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1\section{Introduction}
2
3
4The MAGIC telescope aims to study the gamma ray emission from high energy phenomena and the violent physics
5processes in the universe
6at the lowest energy threshold possible \cite{low_energy}.
7
8Figure~\ref{fig:MAGIC_read-out_scheme} shows a sketch of the MAGIC read-out scheme, including the
9photomultiplier tubes (PMT) camera,
10the analog-optical link, the majority trigger logic and flash analog-to-digital converters (FADCs).
11The used PMTs provide a very fast
12response to the input light signal. The response of the PMTs to sub-ns input light pulses shows a FWHM of
131.0 - 1.2 ns and rise and fall times of 600 and 700\,ps correspondingly~\cite{Magic-PMT}. By modulating
14vertical-cavity surface-emitting laser (VCSEL)
15type laser diodes in amplitude, the fast analog signals from the PMTs are transferred via 162\,m long,
1650/125\,$\mu$m diameter optical fibers to the counting house \cite{MAGIC-analog-link-2}. After transforming the
17light back to an electrical signal, the original PMT pulse has a FWHM of about 2.2 ns and rise and fall
18times of about 1\,ns. % was 2.2 ns
19
20%an analog optical link \ci
21%te{MAGIC-analog-link-2} to the counting house.
22
23
24\begin{figure}[h!]
25\begin{center}
26\includegraphics[width=\textwidth]{Magic_readout_scheme1.eps}
27\end{center}
28\caption[Current MAGIC read-out scheme.]{Current MAGIC read-out scheme: the analog PMT signals are
29transferred via an analog optical link to the counting house -- where after the trigger decision -- the signals
30are digitized by a 300\,MHz FADCs system and written to the hard disk of a data acquisition PC.}
31\label{fig:MAGIC_read-out_scheme}
32\end{figure}
33
34
35
36%After modulating VCSEL type laser diodes, after traveling through 162m of multi-mode graded index fiber of 50/125 $\mu$m diameter and.
37
38
39In order to sample this pulse shape with the 300 MSamples/s FADC system, the original pulse is folded with a
40stretching function of 6ns leading to a FWHM greater than 6\,ns. Because the MAGIC FADCs have a
41resolution of 8 bit only, the signals are split into two branches with gains differing by a factor 10.
42One branch is delayed by 55\,ns and then both branches are multiplexed and consecutively read-out by one FADC.
43Figure~\ref{fig:pulpo_shape_high} shows a typical average of identical signals.
44A more detailed overview about the MAGIC read-out and DAQ system is given in \cite{Magic-DAQ}.
45% The maximum sustained trigger rate could be 1 kHz. The FADCs feature a FIFO memory which allows a significantly higher short-time rate.
46% Obviously by doing this, more LONS is integrated and thus the performance of the telescope on the analysis level is degraded.
47
48
49To reach the highest sensitivity and the lowest possible analysis energy threshold the recorded signals from
50Cherenkov light have to be accurately reconstructed. Therefore the highest possible signal to noise ratio,
51signal reconstruction resolution and a small bias are important.
52
53Monte Carlo (MC) based simulations predict different time structures for gamma and hadron induced shower
54images as well as for images of single muons. An accurate arrival time determination may therefore improve
55the separation power of gamma events from the background events. Moreover, the timing information may be
56used in the image cleaning to discriminate between pixels which signal belongs to the shower and pixels
57which are affected by randomly timed background noise.
58
59
60This note is structured as follows: In section~\ref{sec:reco} the average pulse shapes are reconstructed
61from the recorded
62 FADC samples for calibration and cosmics pulses. These pulse shapes are compared with the pulse shape
63implemented in the MC simulation.
64In section~\ref{sec:algorithms} different signal reconstruction algorithms and their implementation in
65the common MAGIC software framework {\textit{\bf MARS}} are reviewed.
66In section~\ref{sec:criteria} criteria for an optimal
67signal
68reconstruction are developed. Thereafter the signal extraction algorithms under study are applied to
69pedestal, calibration and MC events in sections~\ref{sec:pedestals} to~\ref{sec:mc}.
70The CPU requirements of the different algorithms
71are compared in section~\ref{sec:speed}. Finally in section~\ref{sec:results} the results are summarized
72and in section~\ref{sec:conclusion} a standard signal extraction algorithm for MAGIC is proposed.
73
74\subsection{Characteristics of the current read-out system}
75
76The following intrinsic characteristics of the current read-out system affect especially the signal
77reconstruction:
78
79\begin{description}
80\item[Inner and Outer pixels:\xspace] The MAGIC camera has two types of pixels which incorporate the following differences:
81\begin{enumerate}
82\item Size: The outer pixels have a factor four bigger area than the inner pixels~\cite{MAGIC-design}.
83Their (quantum-efficiency convoluted) effective area is about a factor 2.6 higher.
84\item Gain: The camera is flat-fielded in order to yield a similar reconstructed charge signal for the same photon illumination intensity.
85In order to achieve this, the gain of the inner pixels has been adjusted to about a factor 2.6 higher than the outer
86ones~\cite{tdas-calibration}. This results in lower effective noise charge from the night sky background for the outer pixels.
87\item Delay: The signal of the outer pixels is delayed by about 1.5\,ns with respect to the inner ones.
88\end{enumerate}
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.
90This clock noise results
91in a superimposed AB-pattern for the read-out pedestals. In the standard analysis, the amplitude of this clock noise gets measured in the
92pedestal extraction algorithms and further corrected for by all signal extractors.
93\item[Trigger Jitter:\xspace] The FADC clock is not synchronized with the trigger. Therefore, the relative position of the recorded
94signal samples varies uniformly by one FADC slice with respect to the position of the signal shape by one FADC slice from event to event.
95\item[DAQ jumps:\xspace] Unfortunately, the position of the signal pulse with respect to the first recorded FADC sample is not constant.
96It varies randomly by an integer number of FADC slices -- typically two -- in about 1\% of the channels per event.
97
98\end{description}
99
100%%% Local Variables:
101%%% mode: latex
102%%% TeX-master: "MAGIC_signal_reco"
103%%% TeX-master: "Introduction"
104%%% End:
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