- Timestamp:
- 02/17/05 19:22:24 (20 years ago)
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trunk/MagicSoft/TDAS-Extractor/MonteCarlo.tex
r6574 r6575 1 1 \section{Monte Carlo \label{sec:mc}} 2 2 3 \subsection{Charge Signals \label{sec:mc:charge}} 4 5 Comparing MC signal with and w/o noise for high and low gain pulses. 3 \subsection{Charge Signals with Simulated Noise \label{sec:mc:charge}} 6 4 7 5 \begin{figure}[htp]%%[t!] … … 108 106 \vspace{\floatsep} 109 107 \includegraphics[width=0.49\linewidth]{TDAS_ChargeRes_FixW_WithNoise_LoGain.eps} 110 \caption[ Resolution Fixed Windows]{The measured resolution (RMS of extracted charge divided by the conversion factor minus the number of photoelectrons) versus number of photoelectrons,108 \caption[Charge Resolution Fixed Windows]{The measured resolution (RMS of extracted charge divided by the conversion factor minus the number of photoelectrons) versus number of photoelectrons, 111 109 for fixed window extractors in different window sizes. The top plots show the high-gain and the bottom ones show the 112 110 low-gain regions. Left: without noise, right: with simulated noise.} … … 123 121 \vspace{\floatsep} 124 122 \includegraphics[width=0.49\linewidth]{TDAS_ChargeRes_SlidW_WithNoise_LoGain.eps} 125 \caption[ Resolution Sliding Windows]{The measured resolution (RMS of extracted charge divided by the conversion factor minus the number of photoelectrons) versus number of photoelectrons,123 \caption[Charge Resolution Sliding Windows]{The measured resolution (RMS of extracted charge divided by the conversion factor minus the number of photoelectrons) versus number of photoelectrons, 126 124 for sliding window extractors in different window sizes. The top plots show the high-gain and the bottom ones show the 127 125 low-gain regions. Left: without noise, right: with simulated noise.} … … 138 136 \vspace{\floatsep} 139 137 \includegraphics[width=0.49\linewidth]{TDAS_ChargeRes_DFSpline_WithNoise_LoGain.eps} 140 \caption[ Resolution Spline and Digital Filter]{The measured resolution138 \caption[Charge Resolution Spline and Digital Filter]{The measured resolution 141 139 (RMS of extracted charge divided by the conversion factor minus the number of photoelectrons) versus number of photoelectrons, 142 140 for spline and digital filter extractors in different window sizes. The top plots show the high-gain and the bottom ones show the … … 145 143 \end{figure} 146 144 145 \subsection{Charge Signals with and without Simulated Noise \label{sec:mc:chargenoise}} 146 147 147 \begin{figure}[htp] 148 148 \centering … … 152 152 \vspace{\floatsep} 153 153 \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_Bias_DFSpline_HiGain.eps} 154 \caption { Charge bias: comparation bwtween MC files with and without noise, for155 different extractor methods in highgain region.}154 \caption[Bias due to noise high-gain]{Bias due to noise: Difference of extracted charge of same events, with and without simulated noise, 155 for different extractor methods in the high-gain region.} 156 156 \label{Bias_HiGain} 157 157 \end{figure} … … 163 163 \includegraphics[width=0.49\linewidth]{TimeAndChargePlots/TDAS_Bias_FixW_LoGain.eps} 164 164 \vspace{\floatsep} 165 \includegraphics[width=0.49Q\linewidth]{TimeAndChargePlots/TDAS_Bias_DFSpline_LoGain.eps} 166 \caption { Charge bias: comparation bwtween MC files with and without noise, for167 different extractor methods in lowgain region.}165 \includegraphics[width=0.49Q\linewidth]{TimeAndChargePlots/TDAS_Bias_DFSpline_LoGain.eps} 166 \caption[Bias due to noise low-gain]{Bias due to noise: Difference of extracted charge of same events, with and without simulated noise, 167 for different extractor methods in the low-gain region.} 168 168 \label{Bias_LoGain} 169 169 \end{figure} 170 170 171 \subsection{Arrival Times \label{sec:mc:times}} 172 171 173 \begin{figure}[htp]%%[t!] 172 174 \centering … … 178 180 \vspace{\floatsep} 179 181 \includegraphics[width=0.49\linewidth]{TDAS_TimeRes_SlidW_WithNoise_LoGain.eps} 180 \caption{Time Resolution for Sliding extractors in deifferent window sizes for low (down) and high (upper) 181 gain contribution, with (right) and with out (left) noise.} 182 \caption[Time Resolution Sliding Windows]{The measured time resolution (RMS of extracted time minus simulated time) 183 versus number of photoelectrons, 184 for sliding window extractors in different window sizes. The top plots show the high-gain and the bottom ones show the 185 low-gain regions. Left: without noise, right: with simulated noise.} 182 186 \label{TimeRes_SlidW} 183 187 \end{figure} … … 192 196 \vspace{\floatsep} 193 197 \includegraphics[width=0.49\linewidth]{TDAS_TimeRes_DFSpline_WithNoise_LoGain.eps} 194 \caption{Time Resolution for Splines and Digital Filter extractors for low (down) and high (upper) 195 gain contribution, with (right) and with out (left) noise.} 198 \caption[Time Resolution Spline and Digital Filter]{The measured time resolution (RMS of extracted time minus simulated time) 199 versus number of photoelectrons, 200 for spline and digital filter window extractors in different window sizes. The top plots show the high-gain and the bottom ones show the 201 low-gain regions. Left: without noise, right: with simulated noise.} 196 202 \label{TimeRes_DFSpline} 197 203 \end{figure}
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