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SCIENCE CHINA Information Sciences, Volume 64 , Issue 5 : 152205(2021) https://doi.org/10.1007/s11432-020-2949-5

Adaptive fuzzy backstepping control for attitude stabilization of flexible spacecraft with signal quantization and actuator faults

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  • ReceivedFeb 20, 2020
  • AcceptedApr 30, 2020
  • PublishedApr 12, 2021

Abstract


Acknowledgment

This work was supported by National Natural Science Foundation of China (Grant Nos. 61833009, 61473096, 61690212, 91438202, 61690210, 61333003, 61673133), National Key Research and Development Plan (Grant No. 2016YFB0500901), and Heilongjiang Touyan Team.


References

[1] Timmons K, Coderre K, Pratt W D, et al. The orion spacecraft as a key element in a deep space Gateway. In: Proceedings of IEEE Aerospace Conference, 2018. Google Scholar

[2] Nasir A, Atkins E M, Kolmanovsky I. Robust Science-Optimal Spacecraft Control for Circular Orbit Missions. IEEE Trans Syst Man Cybern Syst, 2020, 50: 923-934 CrossRef Google Scholar

[3] Meng D, Liu H, Li Y. Vibration suppression of a large flexible spacecraft for on-orbit operation. Sci China Inf Sci, 2017, 60: 050203 CrossRef Google Scholar

[4] Sun L, Huo W. Adaptive Fuzzy Control of Spacecraft Proximity Operations Using Hierarchical Fuzzy Systems. IEEE/ASME Trans Mechatron, 2016, 21: 1629-1640 CrossRef Google Scholar

[5] McCamish S B, Romano M, Yun X. Autonomous Distributed Control of Simultaneous Multiple Spacecraft Proximity Maneuvers. IEEE Trans Automat Sci Eng, 2010, 7: 630-644 CrossRef Google Scholar

[6] Zou A M, de Ruiter A H J, Dev Kumar K. Distributed attitude synchronization control for a group of flexible spacecraft using only attitude measurements. Inf Sci, 2016, 343-344: 66-78 CrossRef Google Scholar

[7] Huang P, Lu Y, Wang M. Postcapture Attitude Takeover Control of a Partially Failed Spacecraft With Parametric Uncertainties. IEEE Trans Automat Sci Eng, 2019, 16: 919-930 CrossRef Google Scholar

[8] Yin S, Xiao B, Ding S X. A Review on Recent Development of Spacecraft Attitude Fault Tolerant Control System. IEEE Trans Ind Electron, 2016, 63: 3311-3320 CrossRef Google Scholar

[9] Lu K, Xia Y, Zhu Z. Sliding mode attitude tracking of rigid spacecraft with disturbances. J Franklin Institute, 2012, 349: 413-440 CrossRef Google Scholar

[10] Lu K, Xia Y, Yu C. Finite-Time Tracking Control of Rigid Spacecraft Under Actuator Saturations and Faults. IEEE Trans Automat Sci Eng, 2016, 13: 368-381 CrossRef Google Scholar

[11] Sun L. Adaptive Fault-Tolerant Constrained Control of Cooperative Spacecraft Rendezvous and Docking. IEEE Trans Ind Electron, 2020, 67: 3107-3115 CrossRef Google Scholar

[12] Qiao J, Li Z, Xu J. Composite Nonsingular Terminal Sliding Mode Attitude Controller for Spacecraft With Actuator Dynamics Under Matched and Mismatched Disturbances. IEEE Trans Ind Inf, 2020, 16: 1153-1162 CrossRef Google Scholar

[13] Sun H, Hou L, Zong G. Fixed-Time Attitude Tracking Control for Spacecraft With Input Quantization. IEEE Trans Aerosp Electron Syst, 2019, 55: 124-134 CrossRef ADS Google Scholar

[14] Zhang Z, Shi Y, Zhang Z. Modified Order-Reduction Method for Distributed Control of Multi-Spacecraft Networks With Time-Varying Delays. IEEE Trans Control Netw Syst, 2018, 5: 79-92 CrossRef Google Scholar

[15] Lyu J, Ma Q, Qin J. Finite-time attitude synchronisation for multiple spacecraft. IET Control Theor Appl, 2016, 41: 1106-1114 CrossRef Google Scholar

[16] Chen T, Wen H, Wei Z. Distributed attitude tracking for multiple flexible spacecraft described by partial differential equations. Acta Astronaut, 2019, 159: 637-645 CrossRef ADS Google Scholar

[17] Sun G, Xu S, Li Z. Finite-Time Fuzzy Sampled-Data Control for Nonlinear Flexible Spacecraft With Stochastic Actuator Failures. IEEE Trans Ind Electron, 2017, 64: 3851-3861 CrossRef Google Scholar

[18] Jiang B, Lu J, Liu Y. Periodic Event-Triggered Adaptive Control for Attitude Stabilization Under Input Saturation. IEEE Trans Circuits Syst I, 2020, 67: 249-258 CrossRef Google Scholar

[19] Sun H, Hou L, Zong G. Composite anti-disturbance attitude and vibration control for flexible spacecraft. IET Control Theor Appl, 2017, 39: 2383-2390 CrossRef Google Scholar

[20] Cao L, Xiao B, Golestani M. Faster Fixed-Time Control of Flexible Spacecraft Attitude Stabilization. IEEE Trans Ind Inf, 2020, 16: 1281-1290 CrossRef Google Scholar

[21] Agarwal A, Vukovich G. Proportional-derivative-acceleration controller design for spacecraft with flexible appendages. IJSPACESE, 2019, 5: 123-137 CrossRef Google Scholar

[22] Liu L, Liu Y J, Tong S. Neural Networks-Based Adaptive Finite-Time Fault-Tolerant Control for a Class of Strict-Feedback Switched Nonlinear Systems. IEEE Trans Cybern, 2019, 49: 2536-2545 CrossRef Google Scholar

[23] Zhou Q, Du P, Li H. Adaptive Fixed-Time Control of Error-Constrained Pure-Feedback Interconnected Nonlinear Systems. IEEE Trans Syst Man Cybern Syst, 2020, : 1-12 CrossRef Google Scholar

[24] Zhao X, Mo H, Yan K. Type-2 fuzzy control for driving state and behavioral decisions of unmanned vehicle. IEEE/CAA J Autom Sin, 2019, : 1-9 CrossRef Google Scholar

[25] Yang X, Zheng X, Chen Y. Position Tracking Control Law for an Electro-Hydraulic Servo System Based on Backstepping and Extended Differentiator. IEEE/ASME Trans Mechatron, 2018, 23: 132-140 CrossRef Google Scholar

[26] Basin M V, Yu P, Shtessel Y B. Hypersonic Missile Adaptive Sliding Mode Control Using Finite- and Fixed-Time Observers. IEEE Trans Ind Electron, 2018, 65: 930-941 CrossRef Google Scholar

[27] Pukdeboon C. Extended state observer-based third-order sliding mode finite-time attitude tracking controller for rigid spacecraft. Sci China Inf Sci, 2019, 62: 12206 CrossRef Google Scholar

[28] Chen L, Liu M, Huang X. Adaptive Fuzzy Sliding Mode Control for Network-Based Nonlinear Systems With Actuator Failures. IEEE Trans Fuzzy Syst, 2018, 26: 1311-1323 CrossRef Google Scholar

[29] Ren Z, Cheng P, Shi L. State Estimation Over Delayed Mutihop Network. IEEE Trans Automat Contr, 2018, 63: 3545-3550 CrossRef Google Scholar

[30] Karimi H R, Huijun Gao H R. New Delay-Dependent Exponential $H_{\infty}$ Synchronization for Uncertain Neural Networks With Mixed Time Delays. IEEE Trans Syst Man Cybern B, 2010, 40: 173-185 CrossRef Google Scholar

[31] Yang Z, Cheng P, Chen J. Learning-Based Jamming Attack against Low-Duty-Cycle Networks. IEEE Trans Dependable Secure Comput, 2017, 14: 650-663 CrossRef Google Scholar

[32] Song X, Zheng W X. Linear estimation for discrete-time periodic systems with unknown measurement input and missing measurements. ISA Trans, 2019, 95: 164-172 CrossRef Google Scholar

[33] Xia W, Zheng W X, Xu S. Event?triggered filter design for Markovian jump delay systems with nonlinear perturbation using quantized measurement. Int J Robust NOnlinear Control, 2019, 29: 4644-4664 CrossRef Google Scholar

[34] Xu J, Xu L, Xie L. Decentralized control for linear systems with multiple input channels. Sci China Inf Sci, 2019, 62: 52202 CrossRef Google Scholar

[35] Jiang B, Karimi H R, Kao Y. Reduced-order adaptive sliding mode control for nonlinear switching semi-Markovian jump delayed systems. Inf Sci, 2019, 477: 334-348 CrossRef Google Scholar

[36] Huang C, Zhang X, Lam H K. Synchronization Analysis for Nonlinear Complex Networks with Reaction-Diffusion Terms Using Fuzzy-Model-Based Approach. IEEE Trans Fuzzy Syst, 2020, : 1-1 CrossRef Google Scholar

[37] Zhu S, Liu Y, Lou Y. Stabilization of logical control networks: an event-triggered control approach. Sci China Inf Sci, 2020, 63: 112203 CrossRef Google Scholar

[38] Zhou Q, Wang W, Ma H. Event-Triggered Fuzzy Adaptive Containment Control for Nonlinear Multi-Agent Systems with Unknown Bouc-Wen Hysteresis Input. IEEE Trans Fuzzy Syst, 2019, : 1-1 CrossRef Google Scholar

[39] Wang W, Liang H, Pan Y. Prescribed Performance Adaptive Fuzzy Containment Control for Nonlinear Multiagent Systems Using Disturbance Observer. IEEE Trans Cybern, 2020, 50: 3879-3891 CrossRef Google Scholar

[40] Chen Z, Han Q L, Yan Y. How often should one update control and estimation: review of networked triggering techniques. Sci China Inf Sci, 2020, 63: 150201 CrossRef Google Scholar

[41] Su Y, Wang Q, Sun C. Self-triggered consensus control for linear multi-agent systems with input saturation. IEEE/CAA J Autom Sin, 2020, 7: 150-157 CrossRef Google Scholar

[42] Ma H, Li H Y, Lu R Q, et al. Adaptive event-triggered control for a class of nonlinear systems with periodic disturbances. Sci China Inf Sci, 2020, 63: 150212. Google Scholar

[43] Cai D, Zou H, Wang J. Event-triggered attitude tracking for rigid spacecraft. Sci China Inf Sci, 2019, 62: 222202 CrossRef Google Scholar

[44] Lyke J C. Plug-and-play satellites. IEEE Spectr, 2012, 49: 36-42 CrossRef Google Scholar

[45] Liu M, Zhang L, Shi P. Sliding mode control of continuous-time Markovian jump systems with digital data transmission. Automatica, 2017, 80: 200-209 CrossRef Google Scholar

[46] Tong S, Wang T, Li Y. Fuzzy Adaptive Actuator Failure Compensation Control of Uncertain Stochastic Nonlinear Systems With Unmodeled Dynamics. IEEE Trans Fuzzy Syst, 2014, 22: 563-574 CrossRef Google Scholar

[47] Wang L X. Stable adaptive fuzzy control of nonlinear systems. IEEE Trans Fuzzy Syst, 1993, 1: 146-155 CrossRef Google Scholar

[48] Cao X, Yue C, Liu M. Fault-tolerant sliding mode attitude tracking control for flexible spacecraft with disturbance and modeling uncertainty. Adv Mech Eng, 2017, 9: 168781401769034 CrossRef Google Scholar

[49] Gao Z, Zhu Z H. Adaptive fast sliding model attitude tracking control for flexible spacecraft. In: Proceedings of the 4th International Conference on Control Science and Systems Engineering (ICCSSE), 2018. 264--268. Google Scholar

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