An intelligent HV control and monitoring system for the PHENIX Hadron Blind Detector at the relativistic heavy ion collider

IEEE Nuclear Science Symposuim & Medical Imaging Conference Pub Date : 2010-10-01 DOI:10.1109/NSSMIC.2010.5873884

M. Proissl, B. Azmoun, S. Boose, M. Durham, T. Hemmick, A. Milov, S. Polizzo, M. Purschke, C. Woody

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Abstract

The PHENIX Hadron Blind Detector (HBD) is a high-performance Cherenkov counter used to detect electrons in relativistic heavy ion collisions at RHIC. A High Voltage Control and Monitoring System (HVC) was developed to provide optimal control over the detector for maximal performance and protection against damage from possible discharges. The HVC comprises several novel hardware components including a voltage divider board and trip detection/protection boards for each power supply module, while actual control of the HV is maintained by a software suite which incorporates Modern Optimal Control Theory and Artificial Intelligence concepts. The software suite is made up of several concurrently operating subsystems, which periodically processes measurements fed back from the HV mainframe, the HBD gas pressure (P) and temperature (T) sensors, analyzes the GEM module behavior in reference to its performance over time, determines a custom response and modifies the HV when necessary. Since the HBD gain is very sensitive to P/T fluctuations, the HVC automatically modifies the GEM/Mesh voltage accordingly in order to keep the gain variations within a nominal operating range of +/− 10%. Both hardware and software components of the HVC will be described, along with the successful performance results throughout the commissioning p+p Run-9 and the HBD's final and most important Au+Au Run-10.

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相对论重离子对撞机PHENIX强子盲探测器的智能高压控制与监测系统

PHENIX强子盲探测器(HBD)是一种高性能切伦科夫计数器，用于检测RHIC相对论重离子碰撞中的电子。开发了高压控制和监测系统(HVC)，以提供对检测器的最佳控制，以获得最大性能并防止可能的放电损坏。HVC由几个新颖的硬件组件组成，包括每个电源模块的分压器板和跳闸检测/保护板，而HV的实际控制由一个软件套件维护，该软件套件结合了现代最优控制理论和人工智能概念。该软件套件由多个同时运行的子系统组成，这些子系统定期处理HV主机、HBD气体压力(P)和温度(T)传感器反馈的测量结果，根据GEM模块的性能分析其行为，确定定制响应，并在必要时修改HV。由于HBD增益对P/T波动非常敏感，因此HVC会自动相应地修改GEM/Mesh电压，以便将增益变化保持在+/ - 10%的标称工作范围内。将介绍HVC的硬件和软件组件，以及整个调试p+p Run-9和HBD最终和最重要的Au+Au Run-10的成功性能结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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IEEE Nuclear Science Symposuim & Medical Imaging Conference

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