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	Analysis of Beam Walk in Inter-Satellite Laser Link: Implications for Differential Wavefront Sensing in Gravitational Wave Detection 期刊论文 OAI收割 APPLIED SCIENCES-BASEL, 2024, 卷号: 14, 期号: 13, 页码: 15 作者: Qian, XingGuang; Cui, Zhao; Shi, HaoQi; Wang, Xue; Yao, WeiLai \| 收藏 \| 浏览/下载：19/0 \| 提交时间：2024/08/19 beam walk angle measurement error differential wavefront sensing inter-satellite laser link laser pointing jitter
	Zero-Offset Analysis on Differential Wavefront Sensing Technique in Gravitational Wave Detection Missions 期刊论文 OAI收割 MICROGRAVITY SCIENCE AND TECHNOLOGY, 2023, 卷号: 35, 期号: 1, 页码: 9 作者: Gao RH(高瑞弘); Wang, Yikun; Cui, Zhao; Liu HS(刘河山); Jia, Jianjun \| 收藏 \| 浏览/下载：20/0 \| 提交时间：2023/03/15 Differential wavefront sensing Laser pointing Gravitational waves detection
	On-ground demonstration of laser-link construction for space-based detection of gravitational waves 期刊论文 OAI收割 OPTICS AND LASERS IN ENGINEERING, 2023, 卷号: 160, 页码: 7 作者: Gao RH(高瑞弘); Wang, Yikun; Cui, Zhao; Liu HS(刘河山); Liu, Anwei \| 收藏 \| 浏览/下载：55/0 \| 提交时间：2022/12/20 Gravitational wave detection Interferometer Laser acquisition Differential wavefront sensing Experimental demonstration system
	Linearity performance analysis of the differential wavefront sensing for the Taiji programme 期刊论文 OAI收割 JOURNAL OF MODERN OPTICS, 2020, 卷号: 67, 期号: 5, 页码: 383-393 作者: Gao RH(高瑞弘); Liu HS(刘河山); Luo ZR(罗子人); Jin G(靳刚) \| 收藏 \| 浏览/下载：54/0 \| 提交时间：2020/04/07 Gravitational wave laser interferometer differential wavefront sensing flat top beam
	Method for computer-aided alignment of complex optical system (EI CONFERENCE) 会议论文 OAI收割 2nd International Symposium on Advanced Optical Manufacturing and Testing Technologies: Optical Test and Measurement Technology and Equipment, November 2, 2005 - November 5, 2005, Zian, China 作者: Yu J. 收藏 \| 浏览/下载：29/0 \| 提交时间：2013/03/25 For making complex optical system meet the design requirement such as the space camera used in remote sensing and UVX lithophotography especially for off-axis all-reflecting optical system alignment technology is so necessary. In this paper a method is presented. Based on the ideas of linearity instead of non-linearity and difference quotient instead of differential quotient a mathematical model for computer-aided alignment is proposed. This model included the characteristics of the optical system wavefront difference of its exit pupil and its misalignment of the misaligned optical system. Then comparing self-compiled software with alignment package of CODE V as a result this self-compiled software is much more valid than alignment package of CODE V. For a large aperture long focal length and off-axis three-mirror optical system computer-aided alignment is successful. Finally the wavefront error of the middle field is 0.094 waves RMS and the wavefront error of +0.7 field is 0.106 waves RMS and the wavefront error of -0.7 field is 0.125 waves RMS at =632.8nm are obtained.