Progress towards hardware demonstrations of critical component-level technologies for ultra-stable optical systems

Space Telescopes and Instrumentation 2020: Optical, Infrared, and Millimeter Wave Pub Date : 2020-12-13 DOI:10.1117/12.2560185

L. Coyle, J. S. Knight, Brian A. Hicks, Benjamin Cromey, L. Pueyo, M. East, Sean Brennan, Todd A. Lawton, J. Arenberg, R. Hellekson, Marcel Bluth, J. Tucker, Sang C. Park, M. Eisenhower

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引用次数: 3

Abstract

To achieve the ambitious goal of directly imaging exo-Earths with a coronagraph, future space-based astronomical telescopes will require wavefront stability several orders of magnitude beyond state-of-the-art. The Ultra-Stable Large Telescope Research and Analysis – Technology Maturation (ULTRA-TM) program will mature critical technologies for this new regime of “ultra-stable optical systems” through component-level hardware demonstrations. This paper describes the progress towards demonstrating performance of these technologies in the picometer regime and with flight-like properties – including active systems like segment sensing and actuation and thermal sensing and control, as well as passive systems like low distortion mirror mounts and composite structures. Raising the TRL of these technologies will address the most difficult parts of the stability problem with the longest lead times and provide significant risk reduction for their inclusion in future mission concepts.

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超稳定光学系统关键组件级技术的硬件演示进展

为了实现用日冕仪直接成像系外地球的宏伟目标，未来的天基天文望远镜将需要比最先进的波前稳定性好几个数量级。超稳定大型望远镜研究与分析-技术成熟(ULTRA-TM)项目将通过组件级硬件演示，为这种“超稳定光学系统”的新体制成熟关键技术。本文描述了在皮米范围内展示这些技术性能的进展，并具有类似飞行的特性——包括主动系统，如片段传感和驱动、热传感和控制，以及被动系统，如低畸变镜座和复合结构。提高这些技术的TRL将以最长的交付时间解决稳定性问题中最困难的部分，并为将其纳入未来的任务概念提供显著的风险降低。

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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Space Telescopes and Instrumentation 2020: Optical, Infrared, and Millimeter Wave

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