1 | \section{Introduction}
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2 |
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3 |
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4 | The MAGIC telescope aims to study the gamma ray emission from high energy phenomena and the violent physics
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5 | processes in the universe
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6 | at the lowest energy threshold possible \cite{low_energy}.
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7 |
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8 | Figure~\ref{fig:MAGIC_read-out_scheme} shows a sketch of the MAGIC read-out scheme, including the
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9 | photomultiplier tubes (PMT) camera,
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10 | the analog-optical link, the majority trigger logic and flash analog-to-digital converters (FADCs).
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11 | The used PMTs provide a very fast
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12 | response to the input light signal. The response of the PMTs to sub-ns input light pulses shows a FWHM of
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13 | 1.0 - 1.2 ns and rise and fall times of 600 and 700\,ps correspondingly~\cite{Magic-PMT}. By modulating
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14 | vertical-cavity surface-emitting laser (VCSEL)
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15 | type laser diodes in amplitude, the fast analog signals from the PMTs are transferred via 162\,m long,
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16 | 50/125\,$\mu$m diameter optical fibers to the counting house \cite{MAGIC-analog-link-2}. After transforming the
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17 | light back to an electrical signal, the original PMT pulse has a FWHM of about 2.2 ns and rise and fall
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18 | times of about 1\,ns. % was 2.2 ns
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19 |
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20 | %an analog optical link \ci
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21 | %te{MAGIC-analog-link-2} to the counting house.
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22 |
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23 |
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24 | \begin{figure}[h!]
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25 | \begin{center}
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26 | \includegraphics[width=\textwidth]{Magic_readout_scheme1.eps}
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27 | \end{center}
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28 | \caption[Current MAGIC read-out scheme.]{Current MAGIC read-out scheme: the analog PMT signals are
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29 | transferred via an analog optical link to the counting house -- where after the trigger decision -- the signals
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30 | are digitized by a 300\,MHz FADCs system and written to the hard disk of a data acquisition PC.}
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31 | \label{fig:MAGIC_read-out_scheme}
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32 | \end{figure}
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33 |
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34 |
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35 |
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36 | %After modulating VCSEL type laser diodes, after traveling through 162m of multi-mode graded index fiber of 50/125 $\mu$m diameter and.
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37 |
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38 |
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39 | In order to sample this pulse shape with the 300 MSamples/s FADC system, the original pulse is folded with a
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40 | stretching function of 6ns leading to a FWHM greater than 6\,ns. Because the MAGIC FADCs have a
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41 | resolution of 8 bit only, the signals are split into two branches with gains differing by a factor 10.
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42 | One branch is delayed by 55\,ns and then both branches are multiplexed and consecutively read-out by one FADC.
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43 | Figure~\ref{fig:pulpo_shape_high} shows a typical average of identical signals.
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44 | A more detailed overview about the MAGIC read-out and DAQ system is given in \cite{Magic-DAQ}.
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45 | % The maximum sustained trigger rate could be 1 kHz. The FADCs feature a FIFO memory which allows a significantly higher short-time rate.
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46 | % Obviously by doing this, more LONS is integrated and thus the performance of the telescope on the analysis level is degraded.
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47 |
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48 |
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49 | To reach the highest sensitivity and the lowest possible analysis energy threshold the recorded signals from
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50 | Cherenkov light have to be accurately reconstructed. Therefore the highest possible signal to noise ratio,
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51 | signal reconstruction resolution and a small bias are important.
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52 |
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53 | Monte Carlo (MC) based simulations predict different time structures for gamma and hadron induced shower
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54 | images as well as for images of single muons. An accurate arrival time determination may therefore improve
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55 | the separation power of gamma events from the background events. Moreover, the timing information may be
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56 | used in the image cleaning to discriminate between pixels which signal belongs to the shower and pixels
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57 | which are affected by randomly timed background noise.
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58 |
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59 |
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60 | This note is structured as follows: In section~\ref{sec:reco} the average pulse shapes are reconstructed
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61 | from the recorded
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62 | FADC samples for calibration and cosmics pulses. These pulse shapes are compared with the pulse shape
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63 | implemented in the MC simulation.
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64 | In section~\ref{sec:algorithms} different signal reconstruction algorithms and their implementation in
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65 | the common MAGIC software framework {\textit{\bf MARS}} are reviewed.
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66 | In section~\ref{sec:criteria} criteria for an optimal
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67 | signal
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68 | reconstruction are developed. Thereafter the signal extraction algorithms under study are applied to
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69 | pedestal, calibration and MC events in sections~\ref{sec:pedestals} to~\ref{sec:mc}.
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70 | The CPU requirements of the different algorithms
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71 | are compared in section~\ref{sec:speed}. Finally in section~\ref{sec:results} the results are summarized
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72 | and in section~\ref{sec:conclusion} a standard signal extraction algorithm for MAGIC is proposed.
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73 |
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74 | \subsection{Characteristics of the current read-out system}
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75 |
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76 | The following intrinsic characteristics of the current read-out system affect especially the signal
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77 | reconstruction:
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78 |
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79 | \begin{description}
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80 | \item[Inner and Outer pixels:\xspace] The MAGIC camera has two types of pixels which incorporate the following differences:
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81 | \begin{enumerate}
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82 | \item Size: The outer pixels have a factor four bigger area then the inner pixels~\cite{MAGIC-design}.
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83 | Their (quantum-efficiency convoluted) effective area is about a factor 2.6 higher.
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84 | \item Gain: The camera is flat-fielded in order to yield a similar reconstructed charge signal for the same photon illumination intensity.
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85 | In order to achieve this, the gain of the inner pixels has been adjusted to about a factor 2.6 higher than the outer
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86 | ones~\cite{tdas-calibration}. This results in lower effective noise charge from the night sky background for the outer pixels.
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87 | \item Delay: The signal of the outer pixels is delayed by about 1.5\,ns with respect to the inner ones.
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88 | \end{enumerate}
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89 | \item[Clock noise:\xspace] The MAGIC 300\,MHz FADCs have an intrinsic clock noise of a few least significant bits (LSBs) occurring with a frequency of 150\,MHz.
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90 | This clock noise results
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91 | in a superimposed AB-pattern for the read-out pedestals. In the standard analysis, the amplitude of this clock noise gets measured in the
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92 | pedestal extraction algorithms and further corrected for by all signal extractors.
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93 | \item[Trigger Jitter:\xspace] The FADC clock is not synchronized with the trigger. Therefore, the relative position of the recorded
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94 | signal samples varies uniformly by one FADC slice with respect to the position of the signal shape by one FADC slice from event to event.
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95 | \item[DAQ jumps:\xspace] Unfortunately, the position of the signal pulse with respect to the first recorded FADC sample is not constant.
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96 | It varies randomly by an integer number of FADC slices -- typically two -- in about 1\% of the channels per event.
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97 |
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98 | \end{description}
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99 |
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100 | %%% Local Variables:
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101 | %%% mode: latex
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102 | %%% TeX-master: "MAGIC_signal_reco"
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103 | %%% TeX-master: "Introduction"
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104 | %%% End:
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105 |
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