Abstract
Thin Gap Chambers (TGC) is the end-cap muon trigger detector of the ATLAS experiment, one of the major projects being built at CERN. The TGC detector will be inaccessible during operation due to high radiation levels in the ATLAS cavern. The detector requires a Detector Control System (DCS) to monitor important detector and environmental parameters, calibrate, set and maintain the configuration of Front End electronics, and take appropriate corrective action to maintain the detector stability and reliable performance. The TGC DCS is a distributed system, comprising a central control and configuration master station and about 1,500 micro-controller slaves connected to it using CAN (Controller Area Network). The CAN nodes control hardware devices such as the thresholds for ASD discriminators, and data acquisition parameters. CAN nodes are distributed on the on-chamber trigger-DAQ electronic boards, to service many channels close to their source. In contrast to many other control systems, the TGC DCS makes full utilization of the intelligence offered by the ATLAS ELMB CAN nodes in order to distribute the control of complex tasks on the front end nodes and reduce CAN bus traffic. These nodes implement JTAG and I2C protocols, monitor hardware parameters, generate test patterns, and histogram chamber charge for diagnostics. The hardware and software design, integration, performance and radiation test results are described.
Original language | English |
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Pages (from-to) | 1733-1737 |
Number of pages | 5 |
Journal | IEEE Nuclear Science Symposium Conference Record |
Volume | 3 |
State | Published - 2004 |
Event | 2004 Nuclear Science Symposium, Medical Imaging Conference, Symposium on Nuclear Power Systems and the 14th International Workshop on Room Temperature Semiconductor X- and Gamma- Ray Detectors - Rome, Italy Duration: 16 Oct 2004 → 22 Oct 2004 |
ASJC Scopus subject areas
- Radiation
- Nuclear and High Energy Physics
- Radiology Nuclear Medicine and imaging