Three-dimensional optimal deployment of a tethered subsatellite with an elastic tether

Hao Wen; Dongping Jin; Haiyan Hu

doi:10.1080/00207160701582085

Three-dimensional optimal deployment of a tethered subsatellite with an elastic tether

Hao Wen, Dongping Jin, Haiyan Hu^*

^*Corresponding author for this work

Nanjing University of Aeronautics and Astronautics

Research output: Contribution to journal › Article › peer-review

17 Citations (Scopus)

Abstract

This paper presents the nonlinear optimal control for the deployment process of an elastically tethered subsatellite model, which involves not only the usually addressed in-plane motion, but also the out-of-plane motion. All the nonlinearities in the system model and the mission-related state-control constraints are taken into consideration. Instead of the commonly used state-space model, a second-order differential inclusion formulation is exploited in this paper to achieve a significant reduction of the number of system variables. The optimal control is solved by discretizing the optimal control problem first and then solving the resulting large-scale optimization problem. The case studies in the paper demonstrate well the performance of the proposed strategy.

Original language	English
Pages (from-to)	915-923
Number of pages	9
Journal	International Journal of Computer Mathematics
Volume	85
Issue number	6
DOIs	https://doi.org/10.1080/00207160701582085
Publication status	Published - Jun 2008
Externally published	Yes

Keywords

Differential inclusion
Elastic tether
Optimal control
Out-of-plane motion
Tethered subsatellite system

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10.1080/00207160701582085

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abstract = "This paper presents the nonlinear optimal control for the deployment process of an elastically tethered subsatellite model, which involves not only the usually addressed in-plane motion, but also the out-of-plane motion. All the nonlinearities in the system model and the mission-related state-control constraints are taken into consideration. Instead of the commonly used state-space model, a second-order differential inclusion formulation is exploited in this paper to achieve a significant reduction of the number of system variables. The optimal control is solved by discretizing the optimal control problem first and then solving the resulting large-scale optimization problem. The case studies in the paper demonstrate well the performance of the proposed strategy.",

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AB - This paper presents the nonlinear optimal control for the deployment process of an elastically tethered subsatellite model, which involves not only the usually addressed in-plane motion, but also the out-of-plane motion. All the nonlinearities in the system model and the mission-related state-control constraints are taken into consideration. Instead of the commonly used state-space model, a second-order differential inclusion formulation is exploited in this paper to achieve a significant reduction of the number of system variables. The optimal control is solved by discretizing the optimal control problem first and then solving the resulting large-scale optimization problem. The case studies in the paper demonstrate well the performance of the proposed strategy.

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KW - Elastic tether

KW - Optimal control

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Three-dimensional optimal deployment of a tethered subsatellite with an elastic tether

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Keywords

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