Reachable domain for satellite relative motion along elliptic orbit with uncertainty and process noise

Wen, Changxuan; Ma, Jian

doi:10.1177/0954410019900726

Cited by 4 publications

(1 citation statement)

References 31 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Wen et al (2019) also proposed an algorithm of solving the envelope surface of the relative reachable domain for close-range relative motion based on the linearized dynamical model and the mathematical definition of an envelope. Wen et al (2020) proposed an algorithm to solve for the relative reachable domain envelope as well, and verified the accuracy of the proposed algorithm by comparing the solved relative reachable domain envelopes with the results of a direct Monte Carlo simulation.…”

Section: Introductionmentioning

confidence: 91%

Research on relative reachable domain in target orbit for maneuvering spacecraft

Li,

Zhang

2024

AEAT

View full text Add to dashboard Cite

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.

show abstract

Section: Introductionmentioning

confidence: 91%

Research on relative reachable domain in target orbit for maneuvering spacecraft

Li,

Zhang

2024

AEAT

View full text Add to dashboard Cite

show abstract

Calculating collision probability for long-term satellite encounters through the reachable domain method

Wen

Dong

2022

Astrodyn

View full text Add to dashboard Cite

Time-Dependent Reachable Domain and Its Application to Impulsive Orbital Pursuit–Evasion Analysis

Zhang,

Yang,

Luo

2024

Journal of Spacecraft and Rockets

View full text Add to dashboard Cite

Orbital pursuit–evasion (OPE) has garnered significant attention due to its potential applications in space rendezvous and proximity operations. Conventional methods using differential games do not fully address the impulsive OPE problem, which involves a discontinuous differential system. This paper presents the concept of a time-dependent reachable domain (TDRD) for analyzing the impulsive OPE problem. The range and time constraints for determining the TDRD are first given. These constraints can be solved to identify two different TDRDs: the RD at a given time and the RD over a duration. The numerical results obtained from the proposed method exhibit good agreement with those from Monte Carlo simulations, validating the practicality of using TDRDs for OPE analysis. Four different qualitatively OPE outcomes are defined based on the geometrical relationship between the spacecraft’s TDRDs. A series of application cases are comprehensively examined to prove that TDRDs directly predict the sufficient conditions leading to a specific OPE outcome. These findings demonstrate that the TDRD concept is a potent and efficacious instrument for studying the impulsive OPE problem.

show abstract

Reachable domain for satellite relative motion along elliptic orbit with uncertainty and process noise

Cited by 4 publications

References 31 publications

Research on relative reachable domain in target orbit for maneuvering spacecraft

Research on relative reachable domain in target orbit for maneuvering spacecraft

Calculating collision probability for long-term satellite encounters through the reachable domain method

Time-Dependent Reachable Domain and Its Application to Impulsive Orbital Pursuit–Evasion Analysis

Contact Info

Product

Resources

About