{"title":"机动航天器目标轨道相对可达域研究","authors":"Xuehua Li, Lei Zhang","doi":"10.1108/aeat-02-2023-0046","DOIUrl":null,"url":null,"abstract":"<h3>Purpose</h3>\n<p>Lots of successful space missions require that the maneuvering spacecraft can reach the target spacecraft. Therefore, research on relative reachable domain (RRD) in target orbit for maneuvering spacecraft is particularly important and is currently a hot-debated topic in the field of aerospace. This paper aims at analyzing and simulating the RRD in target orbit for maneuvering spacecrafts with a single fixed-magnitude impulse and continuous thrust, respectively, to provide a basis for analyzing the feasibility of spacecraft maneuvering missions and improving the design efficiency of spacecraft maneuvering missions.</p><!--/ Abstract__block -->\n<h3>Design/methodology/approach</h3>\n<p>Based on the kinematics model of relative motion, RRD in target orbit for maneuvering spacecraft with a single fixed-magnitude impulse can be calculated via analyzing the relationship between orbital elements, position vector and velocity vector of spacecrafts, and relevant studies are introduced to compare simulation results for the same case and validate the method proposed in the paper. 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引用次数: 0
摘要
目的许多成功的航天任务都要求机动航天器能够到达目标航天器。因此,对机动航天器目标轨道相对可达域(RRD)的研究尤为重要,也是目前航天领域争论的热点。本文旨在分别分析和模拟单个定幅脉冲和连续推力机动航天器在目标轨道上的相对可达域,为分析航天器机动飞行任务的可行性和提高航天器机动飞行任务的设计效率提供依据。设计/方法/途径基于相对运动的运动学模型,通过分析航天器的轨道元素、位置矢量和速度矢量之间的关系,可以计算出单个定幅冲量机动航天器在目标轨道上的RRD,并介绍了相关研究,以比较相同情况下的仿真结果,验证本文提出的方法。对于单个定幅冲量的情况,仿真结果初步表明该方法与参考文献(Wen et al.对于连续推力的情况,分析和模拟结果证实了所提方法的有效性。原创性/价值理论分析和仿真结果表明,本文提出的方法比较简单,但能高效、快速、精确地确定机动航天器目标轨道上的RRD。
Research on relative reachable domain in target orbit for maneuvering spacecraft
Purpose
Lots of successful space missions require that the maneuvering spacecraft can reach the target spacecraft. Therefore, research on relative reachable domain (RRD) in target orbit for maneuvering spacecraft is particularly important and is currently a hot-debated topic in the field of aerospace. This paper aims at analyzing and simulating the RRD in target orbit for maneuvering spacecrafts with a single fixed-magnitude impulse and continuous thrust, respectively, to provide a basis for analyzing the feasibility of spacecraft maneuvering missions and improving the design efficiency of spacecraft maneuvering missions.
Design/methodology/approach
Based on the kinematics model of relative motion, RRD in target orbit for maneuvering spacecraft with a single fixed-magnitude impulse can be calculated via analyzing the relationship between orbital elements, position vector and velocity vector of spacecrafts, and relevant studies are introduced to compare simulation results for the same case and validate the method proposed in the paper. With analysis of the dynamic model of relative motion, the calculation of RRD in target orbit for maneuvering spacecraft with continuous thrust can be transformed as the solution of the optimal control problem, and example emulations are carried out to validate the method.
Findings
For the case with a single fixed-magnitude impulse, simulation results show preliminarily that the method is in agreement with the method in Ref. (Wen et al., 2016), which treats the same case and thus is plausibly correct and feasible. For the case with continuous thrust, analysis and simulation results confirm the validity of the proposed method. The methods based on relative motion in this paper can efficiently determining the RRD in target orbit for maneuvering spacecraft.
Originality/value
Both theoretical analyses and simulation results indicate that the method proposed in this paper is comparatively simple but efficient for determine the RRD in target orbit for maneuvering spacecraft swiftly and precisely.
期刊介绍:
Aircraft Engineering and Aerospace Technology provides a broad coverage of the materials and techniques employed in the aircraft and aerospace industry. Its international perspectives allow readers to keep up to date with current thinking and developments in critical areas such as coping with increasingly overcrowded airways, the development of new materials, recent breakthroughs in navigation technology - and more.
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