1 | \section{Pedestal Extraction \label{sec:pedestals}}
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2 |
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3 | \subsection{Pedestal RMS}
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4 |
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5 | The background $BG$ (Pedestal)
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6 | can be completely described by the noise-autocorrelation matrix $\boldsymbol{B}$
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7 | (eq.~\ref{eq:autocorr}),
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8 | where the diagonal elements give what is usually denoted as the ``Pedestal RMS''.
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9 | \par
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10 |
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11 | By definition, the $\boldsymbol{B}$ and thus the ``pedestal RMS''
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12 | is independent from the signal extractor.
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13 |
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14 | \subsection{Bias and Mean-squared Error}
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15 |
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16 | Consider a large number of same signals $S$. By applying a signal extractor
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17 | we obtain a distribution of estimated signals $\widehat{S}$ (for fixed $S$ and
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18 | fixed background fluctuations $BG$). The distribution of the quantity
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19 |
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20 | \begin{equation}
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21 | X = \widehat{S}-S
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22 | \end{equation}
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23 |
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24 | has the mean $B$ and the Variance $MSE$ defined as:
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25 |
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26 | \begin{eqnarray}
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27 | B \ \ \ \ = \ \ \ \ \ \ <X> \ \ \ \ \ &=& \ \ <\widehat{S}> \ -\ S\\
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28 | R \ \ \ \ = \ <(X-B)^2> &=& \ Var[\widehat{S}]\\
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29 | MSE \ = \ \ \ \ \ <X^2> \ \ \ \ &=& \ Var[\widehat{S}] +\ B^2
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30 | \end{eqnarray}
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31 |
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32 | The parameter $B$ is also called the {\textit{\bf BIAS}} of the estimator and $MSE$
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33 | the {\textit{\bf MEAN-SQUARED ERROR}} which combines the variance of $\widehat{S}$ and
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34 | the bias. Both depend generally on the size of $S$ and the background fluctuations $BG$,
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35 | thus: $B = B(S,BG)$ and $MSE = MSE(S,BG)$.
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36 |
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37 | \par
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38 | Usually, one measures easily the parameter $R$, but needs the $MSE$ for statistical analysis (e.g.
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39 | in the image cleaning).
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40 | However, only in case of a vanishing bias $B$, the two numbers are equal. Otherwise,
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41 | the bias $B$ has to be known beforehand. Note that every sliding window extractor has a
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42 | bias, especially at low or vanishing signals $S$.
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43 |
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44 | \subsection{Pedestal Fluctuations as Contribution to the Signal Fluctuations \label{sec:ffactor}}
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45 |
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46 | A photo-multiplier signal yields, to a very good approximation, the
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47 | following relation:
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48 |
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49 | \begin{equation}
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50 | \frac{Var[Q]}{<Q>^2} = \frac{1}{<n_{phe}>} * F^2
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51 | \end{equation}
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52 |
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53 | Here, $Q$ is the signal fluctuation due to the number of signal photo-electrons
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54 | (equiv. to the signal $S$), and $Var[Q]$ the fluctuations of the true signal $Q$
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55 | due to the Poisson fluctuations of the number of photo-electrons. Because of:
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56 |
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57 | \begin{eqnarray}
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58 | \widehat{Q} &=& Q + X \\
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59 | Var(\widehat{Q}) &=& Var(Q) + Var(X) \\
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60 | Var(Q) &=& Var(\widehat{Q}) - Var(X)
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61 | \end{eqnarray}
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62 |
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63 | $Var[Q]$ can be obtained from:
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64 |
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65 | \begin{eqnarray}
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66 | Var(Q) &\approx& Var(\widehat{Q}) - Var(\widehat{Q}=0)
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67 | \label{eq:rmssubtraction}
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68 | \end{eqnarray}
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69 |
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70 | In the last line of eq.~\ref{eq:rmssubtraction}, it is assumed that $R$ does not dependent
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71 | on the signal height\footnote{%
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72 | A way to check whether the right RMS has been subtracted is to make the
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73 | ``Razmick''-plot
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74 |
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75 | \begin{equation}
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76 | \frac{Var[\widehat{Q}]}{<\widehat{Q}>^2} \quad \textit{vs.} \quad \frac{1}{<\widehat{Q}>}
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77 | \end{equation}
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78 |
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79 | This should give a straight line passing through the origin. The slope of
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80 | the line is equal to
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81 |
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82 | \begin{equation}
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83 | c * F^2
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84 | \end{equation}
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85 |
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86 | where $c$ is the photon/ADC conversion factor $<Q>/<m_{pe}>$.}
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87 | (as is the case
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88 | for the digital filter, eq.~\ref{eq:of_noise}). One can then retrieve $R$
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89 | by applying the signal extractor to a {\textit{\bf fixed window}} of pedestal events, where the
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90 | bias vanishes and measure $Var[\widehat{Q}=0]$.
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91 |
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92 | \subsection{Methods to Retrieve Bias and Mean-Squared Error}
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93 |
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94 | In general, the extracted signal variance $R$ is different from the pedestal RMS.
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95 | It cannot be obtained by applying the signal extractor to pedestal events, because of the
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96 | (unknown) bias.
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97 | \par
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98 | In the case of the digital filter, $R$ is expected to be independent from the
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99 | signal amplitude $S$ and depends only on the background $BG$ (eq.~\ref{eq:of_noise}).
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100 | It can then be obtained from the calculation of the variance $Var[\widehat{Q}]$
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101 | by applying the extractor to a fixed window of pure background events (``pedestal events'')
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102 | and get rid of the bias in that way.
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103 | \par
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104 |
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105 | In order to calculate bias and Mean-squared error, we proceeded in the following ways:
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106 | \begin{enumerate}
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107 | \item Determine $R$ by applying the signal extractor to a fixed window
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108 | of pedestal events. The background fluctuations can be simulated with different
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109 | levels of night sky background and the continuous light source, but no signal size
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110 | dependency can be retrieved with this method.
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111 | \item Determine $B$ and $MSE$ from MC events with and without added noise.
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112 | Assuming that $MSE$ and $B$ are negligible for the events without noise, one can
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113 | get a dependency of both values from the size of the signal.
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114 | \item Determine $MSE$ from the fitted error of $\widehat{S}$, which is possible for the
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115 | fit and the digital filter (eq.~\ref{eq:of_noise}).
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116 | In prinicple, all dependencies can be retrieved with this method.
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117 | \end{enumerate}
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118 |
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119 |
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120 | \begin{figure}[htp]
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121 | \centering
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122 | \includegraphics[width=0.3\linewidth]{MExtractTimeAndChargeSpline_Amplitude_Amplitude_Range_01_09_01_10_Run_38993_RelMean.eps}
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123 | \vspace{\floatsep}
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124 | \includegraphics[width=0.3\linewidth]{MExtractTimeAndChargeSpline_Amplitude_Amplitude_Range_01_09_01_10_Run_38995_RelMean.eps}
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125 | \vspace{\floatsep}
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126 | \includegraphics[width=0.3\linewidth]{MExtractTimeAndChargeSpline_Amplitude_Amplitude_Range_01_09_01_10_Run_38996_RelMean.eps}
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127 | \caption{MExtractTimeAndChargeSpline with amplitude extraction:
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128 | Difference in mean pedestal (per FADC slice) between extraction algorithm
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129 | applied on a fixed window of 1 FADC slice (``extractor random'') and a simple addition of
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130 | 2 FADC slices (``fundamental''). On the left, a run with closed camera has been taken, in the center
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131 | an opened camera observing an extra-galactic star field and on the right, an open camera being
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132 | illuminated by the continuous light of the calibration (level: 100). Every entry corresponds to one
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133 | pixel.}
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134 | \label{fig:amp:relmean}
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135 | \end{figure}
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136 |
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137 | \begin{figure}[htp]
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138 | \centering
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139 | \includegraphics[width=0.3\linewidth]{MExtractTimeAndChargeSpline_Rise-and-Fall-Time_0.5_1.5_Range_01_10_02_12_Run_38993_RelMean.eps}
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140 | \vspace{\floatsep}
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141 | \includegraphics[width=0.3\linewidth]{MExtractTimeAndChargeSpline_Rise-and-Fall-Time_0.5_1.5_Range_01_10_02_12_Run_38995_RelMean.eps}
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142 | \vspace{\floatsep}
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143 | \includegraphics[width=0.3\linewidth]{MExtractTimeAndChargeSpline_Rise-and-Fall-Time_0.5_1.5_Range_01_10_02_12_Run_38996_RelMean.eps}
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144 | \caption{MExtractTimeAndChargeSpline with integral over 2 slices:
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145 | Difference in mean pedestal (per FADC slice) between extraction algorithm
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146 | applied on a fixed window of 2 FADC slices (``extractor random'') and a simple addition of
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147 | 2 FADC slices (``fundamental''). On the left, a run with closed camera has been taken, in the center
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148 | an opened camera observing an extra-galactic star field and on the right, an open camera being
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149 | illuminated by the continuous light of the calibration (level: 100). Every entry corresponds to one
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150 | pixel.}
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151 | \label{fig:int:relmean}
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152 | \end{figure}
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153 |
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154 | \begin{figure}[htp]
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155 | \centering
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156 | \vspace{\floatsep}
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157 | \includegraphics[width=0.3\linewidth]{MExtractTimeAndChargeDigitalFilter_Weights_cosmics_weights.dat_Range_01_14_02_14_Run_38993_RelMean.eps}
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158 | \vspace{\floatsep}
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159 | \includegraphics[width=0.3\linewidth]{MExtractTimeAndChargeDigitalFilter_Weights_cosmics_weights.dat_Range_01_14_02_14_Run_38995_RelMean.eps}
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160 | \vspace{\floatsep}
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161 | \includegraphics[width=0.3\linewidth]{MExtractTimeAndChargeDigitalFilter_Weights_cosmics_weights.dat_Range_01_14_02_14_Run_38996_RelMean.eps}
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162 | \caption{MExtractTimeAndChargeDigitalFilter:
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163 | Difference in mean pedestal (per FADC slice) between extraction algorithm
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164 | applied on a fixed window of 6 FADC slices and time-randomized weights (``extractor random'')
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165 | and a simple addition of
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166 | 6 FADC slices (``fundamental''). On the left, a run with closed camera has been taken, in the center
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167 | an opened camera observing an extra-galactic star field and on the right, an open camera being
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168 | illuminated by the continuous light of the calibration (level: 100). Every entry corresponds to one
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169 | pixel.}
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170 | \label{fig:df:relmean}
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171 | \end{figure}
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172 |
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173 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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174 |
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175 | \subsubsection{ \label{sec:ped:fixedwindow} Application of the Signal Extractor to a Fixed Window
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176 | of Pedestal Events}
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177 |
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178 | By applying the signal extractor to a fixed window of pedestal events, we
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179 | determine the parameter $R$ for the case of no signal ($Q = 0$). In the case of
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180 | extractors using a fixed window (extractors nr. \#1 to \#22
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181 | in section~\ref{sec:algorithms}), the results are the same by construction
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182 | as calculating the pedestal RMS.
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183 | \par
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184 | In MARS, this functionality is implemented with a function-call to: \\
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185 |
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186 | {\textit{\bf MJPedestal::SetExtractionWithExtractorRndm()}} and/or \\
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187 | {\textit{\bf MExtractPedestal::SetRandomCalculation()}}\\
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188 |
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189 | Besides fixing the global extraction window, additionally the following steps are undertaken
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190 | in order to assure that the bias vanishes:
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191 |
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192 | \begin{description}
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193 | \item[\textit{MExtractTimeAndChargeSpline}:\xspace] The spline
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194 | maximum position -- which determines the exact extraction window -- is placed arbitrarily
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195 | at a random place within the digitizing binning resolution of one central FADC slice.
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196 | \item[\textit{MExtractTimeAndChargeDigitalFilter}:\xspace] The second step timing
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197 | offset $\tau$ (eq.~\ref{eq:offsettau}) gets randomized for each event.
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198 | \end{description}
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199 |
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200 | \par
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201 |
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202 | The following figures~\ref{fig:amp:relmean} through~\ref{fig:df:relrms} show results
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203 | obtained with the second method for three background intensities:
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204 |
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205 | \begin{enumerate}
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206 | \item Closed camera and no (Poissonian) fluctuation due to photons from the night sky background
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207 | \item The camera pointing to an extra-galactic region with stars in the field of view
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208 | \item The camera illuminated by a continuous light source of intensity 100.
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209 | \end{enumerate}
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210 |
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211 | Figures~\ref{fig:amp:relmean} through~\ref{fig:df:relmean}
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212 | show the calculated biases obtained with this method for all pixels in the camera
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213 | and for the different levels of (night-sky) background.
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214 | One can see that the bias vanishes to an accuracy of better than 1\%
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215 | for the extractors which are used in this TDAS.
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216 |
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217 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%1
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218 |
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219 | \begin{figure}[htp]
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220 | \centering
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221 | \includegraphics[width=0.47\linewidth]{MExtractTimeAndChargeSpline_Amplitude_Amplitude_Range_01_09_01_10_Run_38993_RMSDiff.eps}
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222 | \vspace{\floatsep}
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223 | \includegraphics[width=0.47\linewidth]{MExtractTimeAndChargeSpline_Amplitude_Amplitude_Range_01_09_01_10_Run_38995_RMSDiff.eps}
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224 | \vspace{\floatsep}
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225 | \includegraphics[width=0.47\linewidth]{MExtractTimeAndChargeSpline_Amplitude_Amplitude_Range_01_09_01_10_Run_38996_RMSDiff.eps}
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226 | \caption{MExtractTimeAndChargeSpline with amplitude:
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227 | Difference in RMS (per FADC slice) between extraction algorithm
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228 | applied on a fixed window and the corresponding pedestal RMS.
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229 | Closed camera (left), open camera observing extra-galactic star field (right) and
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230 | camera being illuminated by the continuous light (bottom).
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231 | Every entry corresponds to one pixel.}
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232 | \label{fig:amp:relrms}
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233 | \end{figure}
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234 |
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235 |
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236 | \begin{figure}[htp]
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237 | \centering
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238 | \includegraphics[width=0.47\linewidth]{MExtractTimeAndChargeSpline_Rise-and-Fall-Time_0.5_1.5_Range_01_10_02_12_Run_38993_RMSDiff.eps}
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239 | \vspace{\floatsep}
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240 | \includegraphics[width=0.47\linewidth]{MExtractTimeAndChargeSpline_Rise-and-Fall-Time_0.5_1.5_Range_01_10_02_12_Run_38995_RMSDiff.eps}
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241 | \vspace{\floatsep}
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242 | \includegraphics[width=0.47\linewidth]{MExtractTimeAndChargeSpline_Rise-and-Fall-Time_0.5_1.5_Range_01_10_02_12_Run_38996_RMSDiff.eps}
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243 | \caption{MExtractTimeAndChargeSpline with integral over 2 slices:
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244 | Difference in RMS (per FADC slice) between extraction algorithm
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245 | applied on a fixed window and the corresponding pedestal RMS.
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246 | Closed camera (left), open camera observing extra-galactic star field (right) and
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247 | camera being illuminated by the continuous light (bottom).
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248 | Every entry corresponds to one
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249 | pixel.}
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250 | \label{fig:amp:relrms}
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251 | \end{figure}
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252 |
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253 |
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254 | \begin{figure}[htp]
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255 | \centering
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256 | \includegraphics[width=0.47\linewidth]{MExtractTimeAndChargeDigitalFilter_Weights_cosmics_weights.dat_Range_01_14_02_14_Run_38993_RMSDiff.eps}
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257 | \vspace{\floatsep}
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258 | \includegraphics[width=0.47\linewidth]{MExtractTimeAndChargeDigitalFilter_Weights_cosmics_weights.dat_Range_01_14_02_14_Run_38995_RMSDiff.eps}
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259 | \vspace{\floatsep}
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260 | \includegraphics[width=0.47\linewidth]{MExtractTimeAndChargeDigitalFilter_Weights_cosmics_weights.dat_Range_01_14_02_14_Run_38996_RMSDiff.eps}
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261 | \caption{MExtractTimeAndChargeDigitalFilter:
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262 | Difference in RMS (per FADC slice) between extraction algorithm
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263 | applied on a fixed window and the corresponding pedestal RMS.
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264 | Closed camera (left), open camera observing extra-galactic star field (right) and
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265 | camera being illuminated by the continuous light (bottom).
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266 | Every entry corresponds to one pixel.}
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267 | \label{fig:df:relrms}
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268 | \end{figure}
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269 |
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270 |
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271 |
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272 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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273 |
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274 | Figures~\ref{fig:amp:relrms} through~\ref{fig:amp:relrms} show the
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275 | differences in $R$ between the calculated pedestal RMS and
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276 | the one obtained by applying the extractor, converted to equivalent photo-electrons. One entry
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277 | corresponds to one pixel of the camera.
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278 | The distributions have a negative mean in the case of the digital filter showing the
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279 | ``filter'' capacity of that algorithm. It ``filters out'' between 0.12 photo-electrons night sky
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280 | background for the extra-galactic star-field until 0.2 photo-electrons for the continuous light.
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281 |
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282 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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283 |
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284 |
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285 | \subsubsection{ \label{sec:ped:slidingwindow} Application of the Signal Extractor to a Sliding Window
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286 | of Pedestal Events}
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287 |
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288 | By applying the signal extractor to a global extraction window of pedestal events, allowing
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289 | it to ``slide'' and maximize the encountered signal, we
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290 | determine the bias $B$ and the mean-squared error $MSE$ for the case of no signal ($S=0$).
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291 | \par
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292 | In MARS, this functionality is implemented with a function-call to: \\
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293 |
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294 | {\textit{\bf MJPedestal::SetExtractionWithExtractor()}} \\
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295 |
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296 | \par
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297 | Table~\ref{tab:bias} shows bias, resolution and mean-square error for all extractors using
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298 | a sliding window. In this sample, every extractor had the freedom to move 5 slices,
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299 | i.e. the global window size was fixed to five plus the extractor window size. This first line
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300 | shows the resolution of the smallest existing robust fixed window algorithm in order to give the reference
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301 | value of 2.5 and 3 photo-electrons RMS.
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302 | \par
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303 | One can see that the bias $B$ typically decreases
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304 | with increasing window size (except for the digital filter), while the error $R$ increases with
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305 | increasing window size. There is also a small difference between the obtained error on a fixed window
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306 | extraction and the one obtained from a sliding window extraction in the case of the spline and digital
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307 | filter algorithms.
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308 | The mean-squared error has an optimum somewhere between: In the case of the
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309 | sliding window and the spline at the lowest window size, in the case of the digital filter
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310 | at 4 slices. The global winners are extractors \#25 (spline with integration of 1 slice) and \#29
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311 | (digital filter with integration of 4 slices). All sliding window extractors -- except \#21 --
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312 | have a smaller mean-square error than the resolution of the fixed window reference extractor. This means
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313 | that the global error of the sliding window extractors is smaller than the one of the fixed window extractors
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314 | even if the first have a bias.
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315 |
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316 | \begin{table}[htp]
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317 | \centering
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318 | \scriptsize{
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319 | \begin{tabular}{|c|c|c|c|c|c|c|c|c|c|c|c|c|c|}
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320 | \hline
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321 | \hline
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322 | \multicolumn{14}{|c|}{Statistical Parameters for $S=0$} \\
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323 | \hline
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324 | \hline
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325 | & & \multicolumn{4}{|c|}{Closed camera} & \multicolumn{4}{|c|}{Extra-galactic NSB} & \multicolumn{4}{|c|}{Galactic NSB} \\
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326 | \hline
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327 | \hline
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328 | Nr. & Name & $R$ & $R$ & $B$ & $\sqrt{MSE}$ & $R$ &$R$ & $B$ & $\sqrt{MSE}$& $R$ & $R$& $B$ & $\sqrt{MSE}$ \\
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329 | & & (FW) & (SW)& (SW)& (SW) & (FW) &(SW) & (SW)& (SW) & (FW)&(SW) & (SW)&(SW) \\
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330 | \hline
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331 | \hline
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332 | 4 & Fixed Win. 8 & 1.2 & -- & 0.0 & 1.2 & 2.5 & -- & 0.0 & 2.5 & 3.0 & -- & 0.0 & 3.0 \\
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333 | \hline
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334 | -- & Slid. Win. 1 & 0.4 & 0.4 & 0.4 & 0.6 & 1.2 & 1.2 & 1.3 & 1.8 & 1.4 & 1.4 & 1.5 & 2.0 \\
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335 | 17 & Slid. Win. 2 & 0.5 & 0.5 & 0.4 & 0.6 & 1.4 & 1.4 & 1.2 & 1.8 & 1.6 & 1.6 & 1.5 & 2.2 \\
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336 | 18 & Slid. Win. 4 & 0.8 & 0.8 & 0.5 & 0.9 & 1.9 & 1.9 & 1.2 & 2.2 & 2.2 & 2.3 & 1.6 & 2.8 \\
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337 | 20 & Slid. Win. 6 & 1.0 & 1.0 & 0.4 & 1.1 & 2.2 & 2.2 & 1.1 & 2.5 & 2.6 & 2.7 & 1.4 & 3.0 \\
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338 | 21 & Slid. Win. 8 & 1.2 & 1.3 & 0.4 & 1.4 & 2.5 & 2.5 & 1.0 & 2.7 & 3.0 & 3.2 & 1.4 & 3.5 \\
|
---|
339 | \hline
|
---|
340 | 23 & Spline Amp. & 0.4 & \textcolor{red}{\bf 0.4} & 0.4 & 0.6 & 1.1 & 1.2 & 1.3 & 1.8 & 1.3 & 1.4 & 1.6 & 2.1 \\
|
---|
341 | 24 & \textcolor{red}{\bf Spline Int. 1} & 0.4 & \textcolor{red}{\bf 0.4} & 0.3 & \textcolor{red}{\bf 0.5} & 1.0 & 1.2 & 1.0 & 1.6 & 1.3 & \textcolor{red}{\bf 1.3} & 1.3 & \textcolor{red}{\bf 1.8} \\
|
---|
342 | 25 & Spline Int. 2 & 0.5 & 0.5 & 0.3 & 0.6 & 1.3 & 1.4 & 0.9 & 1.7 & 1.7 & 1.6 & 1.2 & 2.0 \\
|
---|
343 | 26 & Spline Int. 4 & 0.7 & 0.7 & \textcolor{red}{\bf 0.2 } & 0.7 & 1.5 & 1.7 & \textcolor{red}{\bf 0.8} & 1.9 & 2.0 & 2.0 & 1.0 & 2.2 \\
|
---|
344 | 27 & Spline Int. 6 & 1.0 & 1.0 & 0.3 & 1.0 & 2.0 & 2.0 & \textcolor{red}{\bf 0.8} & 2.2 & 2.6 & 2.5 & \textcolor{red}{\bf 0.9} & 2.7 \\
|
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345 | \hline
|
---|
346 | 28 & Dig. Filt. 6 & 0.4 & 0.5 & 0.4 & 0.6 & 1.1 & 1.3 & 1.3 & 1.8 & 1.3 & 1.5 & 1.5 & 2.1 \\
|
---|
347 | 29 & \textcolor{red}{\bf Dig. Filt. 4} & 0.3 & \textcolor{red}{\bf 0.4} & 0.3 & \textcolor{red}{\bf 0.5} & 0.9 & \textcolor{red}{\bf 1.1} & 1.0 & \textcolor{red}{\bf 1.5} & 1.1 & 1.4 & 1.2 & \textcolor{red}{\bf 1.8} \\
|
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348 | \hline
|
---|
349 | \hline
|
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350 | \end{tabular}
|
---|
351 | }
|
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352 | \caption{The statistical parameters bias, resolution and mean error for the sliding window
|
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353 | algorithm. The first line displays the resolution of the smallest existing robust fixed--window extractor
|
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354 | for reference. All units in equiv.
|
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355 | photo-electrons, uncertainty: 0.1 phes. All extractors were allowed to move 5 FADC slices plus
|
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356 | their window size. The ``winners'' for each row are marked in red. Global winners (within the given
|
---|
357 | uncertainty) are the extractors Nr. \#24 (MExtractTimeAndChargeSpline with an integration window of
|
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358 | 1 FADC slice) and Nr.\#29
|
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359 | (MExtractTimeAndChargeDigitalFilter with an integration window size of 4 slices)}
|
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360 | \label{tab:bias}
|
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361 | \end{table}
|
---|
362 |
|
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363 | Figures~\ref{fig:sw:distped} through~\ref{fig:df:distped} show the
|
---|
364 | extracted pedestal distributions for some selected extractors (\#18, \#23, \#25 and \#28)
|
---|
365 | for one examplary channel (pixel 100) and two background situations: Closed camera with only electronic
|
---|
366 | noise and open camera pointing to an extra-galactic source.
|
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367 | One can see the (asymmetric) Poisson behaviour of the
|
---|
368 | night sky background photons for the distributions with open camera.
|
---|
369 |
|
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370 | \begin{figure}[htp]
|
---|
371 | \centering
|
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372 | \includegraphics[height=0.43\textheight]{PedestalSpectrum-18-Run38993.eps}
|
---|
373 | \vspace{\floatsep}
|
---|
374 | \includegraphics[height=0.43\textheight]{PedestalSpectrum-18-Run38995.eps}
|
---|
375 | \caption{MExtractTimeAndChargeSlidingWindow with extraction window of 4 FADC slices:
|
---|
376 | Distribution of extracted "pedestals" from pedestal run with
|
---|
377 | closed camera (top) and open camera observing an extra-galactic star field (bottom) for one channel
|
---|
378 | (pixel 100). The result obtained from a simple addition of 4 FADC
|
---|
379 | slice contents (``fundamental'') is displayed as red histogram, the one obtained from the application of
|
---|
380 | the algorithm on
|
---|
381 | a fixed window of 4 FADC slices as blue histogram (``extractor random'') and the one obtained from the
|
---|
382 | full algorithm allowed to slide within a global window of 12 slices. The obtained histogram means and
|
---|
383 | RMSs have been converted to equiv. photo-electrons.}
|
---|
384 | \label{fig:sw:distped}
|
---|
385 | \end{figure}
|
---|
386 |
|
---|
387 |
|
---|
388 | \begin{figure}[htp]
|
---|
389 | \centering
|
---|
390 | \includegraphics[height=0.43\textheight]{PedestalSpectrum-23-Run38993.eps}
|
---|
391 | \vspace{\floatsep}
|
---|
392 | \includegraphics[height=0.43\textheight]{PedestalSpectrum-23-Run38995.eps}
|
---|
393 | \caption{MExtractTimeAndChargeSpline with amplitude extraction:
|
---|
394 | Spectrum of extracted "pedestals" from pedestal run with
|
---|
395 | closed camera lids (top) and open lids observing an extra-galactic star field (bottom) for one channel
|
---|
396 | (pixel 100). The result obtained from a simple addition of 2 FADC
|
---|
397 | slice contents (``fundamental'') is displayed as red histogram, the one obtained from the application
|
---|
398 | of the algorithm on a fixed window of 1 FADC slice as blue histogram (``extractor random'')
|
---|
399 | and the one obtained from the
|
---|
400 | full algorithm allowed to slide within a global window of 12 slices. The obtained histogram means and
|
---|
401 | RMSs have been converted to equiv. photo-electrons.}
|
---|
402 | \label{fig:amp:distped}
|
---|
403 | \end{figure}
|
---|
404 |
|
---|
405 | \begin{figure}[htp]
|
---|
406 | \centering
|
---|
407 | \includegraphics[height=0.43\textheight]{PedestalSpectrum-25-Run38993.eps}
|
---|
408 | \vspace{\floatsep}
|
---|
409 | \includegraphics[height=0.43\textheight]{PedestalSpectrum-25-Run38995.eps}
|
---|
410 | \caption{MExtractTimeAndChargeSpline with integral extraction over 2 FADC slices:
|
---|
411 | Distribution of extracted "pedestals" from pedestal run with
|
---|
412 | closed camera lids (top) and open lids observing an extra-galactic star field (bottom) for one channel
|
---|
413 | (pixel 100). The result obtained from a simple addition of 2 FADC
|
---|
414 | slice contents (``fundamental'') is displayed as red histogram, the one obtained from the application
|
---|
415 | of time-randomized weigths on a fixed window of 2 FADC slices as blue histogram and the one obtained from the
|
---|
416 | full algorithm allowed to slide within a global window of 12 slices. The obtained histogram means and
|
---|
417 | RMSs have been converted to equiv. photo-electrons.}
|
---|
418 | \label{fig:int:distped}
|
---|
419 | \end{figure}
|
---|
420 |
|
---|
421 | \begin{figure}[htp]
|
---|
422 | \centering
|
---|
423 | \includegraphics[height=0.43\textheight]{PedestalSpectrum-28-Run38993.eps}
|
---|
424 | \vspace{\floatsep}
|
---|
425 | \includegraphics[height=0.43\textheight]{PedestalSpectrum-28-Run38995.eps}
|
---|
426 | \caption{MExtractTimeAndChargeDigitalFilter: Spectrum of extracted "pedestals" from pedestal run with
|
---|
427 | closed camera lids (top) and open lids observing an extra-galactic star field (bottom) for one channel
|
---|
428 | (pixel 100). The result obtained from a simple addition of 6 FADC
|
---|
429 | slice contents (``fundamental'') is displayed as red histogram, the one obtained from the application
|
---|
430 | of time-randomized weigths on a fixed window of 6 slices as blue histogram and the one obtained from the
|
---|
431 | full algorithm allowed to slide within a global window of 12 slices. The obtained histogram means and
|
---|
432 | RMSs have been converted to equiv. photo-electrons.}
|
---|
433 | \label{fig:df:distped}
|
---|
434 | \end{figure}
|
---|
435 |
|
---|
436 | \subsection{ \label{sec:ped:singlephe} Single Photo-Electron Extraction with the Digital Filter}
|
---|
437 |
|
---|
438 | Figures~\ref{fig:df:sphespectrum} show spectra
|
---|
439 | obtained with the digital filter applied on two different global search windows.
|
---|
440 | One can clearly distinguish a pedestal peak (fitted to Gaussian with index 0)
|
---|
441 | and further, positive contributions.
|
---|
442 | \par
|
---|
443 | Because the background is determined by the single photo-electrons from the night-sky background,
|
---|
444 | the following possibilities can occur:
|
---|
445 |
|
---|
446 | \begin{enumerate}
|
---|
447 | \item There is no ``signal'' (photo-electron) in the extraction window and the extractor
|
---|
448 | finds only electronic noise.
|
---|
449 | Usually, the returned signal charge is then negative.
|
---|
450 | \item There is one photo-electron in the extraction window and the extractor finds it.
|
---|
451 | \item There are more than on photo-electrons in the extraction window, but separated by more than
|
---|
452 | two FADC slices whereupon the extractor finds the one with the highest charge (upward fluctuation).
|
---|
453 | \item The extractor finds an overlap of two or more photo-electrons.
|
---|
454 | \end{enumerate}
|
---|
455 |
|
---|
456 | Although the probability to find a certain number of photo-electrons in a fixed window follows a
|
---|
457 | Poisson distribution, the one for employing the sliding window is {\textit{not}} Poissonian. The extractor
|
---|
458 | will usually find one photo-electron even if more are present in the global search window, i.e. the
|
---|
459 | probability for two or more photo-electrons to occur in the global search window is much higher than
|
---|
460 | the probability for these photo-electrons to overlap in time such as to be recognized as a double
|
---|
461 | or triple photo-electron pulse by the extractor. This is especially true for small extraction windows
|
---|
462 | and for the digital filter.
|
---|
463 |
|
---|
464 | \par
|
---|
465 |
|
---|
466 | Given a global extraction window of size $WS$ and an average rate of photo-electrons from the night-sky
|
---|
467 | background $R$, we will now calculate the probability for the extractor to find zero photo-electrons in the
|
---|
468 | $WS$. The probability to find any number of $k$ photo-electrons can be written as:
|
---|
469 |
|
---|
470 | \begin{equation}
|
---|
471 | P(k) = \frac{e^{-R\cdot WS} (R \cdot WS)^k}{k!}
|
---|
472 | \end{equation}
|
---|
473 |
|
---|
474 | and thus:
|
---|
475 |
|
---|
476 | \begin{equation}
|
---|
477 | P(0) = e^{-R\cdot WS}
|
---|
478 | \end{equation}
|
---|
479 |
|
---|
480 | The probability to find one or more photo-electrons is then:
|
---|
481 |
|
---|
482 | \begin{equation}
|
---|
483 | P(>0) = 1 - e^{-R\cdot WS}
|
---|
484 | \end{equation}
|
---|
485 |
|
---|
486 | In figures~\ref{fig:df:sphespectrum},
|
---|
487 | one can clearly distinguish the pedestal peak (fitted to Gaussian with index 0),
|
---|
488 | corresponding to the case of $P(0)$ and further
|
---|
489 | contributions of $P(1)$ and $P(2)$ (fitted to Gaussians with index 1 and 2).
|
---|
490 | One can also see that the contribution of $P(0)$ dimishes
|
---|
491 | with increasing global search window size.
|
---|
492 |
|
---|
493 | \begin{figure}
|
---|
494 | \centering
|
---|
495 | \includegraphics[height=0.3\textheight]{SinglePheSpectrum-28-Run38995-WS2.5.eps}
|
---|
496 | \vspace{\floatsep}
|
---|
497 | \includegraphics[height=0.3\textheight]{SinglePheSpectrum-28-Run38995-WS4.5.eps}
|
---|
498 | \vspace{\floatsep}
|
---|
499 | \includegraphics[height=0.3\textheight]{SinglePheSpectrum-28-Run38995-WS8.5.eps}
|
---|
500 | \caption{MExtractTimeAndChargeDigitalFilter: Spectrum obtained from the extraction
|
---|
501 | of a pedestal run using a sliding window of 6 FADC slices allowed to move within a window of
|
---|
502 | 7 (top), 9 (center) and 13 slices.
|
---|
503 | A pedestal run with galactic star background has been taken and one exemplary pixel (Nr. 100).
|
---|
504 | One can clearly see the pedestal contribution and a further part corresponding to one or more
|
---|
505 | photo-electrons.}
|
---|
506 | \label{fig:df:sphespectrum}
|
---|
507 | \end{figure}
|
---|
508 |
|
---|
509 | In the following, we will make a short consistency test: Assuming that the spectral peaks are
|
---|
510 | attributed correctly, one would expect the following relation:
|
---|
511 |
|
---|
512 | \begin{equation}
|
---|
513 | P(0) / P(>0) = \frac{e^{-R\cdot WS}}{1-e^{-R\cdot WS}}
|
---|
514 | \end{equation}
|
---|
515 |
|
---|
516 | We tested this relation assuming that the fitted area underneath the pedestal peak $Area_0$ is
|
---|
517 | proportional to $P(0)$ and the sum of the fitted areas underneath the single photo-electron peak
|
---|
518 | $Area_1$ and the double photo-electron peak $Area_2$ proportional to $P(>0)$. Thus, one expects:
|
---|
519 |
|
---|
520 | \begin{equation}
|
---|
521 | Area_0 / (Area_1 + Area+2 ) = \frac{e^{-R\cdot WS}}{1-e^{-R\cdot WS}}
|
---|
522 | \end{equation}
|
---|
523 |
|
---|
524 | We estimated the effective window size $WS$ as the sum of the range in which the digital filter
|
---|
525 | amplitude weights are greater than 0.5 (1.5 FADC slices) and the global search window minus the
|
---|
526 | size of the window size of the weights (which is 6 FADC slices). Figures~\ref{fig:df:ratiofit}
|
---|
527 | show the result for two different levels of night-sky background. The fitted rates deliver
|
---|
528 | 0.08 and 0.1 phes/ns, respectively. These rates are about 50\% too low compared to the results obtained
|
---|
529 | in the November 2004 test campaign. However, we should take into account that the method is at
|
---|
530 | the limit of distinguishing single photo-electrons. It may occur often that a single photo-electron
|
---|
531 | signal is too low in order to get recognized as such. We tried various pixels and found that
|
---|
532 | some of them do not permit to apply this method at all. The ones which succeed, however, yield about
|
---|
533 | the same fitted rates. To conclude, one may say that there is consistency within the double-peak
|
---|
534 | structure of the pedestal spectrum found by the digital filter which can be explained by the fact that
|
---|
535 | single photo-electrons are found.
|
---|
536 | \par
|
---|
537 |
|
---|
538 | \begin{figure}[htp]
|
---|
539 | \centering
|
---|
540 | \includegraphics[height=0.4\textheight]{SinglePheRatio-28-Run38995.eps}
|
---|
541 | \vspace{\floatsep}
|
---|
542 | \includegraphics[height=0.4\textheight]{SinglePheRatio-28-Run39258.eps}
|
---|
543 | \caption{MExtractTimeAndChargeDigitalFilter: Fit to the ratio of the area beneath the pedestal peak and
|
---|
544 | the single and double photo-electron(s) peak(s) with the extraction algorithm
|
---|
545 | applied on a sliding window of different sizes.
|
---|
546 | In the top plot, a pedestal run with extra-galactic star background has been taken and in the bottom,
|
---|
547 | a galatic star background. An exemplary pixel (Nr. 100) has been used.
|
---|
548 | Above, a rate of 0.08 phe/ns and below, a rate of 0.1 phe/ns has been obtained.}
|
---|
549 | \label{fig:df:ratiofit}
|
---|
550 | \end{figure}
|
---|
551 |
|
---|
552 | Figure~\ref{fig:df:convfit} shows the obtained ``conversion factors'' and ``F-Factor'' computed as:
|
---|
553 |
|
---|
554 | \begin{eqnarray}
|
---|
555 | c_{phe} &=& \frac{1}{\mu_1 - \mu_0} \\
|
---|
556 | F_{phe} &=& \sqrt{1 + \frac{\sigma_1^2 - \sigma_0^2}{(\mu_1 - \mu_0)^2} }
|
---|
557 | \end{eqnarray}
|
---|
558 |
|
---|
559 | where $\mu_0$ is the mean position of the pedestal peak and $\mu_1$ the mean position of the (assumed)
|
---|
560 | single photo-electron peak. The obtained conversion factors are systematically lower than the ones
|
---|
561 | obtained from the standard calibration and decrease with increasing window size. This is consistent
|
---|
562 | with the assumption that the digital filter finds the upward fluctuating pulse out of several. Therefore,
|
---|
563 | $\mu_1$ is biased against higher values. The F-Factor is also systematically low, which is also consistent
|
---|
564 | with the assumption that the spacing between $\mu_1$ and $\mu_0$ is artificially high. One can also see
|
---|
565 | that the error bars are too high for a ``calibration'' of the F-Factor.
|
---|
566 | \par
|
---|
567 | In conclusion, one can say that the digital filter is at the edge of being able to see single photo-electrons,
|
---|
568 | however a single photo-electron calibration cannot yet be done with the current FADC system because the
|
---|
569 | resolution is too poor.
|
---|
570 |
|
---|
571 | \begin{figure}[htp]
|
---|
572 | \centering
|
---|
573 | \includegraphics[height=0.4\textheight]{ConvFactor-28-Run38995.eps}
|
---|
574 | \vspace{\floatsep}
|
---|
575 | \includegraphics[height=0.4\textheight]{FFactor-28-Run38995.eps}
|
---|
576 | \caption{MExtractTimeAndChargeDigitalFilter: Obtained conversion factors (top) and F-Factors (bottom)
|
---|
577 | from the position and width of
|
---|
578 | the fitted Gaussian mean of the single photo-electron peak and the pedestal peak depending on
|
---|
579 | the applied global extraction window sizes.
|
---|
580 | A pedestal run with extra-galactic star background has been taken and
|
---|
581 | an exemplary pixel (Nr. 100) used. The conversion factor obtained from the
|
---|
582 | standard calibration is shown as a reference line. The obtained conversion factors are systematically
|
---|
583 | lower than the reference one.}
|
---|
584 | \label{fig:df:convfit}
|
---|
585 | \end{figure}
|
---|
586 |
|
---|
587 |
|
---|
588 |
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589 | %%% Local Variables:
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590 | %%% mode: latex
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591 | %%% TeX-master: "MAGIC_signal_reco"
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592 | %%% TeX-master: "MAGIC_signal_reco"
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593 | %%% TeX-master: "MAGIC_signal_reco"
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594 | %%% End:
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