罗马日冕仪的分析性能模型和误差预算

IF 1.7 3区 工程技术 Q2 ENGINEERING, AEROSPACE
Bijan Nemati, John Krist, Ilya Poberezhskiy, Brian Kern
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引用次数: 2

摘要

美国国家航空航天局正在开发的南希·格蕾丝·罗曼太空望远镜(“罗曼”)将调查暗能量现象的可能原因,并探测和表征太阳系外行星。2.4米的太空望远镜有两个主要仪器:一个广角红外成像仪和一个日冕仪。日冕仪(CGI)是一种技术演示,旨在帮助弥合当前最先进的空间和地面仪器与未来高对比度空间日冕仪之间的差距,这些日冕仪将能够探测和表征其他恒星可居住区内的类地行星。使用自适应光学,包括两个高密度可变形镜和低阶和高阶波前传感和控制,CGI被设计用来抑制高达9个数量级的恒星光,有可能直接探测和表征木星级的系外行星。对比度是星光抑制的量度,高对比度是日冕仪的主要优点。但这并不是唯一重要的特征:对比度必须与接受行星光相平衡。剩余的未被抑制的星光也必须有一个稳定的形态,以便进一步的估计和减法。为了在空间干扰和辐射环境下实现这些目标,日冕仪必须设计和制造成一个高度优化的系统。CGI错误预算是用于指导优化的顶级工具,支持各种竞争错误的交易。错误预算是基于分析模型的,它能够快速计算和跟踪系统工程过程中出现的众多不同问题的性能。我们概述了日冕仪系统工程方法和误差预算。然后,我们详细描述了直接成像和光谱学的分析模型,并展示了它与误差预算的关系。我们介绍了一些有用的辅助指标,提供洞察仪器的能力。由于模型总是需要验证的,所以我们描述了CGI分析模型的验证方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Analytical performance model and error budget for the Roman coronagraph instrument
The Nancy Grace Roman Space Telescope (“Roman”), under development by NASA, will investigate possible causes for the phenomenon of dark energy and detect and characterize extrasolar planets. The 2.4 m space telescope has two main instruments: a wide-field, infrared imager and a coronagraph. The coronagraph instrument (CGI) is a technology demonstrator designed to help bridge the gap between the current state-of-the-art space and ground instruments and future high-contrast space coronagraphs that will be capable of detecting and characterizing Earth-like planets in the habitable zones of other stars. Using adaptive optics, including two high-density deformable mirrors and low- and high-order wavefront sensing and control, CGI is designed to suppress the star light by up to nine orders of magnitude, potentially enabling the direct detection and characterization of Jupiter-class exoplanets. Contrast is the measure of starlight suppression, and high contrast is the chief virtue of a coronagraph. But it is not the only important characteristic: contrast must be balanced against acceptance of planet light. The remaining unsuppressed starlight must also have a stable morphology to allow further estimation and subtraction. To achieve all these goals in the presence of the disturbance and radiation environment of space, the coronagraph must be designed and fabricated as a highly optimized system. The CGI error budget is the top-level tool used to guide the optimization, enabling trades of various competing errors. The error budget is based on an analytical model, which enables rapid calculation and tracking of performance for the numerous and diverse questions that arise in the system engineering process. We outline the coronagraph system engineering approach and the error budget. We then describe in detail the analytical model for direct imaging and spectroscopy and show how it connects to the error budget. We introduce a number of useful ancillary metrics that provide insight into the capabilities of the instrument. Since models always need to be validated, we describe the validation approach for the CGI analytical model.
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来源期刊
CiteScore
4.40
自引率
13.00%
发文量
119
期刊介绍: The Journal of Astronomical Telescopes, Instruments, and Systems publishes peer-reviewed papers reporting on original research in the development, testing, and application of telescopes, instrumentation, techniques, and systems for ground- and space-based astronomy.
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