Attitude Takeover Control of Failed Spacecraft

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Attitude Takeover Control of Failed Spacecraft

Huang, Panfeng/ Zhang, Fan/ Lu, Yingbo

ウェブストア価格 ¥51,744（本体¥47,040）
Elsevier - Health Sciences Division（2024/07発売）
外貨定価 US$ 250.00
ポイント 470pt

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製本 Paperback:紙装版/ペーパーバック版／ページ数 492 p.
言語 ENG
商品コード 9780443247446
DDC分類 629.11

Full Description

Attitude Takeover Control of Failed Spacecraft is both necessary and urgently required. This book provides an overview of the topic and the role of space robots in handling various types of failed spacecraft. The book divides the means of attitude takeover control into three types, including space manipulator capture, tethered space robot capture, and cellular space robot capture. Spacecraft attitude control is the process of controlling the orientation of a spacecraft (vehicle or satellite) with respect to an inertial frame of reference or another entity such as the celestial sphere, certain fields, and nearby objects, etc.

It has become increasingly important: with the increasing number of human space launch activities, the number of failed spacecraft has increased dramatically in recent years.

1. Introduction

Part I Space Manipulator Capturing
2. Trajectory Prediction of Space Robot for Capturing Non-Cooperative Target
3. Combined Spacecraft Stabilization Control after Multiple Impacts During Space Robot Capture the Tumbling Target
4. Attitude Takeover Control of a Failed Spacecraft without Parameter Uncertainties
5. Reconfigurable Spacecraft Attitude Takeover Control in Post-capture of Target by Space Manipulators
6. Attitude Takeover Control of a Failed Spacecraft with Parameter Uncertainties

Part II Tethered Space Robot Capturing
7. Adaptive Control for Space Debris Removal with Uncertain Kinematics, Dynamics and States
8. Adaptive Neural Network Dynamic Surface Control of the Post-Capture Tethered System with Full State Constraints
9. Adaptive Prescribed Performance Control for the Postcapture Tethered Combination via Dynamic Surface Technique
10. An Energy Based Saturated Controller for the Postcapture Underactuated Tethered System
11. Capture Dynamics and Net Closing Control for Tethered Space Net Robot
12. Impulsive Super-Twisting Sliding Mode Control for Space Debris Capturing via Tethered Space Net Robot

Part III Cellular Space Robot Capturing
13. A Self-Reconfiguration Planning Strategy for Cellular Satellites
14. Reinforcement-Learning-Based Task Planning for Self- Reconfiguration of Cellular Space Robot
15. Interactive Inertial Parameters Identification for Spacecraft Takeover Control Using Cellular Space Robot
16. Spacecraft Attitude Takeover Control via Cellular Space Robot with Distributed Control Allocation
17. Spacecraft Attitude Takeover Control via Cellular Space Robot with Saturation

Appendix A: Conclusion