SuperNEMO实验的电子设备，重点是控制和读出

2013 IEEE Nuclear Science Symposium and Medical Imaging Conference (2013 NSS/MIC) Pub Date : 2013-10-26 DOI:10.1109/NSSMIC.2013.6829746

D. Breton, T. Cacérès, C. Cheikali, O. Duarte, X. Garrido, J. Maalmi, F. Mauger, P. Rusquart

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引用次数: 0

摘要

SuperNEMO (SN)是基于跟踪加量热技术的下一代无中微子双β衰变(0νββ)实验。演示模块的建造已于2013年开始，预计将于2014年在LSM地下实验室(法国)安装。SN实验旨在测量从ββ衰变中发射的每个β粒子的能量和飞行时间。演示器由与跟踪探测器(6102通道)相关联的量热计探测器(712通道)制成。这些探测器前端电子设备使用基于六个类似板条箱的统一架构，每个板条箱最多可容纳20个前端板(FEB)和1个控制板(SN_CROB)。feb执行探测器通道的采集。SN_CROB板收集来自量热计或跟踪器feb的前端数据，并将它们通过以太网链路发送到数据采集(DAQ)系统。它从前端数据中提取触发原语(TP)，并通过串行链路发送到触发板(SN_TB)。此外，SN_CROB板为板条箱中的所有板分配时钟，触发器和控制信号。它还可以提供自己的时钟。

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Electronics for the SuperNEMO experiment, with focus on Control and ReadOut

SuperNEMO (SN) is the next-generation neutrinoless double beta decay (0νββ) experiment based on a tracking plus calorimetry technique. The construction of the demonstrator module has started in 2013 and its installation is expected in 2014 in LSM underground laboratory (France). The SN experiment is designed to measure both energy and time of flight of each beta particle emitted from ββ decays.The demonstrator is made of a calorimeter detector (712 channels) associated to a tracking detector (6102 channels). These detectors front-end electronics use an unified architecture based on six similar crates that each host up to 20 Front-End Boards (FEB) and 1 Control board (SN_CROB). The FEBs perform the acquisition of the detector channels. The SN_CROB board gathers the front-end data from the calorimeter or tracker FEBs and sends them through Ethernet link to the data acquisition (DAQ) system. It extracts the Trigger Primitive (TP) from the front-end data and sends them through serial link to the Trigger Board (SN_TB). Moreover the SN_CROB board distributes the clock, the trigger and the control signals for all the boards in a crate. It can also provide its own clock.

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2013 IEEE Nuclear Science Symposium and Medical Imaging Conference (2013 NSS/MIC)

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