基于广义相对论的轨道摄动下星间激光相位比对

Jian Liang; Qian Jia; Lei Liu; Shuo Tang

doi:10.16708/j.cnki.1000-758X.2022.0021

基于广义相对论的轨道摄动下星间激光相位比对

Jian Liang, Qian Jia, Lei Liu, Shuo Tang

航天学院

科研成果: 期刊稿件 › 文章 › 同行评审

1 引用（Scopus）

摘要

For inter-satellite laser ranging from picometers to nanometers level, this paper established the one-way and two-way laser phase comparison models between satellites in GCRS. The general relativity effect was considered in the established models induced by orbit perturbations. In the vicinity of the Earth, simulation studies of satellites with different orbital altitudes were carried out to investigate the phase comparison error resulting from the general relativity effect. Then, the inter-satellite laser ranging error was obtained by the phase comparison error. Simulation results show that the minimum laser ranging error of general relativity effect is of the order of 100 picometers, and the maximum error is of the order of 1 micron. It can be concluded that the higher the orbit height, the smaller the inter-satellite laser ranging error of general relativity effect, and the larger the distance between satellites, the larger the inter-satellite laser ranging error of general relativity effect.

投稿的翻译标题	General relativistic theory for laser phase comparison between satellites under orbit perturbations
源语言	繁体中文
页（从-至）	46-55
页数	10
期刊	Zhongguo Kongjian Kexue Jishu/Chinese Space Science and Technology
卷	42
期	2
DOI	https://doi.org/10.16708/j.cnki.1000-758X.2022.0021
出版状态	已出版 - 25 4月 2022

关键词

General relativity
Inter-satellite laser ranging
Laser phase comparison
Orbit perturbations
Ranging error

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10.16708/j.cnki.1000-758X.2022.0021

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引用此

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title = "基于广义相对论的轨道摄动下星间激光相位比对",

abstract = "For inter-satellite laser ranging from picometers to nanometers level, this paper established the one-way and two-way laser phase comparison models between satellites in GCRS. The general relativity effect was considered in the established models induced by orbit perturbations. In the vicinity of the Earth, simulation studies of satellites with different orbital altitudes were carried out to investigate the phase comparison error resulting from the general relativity effect. Then, the inter-satellite laser ranging error was obtained by the phase comparison error. Simulation results show that the minimum laser ranging error of general relativity effect is of the order of 100 picometers, and the maximum error is of the order of 1 micron. It can be concluded that the higher the orbit height, the smaller the inter-satellite laser ranging error of general relativity effect, and the larger the distance between satellites, the larger the inter-satellite laser ranging error of general relativity effect.",

keywords = "General relativity, Inter-satellite laser ranging, Laser phase comparison, Orbit perturbations, Ranging error",

author = "Jian Liang and Qian Jia and Lei Liu and Shuo Tang",

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T1 - 基于广义相对论的轨道摄动下星间激光相位比对

AU - Liang, Jian

AU - Jia, Qian

AU - Liu, Lei

AU - Tang, Shuo

PY - 2022/4/25

Y1 - 2022/4/25

N2 - For inter-satellite laser ranging from picometers to nanometers level, this paper established the one-way and two-way laser phase comparison models between satellites in GCRS. The general relativity effect was considered in the established models induced by orbit perturbations. In the vicinity of the Earth, simulation studies of satellites with different orbital altitudes were carried out to investigate the phase comparison error resulting from the general relativity effect. Then, the inter-satellite laser ranging error was obtained by the phase comparison error. Simulation results show that the minimum laser ranging error of general relativity effect is of the order of 100 picometers, and the maximum error is of the order of 1 micron. It can be concluded that the higher the orbit height, the smaller the inter-satellite laser ranging error of general relativity effect, and the larger the distance between satellites, the larger the inter-satellite laser ranging error of general relativity effect.

AB - For inter-satellite laser ranging from picometers to nanometers level, this paper established the one-way and two-way laser phase comparison models between satellites in GCRS. The general relativity effect was considered in the established models induced by orbit perturbations. In the vicinity of the Earth, simulation studies of satellites with different orbital altitudes were carried out to investigate the phase comparison error resulting from the general relativity effect. Then, the inter-satellite laser ranging error was obtained by the phase comparison error. Simulation results show that the minimum laser ranging error of general relativity effect is of the order of 100 picometers, and the maximum error is of the order of 1 micron. It can be concluded that the higher the orbit height, the smaller the inter-satellite laser ranging error of general relativity effect, and the larger the distance between satellites, the larger the inter-satellite laser ranging error of general relativity effect.

KW - General relativity

KW - Inter-satellite laser ranging

KW - Laser phase comparison

KW - Orbit perturbations

KW - Ranging error

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JO - Zhongguo Kongjian Kexue Jishu/Chinese Space Science and Technology

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基于广义相对论的轨道摄动下星间激光相位比对

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