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The Improved Design of Multi-channel Thin Gap Chamber Simulation Signal Source for the ATLAS Detector Upgrade |
| HU Kun1,2**, LU Hou-Bing1,2,3, WANG Xu1,2, LI Feng1,2, HAN Liang1,2, JIN Ge1,2 |
1State Key Laboratory of Particle Detection & Electronics, University of Science and Technology of China, Hefei 230026
2Department of Modern Physics, University of Science and Technology of China, Hefei 230026
3Hefei Electronic Engineering Institute, Hefei 230037
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| Cite this article: |
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HU Kun, LU Hou-Bing, WANG Xu et al 2015 Chin. Phys. Lett. 32 080701 |
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Abstract We develop an improved design of thin gap chamber (TGC) simulation signal source. To further simulate the feature of TGC detector, a novel thought is proposed. The TGC source has 256 channels. Every channel can randomly output the signal in 25 ns. The design is based on true random number generator (TRNG). Considering the electrical connection between the TGC source and the developing trigger electronics, the GFZ connector is used. The experimental results show that the improved TGC simulation signal source can uniformly output the random signal in every channel. The output noise is less than 3 mVrms.
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Received: 27 March 2015
Published: 02 September 2015
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| PACS: |
07.05.Hd
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(Data acquisition: hardware and software)
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29.40.Gx
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(Tracking and position-sensitive detectors)
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07.77.-n
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(Atomic, molecular, and charged-particle sources and detectors)
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