System engineering for spaceborne optical interferometers

2004 IEEE Aerospace Conference Proceedings (IEEE Cat. No.04TH8720) Pub Date : 2004-03-06 DOI:10.1109/AERO.2004.1368006

Riley M. Duren

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引用次数: 2

Abstract

Spaceborne optical interferometry truly represents uncharted territory - one in which the community developing such missions is still "learning the ropes". This paper is based on a collection of lessons-learned based on related missions including StarLight, a formation-flying stellar interferometry mission that merged with the Terrestrial Planet Finder technology development program just prior to entering phase C/D, the Space Interferometry Mission (currently in phase B), and the Shuttle Radar Topography Mission (a radar interferometer which flew in 2000). In first order, optical interferometry missions differ from classical deep-space science missions in several key respects: they are highly distributed systems, they are sensitive to small, cross-coupling error sources, and their operation is very complex. This leads to three unique system engineering challenges associated with implementing such missions: error handling and performance modeling, validation and verification (V&V), and system robustness. With an upcoming suite of interferometry missions approaching the transition from technology-development mode to flight project implementation mode the time is ripe for a discussion of these challenges and proposed solutions.

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星载光学干涉仪系统工程

星载光学干涉测量确实代表了未知的领域——在这一领域，开发此类任务的社区仍在“学习窍门”。本文基于相关任务的经验教训收集，包括StarLight，一个编队飞行恒星干涉测量任务，在进入C/D阶段之前与类地行星探测技术开发计划合并，空间干涉测量任务(目前处于B阶段)，以及航天飞机雷达地形任务(2000年飞行的雷达干涉仪)。首先，光学干涉测量任务与经典深空科学任务在以下几个关键方面有所不同:它们是高度分布的系统，对小的交叉耦合误差源敏感，操作非常复杂。这导致了与实现这样的任务相关的三个独特的系统工程挑战:错误处理和性能建模、确认和验证(V&V)，以及系统健壮性。随着一系列干涉测量任务即将从技术开发模式过渡到飞行项目实施模式，讨论这些挑战和提出解决方案的时机已经成熟。

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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2004 IEEE Aerospace Conference Proceedings (IEEE Cat. No.04TH8720)

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