雅典娜X-IFU检测链设计

H. Geoffray, B. Jackson, S. Bandler, S. Smith, W. Doriese, M. Durkin, J. van der Kuur, B. van Leeuwen, M. Kirivanta, D. PRELE, L. Ravera, Y. Parot, H. V. van Weers, J. D. den Herder, Joseph Adams, J. Chervenak, C. Reintsema, J. Ullom, F. Brachet, A. Ledot, P. Peille, D. Barret
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引用次数: 1

摘要

x射线积分场单元(X-IFU)仪器是ESA雅典娜x射线天文台的高分辨率x射线光谱仪。X-IFU将提供0.2至12 keV的光谱,光谱分辨率为2.5 eV,从5英寸像素到7 keV,具有5'等效直径的六角形视场。主传感器阵列及其相关的检测链是X-IFU仪器的主要子系统之一,是X-IFU仪器性能的主要贡献者。法国航天局(CNES)正在领导X-IFU的开发;其他主要合作伙伴包括NASA-GFSC、SRON、VTT、APC、NIST和IRAP。本文更新了X-IFU检测链的b相定义。读出基于时分多路复用(TDM)。检测链的不同子组件(主传感器阵列、冷电子级和热电子级)需要全局设计优化,以实现最佳性能。检测链对EMI/EMC环境的敏感性需要详细分析和实施专用设计解决方案。本文着重于这些方面,同时对检测链设计描述进行了更新。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Design of the detection chain for Athena X-IFU
The x-ray integral field unit (X-IFU) instrument is the high-resolution x-ray spectrometer of the ESA Athena x-ray observatory. X-IFU will deliver spectra from 0.2 to 12 keV with a spectral resolution of 2.5 eV up to 7 keV from 5" pixels, with a hexagonal field of view of 5' equivalent diameter. The main sensor array and its associated detection chain is one of the major sub-systems of the X-IFU instrument, and is the main contributor to X-IFU’s performance. CNES (the French Space Agency) is leading the development of X-IFU; additional major partners are NASA-GFSC, SRON, VTT, APC, NIST, and IRAP. This paper updates the B-phase definition of the X-IFU detection chain. The readout is based on time-division multiplexing (TDM). The different sub-components of the detection chain (the main sensor array, the cold electronics stages, and the warm electronics) require global design optimization in order to achieve the best performance. The detection chain’s sensitivity to the EMI/EMC environment requires detailed analysis and implementation of dedicated design solutions. This paper focuses on these aspects while providing an update to the detection-chain design description.
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