Index: trunk/MagicSoft/GRB-Proposal/Introduction.tex =================================================================== --- trunk/MagicSoft/GRB-Proposal/Introduction.tex (revision 6145) +++ trunk/MagicSoft/GRB-Proposal/Introduction.tex (revision 6146) @@ -75,2 +75,8 @@ +\subsection{Observation of Soft Gamma Repeaters(SGRs)} +A stronge magnetic neutron star, a so-called ``Soft Gamma Repeaters (SGRs)'' p +eriodically emit gamma-ray, and are extremely rare stars. Only four identified +SGRs are discovered in the last 20 years: SGR0526-66, SGR1806-20, SGR1900+14, SG +R1627-41. GRBs and SGRs can be explained with an unique precessing gamma jet mod +el observed at different beam-angle and at different ages. Index: trunk/MagicSoft/GRB-Proposal/Strategies.tex =================================================================== --- trunk/MagicSoft/GRB-Proposal/Strategies.tex (revision 6145) +++ trunk/MagicSoft/GRB-Proposal/Strategies.tex (revision 6146) @@ -6,5 +6,5 @@ from the claimed GRB observation frequency of about 150-200 GRBs/year by the SWIFT collaboration~\cite{SWIFT} and the results of the studies on the MAGIC duty-cycle -made by Nicola Galante~\cite{NICOLA} and Satoko Mizobuchi~\cite{SATOKO}. +made by Nicola Galante~\cite{NICOLA}. Considering a MAGIC duty-cycle of about 10\% and a tolerance of 5 hours to point the GRB, we should be able to point about 1-2 GRB/month. @@ -20,5 +20,5 @@ yet under observational control. -This reduction of the real duty-cycle w.r.t. the studies~\cite{NICOLA,SATOKO} +This reduction of the real duty-cycle w.r.t. the studies~\cite{NICOLA} gets compensated by the tolerance of 5 hours for considering the alert observable (5 hours more before the beginning of the night Index: trunk/MagicSoft/GRB-Proposal/Timing.tex =================================================================== --- trunk/MagicSoft/GRB-Proposal/Timing.tex (revision 6145) +++ trunk/MagicSoft/GRB-Proposal/Timing.tex (revision 6146) @@ -1,25 +1,16 @@ \section{Timing considerations} -{\ldots \it \bf HAS TO BE UPDATED AND COMPLETED!! \ldots \\} {\it Here, all possible models should go in with reasonning why certain time or flux estimates are proposed.  We have now only estimates on extrapolations -of the \eg power-laws. Maybe we should include: IC (in many possible combinations), -hadronic emission models (see~\cite{TASC}), Cannonball model. } +of the \eg power-laws. Maybe we should include: IC (in many possible combinations), hadronic emission models (see~\cite{TASC}), Cannonball model.} \par -The EGRET~\cite{EGRET} instrument on the CGRO -has detected GeV emission of GRB940217 promptly and 90 min. after -the burst onset. -\\ +The EGRET~\cite{EGRET} instrument on the CGRO has detected GeV emission of GRB940217 promptly and 90 min. after the burst onset.\\ \par -In~\cite{DERMER}, two peaks in the GeV light curve are calculated. An early maximum coincident -with the MeV peak is the high-energy extension of the synchrotron component, some seconds -after the burst onset. The second maximum peaking at $\approx$ 1.5 hours is due primarily to -SSC radiation with significant emission of up to $10^5$ sec. ($\approx 25$ hours) after the burst. -\\ + +In~\cite{DERMER}, two peaks in the GeV light curve are calculated. An early maximum coincident with the MeV peak is the high-energy extension of the synchrotron component, some seconds after the burst onset. The second maximum peaking at $\approx$ 1.5 hours is due primarily to SSC radiation with significant emission of up to $10^5$ sec. ($\approx 25$ hours) after the burst.\\ \par -Li, Dai and Lu~\cite{LI} suggest GeV emission after pion production and some thermalization of the -UHE component with radiation maxima of up to one day or even one week (accompanied by long-term -neutrino emission). + +Li, Dai and Lu~\cite{LI} suggest GeV emission after pion production and some thermalization of the UHE component with radiation maxima of up to one day or even one week (accompanied by long-term neutrino emission). \par