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2 | \documentclass{icrc}
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3 |
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4 | \usepackage{times}
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5 | \usepackage{graphicx} % when using Latex and dvips
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6 | % % (the latter best with option -Pcmz, if available,
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7 | % % to invoke Type 1 cm fonts)
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8 | %\usepackage[pdftex]{graphicx} % when using pdfLatex (preferred)
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9 |
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10 | \begin{document}
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11 |
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12 | \title{Detailed Monte Carlo studies for the MAGIC telescope}
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13 | \author[1]{O. Blanch}
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14 | \affil[1]{IFAE, Barcelona, Spain}
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15 | \author[2]{J.C. Gonzalez}
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16 | \affil[2]{Universidad Complutense Madrid, Spain}
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17 | \author[3]{H. Kornmayer}
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18 | \affil[3]{Max-Planck-Institut f\"ur Physik, M\"unchen, Germany}
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19 | \correspondence{H. Kornmayer (h.kornmayer@web.de)}
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20 |
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21 | \firstpage{1}
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22 | \pubyear{2001}
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23 |
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24 | % \titleheight{11cm} % uncomment and adjust in case your title block
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25 | % does not fit into the default and minimum 7.5 cm
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26 |
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27 | \maketitle
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28 |
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29 | \begin{abstract}
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30 | For the understanding of a large Cherenkov telescope a detailed
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31 | simulation of air showers and of the detector response are
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32 | unavoidable. Such a simulation must take into account the development
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33 | of air showers in the atmosphere, the reflectivity of the mirrors,
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34 | the response of photo detectors
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35 | and the influence of both the light of night sky and the light of
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36 | bright stars.
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37 | A detailed study will be presented.
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38 | \end{abstract}
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39 |
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40 | \section{Introduction}
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41 |
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42 | In this year the construction of the the $17~\mathrm{m}$ diameter
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43 | Che\-ren\-kov telescope called MAGIC will be finished. The aim of this
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44 | detector is the observation of $\gamma$-ray sources in the
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45 | enery region above $\approx 10~\mathrm{TeV}$.
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46 | The size of the telesope mirros will be around $250~\mathrm{m^2}$.
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47 | The air showers induced by cosmic ray particles (hadrons and gammas)
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48 | will be detected with a "classical" camera consisting of 577
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49 | photomultiplier tubes (PMT). The analog signals of these PMTs will
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50 | be recorded by a FADC system running with a frequency of
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51 | $f = 333~\mathrm{MHz}$.
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52 | The readout of the FADCs by a dedicated trigger system containing
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53 | different trigger levels.
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54 |
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55 | The goal of the trigger system is to reject the hadronic cosmic ray
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56 | background from the gamma rays, for which a lower threshold is aimed.
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57 | For a better understanding of the MAGIC telescope and its different
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58 | systems (trigger, FADC) a detailed Monte Carlo (MC) study is
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59 | unavoidable. Such an study has to take into account the simulation
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60 | of air showers, the effect of absorption in the atmosphere, the
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61 | behaviour of the PMTs and the response of the trigger and FADC
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62 | system.
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63 | For a big telescope like MAGIC there is an additional source of
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64 | noise, which is the light of the night sky. As a rude assumption
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65 | there will be around 50 stars with magnitude $m \le 9$ in the
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66 | field of view of the camera. So one other game of this
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67 | study is to invent methods to become rid of the light from
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68 | stars.
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69 |
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70 | Here we present the first results of such an investigation.
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71 |
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72 | \section{Generation of MC data samples}
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73 |
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74 | The simulation of the MAGIC telescope is seperated in a
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75 | subsequent chain of smaller simulation parts. First the
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76 | air showers are simulated with the
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77 | CORSIKA program \citep{hk95}.
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78 | In the next step we simulate the reflection of the
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79 | Cherenkov photons on the mirror dish.
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80 | Then the behaviour of the PMTs is simulated and the
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81 | response of the trigger and FADC system is generated.
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82 | In the followin subsections you find a more precise
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83 | description of all the programs.
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84 |
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85 | \subsection{Air shower simulation}
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86 |
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87 | The simulation of gammas and of hadrons is done with
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88 | the CORSIKA program, version ????.
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89 | For the simulation of hadronic
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90 | showers we use the VENUS model. We simulate showers
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91 | for different zenith angles
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92 | ($\Theta = 0^\circ, 5^\circ, 10^\circ, 15^\circ,
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93 | 20^\circ, 25^\circ $).
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94 | Gammas where simulated like a point source
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95 | whereas the hadrons are simulated isotropic around
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96 | the given zenith angle. We found that hadronic showers
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97 | have also for big impact parameters $I$ a non-zero
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98 | probability to trigger the telescope. Therefore we
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99 | simulate hadrons with $I < 400~\mathrm{m}$ and gammas
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100 | with $I < 200~\mathrm{m}$.
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101 | The number of generated showers can be found in table
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102 | \ref{tab_showers}.
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103 | %
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104 | %
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105 | %
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106 | \begin{table}[b]
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107 | \begin{center}
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108 | \begin{tabular}{|c||r|r||}
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109 | \hline
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110 | zenith angle & gammas & protons \\
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111 | \hline \hline
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112 | $\Theta = 0^\circ$ & & \\
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113 | $\Theta = 5^\circ$ & & \\
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114 | $\Theta = 10^\circ$ & & \\
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115 | $\Theta = 15^\circ$ & & $\approx 5 \cdot 10^6$ \\
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116 | $\Theta = 20^\circ$ & & \\
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117 | $\Theta = 25^\circ$ & & \\
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118 | \hline
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119 | \end{tabular}
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120 | \end{center}
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121 | \caption {Number of generated showers}
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122 | \label{tab_showers}
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123 | \end{table}
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124 | %
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125 | %
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126 | %
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127 | For each simulated shower all
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128 | Cherenkov photons hitting the groud at observation level
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129 | close to the telesope position are stored.
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130 |
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131 | \subsection{mirror simulation}
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132 |
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133 | The output of the air shower simualition is used
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134 | as the input to the mirror simulation. But before
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135 | simulating the mirror themself, one has to take the
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136 | absorption in the atmosphere into account. For each
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137 | Cherenkov photon the height of production and
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138 | the wavelength is known. Taking the Rayleigh and
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139 | Mie scattering into account one is able to calculate
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140 | the effect of absorption in the atmosphere.
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141 | The next step in the simulation is the reflection of
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142 | the Cherenkov photons on the mirrors. Therefore one
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143 | has to define in that step the pointing of the
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144 | telescope. Each photon hitting one of the mirrors will
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145 | be tracked to the camera plane. Here we take an
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146 | reflectivity of around 90\% into account.
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147 | All Cherenkov photons reaching the camera plane will be
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148 | stored.
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149 |
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150 | \subsection{camera simulation}
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151 |
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152 | The camera simulates the behaviour of the PMTs and the
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153 | electronics of the trigger and FADC system. After the
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154 | pixelisation we take the wavelength dependent quantum
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155 | efficiency (QE) for each PMT into account.
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156 | In figure \ref{fig_qe}
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157 | the QE of a typical MAGIC PMT is shown.
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158 | %
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159 | %
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160 | %
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161 | \begin{figure}[hb]
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162 | \vspace*{2.0mm} % just in case for shifting the figure slightly down
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163 | \includegraphics[width=8.3cm]{qe_123.eps} % .eps for Latex,
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164 | % pdfLatex allows .pdf, .jpg, .png and .tif
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165 | \caption{quantum efficency of the PMT for pixel 123}
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166 | \label{fig_qe}
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167 | \end{figure}
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168 | %
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169 | %
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170 | %
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171 | For each photo electron (PE) leaving the photo cathod we
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172 | generate a "standard" response function that we add to
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173 | the analog signal of that PMT - seperatly for the
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174 | trigger and the FADC system.
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175 | At the present these response function are gaussians with
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176 | a given width.
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177 | The amplitude of the response function is randomized
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178 | by using the function of figure \ref{fig_ampl}.
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179 | By superimpose all photons of one pixel an by taking
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180 | the arrival time into account we get the response
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181 | of the trigger and FADC system for that pixel (see
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182 | also figure \ref{fig_starresp}).
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183 | This is done for all pixels in the camera.
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184 |
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185 | Then the simulation of the trigger electronic is applied.
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186 | We look in the generated analog signal if the discriminator
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187 | threshold is achieved. If yes we will create a digital output
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188 | signal for that pixels. Then we decided if a first level trigger
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189 | occurs by looking for next neighbour (NN)conditions at a given
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190 | time. If a given NN condition (Multiplicity, Topology, ...)
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191 | is fullfilled, a first level trigger is generated and the
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192 | content of the FADC system is written to disk. An triggered
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193 | event is generated.
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194 | %
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195 | %
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196 | %
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197 | \begin{figure}[t]
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198 | \vspace*{2.0mm} % just in case for shifting the figure slightly down
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199 | \includegraphics[width=8.3cm]{ampldist.eps} % .eps for Latex,
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200 | % pdfLatex allows .pdf, .jpg, .png and .tif
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201 | \caption{The distibution of amplitude of the standard response function.}
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202 | \label{fig_ampl}
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203 | \end{figure}
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204 | %
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205 | %
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206 | %
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207 |
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208 | \subsection{starlight simulation}
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209 |
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210 | Due to the big mirror surface the light from the stars around
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211 | the position of an expected gamma ray source is contributing to
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212 | the noise in the camera. We developed a program that allows use
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213 | to simulate the star light together with the generated shower.
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214 | This program takes all stars in the field of view of the camera
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215 | around chosen sky region. The light of these stars is track up to
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216 | the camera taking the frequency of the light into account.
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217 | After simulating the response of the photo cathode, we
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218 | get the number of emitted photo electrons per pixel and
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219 | time.
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220 | These number is used to generate a noise signal for all the pixels.
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221 | In figure \ref{fig_starresp} the response of the trigger and the
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222 | FADC system can be seen for one pixel with a star of
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223 | magnitude $m = 7$.
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224 | These stars are typical, because there will
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225 | be always one $7^m$ star in the trigger area of the camera.
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226 | %
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227 | %
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228 | %
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229 | \begin{figure}[h]
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230 | \vspace*{2.0mm} % just in case for shifting the figure slightly down
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231 | \includegraphics[width=8.3cm]{signal.eps} % .eps for Latex,
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232 | % pdfLatex allows .pdf, .jpg, .png and .tif
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233 | \caption{The response of a pixel due to a star with magnitude
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234 | $m=7$ in the field of view. On the left plot the response of the
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235 | trigger system is plotted while on the right plot the content in the
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236 | FADC system is shown.}
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237 | \label{fig_starresp}
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238 | \end{figure}
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239 | %
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240 | %
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241 | %
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242 |
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243 | \section{Results}
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244 |
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245 | \subsection{Trigger studies}
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246 |
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247 | The MC data produced are used to calculate some important
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248 | parameter of the MAGIC telescope on the level of the
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249 | trigger system.
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250 | The trigger system build up will consist of different
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251 | trigger levels. The discriminator of each channel is called the
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252 | zero-level-trigger. For a given signal each discriminator will
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253 | produce a digital output signal of a given length. So the important
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254 | parameters of such an system are the threshold of each discriminator
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255 | and the length of the digital output.
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256 |
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257 | The first-level-trigger is looking in the digital output of the
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258 | 271 pixels of the trigger system for next neighbor (NN) conditions.
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259 | The adjustable settings on the first-level-trigger
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260 | are the mulitiplicity, the topology and the minimum required
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261 | overlapping time.
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262 |
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263 | The second-level-trigger of the MAGIC telescope will be a
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264 | pattern-recognition method. This part is still in the design
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265 | phase. All results presented here are based on studies of the
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266 | first-level-trigger.
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267 |
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268 | \subsubsection{Collection area}
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269 |
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270 |
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271 | \subsubsection{Threshold of MAGIC telescope}
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272 |
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273 | \subsubsection{Expected rates}
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274 |
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275 | \section{Conclusion}
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276 |
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277 | \begin{acknowledgements}
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278 | The authors thanks all the members of the MAGIC collaboration
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279 | for their support in production of the big amount of simulated data.
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280 | \end{acknowledgements}
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281 |
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282 | %\appendix
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283 | %
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284 | %\section{Appendix section 1}
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285 | %
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286 | %Text in appendix.
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287 | %
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288 |
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289 | \begin{thebibliography}{99}
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290 |
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291 | \bibitem[Heck and Knapp(1995)]{hk95}
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292 | Heck, D. and Knapp J., CORSIKA Manual, 1995.
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293 |
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294 | \bibitem[Abramovitz and Stegun(1964)]{as64}
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295 | Abramowitz, M. and Stegun, I. A., Handbook of Mathematical Functions,
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296 | U. S. Govt. Printing Office, Washington D. C., 1964.
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297 |
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298 | \bibitem[Aref(1983)]{a83}
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299 | Aref, H., Integrable, chaotic, and turbulent vortex motion in
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300 | two-dimensional flows, Ann. Rev. Fluid Mech., 15, 345--389, 1983.
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301 |
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302 | \end{thebibliography}
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303 |
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304 | \end{document}
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