Evaluating a strategy for measuring deformations of the primary reflector of the Green Bank telescope using a terrestrial laser scanner

Advanced Control for Applications Pub Date : 2022-02-14 DOI:10.1002/adc2.99

Pedro Salas, Paul Marganian, Joe Brandt, John Shelton, Nathan Sharp, Laura Jensen, Marty Bloss, Carla Beaudet, Dennis Egan, Nathaniel Sizemore, David T. Frayer, Andrew Seymour, Frederic R. Schwab, Felix J. Lockman

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引用次数: 2

Abstract

Astronomical observations in the molecule rich 3-mm window using large reflector antennas provide a unique view of the Universe. To efficiently carry out these observations gravitational and thermal deformations have to be corrected. Terrestrial laser scanners have been used to measure the deformations in large reflector antennas due to gravity, but have not yet been used for measuring thermal deformations. In this work, we investigate the use of a terrestrial laser scanner to measure thermal deformations on the primary reflector of the Green Bank Telescope (GBT). Our method involves the use of differential measurements to reduce the systematic effects of the terrestrial laser scanner. We use the active surface of the primary reflector of the GBT to validate our method and explore its limitations. We find that when using differential measurements it is possible to accurately measure deformations corresponding to different Zernike polynomials down to an amplitude of 60 $μ$ m. The difference between the amplitudes of known deformations and those measured are $< 140 μ$ m when the wind speed is $≲ 2$ m s $^{- 1}$ . From these differences we estimate that it should be possible to bring the surface error of the GBT down to $240 \pm 6 μ$ m. This suggests that using a commercial off-the-shelf terrestrial laser scanner it is possible to measure deformations induced by thermal gradients on a large parabolic reflector.

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利用地面激光扫描仪测量格林班克望远镜主反射面变形的策略评估

在分子丰富的3毫米窗口中使用大型反射天线进行天文观测，提供了一个独特的宇宙视图。为了有效地进行这些观测，必须对重力和热变形进行校正。地面激光扫描仪已被用于测量大型反射天线由于重力引起的变形，但尚未用于测量热变形。在这项工作中，我们研究了使用地面激光扫描仪来测量格林班克望远镜(GBT)主反射镜上的热变形。我们的方法包括使用差分测量来减少地面激光扫描仪的系统影响。我们使用GBT主反射面的活动面来验证我们的方法并探索其局限性。我们发现，当使用差分测量时，可以精确地测量对应于不同泽尼克多项式的变形，其幅度可达60 μ m。已知变形幅度与测量值之间的差异为<风速≤2 m s−1时，风速为140 μ m。根据这些差异，我们估计有可能将GBT的表面误差降低到240±6 μ m，这表明使用商用现成的地面激光扫描仪可以测量大型抛物面反射器上由热梯度引起的变形。

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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来源期刊

Advanced Control for Applications

CiteScore

2.60

自引率

0.00%

发文量