillHeader((UInt_t) calevent, 0);
|
---|
4778 |
|
---|
4779 | // Set flag to indicate this is a calibration or a pedestal run:
|
---|
4780 | if (phot_per_pix > 1.e-3)
|
---|
4781 | {
|
---|
4782 | // Set trigger pattern. WARNING: the trigger pattern of real
|
---|
4783 | // data is inverted for the MRawRunHeader.fFormatVersion=5
|
---|
4784 | // which is the one we now set in the camera outputs. Hence
|
---|
4785 | // we use the binary inversion operators "~" below. The Calibration
|
---|
4786 | // pattern, on the contrary, is not inverted.
|
---|
4787 | EvtHeader[ict]->SetTriggerPattern((UInt_t)(~(MTriggerPattern::kCalibration |
|
---|
4788 | MTriggerPattern::kTriggerLvl1)));
|
---|
4789 | //
|
---|
4790 | // FIXME! For now color and intensity of the pulser is fixed!
|
---|
4791 | EvtHeader[ict]->SetCalibrationPattern((UInt_t)((BIT(11) | BIT(12))<<16));
|
---|
4792 | }
|
---|
4793 | else // 0 cal. photons per pixel ==> pedestal run
|
---|
4794 | EvtHeader[ict]->SetTriggerPattern((UInt_t)~MTriggerPattern::kPedestal);
|
---|
4795 |
|
---|
4796 |
|
---|
4797 | McEvt[ict]->Fill( 0, 0, 0., -1.0, -1.0, -1.0, 0., 0., 0., 0., 0.,
|
---|
4798 | 0., 0., 0., 0., 0., 0., 0., 0.,
|
---|
4799 | 0., 0., 0., 0., 0, 0, 0,
|
---|
4800 | (UInt_t) ntotphot[ict],
|
---|
4801 | (UInt_t) ntotphe[ict],
|
---|
4802 | (UInt_t) nphe_from_nsb[ict]+ ntotphe[ict],
|
---|
4803 | 0., 0., 0., pulsetime[ict]);
|
---|
4804 |
|
---|
4805 | //
|
---|
4806 | // Fill the FADC information
|
---|
4807 | //
|
---|
4808 | for(UInt_t ui = first_pixel[ict]; ui <= last_pixel[ict]; ui++)
|
---|
4809 | {
|
---|
4810 | for (int jslice = 0; jslice < FADC_slices_written; jslice++)
|
---|
4811 | {
|
---|
4812 | fadcValues->AddAt(Fadc_CT[ict]->GetFadcSignal(ui, jslice),jslice);
|
---|
4813 | fadcValuesLow->AddAt(Fadc_CT[ict]->GetFadcLowGainSignal(ui,jslice),jslice);
|
---|
4814 | }
|
---|
4815 | EvtData[ict]->AddPixel(ui,fadcValues,0);
|
---|
4816 | EvtData[ict]->AddPixel(ui,fadcValuesLow,kTRUE);
|
---|
4817 | }
|
---|
4818 | }
|
---|
4819 |
|
---|
4820 | EvtTree->Fill();
|
---|
4821 |
|
---|
4822 | // clear all
|
---|
4823 | for(int ict=0;ict<ct_Number;ict++)
|
---|
4824 | {
|
---|
4825 | EvtHeader[ict]->Clear() ;
|
---|
4826 | EvtData[ict]->ResetPixels(0,0);
|
---|
4827 | McEvt[ict]->Clear() ;
|
---|
4828 | }
|
---|
4829 | }
|
---|
4830 |
|
---|
4831 | return(0);
|
---|
4832 | }
|
---|
4833 |
|
---|
4834 |
|
---|
4835 | //------------------------------------------------------------
|
---|
4836 | //
|
---|
4837 | // Function produce_calib_phes, A. Moralejo Oct 2004
|
---|
4838 | //
|
---|
4839 | //------------------------------------------------------------
|
---|
4840 |
|
---|
4841 | int produce_calib_phes( MGeomCam *camgeom, // The camera layout
|
---|
4842 | MTrigger *trigger,
|
---|
4843 | MFadc *fadc,
|
---|
4844 | int *itotnphe, // total number of produced photoelectrons
|
---|
4845 | float *nphe, // number of photoelectrons in each pixel
|
---|
4846 | int *nphot, // total number of photons in all pixels
|
---|
4847 | int ict, // Telescope that is being analised to get the right QE.
|
---|
4848 | float lambda, // Mean wavelength of light in nm
|
---|
4849 | float sigma_lambda, // Sigma of wavelengtgaussian spread
|
---|
4850 | float phot_per_pix, // Average # of photons per inner pixel
|
---|
4851 | float sigma_time, // Sigma of time spread of photons
|
---|
4852 | int selected_pixel,// if >= 0, only this pixel is used!
|
---|
4853 | float fadc_jitter // Random shift (max 1 slice) of pulses in
|
---|
4854 | // FADC, to simulate FADC clock noise.
|
---|
4855 | )
|
---|
4856 | {
|
---|
4857 |
|
---|
4858 | int ipixnum;
|
---|
4859 | float cx, cy, wl, time, phi, phi_deg, qe;
|
---|
4860 | float **qept;
|
---|
4861 | float radius_mm, focal_dist_mm;
|
---|
4862 | int total_photons;
|
---|
4863 | float *pmtjit;
|
---|
4864 |
|
---|
4865 | static UInt_t seed = (UInt_t)(get_seeds(0)*get_seeds(1));
|
---|
4866 |
|
---|
4867 | pmtjit = new float[camgeom->GetNumPixels()];
|
---|
4868 |
|
---|
4869 | // reset variables
|
---|
4870 |
|
---|
4871 | TRandom random;
|
---|
4872 | random.SetSeed(seed);
|
---|
4873 |
|
---|
4874 | for ( uint i = 0; i < camgeom->GetNumPixels(); i++ )
|
---|
4875 | {
|
---|
4876 | nphe[i] = 0.0;
|
---|
4877 |
|
---|
4878 | //
|
---|
4879 | // PMT time jitter: gaussian, not negative (MTrigger::FillShow does
|
---|
4880 | // not accept negative times!)
|
---|
4881 | //
|
---|
4882 | do
|
---|
4883 | pmtjit[i] = random.Gaus(3.*pmt_jitter, pmt_jitter);
|
---|
4884 | while(pmtjit[i]<0.);
|
---|
4885 | }
|
---|
4886 |
|
---|
4887 | *itotnphe = 0;
|
---|
4888 | *nphot = 0;
|
---|
4889 |
|
---|
4890 | //
|
---|
4891 | // Create photons and "map" them into the pixels
|
---|
4892 | //
|
---|
4893 |
|
---|
4894 | // Maximum radius of camera:
|
---|
4895 | radius_mm = camgeom->GetMaxRadius();
|
---|
4896 |
|
---|
4897 | // Distance from center of mirror dish to camera plane:
|
---|
4898 | focal_dist_mm = camgeom->GetCameraDist()*1000;
|
---|
4899 |
|
---|
4900 | // Cosine of the angle between telescope axis and line from center of mirror
|
---|
4901 | // dish to the edge of the camera:
|
---|
4902 | float cos_epsilon_max = cos(atan2(radius_mm, focal_dist_mm));
|
---|
4903 |
|
---|
4904 |
|
---|
4905 |
|
---|
4906 | // Calculate total number of photons to be produced.
|
---|
4907 | if (selected_pixel < 0)
|
---|
4908 | total_photons = (int) (phot_per_pix * 3.14159265 * radius_mm * radius_mm /
|
---|
4909 | (*camgeom)[0].GetA());
|
---|
4910 | else
|
---|
4911 | total_photons = (int) (phot_per_pix *
|
---|
4912 | (*camgeom)[selected_pixel].GetA() / (*camgeom)[0].GetA());
|
---|
4913 |
|
---|
4914 | // loop over the photons
|
---|
4915 |
|
---|
4916 | for (int iph = 0; iph < total_photons; iph++)
|
---|
4917 | {
|
---|
4918 | //
|
---|
4919 | // Simulate arrival times of photons to camera plane. We do not simulate the small
|
---|
4920 | // delays between pixels due to the different distances to the pulser.
|
---|
4921 | //
|
---|
4922 | // We do not want negative times, so center the gaussian at 3 sigma
|
---|
4923 | // and reject negative values:
|
---|
4924 |
|
---|
4925 | do
|
---|
4926 | time = random.Gaus(3*sigma_time, sigma_time);
|
---|
4927 | while (time < 0.);
|
---|
4928 |
|
---|
4929 | // wavelength
|
---|
4930 | wl = random.Gaus(lambda, sigma_lambda);
|
---|
4931 |
|
---|
4932 | if( (wl > WAVEBANDBOUND6) || (wl < WAVEBANDBOUND1))
|
---|
4933 | continue;
|
---|
4934 |
|
---|
4935 | if (selected_pixel < 0)
|
---|
4936 | {
|
---|
4937 | // Obtain photon coordinates on the camera. We assume a point source of light placed
|
---|
4938 | // in the center of the mirror dish.
|
---|
4939 |
|
---|
4940 | // polar angle
|
---|
4941 | float psi = RandomNumber * 2 * 3.14159265;
|
---|
4942 | // angle between the telescope axis and the photon trajectory.
|
---|
4943 | float epsilon = acos(1.-RandomNumber*(1.-cos_epsilon_max));
|
---|
4944 | float tanepsilon = tan(epsilon);
|
---|
4945 |
|
---|
4946 | cx = focal_dist_mm*tanepsilon*cos(psi); // mm
|
---|
4947 | cy = focal_dist_mm*tanepsilon*sin(psi); // mm
|
---|
4948 |
|
---|
4949 | if (sqrt(cx*cx + cy*cy) > radius_mm )
|
---|
4950 | continue;
|
---|
4951 |
|
---|
4952 | // Angle between photon trajectory and camera plane:
|
---|
4953 | phi = 3.14159265/2.-epsilon; // rad
|
---|
4954 |
|
---|
4955 | //
|
---|
4956 | // Pixelization
|
---|
4957 | //
|
---|
4958 | ipixnum = bpoint_is_in_pix(cx, cy, camgeom);
|
---|
4959 |
|
---|
4960 | // -1 = the photon is in none of the pixels
|
---|
4961 | // 0 = the phton is in the central pixel, which is not used
|
---|
4962 | if (ipixnum==-1 || ipixnum==0)
|
---|
4963 | continue;
|
---|
4964 | }
|
---|
4965 | else
|
---|
4966 | {
|
---|
4967 | // Angle between photon trajectory and camera plane:
|
---|
4968 | phi = atan2( focal_dist_mm,
|
---|
4969 | sqrt( (*camgeom)[selected_pixel].GetX()*(*camgeom)[selected_pixel].GetX()+
|
---|
4970 | (*camgeom)[selected_pixel].GetY()*(*camgeom)[selected_pixel].GetY()));
|
---|
4971 |
|
---|
4972 | ipixnum = selected_pixel;
|
---|
4973 | }
|
---|
4974 |
|
---|
4975 |
|
---|
4976 | // increase number of photons within pixels
|
---|
4977 | *nphot += 1;
|
---|
4978 |
|
---|
4979 | //
|
---|
4980 | // QE simulation
|
---|
4981 | //
|
---|
4982 | // set pointer to the QE table of the relevant pixel
|
---|
4983 |
|
---|
4984 | qept = (float **)QE[ict][ipixnum];
|
---|
4985 |
|
---|
4986 | // check if wl is inside table; outside the table, QE is assumed to be zero
|
---|
4987 |
|
---|
4988 | if((wl < qept[0][0]) || (wl > qept[0][pointsQE[ict]-1]))
|
---|
4989 | continue;
|
---|
4990 |
|
---|
4991 |
|
---|
4992 | // find data point in the QE table (-> k)
|
---|
4993 | int k = 1; // start at 1 because the condition was already tested for 0
|
---|
4994 | while (k < pointsQE[ict]-1 && qept[0][k] < wl)
|
---|
4995 | k++;
|
---|
4996 |
|
---|
4997 | // calculate the qe value between 0. and 1.
|
---|
4998 |
|
---|
4999 | qe = lin_interpol(qept[0][k-1], qept[1][k-1], qept[0][k], qept[1][k], wl) / 100.0;
|
---|
5000 |
|
---|
5001 |
|
---|
5002 | //
|
---|
5003 | // Apply incident angular correction due to Light Guides, plexiglas,
|
---|
5004 | // 1st dynode collection efficiency, double crossings... etc.
|
---|
5005 | // This information is contained in the file Data/LightCollection.dat,
|
---|
5006 | // and has been read into the array WC (which stands for "Winston Cones")
|
---|
5007 | //
|
---|
5008 | phi_deg = phi*180./3.14159265;
|
---|
5009 |
|
---|
5010 | // find data point in the WC table (-> k)
|
---|
5011 |
|
---|
5012 | if ( camgeom->GetPixRatio(ipixnum) < 1.) // => Pixel is outer pixel
|
---|
5013 | {
|
---|
5014 | k = 0;
|
---|
5015 | while (k < pointsWC-1 && WC_outer[0][k] < phi_deg)
|
---|
5016 | k++;
|
---|
5017 | // correct the qe with WC data.
|
---|
5018 | qe = qe*lin_interpol(WC_outer[0][k-1], WC_outer[1][k-1],
|
---|
5019 | WC_outer[0][k], WC_outer[1][k], phi_deg);
|
---|
5020 | }
|
---|
5021 |
|
---|
5022 | else // => Pixel is inner pixel
|
---|
5023 | {
|
---|
5024 | k = 0;
|
---|
5025 | while (k < pointsWC-1 && WC[0][k] < phi_deg)
|
---|
5026 | k++;
|
---|
5027 | // correct the qe with WC data.
|
---|
5028 | qe = qe*lin_interpol(WC[0][k-1], WC[1][k-1], WC[0][k], WC[1][k], phi_deg);
|
---|
5029 | }
|
---|
5030 |
|
---|
5031 |
|
---|
5032 | // if random > quantum efficiency, reject it
|
---|
5033 |
|
---|
5034 | if ( (RandomNumber) > qe ) {
|
---|
5035 | continue;
|
---|
5036 | }
|
---|
5037 |
|
---|
5038 | //
|
---|
5039 | // The photon has produced a photo electron
|
---|
5040 | //
|
---|
5041 |
|
---|
5042 | // increment the number of photoelectrons in the relevant pixel
|
---|
5043 |
|
---|
5044 | nphe[ipixnum] += 1.;
|
---|
5045 |
|
---|
5046 | // store the new photoelectron
|
---|
5047 |
|
---|
5048 | fadc->Fill(ipixnum, time + pmtjit[ipixnum] + fadc_jitter,
|
---|
5049 | trigger->FillShow(ipixnum, time + pmtjit[ipixnum] + fadc_jitter),
|
---|
5050 | !((*camgeom)[ipixnum].GetD()>(*camgeom)[0].GetD()));
|
---|
5051 |
|
---|
5052 | *itotnphe += 1;
|
---|
5053 | }
|
---|
5054 |
|
---|
5055 | seed = random.GetSeed(); // Get seed for next call
|
---|
5056 |
|
---|
5057 | return(0);
|
---|
5058 |
|
---|
5059 | }
|
---|
5060 |
|
---|
5061 | // @endcode
|
---|
5062 |
|
---|
5063 |
|
---|
5064 | //=------------------------------------------------------------
|
---|
5065 | //!@subsection Log of this file.
|
---|
5066 |
|
---|
5067 | //!@{
|
---|
5068 | //
|
---|
5069 | // $Log: not supported by cvs2svn $
|
---|
5070 | // Revision 1.96 2005/03/01 21:57:01 moralejo
|
---|
5071 | //
|
---|
5072 | // Set parameters for the shape of the low gain pulse in the FADC to more
|
---|
5073 | // precise values. Low gain pulse from real data was provided by H. Bartko.
|
---|
5074 | //
|
---|
5075 | // Revision 1.95 2005/03/01 20:13:17 moralejo
|
---|
5076 | // Added comments
|
---|
5077 | //
|
---|
5078 | // Revision 1.94 2005/03/01 20:10:44 moralejo
|
---|
5079 | // Revision 1.93 2005/03/01 20:06:46 moralejo
|
---|
5080 | //
|
---|
5081 | // In MFadc.[hxx,cxx]
|
---|
5082 | // Eliminated function MFadc::Set which was neither used nor needed
|
---|
5083 | // Eliminated function MFadc::Baseline which was neither used nor needed
|
---|
5084 | // Set different pulse shape for the low gain for the case in which
|
---|
5085 | // the "Pulpo" pulse shape is chosen for the FADC simulation.
|
---|
5086 | //
|
---|
5087 | // Revision 1.92 2005/02/18 12:19:32 moralejo
|
---|
5088 | //
|
---|
5089 | // Changes in MFadc. Added possibility to set a shift (for the moment an
|
---|
5090 | // integer number of FADC slices) between the signal peak in the high gain
|
---|
5091 | // and in the low gain.
|
---|
5092 | //
|
---|
5093 | // Revision 1.91 2005/02/18 10:24:51 moralejo
|
---|
5094 | //
|
---|
5095 | // Added switch to low gain (see MFadc.cxx). Before, in all events all
|
---|
5096 | // pixels had low gain branch, no matter how small the signal in the high
|
---|
5097 | // gain was. Now we require a minimum signal in the high gain to fill the
|
---|
5098 | // low gain slices with the scaled-down signal. In case the switch does
|
---|
5099 | // not occur, the low gain slices are simply the continuation of the
|
---|
5100 | // high gain ones, with the noise the same as in the high gain.
|
---|
5101 | //
|
---|
5102 | // Revision 1.90 2005/02/17 15:37:12 moralejo
|
---|
5103 | //
|
---|
5104 | // Corrected bug in the setting of the trigger patterns. It turns out that
|
---|
5105 | // in the current data format, MRawRunHeader.fFormatVersion=5, as of
|
---|
5106 | // February 2005, the trigger bits are "inverted" ( 0 <-> 1 ) in their meaning
|
---|
5107 | // (see Mars/mtrigger/MTriggerPattern).
|
---|
5108 | //
|
---|
5109 | // Revision 1.89 2005/02/17 09:15:28 moralejo
|
---|
5110 | //
|
---|
5111 | // Set as default option that of writing all event headers to output file,
|
---|
5112 | // not only those of the triggered events. To disable it, set the input card
|
---|
5113 | // flag "no_write_all_event_headers".
|
---|
5114 | //
|
---|
5115 | // Changed such that output images for events below the minimum number of
|
---|
5116 | // photoelectrons nphe2NSB required to simulate the noise (NSB & electronic)
|
---|
5117 | // will be empty. This will avoid the problem of these events being processed,
|
---|
5118 | // without any noise, later in the chain. Although those images are not in the
|
---|
5119 | // output, one can still check in the headers (MMcTrig) how many such events
|
---|
5120 | // with less than nphe2NSB photoelectrons would have triggered.
|
---|
5121 | //
|
---|
5122 | // Revision 1.88 2005/02/11 20:00:01 moralejo
|
---|
5123 | //
|
---|
5124 | // Added to output container "MMcEvtBasic" with the most important MC
|
---|
5125 | // parameters, to be kept for all events (triggered or not) through
|
---|
5126 | // the whole analysis chain in order to allow the calculation of effective
|
---|
5127 | // areas.
|
---|
5128 | //
|
---|
5129 | // Updated version of MRawRunHeader from 4 to 5. This means the trigger and
|
---|
5130 | // calibration patterns are correctly set and can be decoded.
|
---|
5131 | //
|
---|
5132 | // Revision 1.87 2005/02/10 19:28:10 moralejo
|
---|
5133 | //
|
---|
5134 | // Substituted input card option "write_all_events" by
|
---|
5135 | // "write_all_event_headers". If set, this will make camera to write out
|
---|
5136 | // the event headers of all the processed events, no matter whether they
|
---|
5137 | // have triggered or not.
|
---|
5138 | //
|
---|
5139 | // Revision 1.86 2005/02/10 14:49:21 moralejo
|
---|
5140 | //
|
---|
5141 | // Added setting of trigger flags in MRawEvtHeader::fTriggerPattern:
|
---|
5142 | // Lvl1 flag for normal shower runs, Calibration flag for calibration
|
---|
5143 | // runs and Pedestal flag for "calibration runs" in which the number
|
---|
5144 | // of photons per pixel is set to 0.
|
---|
5145 | //
|
---|
5146 | // Revision 1.85 2005/02/10 12:00:32 moralejo
|
---|
5147 | //
|
---|
5148 | // Changed call to EvtHeader[ict]->FillHeader in line 2535: second argument
|
---|
5149 | // was 20, and I set it now to 0. No idea why that was 20: like that, it was
|
---|
5150 | // setting a CL trigger pattern on all events (???!!!)
|
---|
5151 | //
|
---|
5152 | // Revision 1.84 2004/12/15 01:56:39 moralejo
|
---|
5153 | //
|
---|
5154 | // Added input card option pmt_jitter_ns to simulate the time jitter of
|
---|
5155 | // PMTs. The input parameter is the sigma of a gaussian, which by
|
---|
5156 | // default is sigma=0.25 ns. This jitter is applied to each phe-
|
---|
5157 | // independently. We have not applied this to the NSB noise, since the
|
---|
5158 | // arrival time of NSB photons is random and nothing would change.
|
---|
5159 | //
|
---|
5160 | // Revision 1.83 2004/11/17 11:43:13 moralejo
|
---|
5161 | //
|
---|
5162 | // Made the necessary changes in starresponse to account for the new option
|
---|
5163 | // to switch off gain fluctuations for the NSB noise database generation.
|
---|
5164 | // The option in the Star Response card is "gain_fluctuations_off". The
|
---|
5165 | // version number of the NSB database has been updated to 1004 (see
|
---|
5166 | // MStarLight.hxx), now including information on whether the gain
|
---|
5167 | // fluctuations were on or off when the NSB database was generated.
|
---|
5168 | //
|
---|
5169 | // Revision 1.82 2004/11/17 11:34:49 moralejo
|
---|
5170 | //
|
---|
5171 | // Added input card command "noise_gain_fluctuations_off", to disable the
|
---|
5172 | // PMT gain fluctuations also for the NSB noise (just for tests). Added
|
---|
5173 | // a flag to MMcFadcHeader and MMcTrigHeader about this. Also copied the flag
|
---|
5174 | // fGainFluctuations of MMcFadcHeader to MMcTrigHeader, since the gain
|
---|
5175 | // fluctuations affect both the trigger and the signal in the FADC.
|
---|
5176 | //
|
---|
5177 | // Revision 1.81 2004/11/04 22:00:51 moralejo
|
---|
5178 | //
|
---|
5179 | // Removed unused variables fTelesTheta and fTelesPhi from MMcRunHeader. They
|
---|
5180 | // were not useful because telescope orientation may change from event to
|
---|
5181 | // event. Added fMirrorFraction to the MMcConfigRunHeader container in the
|
---|
5182 | // camera output.
|
---|
5183 | //
|
---|
5184 | // Revision 1.80 2004/10/26 19:21:05 moralejo
|
---|
5185 | //
|
---|
5186 | // Added fFadcTimeJitter to root output, in container MMcEvt. Added
|
---|
5187 | // also fGainFluctuations boolean flag to MMcFadcHeader, to keep track of
|
---|
5188 | // whether PMT gain fluctuations are simulated or not.
|
---|
5189 | //
|
---|
5190 | // Revision 1.79 2004/10/26 14:02:32 moralejo
|
---|
5191 | //
|
---|
5192 | // Added option to switch off gain fluctuations (gain_fluctuations_off)
|
---|
5193 | //
|
---|
5194 | // Revision 1.78 2004/10/21 17:44:07 moralejo
|
---|
5195 | //
|
---|
5196 | // Fixed error recently introduced in MLons::GetResponse. The NSB database
|
---|
5197 | // was not correclt ycopied to the FADC when the randomly selected time was
|
---|
5198 | // too close to the end of the database. This happened about 2% of times and
|
---|
5199 | // produced some repetitive noise peaks in the FADC.
|
---|
5200 | // Changed in camera.cxx the arguments of lons.SetSeed y lons_outer.SetSeed
|
---|
5201 | //
|
---|
5202 | // Revision 1.77 2004/10/19 10:35:05 moralejo
|
---|
5203 | // *** empty log message ***
|
---|
5204 | //
|
---|
5205 | // Revision 1.76 2004/10/14 16:56:43 moralejo
|
---|
5206 | //
|
---|
5207 | // - Added calibration_run option to produce calibration MC files.
|
---|
5208 | //
|
---|
5209 | // - Added jitter of pulse position +- 0.5 slices due to FADC clock noise.
|
---|
5210 | //
|
---|
5211 | // Revision 1.75 2004/10/14 12:55:02 moralejo
|
---|
5212 | // *** empty log message ***
|
---|
5213 | //
|
---|
5214 | // Revision 1.74 2004/10/13 17:05:05 moralejo
|
---|
5215 | // *** empty log message ***
|
---|
5216 | //
|
---|
5217 | // Revision 1.72 2004/10/12 13:39:34 moralejo
|
---|
5218 | //
|
---|
5219 | // Lots of changes intended to make it possible to select the FADC sampling
|
---|
5220 | // frequency from the input card, through the command fadc_GHz. The most
|
---|
5221 | // important ones are the following:
|
---|
5222 | //
|
---|
5223 | // - Removed FADC_SLICES de Mars/mmc/Mdefine.h
|
---|
5224 | // Already defined in MFadcDefine.h!
|
---|
5225 | //
|
---|
5226 | // - Replaced fixed numbers in array dimensions of starresponse.cxx
|
---|
5227 | //
|
---|
5228 | // - Added in MFadc.cxx and MFadc.hxx (Float_t) casts to initializations
|
---|
5229 | // of single phe response array
|
---|
5230 | //
|
---|
5231 | // - IMPORTANT: Fixed MFadc::GetResponse -> The returned single phe response
|
---|
5232 | // had only RESPONSE_SLICES (which is actually for the trigger branch),
|
---|
5233 | // whereas it should have RESPONSE_SLICES_MFADC. Fixed the same confusion
|
---|
5234 | // in other two points of the code (filling of the FADC for the signal),
|
---|
5235 | // in Fill() and FillOuter().
|
---|
5236 | //
|
---|
5237 | // - RESPONSE_SLICES_MFADC is now eliminated, since this quantity is now
|
---|
5238 | // decided by MFadc depending on other parameters.
|
---|
5239 | //
|
---|
5240 | // - Fixed problem in starresponse.cxx due to which the histograms fadcresp
|
---|
5241 | // and fadcbase in the root output were actually identical.
|
---|
5242 | //
|
---|
5243 | // - Changed starresponse.cxx such that above 1 phe/ns/pixel the precision
|
---|
5244 | // of the database is forced to be 0.1, and below 1, to 0.01 phe/ns/pixel
|
---|
5245 | //
|
---|
5246 | // - In Camera/creadparam.cxx: Now unkown tokens cause the program to stop,
|
---|
5247 | // instead of being simply skipped as it was until now.
|
---|
5248 | //
|
---|
5249 | // - Fixed error in MStarLight::StoreHisto. TH1::SetBinContent uses bin numbers
|
---|
5250 | // from 1 to nbins (in old code 0 to nbins-1 was assumed).
|
---|
5251 | //
|
---|
5252 | // - In MLons.cxx: use memcpy to copy pieces of the database into the FADC and
|
---|
5253 | // trigger branches, to (hopefully) speed up execution. For this I had to add
|
---|
5254 | // 2 getter functions in MStarLight.hxx
|
---|
5255 | //
|
---|
5256 | // - Everywhere: changed the shape parameter for trigger and FADC response to
|
---|
5257 | // be an Int. Changed version of NSB database from 1002 to 1003.
|
---|
5258 | //
|
---|
5259 | // - In MTrigger.cxx, changed all initializations of SlicesFirst and
|
---|
5260 | // SlicesSecond to 0 (instead of -50 as it was before). This controls the
|
---|
5261 | // time of trigger. If no trigger happened (like when making pedestal files)
|
---|
5262 | // the time was negative and the array index used to retrieve the noise from
|
---|
5263 | // the database was negative, resulting in "discontinuities" in the noise
|
---|
5264 | // (half-photoelectrons for instance).
|
---|
5265 | //
|
---|
5266 | // - In MStarLight changed fBinsTrig and fBinsFadc from Float_t to Int_t
|
---|
5267 | //
|
---|
5268 | // - Replace WIDTH_FADC_TIMESLICE by FADC_SLICES_PER_NSEC (which is the
|
---|
5269 | // inverse of the former)
|
---|
5270 | //
|
---|
5271 | // - Replaced SLICES_PER_NSEC by TRIG_SLICES_PER_NSEC
|
---|
5272 | //
|
---|
5273 | // - TRIGBINS eliminated. It depends on other two values
|
---|
5274 | // TRIGBINS = TIMERANGE*TRIG_SLICES_PER_NSEC
|
---|
5275 | //
|
---|
5276 | // - FADCBINS eliminated. It depends on other two values
|
---|
5277 | // FADCBINS = TIMERANGE*FADC_SLICES_PER_NSEC
|
---|
5278 | //
|
---|
5279 | // - MTriggerDefine.h Changed RESPONSE_SLICES to RESPONSE_SLICES_TRIG
|
---|
5280 | //
|
---|
5281 | // - Added to the MLons constructor an argument regarding the FADC sampling
|
---|
5282 | // frequency
|
---|
5283 | //
|
---|
5284 | // - MFadc: now the number of response slices for the FADC simulation is
|
---|
5285 | // decided by the program according to the other parameters.
|
---|
5286 | //
|
---|
5287 | // - MStarLight: Added arguments (fadc_slices_per_ns, response_slices_fadc)
|
---|
5288 | // to constructor.
|
---|
5289 | //
|
---|
5290 | // - creadparam.cxx, camera.cxx Changed default value of digital_noise to 0.
|
---|
5291 | //
|
---|
5292 | // Revision 1.71 2004/09/17 09:20:52 moralejo
|
---|
5293 | //
|
---|
5294 | // Updated some calls to current version of Mars:
|
---|
5295 | //
|
---|
5296 | // - EvtData[i]->InitRead(RunHeader) instead of EvtData[i]->Init(RunHeader);
|
---|
5297 | // - MRawRunHeader::kMagicNumber instead of just kMagicNumber
|
---|
5298 | // - EvtData[i]->ResetPixels (0, 0) instead of EvtData[i]->DeletePixels();
|
---|
5299 | //
|
---|
5300 | // Revision 1.70 2004/09/16 15:23:12 moralejo
|
---|
5301 | //
|
---|
5302 | // Changed "flashadc" and "trigger" in procedure produce_nsbrates from
|
---|
5303 | // objects to pointers (followed by dynamical allocation). This is only
|
---|
5304 | // to avoid memory problems (-> segmentation fault) in some systems.
|
---|
5305 | // Introduced missing initialization to 0 of *itotnphe in produce_phes.
|
---|
5306 | // Now the number of phes produced by stars shown on the screen make sense.
|
---|
5307 | //
|
---|
5308 | //
|
---|
5309 | // Revision 1.69 2004/03/30
|
---|
5310 | // Changed calculation of MMcFadcHeader.fPedesSigmaHigh and
|
---|
5311 | // MMcFadcHeader.fPedesSigmaLow to do as in real data (see comments in
|
---|
5312 | // code). Changed meaning of MMcFadcHeader.fAmplFadc and fAmplFadcOuter,
|
---|
5313 | // from amplitude to integral of single photoelectron pulse in FADC
|
---|
5314 | // counts. Added possibility to choose a realistic pulse shaped (as
|
---|
5315 | // measured using pulpo). Changed file Data/lightguides.dat by
|
---|
5316 | // Data/LightCollection.dat, intended to contain the information on
|
---|
5317 | // light collection efficiency regarding Winston cones, plexiglas, double
|
---|
5318 | // PMT crossing and colection efficiency of 1st dynode of PMT. Now the
|
---|
5319 | // information for inner and outer pixels can be different, since in the
|
---|
5320 | // LightCollection.dat file they are set independently.
|
---|
5321 | //
|
---|
5322 | // Revision 1.68 2004/02/06 17:39:24 blanch
|
---|
5323 | // Compiling with root 3.05 and updating MARS files.
|
---|
5324 | //
|
---|
5325 | // Revision 1.67 2004/01/30 09:51:18 blanch
|
---|
5326 | // [Changes mainly done by A. Moralejo]
|
---|
5327 | //
|
---|
5328 | // Several minnor changes have been done. For instance, some name of the
|
---|
5329 | // variables have been modified to a more self-explained name and
|
---|
5330 | // modifications while reading the asciis files at the end of the reflector file
|
---|
5331 | // has been introduced.
|
---|
5332 | //
|
---|
5333 | // The possibilty to enlarge the point spread function has been introduced
|
---|
5334 | // in order to be able to simualte the current data.
|
---|
5335 | //
|
---|
5336 | // All pixels are always written.
|
---|
5337 | //
|
---|
5338 | // Revision 1.65 2003/10/26 19:43:00 blanch
|
---|
5339 | // - The screen output information has been improved to prevent some
|
---|
5340 | // non-desired running conditions just looking at the output screen.
|
---|
5341 | // - One MMcEvt for each Telsecope is stored in the output file.
|
---|
5342 | // - 500 empty events are simualted to get a more precise estimation of the
|
---|
5343 | // pedestal Sigma for each pixel.
|
---|
5344 | //
|
---|
5345 | // Revision 1.64 2003/10/21 07:42:50 blanch
|
---|
5346 | // A factor 2.35 to transform the fwhm into the sigma of gaussian was missing
|
---|
5347 | // in the storing of FADC single hpe pulse determination.
|
---|
5348 | //
|
---|
5349 | // Revision 1.63 2003/10/17 19:38:31 blanch
|
---|
5350 | // Now the camera program will stop if a undefined Geometry is required.
|
---|
5351 | // The NSB is internally scaled for any camera geometry and qe.
|
---|
5352 | // The seeds in the input card are used to initilize the random numbers.
|
---|
5353 | // The Amplitud stored in the MMcFadcHeader is the amplitud of the sphe reponse.
|
---|
5354 | // The Pedestal rms is simulated in an artificial empty event.
|
---|
5355 | //
|
---|
5356 | // Revision 1.62 2003/09/26 11:25:07 blanch
|
---|
5357 | // Modification to be able to read MGeomCam branch for any Geometry.
|
---|
5358 | //
|
---|
5359 | // Revision 1.61 2003/09/25 17:09:20 blanch
|
---|
5360 | // Bug on the number of phe from diffuse NSB fixed.
|
---|
5361 | //
|
---|
5362 | // Revision 1.60 2003/09/23 16:50:55 blanch
|
---|
5363 | // WE do not read ct_file anymore since all Telescope information is
|
---|
5364 | // in the reflector or in MGeomCam.
|
---|
5365 | //
|
---|
5366 | // Revision 1.58 2003/09/15 09:59:53 blanch
|
---|
5367 | // The concept of the camera prgoram has not changed but this version has
|
---|
5368 | // quite a lot of changes to allow several Camera geometries as well as
|
---|
5369 | // multitelescope.
|
---|
5370 | //
|
---|
5371 | // It is suposed to be the first working code for camera 0.7.
|
---|
5372 | //
|
---|
5373 | // Revision 1.57 2003/07/17 18:02:46 blanch
|
---|
5374 | // Several new features introduced as well as fixed bugs
|
---|
5375 | //
|
---|
5376 | // - 1/100 events printed out
|
---|
5377 | // - Low gain implemented
|
---|
5378 | // - Different response for outer and inner pixels
|
---|
5379 | // - Some warnings removed
|
---|
5380 | // - pedestal and qe file from inpuit card
|
---|
5381 | // - Faster electronic simulation
|
---|
5382 | //
|
---|
5383 | // Revision 1.55 2003/02/12 12:22:10 blanch
|
---|
5384 | // *** empty log message ***
|
---|
5385 | //
|
---|
5386 | // Revision 1.54 2003/02/12 11:55:01 blanch
|
---|
5387 | // *** empty log message ***
|
---|
5388 | //
|
---|
5389 | // Revision 1.53 2003/01/23 18:35:21 blanch
|
---|
5390 | // *** empty log message ***
|
---|
5391 | //
|
---|
5392 | // Revision 1.52 2003/01/20 17:19:20 blanch
|
---|
5393 | // It fills the MMcCorsikaRun.
|
---|
5394 | //
|
---|
5395 | // Revision 1.51 2003/01/14 13:40:17 blanch
|
---|
5396 | // MRawRunHeader::fNumEvents has been filled with the number of events in
|
---|
5397 | // this file.
|
---|
5398 | // Problems in fImpact computation have been solved.
|
---|
5399 | // Option to set a dc value to rise the discriminator threshold has been added.
|
---|
5400 | //
|
---|
5401 | // Revision 1.50 2003/01/07 16:33:31 blanch
|
---|
5402 | // Star Field Rotation has been implemented by Raul Orduna. Now there is a
|
---|
5403 | // rotation for each shower. It is done by a non enter pixel rotation assuming
|
---|
5404 | // a circular symetry of the camera. It is not exact but it is accurate enough and
|
---|
5405 | // much faster.
|
---|
5406 | //
|
---|
5407 | // Revision 1.49 2002/12/13 10:04:07 blanch
|
---|
5408 | // *** empty log message ***
|
---|
5409 | //
|
---|
5410 | // Revision 1.48 2002/12/12 17:40:50 blanch
|
---|
5411 | // *** empty log message ***
|
---|
5412 | //
|
---|
5413 | // Revision 1.47 2002/12/10 17:19:31 blanch
|
---|
5414 | // *** empty log message ***
|
---|
5415 | //
|
---|
5416 | // Revision 1.46 2002/11/08 17:51:00 blanch
|
---|
5417 | // *** empty log message ***
|
---|
5418 | //
|
---|
5419 | // Revision 1.45 2002/10/29 17:15:27 blanch
|
---|
5420 | // Reading several reflector versions.
|
---|
5421 | //
|
---|
5422 | // Revision 1.44 2002/10/18 16:53:03 blanch
|
---|
5423 | // Modification to read several reflector files.
|
---|
5424 | //
|
---|
5425 | // Revision 1.43 2002/09/13 10:53:39 blanch
|
---|
5426 | // Minor change to remove some undisired comments.
|
---|
5427 | //
|
---|
5428 | // Revision 1.42 2002/09/09 16:00:49 blanch
|
---|
5429 | // Statement has been included to avoid writting to disk MParContainer and MArray.
|
---|
5430 | // It has also been added the effect of the WC, the actual values must be added,
|
---|
5431 | // once they are measured.
|
---|
5432 | //
|
---|
5433 | // Revision 1.41 2002/09/04 09:57:42 blanch
|
---|
5434 | // Modifications done to use MGeomCam from MARS.
|
---|
5435 | //
|
---|
5436 | // Revision 1.40 2002/07/16 16:15:22 blanch
|
---|
5437 | // A first implementation of the Star field rotation has been done.
|
---|
5438 | //
|
---|
5439 | // Revision 1.39 2002/04/27 10:48:39 blanch
|
---|
5440 | // Some unused varibles have been removed.
|
---|
5441 | //
|
---|
5442 | // Revision 1.38 2002/03/18 18:44:29 blanch
|
---|
5443 | // Small modificatin to set the electronic Noise in the MMcTrigHeader class.
|
---|
5444 | //
|
---|
5445 | // Revision 1.37 2002/03/18 16:42:20 blanch
|
---|
5446 | // The data member fProductionSite of the MMcRunHeader has been set to 0,
|
---|
5447 | // which means that the prodution site is unknown.
|
---|
5448 | //
|
---|
5449 | // Revision 1.35 2002/03/15 15:15:52 blanch
|
---|
5450 | // Several modifications to simulate the actual trigger zone.
|
---|
5451 | //
|
---|
5452 | // Revision 1.34 2002/03/13 18:13:56 blanch
|
---|
5453 | // Some changes to fill correctly the new format of MMcRunHeader.
|
---|
5454 | //
|
---|
5455 | // Revision 1.33 2002/03/04 17:21:48 blanch
|
---|
5456 | // Small and not important changes.
|
---|
5457 | //
|
---|
5458 | // Revision 1.32 2002/02/28 15:04:52 blanch
|
---|
5459 | // A small back has been solved. Before, while not using the option
|
---|
5460 | // writte_all_images, not all triggered showers were stored. Now it is solved.
|
---|
5461 | // For that it is important that the less restrictive trigger option is
|
---|
5462 | // checked first.
|
---|
5463 | // A new facility has been introduced and now one can choose the step size in
|
---|
5464 | // trigger loop mode for the discriminator threshold.
|
---|
5465 | // The close-compact topology for less than 3 pixels does not make sense. Before
|
---|
5466 | // the program was ignoring that, now it switch to simple neighbour condition.
|
---|
5467 | //
|
---|
5468 | // Revision 1.31 2002/01/18 17:41:02 blanch
|
---|
5469 | // The option of adding noise to all pixels or to not adding the noise
|
---|
5470 | // has been added.
|
---|
5471 | // We removed the pixels larger than 577. When there were more than one
|
---|
5472 | // trigger in one shower, the pixel number was increasing. Now it is
|
---|
5473 | // flagged by the variable MMcTrig::fFirstLvlTrig.
|
---|
5474 | //
|
---|
5475 | // Revision 1.30 2001/11/27 09:49:54 blanch
|
---|
5476 | // Fixing bug which was treating wrongly the extension of star photons.
|
---|
5477 | //
|
---|
5478 | // Revision 1.29 2001/11/14 17:38:23 blanch
|
---|
5479 | // Sveral changes have been done:
|
---|
5480 | // - bpoint_in_in_pixel has been dodified to speed up the program
|
---|
5481 | // - Some minor changes have been done to remove warnings
|
---|
5482 | // - buffer size and split version of the Branches have been removed
|
---|
5483 | // - Some modifications were needed to adat the program to the new
|
---|
5484 | // MRawEvtData::DeletePixels
|
---|
5485 | //
|
---|
5486 | // Revision 1.28 2001/10/26 16:31:45 blanch
|
---|
5487 | // Removing several warnings.
|
---|
5488 | //
|
---|
5489 | // Revision 1.27 2001/09/05 10:04:33 blanch
|
---|
5490 | // *** empty log message ***
|
---|
5491 | //
|
---|
5492 | // Revision 1.26 2001/07/19 09:29:53 blanch
|
---|
5493 | // Different threshold for each pixel can be used.
|
---|
5494 | //
|
---|
5495 | // Revision 1.25 2001/05/08 08:07:54 blanch
|
---|
5496 | // New numbering for branches from different trigger conditions has been
|
---|
5497 | // implemented. Now, they are calles: ClassName;1., ClasNema;2., ...
|
---|
5498 | // The MontaCarlo Headers (MMcTrigHeader and MMcFadcHeader) have been move to
|
---|
5499 | // the RunHeaders tree. Also the MRawRunHeader is thera with some of its
|
---|
5500 | // information already filled.
|
---|
5501 | //
|
---|
5502 | // Revision 1.24 2001/04/06 16:48:09 magicsol
|
---|
5503 | // New camera version able to read the new format of the reflector output:
|
---|
5504 | // reflector 0.4
|
---|
5505 | //
|
---|
5506 | // Revision 1.23 2001/03/28 16:13:41 blanch
|
---|
5507 | // While feeling the MMcFadeHeader branch the boolean conditoin was wrong. It has
|
---|
5508 | // been solved.
|
---|
5509 | //
|
---|
5510 | // Revision 1.22 2001/03/20 18:52:43 blanch
|
---|
5511 | // *** empty log message ***
|
---|
5512 | //
|
---|
5513 | // Revision 1.21 2001/03/19 19:53:03 blanch
|
---|
5514 | // Some print outs have been removed.
|
---|
5515 | //
|
---|
5516 | // Revision 1.20 2001/03/19 19:30:06 magicsol
|
---|
5517 | // Minor changes have been done to improve the FADC pedestals treatment.
|
---|
5518 | //
|
---|
5519 | // Revision 1.19 2001/03/05 11:14:41 magicsol
|
---|
5520 | // I changed the position of readinf a parameter. It is a minnor change.
|
---|
5521 | //
|
---|
5522 | // Revision 1.18 2001/03/05 10:36:52 blanch
|
---|
5523 | // A branch with information about the FADC simulation (MMcFadcHeader) is writen
|
---|
5524 | // in the McHeaders tree of the aoutput root file.
|
---|
5525 | // The NSB contribution is only applied if the the number of phe form the shower
|
---|
5526 | // are above a given number.
|
---|
5527 | //
|
---|
5528 | // Revision 1.17 2001/02/23 11:05:57 magicsol
|
---|
5529 | // Small changes due to slightly different output format and the introduction of
|
---|
5530 | // pedesals for teh FADC.
|
---|
5531 | //
|
---|
5532 | // Revision 1.16 2001/01/18 18:44:40 magicsol
|
---|
5533 | // *** empty log message ***
|
---|
5534 | //
|
---|
5535 | // Revision 1.15 2001/01/17 09:32:27 harald
|
---|
5536 | // The changes are neccessary to have the same name for trees in MC and in
|
---|
5537 | // data. So now there should be no differences in MC data and real data from
|
---|
5538 | // FADC system.
|
---|
5539 | //
|
---|
5540 | // Revision 1.14 2001/01/15 12:33:34 magicsol
|
---|
5541 | // Some modifications have been done to use the new (Dec'2000) Raw data format.
|
---|
5542 | // There are also some minnors modifications to adapt the improvements in the
|
---|
5543 | // MTrigger class (overlaping time and trigger cells).
|
---|
5544 | //
|
---|
5545 | // Revision 1.13 2000/10/25 08:14:23 magicsol
|
---|
5546 | // The routine that produce poisson random numbers to decide how many phe
|
---|
5547 | // form NSB are emmited in each pixel has been replaced. Now a ROOT routine
|
---|
5548 | // is used.
|
---|
5549 | //
|
---|
5550 | // Revision 1.10 2000/07/04 14:10:20 MagicSol
|
---|
5551 | // Some changes have been done in the root output file. The RawEvt tree is only
|
---|
5552 | // stored in the single trigger mode.
|
---|
5553 | // The trigger input parameters are also given by the general input card.
|
---|
5554 | // The diffuse NSB and the star NSB have been decoupled. Now the contribution of
|
---|
5555 | // each one can be studied seperately.
|
---|
5556 | //
|
---|
5557 | // Revision 1.9 2000/06/13 13:25:24 blanch
|
---|
5558 | // The multiple arrays have been replaced, since they do not work
|
---|
5559 | // in alpha machines. Now we are using pointers and the command new
|
---|
5560 | // to allocate memory.
|
---|
5561 | //
|
---|
5562 | // Revision 1.8 2000/05/11 13:57:27 blanch
|
---|
5563 | // The option to loop over several trigger configurations has been included.
|
---|
5564 | // Some non-sense with triggertime range has been solved.
|
---|
5565 | // Montecarlo information and ADC counts are saved in a root file.
|
---|
5566 | // There was a problem with the maximum number of phe that the program could analyse. Now there is not limit.
|
---|
5567 | //
|
---|
5568 | // Revision 1.7 2000/03/24 18:10:46 blanch
|
---|
5569 | // A first FADC simulation and a trigger simulation are already implemented.
|
---|
5570 | // The calculation of the Hillas Parameters have been removed, since it was decided that it should be in the analysis software.
|
---|
5571 | // A loop over trigger threshold and some corretcions in the time range where it looks for a trigger will be implemented as soon as possible.
|
---|
5572 | //
|
---|
5573 | // Revision 1.6 2000/03/20 18:35:11 blanch
|
---|
5574 | // The trigger is already implemented but it does not save the trigger information in any file as it is implemented in timecam. In the next days there will be a version which also creates the files with the trigger information. It is going to be a mixing of the current camera and timecam programs.
|
---|
5575 | //
|
---|
5576 | // Revision 1.5 2000/02/18 17:40:35 petry
|
---|
5577 | // This version includes drastic changes compared to camera.cxx 1.4.
|
---|
5578 | // It is not yet finished and not immediately useful because the
|
---|
5579 | // trigger simulation is not yet re-implemented. I had to take it
|
---|
5580 | // out together with some other stuff in order to tidy the whole
|
---|
5581 | // program up. This is not meant as an insult to anyone. I needed
|
---|
5582 | // to do this in order to be able to work on it.
|
---|
5583 | //
|
---|
5584 | // This version has been put in the repository in order to be
|
---|
5585 | // able to share the further development with others.
|
---|
5586 | //
|
---|
5587 | // If you need something working, wait or take an earlier one.
|
---|
5588 | // See file README.
|
---|
5589 | //
|
---|
5590 | // Revision 1.4 2000/01/25 08:36:23 petry
|
---|
5591 | // The pixelization in previous versions was buggy.
|
---|
5592 | // This is the first version with a correct pixelization.
|
---|
5593 | //
|
---|
5594 | // Revision 1.3 2000/01/20 18:22:17 petry
|
---|
5595 | // Found little bug which makes camera crash if it finds a photon
|
---|
5596 | // of invalid wavelength. This bug is now fixed and the range
|
---|
5597 | // of valid wavelengths extended to 290 - 800 nm.
|
---|
5598 | // This is in preparation for the NSB simulation to come.
|
---|
5599 | // Dirk
|
---|
5600 | //
|
---|
5601 | // Revision 1.2 1999/11/19 08:40:42 harald
|
---|
5602 | // Now it is possible to compile the camera programm under osf1.
|
---|
5603 | //
|
---|
5604 | // Revision 1.1.1.1 1999/11/05 11:59:31 harald
|
---|
5605 | // This the starting point for CVS controlled further developments of the
|
---|
5606 | // camera program. The program was originally written by Jose Carlos.
|
---|
5607 | // But here you can find a "rootified" version to the program. This means
|
---|
5608 | // that there is no hbook stuff in it now. Also the output of the
|
---|
5609 | // program changed to the MagicRawDataFormat.
|
---|
5610 | //
|
---|
5611 | // The "rootification" was done by Dirk Petry and Harald Kornmayer.
|
---|
5612 | //
|
---|
5613 | // Revision 1.3 1999/10/22 15:01:28 petry
|
---|
5614 | // version sent to H.K. and N.M. on Fri Oct 22 1999
|
---|
5615 | //
|
---|
5616 | // Revision 1.2 1999/10/22 09:44:23 petry
|
---|
5617 | // first synthesized version which compiles and runs without crashing;
|
---|
5618 | //
|
---|
5619 | // Revision 1.1.1.1 1999/10/21 16:35:10 petry
|
---|
5620 | // first synthesised version
|
---|
5621 | //
|
---|
5622 | // Revision 1.13 1999/03/15 14:59:05 gonzalez
|
---|
5623 | // camera-1_1
|
---|
5624 | //
|
---|
5625 | //
|
---|
5626 | //!@}
|
---|
5627 |
|
---|
5628 | //=EOF
|
---|