Chaotic attitude synchronization and anti-synchronization of master-slave satellites using a robust fixed-time adaptive controller

被引:28
作者
Alsaade, Fawaz W. [1 ]
Yao, Qijia [2 ]
Bekiros, Stelios [3 ,4 ,5 ]
Al-zahrani, Mohammed S. [6 ]
Alzahrani, Ali S. [7 ]
Jahanshahi, Hadi [8 ]
机构
[1] King Faisal Univ, Dept Comp Sci, Coll Comp Sci & Informat Technol, Alhassa 31982, Saudi Arabia
[2] Beijing Inst Technol, Sch Aerosp Engn, Beijing 100081, Peoples R China
[3] Univ Malta, FEMA, MSD, Msida 2080, Malta
[4] London Sch Econ & Polit Sci, Dept Hlth Policy, LSE Hlth, London WC2 A2AE, England
[5] IPAG Business Sch, 184 Bd St Germain, F-75006 Paris, France
[6] King Faisal Univ, Dept Comp Networks & Commun, Coll Comp Sci & Informat Technol, Alahsa 31982, Saudi Arabia
[7] King Faisal Univ, Dept Comp Engn, Coll Comp Sci & Informat Technol, Alahsa 31982, Saudi Arabia
[8] Univ Manitoba, Dept Mech Engn, Winnipeg, MB R3T 5V6, Canada
关键词
Chaotic attitude synchronization; Chaotic attitude anti-synchronization; Master-slave satellites; Fixed-time control; Adaptive control; BACKSTEPPING SYNCHRONIZATION; SPACE MANIPULATOR; TRACKING CONTROL; SYSTEMS; STABILIZATION;
D O I
10.1016/j.chaos.2022.112883
中图分类号
O1 [数学];
学科分类号
0701 ; 070101 ;
摘要
It is well known that the satellite attitude motion exhibits the chaotic phenomenon. This article addresses the challenging problem of chaotic attitude synchronization and anti-synchronization for master-slave satellites under unknown moments of inertia and disturbance torques. First, a fixed-time adaptive synchronization controller is designed by combining the fixed-time control technique and adaptive control technique. The parametric adaptation laws are adopted to identify the unknown parameters in the synchronization error system. Benefiting from the adaptive identifications, the proposed controller is highly robust to unknown moments of inertia and disturbance torques. The practical fixed-time stability of the resulting closed-loop system is strictly achieved. The proposed controller can guarantee all error variables in the closed-loop system regulate to the small residual sets around zero in fixed time. Then, a fixed-time adaptive anti-synchronization controller is developed in a similar way. Finally, simulations studies are conducted to demonstrate the effectiveness and excellent control performance of the proposed controllers.
引用
收藏
页数:10
相关论文
共 85 条
[61]   Adaptive backstepping synchronization between chaotic systems with unknown Lipschitz constant [J].
Tu, Jianjun ;
He, Hanlin ;
Xiong, Ping .
APPLIED MATHEMATICS AND COMPUTATION, 2014, 236 :10-18
[62]   A variable-order fractional neural network: Dynamical properties, data security application, and synchronization using a novel control algorithm with a finite-time estimator [J].
Wang, Bo ;
Jahanshahi, Hadi ;
Aricioglu, Burak ;
Borue, Baris ;
Kacar, Sezgin ;
Alotaibi, Naif D. .
JOURNAL OF THE FRANKLIN INSTITUTE-ENGINEERING AND APPLIED MATHEMATICS, 2023, 360 (17) :13648-13670
[63]   Experimental validation of disturbance observer-based adaptive terminal sliding mode control subject to control input limitations for SISO and MIMO systems [J].
Wang, Bo ;
Derbeli, Mohamed ;
Barambones, Oscar ;
Yousefpour, Amin ;
Jahanshahi, Hadi ;
Bekiros, Stelios ;
Aly, Ayman A. A. ;
Alharthi, Mosleh M. M. .
EUROPEAN JOURNAL OF CONTROL, 2022, 63 :151-163
[64]   Incorporating fast and intelligent control technique into ecology: A Chebyshev neural network-based terminal sliding mode approach for fractional chaotic ecological systems [J].
Wang, Bo ;
Jahanshahi, Hadi ;
Dutta, Hemen ;
Zambrano-Serrano, Ernesto ;
Grebenyuk, Vladimir ;
Bekiros, Stelios ;
Aly, Ayman A. .
ECOLOGICAL COMPLEXITY, 2021, 47
[65]   Control of a Symmetric Chaotic Supply Chain System Using a New Fixed-Time Super-Twisting Sliding Mode Technique Subject to Control Input Limitations [J].
Wang, Bo ;
Jahanshahi, Hadi ;
Volos, Christos ;
Bekiros, Stelios ;
Yusuf, Abdullahi ;
Agarwal, Praveen ;
Aly, Ayman A. .
SYMMETRY-BASEL, 2021, 13 (07)
[66]   A New RBF Neural Network-Based Fault-Tolerant Active Control for Fractional Time-Delayed Systems [J].
Wang, Bo ;
Jahanshahi, Hadi ;
Volos, Christos ;
Bekiros, Stelios ;
Khan, Muhammad Altaf ;
Agarwal, Praveen ;
Aly, Ayman A. .
ELECTRONICS, 2021, 10 (12)
[67]   Adaptive synchronization of uncertain chaotic systems via backstepping design [J].
Wang, C ;
Ge, SS .
CHAOS SOLITONS & FRACTALS, 2001, 12 (07) :1199-1206
[68]   Finite-time chaos synchronization of unified chaotic system with uncertain parameters [J].
Wang, Hua ;
Han, Zheng-zhi ;
Xie, Qi-yue ;
Zhang, Wei .
COMMUNICATIONS IN NONLINEAR SCIENCE AND NUMERICAL SIMULATION, 2009, 14 (05) :2239-2247
[69]   Adaptive fixed-time control for Lorenz systems [J].
Wang, Huanqing ;
Yue, Hanxue ;
Liu, Siwen ;
Li, Tieshan .
NONLINEAR DYNAMICS, 2020, 102 (04) :2617-2625
[70]   Fixed-time synchronization control of memristive MAM neural networks with mixed delays and application in chaotic secure communication [J].
Wang, Weiping ;
Jia, Xiao ;
Luo, Xiong ;
Kurths, Juergen ;
Yuan, Manman .
CHAOS SOLITONS & FRACTALS, 2019, 126 :85-96