1 | \section{The Burst Alarm System at La Palma}
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2 |
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3 | {\bf Current status:}
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4 |
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5 | \par
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6 |
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7 | The Burst Alarm System {\it gspot} (Gamma
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8 | Sources Pointing Trigger) is working in La Palma since last summer.
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9 | It performs a full-time survey of the {\it GRB Coordinates Network} (\g) alerts~\cite{GCN}.
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10 | Different satellite experiments
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11 | send GRB coordinates to the \g which distributes
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12 | the alerts to registered users.
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13 | The Burst Alarm System is composed of a core program which
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14 | manages the monitoring of the \g and the communication with the Central Control (CC).
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15 | It also handles three communication channels to notice the shifters
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16 | about an alert. It is a C based daemon running 24
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17 | hours a day on the {\it www} machine, our external server, in a
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18 | {\it stand alone} mode. It does not need to be operated and is
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19 | fully automatic. It manages network disconnections
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20 | within the external net and/or the internal one.
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21 |
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22 |
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23 | \subsection{The Connection to the GCN}
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24 |
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25 | The connection to the \g is performed by {\it gspot} through a
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26 | TCP/IP connection to a computer at the Goddard Space Flight Center (GSFC).
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27 | This computer distributes the alerts from the satellite
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28 | experiments through an internet socket connection. {\it gspot}
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29 | acts as a server while the client, running at the GSFC,
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30 | manages the communication of the data concerning the GRBs
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31 | and concerning the status of the connection. \\
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32 |
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33 | The format of the data distributed through the \g differ between the individual satellites
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34 | and the kind of package. Currently, three satellites participate in the GRB survey:
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35 | HETE-2~\cite{HETE}, INTEGRAL~\cite{INTEGRAL} and SWIFT~\cite{SWIFT}.
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36 | The alerts include the UTC, the GRB coordinates (not always), error on coordinates
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37 | (not always) and intensity (photon counts) of the burst.
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38 | The first notices from HETE-2 and INTEGRAL usually do not include the coordinates.
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39 | In few cases only coordinates are distributed in refined notices.
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40 | The \sw alerts are predicted to arrive with coordinates between 30-80 sec after the onset of the burst.
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41 | The error on the coordinates from the BAT detector will be 4 arcmin which is smaller than the size of one
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42 | inner pixel of the \ma camera.\\
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43 |
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44 | In case of an alert {\it gspot} stores the informations and enters
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45 | an {\bf Alarm State}. The duration of the alarm depends on the following parameters:
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46 |
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47 | \begin{itemize}
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48 | \item {\bf Darkness of the sky}: The Sun has to be below
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49 | to the astronomical horizon at 108$^\circ$ zenith.
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50 | \item {\bf Position of GRB}: The GRB equatorial
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51 | coordinates are transformed into local horizontal coordinates.
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52 | The resulting GRB zenith angle has to be smaller than 70$^\circ$. In case that the moon is
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53 | shining, the zenith angle limit is reduced to 65$^\circ$.
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54 | \item {\bf Position of moon}: The angular
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55 | distance from the GRB to the moon has to be at least 30$^\circ$.
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56 | \end{itemize}
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57 |
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58 | If one or more of these conditions fail, {\it gspot} enters into a
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59 | {\color[rgb]{0.9,0.75,0.}\bf Yellow Alarm State}: The GRB is not observable at the moment.
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60 | Currently, the program does not calculate if and when the GRB will become observable for \ma.
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61 | If all the mentioned conditions are satisfied,
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62 | {\it gspot} enters into a \textcolor{red}{\bf Red Alarm State}, it means that the GRB is considered to be observable now.\\
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63 |
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64 | In both cases (in \textcolor{red}{\bf RED} and {\color[rgb]{0.9,0.75,0.}\bf YELLOW} Alarm State), {\it gspot} establishes the communication with the CC and sends the GRB equatorial coordinates (RA/DEC J2000).
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65 | For the communication with CC the format defined in~\cite{CONTROL} is used. At the same time,
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66 | the shifters and the GRB-MAGIC group is contacted.
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67 |
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68 | \subsection{The Interface to the Central Control}
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69 |
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70 | An interface of {\it gspot} sends all the relevant information to the CC.
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71 | In the case that {\it gspot} is not in alarm state,
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72 | the standard packages are continuously exchanged between CC and {\it gspot}, containing the main global status
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73 | of the two subsystems.
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74 | In the alert case, {\it gspot} starts to send special alert packages to the CC,
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75 | containing information about the GRB and the ''color'' of the alert.
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76 | The exchange of the alert packages continues until:
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77 |
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78 | \begin{itemize}
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79 | \item {\it gspot} receives from the CC the confirmation
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80 | that the alert notice has been received; The CC must send back the alert in order
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81 | to perform a cross-check of the relevant data.
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82 | \item the alarm state expires after {\bf 5 hours}
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83 | \end{itemize}
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84 |
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85 | The CC informs the shift crew about the alert and undertakes
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86 | further steps only in case of a \textcolor{red}{\bf red alerts}.
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87 | In this case, a pop-up window
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88 | appears with all the alert information received by the burst monitor.
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89 | The operator has to confirm the notice by closing the pop-up window.
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90 | He can decide to stop the current scheduled observation and to point the GRB.
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91 | A new button will be displayed in the CC and allows to point the telescope to
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92 | the GRB coordinates.
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93 |
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94 | \subsection{GRB Archive and Emails to the GRB-mailing List}
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95 |
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96 | In case of an alert -- even if it did not contain the necessary coordinates -- the
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97 | information is translated into ''human language'' and stored in ASCII files.
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98 | At the same time, an e-mail is sent to the MAGIC GRB-mailing list
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99 | {\it grb@mppmu.mpg.de}.
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100 |
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101 | \subsection{The GRB Web Page}
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102 |
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103 | The status of the GRB Alert System and relevant informations about the latest
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104 | alert are displayed on a separate web page. The page is hosted at the web server in La Palma a
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105 | and can be accessed under:\\
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106 |
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107 | \qquad \qquad http://www.magic.iac.es/site/grbm/\\
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108 |
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109 | The web page updates itself automatically every 10 seconds. In this way
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110 | the status of the Burst Alarm System can be checked by the shifters and from outside.
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111 |
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112 | \subsection{The Acoustic Alert}
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113 |
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114 | A further CC-independent acoustic alarm called {\it phava}
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115 | (PHonetic Alarm for Valued Alerts) will be installed
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116 | in La Palma soon. It will provide a loud acoustic signal
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117 | even if the CC is switched off, so that persons in the counting house
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118 | can be noticed about the alert situation. The signal will be on as long as
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119 | {\it gspot} remains in alarm state, and for a minimum of 1 minute.
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120 | The device features also a display with the status of the system and the alert.
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121 |
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122 | \subsection{Summary of Alerts Received Until Now}
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123 |
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124 | Since July 15$^{th}$, 2004, {\it gspot} has been working stably at La Palma.
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125 | It has received about 100 alerts from HETE-2 and INTEGRAL, out of which
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126 | 21 contained GRB's coordinates. Time delays to the onset of the burst
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127 | were of the order of several minutes to tens of minutes. The Burst Monitor can be considered stable
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128 | since November, 2004. Since then, we have received the following two significant alerts:\\
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129 |
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130 | \begin{tabular}{lllcccl}
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131 | 19th & December & 2004 & 1:44 am & INTEGRAL satellite & Zd $\sim 60^\circ$ & Time delay 71 sec.\\
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132 | 28th & January & 2005 & 5:36 am & HETE-2 satellite & Zd $\sim 65^\circ$ & Time delay 73 min. \\ \\
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133 | \end{tabular}
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134 |
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135 | In both cases the weather conditions at La Palma were bad.
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136 |
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137 | \subsection{Experience from SWIFT GRBs until now}
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138 |
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139 | According to the \sw home page~\cite{SWIFT}, the satellite has detected 16 GRBs since mid-December last year.
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140 | The bursts were detected by chance during the commissioning phase. Since 15th of February the satellite sends
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141 | burst allerts to the \g in real time. The current sample contains three bursts
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142 | which could have been observed by \ma. The coordinates of the last burst from 15th February were send via an
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143 | alert within few seconds. The weather conditions did not allow any observation in this nights.\\
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144 |
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145 | \begin{tabular}{lllcc}
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146 | 19th & December & 2004 & 1:42 am & Zd $\sim 65^\circ$ \\
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147 | 26th & December & 2004 & 8:34 pm & Zd $\sim 52^\circ$ \\
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148 | 15th & Februar & 2005 & 2:33 am & Zd $\sim 17^\circ$ \\ \\
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149 | \end{tabular}
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150 |
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151 | \subsection{Comparison between the Satellite Orbits}
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152 |
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153 | Figure~\ref{fig:orbit} shows the orbits of the \sw, \he and \ig satellites.
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154 | The \sw and \he satellites are situated in a circular orbit with
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155 | 20.6$^\circ$ and 2$^\circ$ inclination, respectively.
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156 | One revolution of the \sw and \he satellites last about 100\,min.
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157 | The \ig satellite has a
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158 | highly eccentric orbit with a revolution period of three sidereal days around the Earth.
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159 |
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160 | \par
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161 |
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162 | It is difficult to draw strong conclusions from the individual satellites' orbits.
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163 | The orientation of the satellites' FOV is influenced by the scheduled targets.
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164 | However, \sw is the satellite with the largest inclination and overlaps mostly with the FOV of \ma.
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165 | This increases the chance to receive {\bf Red Alarms} from this satellite.
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166 |
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167 | \begin{figure}[htp]
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168 | \centering
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169 | \includegraphics[width=0.7\linewidth]{GCNsatellites.eps}
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170 | \caption{Orbits of the \sw (top), \he (center) and \ig (bottom) satellites: The pointed lines
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171 | show the orbit while the drawn lines show the horizon of the Sun. Here, a typical night at
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172 | La Palma is shown. The \sw satellite passes over the Roque seven times each night.}
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173 | \label{fig:orbit}
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174 | \end{figure}
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175 |
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176 | \subsection{Routines to Be Defined}
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177 |
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178 | The Burst Alarm System is currently able to provide the minimum
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179 | features needed to point and to observe a GRB. However, in order to improve our efficiency
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180 | to point and observe GRBs, several procedures have to be defined:
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181 |
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182 | \begin{itemize}
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183 | \item {\bf Yellow Alarm strategy}:
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184 | The strategy to follow a {\bf Yellow Alarm} is not defined yet.
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185 | In such a case, the CC does not undertake any steps,
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186 | except confirming the alarm notice to the Burst Monitor. We have not
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187 | calculated yet if and when the GRB will become observable.
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188 | It would make sense to check if we could point to the burst during the period of 5 hours.
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189 | The Alarm System should change to a {\bf Red Alarm State}, then.
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190 |
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191 | \item {\bf Sequence of alerts}:
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192 | How to deal with new alerts that are distributed during the time
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193 | that {\it gspot} is in alarm state? Currently, {\it gspot}
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194 | locks its alert status until it exits the alarm state (see session 2.2).
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195 | This feature was implemented to avoid any loss of GRB information.
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196 | Such a situation can occur for example if more than one burst alert is sent before
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197 | the shift crew launches the CC.
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198 | To solve this problem, we will change the {\it gspot} routine
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199 | by implementing a list of all available GRB alerts.
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200 |
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201 |
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202 | \par
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203 |
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204 | If more than one alert is present in the list, the program
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205 | will weight the possible GRBs according to the following criteria:
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206 | (1) the total time of observability within the canonical 5 hours,
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207 | (2) the intensity of the burst and
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208 | (3) the time until the GRB becomes observable.
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209 | The information of the best GRB will be sent to the CC.
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210 |
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211 | \end{itemize}
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212 |
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213 | %%% Local Variables:
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214 | %%% mode: latex
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215 | %%% TeX-master: "GRB_proposal_2005"
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216 | %%% End:
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