source: trunk/MagicSoft/GRB-Proposal/Strategies.tex@ 9140

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1\section{Proposed Observation Strategies}
2
3\subsection{Estimation of the Required Observation Time}
4
5A rough estimate of the needed observation time for GRBs derives
6from the estimated number of GRB follow-up observations which can be
7expressed in the following formula:
8
9\begin{equation}
10N_{obs} = N_{alert} \cdot DC \cdot F_{overlap}
11\end{equation}
12
13where $N_{obs}$ is the mean number of observed bursts, $N_{alert}$ the mean
14number of sent alerts, $DC$ the duty cycle (including the reduction of sky coverage
15due to the maximum allowed zenith angle) and $F_{overlap}$ a reduction factor due to
16the non-overlapping sky coverage between the satellites and \ma. \\
17
18The claimed GRB observation frequency $N_{obs}(SWIFT)$ is predicted to about 150-200 GRBs/year
19by the \sw collaboration~\cite{SWIFT}. We estimate $DC$ from studies on the \ma duty-cycle
20made by Nicola Galante~\cite{NICOLA}.
21The duty-cycle studies are based on real weather data from the year 2002 taking the following criteria:
22
23\begin{itemize}
24\item maximum wind speeds of 10\,m/s
25\item maximum humidity of 80\%
26\item darkness at astronomical horizon
27\end{itemize}
28
29In these duty-cycle studies also full-moon nights were considered (requiring
30a minimum angular distance between the GRB and the Moon of 30$^\circ$) yielding a
31total of 10\%.
32
33\par
34
35The duty-cycle in~\cite{NICOLA} will be increased by taking into account that \ma should also observe the
36afterglow emission of a burst that occurred up to 5 hours before the start of the shift.
37The afterglow observation is equivalent to an increase of the duty-cycle of about 6 days per month.
38However, taking off the full-moon time, we remain with the anticipated 10\%.\\
39
40The overlap factor $F_{overlap}$ is difficult to estimate since the \sw satellite will continuously slew
41to new sources or follow detected bursts. Figure~\ref{fig:orbit} shows that the satellite will pass very
42precisely over La Palma during the night. Taking into account that it will not look towards the Sun,
43we expect that $F_{overlap}(SWIFT)$ will be at least 0.5 or higher. \\
44
45In conclusion, we can calculate a worst case scenario with 150 \sw alerts per year and an overlap factor
46of 0.5 yielding $N_{obs}^{min} \sim 0.6$/month.
47An upper limit can be derived from 200 \sw alerts and a complete
48overlap with $F_{overlap}(SWIFT) = 1$ yielding $N_{obs}^{max} \sim 1.6$/month.
49
50\subsection{Determine the Maximum Zenith Angle}
51
52We determine the maximum zenith angle for GRB observations by requiring that the overwhelming
53majority of possible GRBs will have in principle an observable spectrum. Figure~\ref{fig:grh}
54shows the gamma-ray horizon (GRH) as computed in~\cite{KNEISKE,SALOMON}. The GRH is defined as the
55gamma-ray energy at which a fraction of $1/\mathrm{e}$ of a hypothetical mono-energetic flux gets absorbed after
56travelling a distance, expressed in redshift $z$, from the source. One can see that at typical
57GRB distances of $z=1$, all gamma-rays above 100\,GeV get absorbed before they can reach the Earth.
58
59\par
60
61Even the closest GRB with known redshift ever observed, GRB030329~\cite{GRB030329}, lies at a redshift
62of $z=0.1685$. In this case $\gamma$-rays above 200\,GeV get entirely absorbed.
63
64\begin{figure}[htp]
65\centering
66\includegraphics[width=0.85\linewidth]{f4.eps}
67\caption{Gamma Ray Horizon as derived in~\cite{KNEISKE}}
68\label{fig:grh}
69\end{figure}
70
71\par
72
73We assume now a current energy threshold of 50\,GeV for \ma at a zenith angle of
74$\theta = 0$\footnote{As this proposal is going to be reviewed in a couple of months, improvements of the energy threshold will be taken into account then.}. According to~\cite{ecl}, the energy threshold of a Cherenkov telescope scales with zenith angle like:
75
76\begin{equation}
77E_{thr}(\theta) = E_{thr}(0) \cdot (\cos\theta)^{-2.7}
78\label{eq:ethrvszenith}
79\end{equation}
80
81Eq.~\ref{eq:ethrvszenith} leads to an energy threshold of about 5.6\,TeV at $\theta = 80^\circ$,
82900\,GeV at $\theta = 70^\circ$ and 500\,GeV at $\theta = 65^\circ$.
83Inserting these results into the GRH (figure~\ref{fig:grh}), one gets a maximal observable GRB
84distance of $z = 0.1$ at $\theta = 70^\circ$ and $z = 0.2$ at $\theta = 65^\circ$.
85We think that the probability for GRBs to occur at these distances is sufficiently small in order to
86neglect the very difficult observations beyond these limits.
87
88\subsection{GRB Observations in Case of Moon Shine}
89
90{\it gspot} allows only GRBs with an angular distance of $> 30^\circ$ from the Moon.
91Telescope slewing in case of a GRB alert will be done
92without closing the camera lids, so that the camera could be
93flashed by the Moon during such movement. In principle,
94a fast Moon flash should not damage the PMTs, but the behaviour
95of the camera and the Camera Control {\it La Guagua} must
96be tested. On the other hand, if such tests conclude that it is not safe
97to get even a short flash from the Moon, the Steering System, while slewing,
98will have to follow a path around the Moon.
99
100\par
101
102In December 2004, the shift in La Palma observed the Crab-Nebula even during half-moon. During the observation, the nominal HV could be maintained while the currents were kept below 2\,$\mu$A. This means that only full-moon periods are not suitable for GRB-observations. We want to stress the fact that observations at moon-time increase the chances to catch GRBs by 80\%. It is therefore mandatory that the shifters keep the camera in fully operational conditions with high-voltages switched on from the beginning of a half-moon night until the end. This includes periods where no other half-moon observations are scheduled. If no other data can be taken during those periods, the telescope should be pointed to a Southern direction, close to the Zenith. This increases the probability to overlap with the FoV of \sw.
103
104\par
105
106In these conditions, because of higher background with moon-light, we suggest to decrease the maximum zenith angle from
107$\theta_{max} = 70^\circ$ to $\theta_{max} = 65^\circ$.
108
109\subsection{Active Mirror Control Behaviour}
110
111To reduce the time before the start of the observation, the use of the look-up tables (LUTs) is necessary.
112Once generated, the {\it AMC} will use the LUTs and automatically focus the panels for a given
113telescope position. The {\it CC} should send the burst coordinates to the {\it Drive} and the {\it AMC}
114software in the same time. In this way the panels could be focused already during the telescope movement.
115
116\subsection{Calibration}
117
118For ordinary source observation, the calibration is currently performed in the following way:
119
120\begin{itemize}
121\item At the beginning of the source observation, a dedicated pedestal run followed by a calibration run is taken.
122\item During the data runs, interlaced calibration events are taken at a rate of 50\,Hz.
123\end{itemize}
124
125We would like to continue taking the interlaced calibration events when a GRB alert is launched, but leave out the pedestal and calibration run in order not to loose valuable time.
126
127\subsection{In case of Follow-up: Next Steps}
128
129We propose to analyze the GRB data at the following day in order to tell whether a follow-up observation during the next night is useful. We think that a limit of 3\,$\sigma$ significance should be enough to start such a follow-up observation of the same place. This follow-up observation can then be used in two ways:
130
131\begin{itemize}
132\item In case of a repeated outbursts for a longer time period of direct observation.
133\item Or else, for having off-data at exactly the same sky location.
134\end{itemize}
135
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