\section{Proposed Observation Strategies} \subsection{Estimation of the Required Observation Time} A rough estimate of the needed observation time for GRBs derives from the estimated number of GRB follow-up observations which can be expressed in the following formula: \begin{equation} N_{obs} = N_{alert} \cdot DC \cdot F_{overlap} \end{equation} where $N_{obs}$ is the mean number of observed bursts, $N_{alert}$ the mean number of sent alerts, $DC$ the duty cycle (including the reduction of sky coverage due to the maximum allowed zenith angle) and $F_{overlap}$ a reduction factor due to the non-overlapping sky coverage between the satellites and \ma. \\ The claimed GRB observation frequency $N_{obs}(SWIFT)$ is predicted to about 150-200 GRBs/year by the \sw collaboration~\cite{SWIFT}. We estimate $DC$ from studies on the \ma duty-cycle made by Nicola Galante~\cite{NICOLA}. The duty-cycle studies are based on real weather data from the year 2002 taking the following criteria: \begin{itemize} \item maximum wind speeds of 10\,m/s \item maximum humidity of 80\% \item darkness at astronomical horizon \end{itemize} In these duty-cycle studies also full-moon nights were considered (requiring a minimum angular distance between the GRB and the Moon of 30$^\circ$) yielding a total of 10\%. \par The duty-cycle in~\cite{NICOLA} will be increased by taking into account that \ma should also observe the afterglow emission of a burst that occurred up to 5 hours before the start of the shift. The afterglow observation is equivalent to an increase of the duty-cycle of about 6 days per month. However, taking off the full-moon time, we remain with the anticipated 10\%.\\ The overlap factor $F_{overlap}$ is difficult to estimate since the \sw satellite will continuously slew to new sources or follow detected bursts. Figure~\ref{fig:orbit} shows that the satellite will pass very precisely over La Palma during the night. Taking into account that it will not look towards the Sun, we expect that $F_{overlap}(SWIFT)$ will be at least 0.5 or higher. \\ In conclusion, we can calculate a worst case scenario with 150 \sw alerts per year and an overlap factor of 0.5 yielding $N_{obs}^{min} \sim 0.6$/month. An upper limit can be derived from 200 \sw alerts and a complete overlap with $F_{overlap}(SWIFT) = 1$ yielding $N_{obs}^{max} \sim 1.6$/month. \subsection{Determine the Maximum Zenith Angle} We determine the maximum zenith angle for GRB observations by requiring that the overwhelming majority of possible GRBs will have in principle an observable spectrum. Figure~\ref{fig:grh} shows the gamma-ray horizon (GRH) as computed in~\cite{KNEISKE,SALOMON}. The GRH is defined as the gamma-ray energy at which a fraction of $1/\mathrm{e}$ of a hypothetical mono-energetic flux gets absorbed after travelling a distance, expressed in redshift $z$, from the source. One can see that at typical GRB distances of $z=1$, all gamma-rays above 100\,GeV get absorbed before they can reach the Earth. \par Even the closest GRB with known redshift ever observed, GRB030329~\cite{GRB030329}, lies at a redshift of $z=0.1685$. In this case $\gamma$-rays above 200\,GeV get entirely absorbed. \begin{figure}[htp] \centering \includegraphics[width=0.85\linewidth]{f4.eps} \caption{Gamma Ray Horizon as derived in~\cite{KNEISKE}} \label{fig:grh} \end{figure} \par We assume now a current energy threshold of 50\,GeV for \ma at a zenith angle of $\theta = 0$\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: \begin{equation} E_{thr}(\theta) = E_{thr}(0) \cdot (\cos\theta)^{-2.7} \label{eq:ethrvszenith} \end{equation} Eq.~\ref{eq:ethrvszenith} leads to an energy threshold of about 5.6\,TeV at $\theta = 80^\circ$, 900\,GeV at $\theta = 70^\circ$ and 500\,GeV at $\theta = 65^\circ$. Inserting these results into the GRH (figure~\ref{fig:grh}), one gets a maximal observable GRB distance of $z = 0.1$ at $\theta = 70^\circ$ and $z = 0.2$ at $\theta = 65^\circ$. We think that the probability for GRBs to occur at these distances is sufficiently small in order to neglect the very difficult observations beyond these limits. \subsection{GRB Observations in Case of Moon Shine} {\it gspot} allows only GRBs with an angular distance of $> 30^\circ$ from the Moon. Telescope slewing in case of a GRB alert will be done without closing the camera lids, so that the camera could be flashed by the Moon during such movement. In principle, a fast Moon flash should not damage the PMTs, but the behaviour of the camera and the Camera Control {\it La Guagua} must be tested. On the other hand, if such tests conclude that it is not safe to get even a short flash from the Moon, the Steering System, while slewing, will have to follow a path around the Moon. \par In 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. \par In these conditions, because of higher background with moon-light, we suggest to decrease the maximum zenith angle from $\theta_{max} = 70^\circ$ to $\theta_{max} = 65^\circ$. \subsection{Active Mirror Control Behaviour} To reduce the time before the start of the observation, the use of the look-up tables (LUTs) is necessary. Once generated, the {\it AMC} will use the LUTs and automatically focus the panels for a given telescope position. The {\it CC} should send the burst coordinates to the {\it Drive} and the {\it AMC} software in the same time. In this way the panels could be focused already during the telescope movement. \subsection{Calibration} For ordinary source observation, the calibration is currently performed in the following way: \begin{itemize} \item At the beginning of the source observation, a dedicated pedestal run followed by a calibration run is taken. \item During the data runs, interlaced calibration events are taken at a rate of 50\,Hz. \end{itemize} We 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. \subsection{In case of Follow-up: Next Steps} We 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: \begin{itemize} \item In case of a repeated outbursts for a longer time period of direct observation. \item Or else, for having off-data at exactly the same sky location. \end{itemize} %%% Local Variables: %%% mode: latex %%% TeX-master: "GRB_proposal_2005" %%% TeX-master: "GRB_proposal_2005" %%% End: