Changeset 817 for trunk/ICRC_01
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- 05/30/01 14:10:58 (24 years ago)
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trunk/ICRC_01/mccontrib.tex
r816 r817 273 273 digital output. 274 274 275 The first-level-trigger is looking in the digital output of the 276 271 pixels of the trigger system for next neighbor (NN) conditions. 277 The adjustable settings on the first-level-trigger 275 The first-level-trigger checks in the digital output of the 276 271 pixels of the trigger system for next neighbor (NN) 277 conditions. 278 The adjustable settings of the first-level-trigger 278 279 are the mulitiplicity, the topology and the minimum required 279 280 overlapping time. 280 281 281 282 The MC data produced are used to calculate some important 283 parameter of the MAGIC telescope on the level of the284 trigger system. 285 286 The second-level-trigger of the MAGIC telescope will be a 287 pattern-recognition method. This part is still in the design288 phase. All results presented here are based on studies of the 289 first-level-trigger. 282 The second-level-trigger of the MAGIC telescope will be based 283 on a pattern-recognition method. 284 This part is still in the design phase. 285 All results presented here are based on studies of the 286 first-level-trigger. It not mentioned somewhere else, 287 the MC data are produced with "standard" 288 values (discriminator threshold = 4 mV, gate length = 6 nsec, 289 multiplicity = 4, topology of NN = {\sl closed package}). 290 290 291 291 292 292 293 \subsubsection{Collection area} 294 295 293 296 294 297 The trigger collection area is defined as the integral … … 296 299 A(E,\Theta) = \int_{F}{ T(E,\Theta,F) dF} 297 300 \end{equation} 298 where T is the trigger probablity. F is perpendicular to 299 the shower axis. The results for different zenith angle $\Theta$ and 301 where T is the trigger probablity. F is a plane perpendicular 302 to the shower axis. 303 The results for different zenith angle $\Theta$ and 300 304 for different discriminator thresholds are shown in figure 301 305 \ref{fig_collarea}. 306 At low energies ($ E < 100 ~\mathrm{GeV}$), the collection area 307 decreases with increasing zenith angle , and it decreases with 302 308 % 303 309 % … … 314 320 % 315 321 % 316 As bigger the zenith angle the smaller becomes the collection area 317 for lower energies. As bigger the discriminator threshold is set, as 318 lower is the trigger collection area for low energies. 322 increasing diskriminator threshold. 319 323 320 324 … … 322 326 323 327 The threshold of the MAGIC telesope is defined as the peak 324 in the $dN/dE$ distribution. For all different trigger settings 328 in the $dN/dE$ distribution for triggered showers. 329 For all different trigger settings 325 330 this value is determined. The energy threshold could 326 depend among other variables on the Background simulated conditions,331 depend among other variables on the background conditions, 327 332 the threshold of the trigger discriminator and the zenith angle. We 328 check the influence of the three above-mentionedvariables.333 check the influence of these three variables. 329 334 330 335 For both, gammas and protons, some different background conditions 331 336 have been simulated (without any background light, diffuse light, 332 and light from Crab Nebula field of view). The results pointed out333 that there is not any variation of the energy threshold inside our334 error, which is few GeV, in determining the maximum. It is335 worth to remember that this is based only in first level trigger.336 Most likely there will be some effects when one entersthe second337 and light from Crab Nebula field of view). 338 No significant variation of the energy threshold is observed. 339 It should be stressed that this is based only on first level 340 triggers. 341 Most likely some effects will be seen after the second 337 342 level trigger and the shower reconstruction. 338 343 339 M agicwill do observations in a large range of zenith angles,340 therefore i s worth to studythe energy threshold as function of341 the zenith angle . In figure \ref{fig_enerthres}, it is shown for 0, 5342 and 10 degrees.Even though larger statistic is needed, the energy343 threshold increases slowly with the zenith angle .344 MAGIC will do observations in a large range of zenith angles, 345 therefore it is worth studying the energy threshold as function of 346 the zenith angle (see figure \ref{fig_enerthres}). 347 Even though larger statistic is needed, the energy 348 threshold increases slowly with the zenith angle, as expected. 344 349 \begin{figure}[hb] 345 350 \vspace*{2.0mm} % just in case for shifting the figure slightly down … … 353 358 photons in the camera plane are needed to trigger the Telescope. 354 359 And it helps the low energy showers to fulfil the required trigger 355 conditions. In figure \ref{fig_enerthres} one can see that the threshold 356 energy decreases while lowering the discriminator. It is 29 GeV for 3 mV 357 and 105 GeV for 7 mV. Since one of the aims of the Telescope is lowering as 358 much as possible the energy threshold, a low discriminator value is 359 preferred. But for 3 mV the expected rate due to protons increases a 360 conditions. 361 In figure \ref{fig_enerthres} one can see that the threshold 362 energy decreases when lowering the discriminator. 363 It is 29 GeV for 3 mV and 105 GeV for 7 mV. 364 Since we are aiming for a low energy threshold, 365 a low discriminator value is preferred. 366 However, for 3 mV the expected rate due to protons increases a 360 367 lot (see section ~\ref{sec-rates}), while it keeps under control at 4 mV. 361 Therefore, the threshold of the discriminator would be kept a bove362 4 mV, which yields a energy threshold of 45 GeV.368 Therefore, the threshold of the discriminator would be kept around 369 4 mV, which yields an energy threshold of 45 GeV. 363 370 364 371 \subsubsection{Expected rates}\label{sec-rates}
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