Abstract
Aim of the TA-EUSO project is to install a prototype of the JEM-EUSO telescope on the Telescope Array site in Black Rock Mesa, Utah and perform observation of natural and artificial ultraviolet light. The detector consists of one Photo Detector Module (PDM), identical to the 137 present on the JEM- EUSO focal surface. Each PDM is composed by 36 Hamamatsu multi-anode photomultipliers (64 channels per tube), for a total of 2304 channels. Front-End readout is performed by 36 ASICS, with trigger and readout tasks performed by two FPGA boards that send the data to a CPU and storage system. Two, 1 meter side square Fresnel lenses provide a field-of-view of 8 degrees. The telescope will be housed in a container located in front of the fluorescence detector of the Telescope Array collaboration, looking in the direction of the ELF (Electron Light Source) and CLF (Central Laser Facility). Aim of the project is to calibrate the response function of the EUSO telescope with the TA fluorescence detector in presence of a shower of known intensity and distribution. An initial run of about six months starting from end 2012 is foreseen, during which we expect to observe, triggered by TA electronics, a few cosmic ray events which will be used to further refine the calibration of the EUSO-Ground with TA. Medium term plans include the increase of the number of PDM and therefore the field of view.
Highlights
Aim of the TA-EUSO project is to install a prototype of the JEM-EUSO telescope on the Telescope Array site in Black Rock Mesa, Utah and perform observation of natural and artificial ultraviolet light
The detector consists of one Photo Detector Module (PDM), identical to the 137 present on the JEMEUSO focal surface
Front-End readout is performed by 36 ASICS, with trigger and readout tasks performed by two FPGA boards that send the data to a CPU and storage system
Summary
TA-EUSO The TA-EUSO project aims to install a fully functional prototype of JEM-EUSO on Black Rock Mesa, the site of one of the fluorescence light detector of the Telescope Array collaboration From there it will observe artificial light (Laser and electron-generated UV) and events coming from cosmic rays. In this case studies of the tranversal profile of the shower will be performed. Second level triggering algorithms is implemented by the CCB (Cluster Control Boards), DSPs with about 1Gflop computing capability which further process the data At this level background is rejected by another factor 103. High level data, coming from artificial light sources and cosmic ray events will be transferred via network, wehereas the calibration and pedestal raw data will be physically transferred to an higher (Grid-based) link location
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