Author :
Alme, J. ; Campagnolo, R. ; Fehlker, D. ; Gutierrez, C. Gonzalez ; Helstrup, H. ; Hille, P.T. ; Müller, H. ; Munkejord, M. ; Musa, L. ; Karlsson, A. D Oltean ; Pimenta, R. ; Richter, M. ; Rossebø, A. ; Røed, K. ; Röhrich, D. ; Skaali, T.B. ; Stangeland, A
Abstract :
The ALICE detector is a dedicated heavy-ion detector at Large Hadron Collider in 2007, which is to be commissioned during 2007 at CERN. The ALICE triggers are handled by the central trigger processor, and distributed to all sub-detectors, amongst other the time projection chamber and the photon spectrometer. The front end electronics of the time projection chamber and the photon spectrometer share many of the same components. The photon spectrometer provides the trigger system with a level 0 and level 1 trigger (e.g high-pt photons) by the use of several trigger router units and a trigger OR board. The trigger electronics and the front end electronics are situated close to the collision-point, and errors due to radiation effects are to be expected. This article will give an overview of the trigger system from trigger generation with the photon spectrometer to trigger reception of the front end electronics of both detectors. How to deal with the possible effects of the radiation environment on the trigger handling will be evaluated.
Keywords :
field programmable gate arrays; gamma-ray spectrometers; nuclear electronics; readout electronics; time projection chambers; trigger circuits; ALICE experiment; LHC; central trigger processor; front end electronics; heavy-ion detector; photon spectrometer; radiation-tolerant SRAM-FPGA based trigger electronics; readout electronics; time projection chamber; Data analysis; Detectors; Field programmable gate arrays; Hardware; Large Hadron Collider; Magnetic separation; Physics; Radiation effects; Readout electronics; Spectroscopy; Detectors; Radiation Environment; Readout Electronics; Trigger Systems;
