An Interferometric Wave Front Sensor for Measuring Post-Coronagraph Errors on Large Optical Telescopes

J. Wallace, B. Macintosh, M. Shao, R. Bartos, P. Dumont, B. Levine, S. Rao, R. Samuele, C. Shelton
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引用次数: 1

Abstract

The Gemini Planet Imager (GPI) [B.Macintosh et al.], now in the early stages of development, is a ground-based extreme adaptive optics system with an advanced coronagraphic system and integral-field spectrometer. At commissioning in early 2011, it will be deployed on one of the twin eight meter Gemini Telescopes. This powerful instrument, which works at a science wavelength in the near-infrared, will enable the direct detection and characterization of self-luminous Jupiter-class planets from the ground. Semi-static and non-common path wave front errors that are not sensed by the active wave front sensor in the adaptive optics system will lead to a focal plane speckle pattern that will mask exo-planets. The GPI Instrument will incorporate an interferometric wave front sensor, designed and developed at JPL, which will measure these errors. This talk will emphasis this novel sensor and describes how it is used to measure the non-common path amplitude and phase errors in the system that would otherwise limit the achievable contrast. We will describe the system error budget as well as simulations that model the system performance. Finally, we will also discuss the status of our laboratory testbed that is designed to test the fundamental principles of post-coronagraph wave front sensing. This system promises a rich combination of interferometry and large optical systems in support of cutting edge science research.
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用于测量大型光学望远镜日冕后误差的干涉波前传感器
双子座行星成像仪(GPI) [B]。Macintosh等人],现在处于早期开发阶段,是一种基于地面的极端自适应光学系统,具有先进的日冕系统和积分场光谱仪。在2011年初的调试中,它将被部署在一对8米双子望远镜中的一个上。这台功能强大的仪器,工作在近红外的科学波长,将使从地面直接探测和表征自发光的木星类行星成为可能。在自适应光学系统中,主动波前传感器无法检测到的半静态和非共程波前误差将导致焦平面散斑图案,从而掩盖系外行星。GPI仪器将包括一个干涉波前传感器,由喷气推进实验室设计和开发,将测量这些误差。本讲座将重点介绍这种新型传感器,并描述如何使用它来测量系统中的非共径幅度和相位误差,否则将限制可实现的对比度。我们将描述系统误差预算以及模拟系统性能。最后,我们还将讨论我们的实验室测试台的现状,该测试台旨在测试后日冕波前传感的基本原理。该系统保证了干涉测量和大型光学系统的丰富组合,以支持前沿科学研究。
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