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编队卫星分布式鲁棒饱和姿态协同控制 被引量:3

Decentralized Robust Saturated Attitude Coordination Control of Satellites Within Formation
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摘要 研究跟踪时变参考姿态情况下控制输入饱和的编队飞行卫星姿态协同控制问题。针对不同情形,通过恰当地利用双曲正切函数,提出3种连续有界的协同控制器。首先,在无外部扰动和参数不确定性的情况下,提出一种理想的饱和协同控制器。进一步,考虑角速度不可测量的情况,利用无源滤波器设计无角速度反馈的饱和协同控制器。当外部扰动和参数不确定性存在时,通过在双曲正切函数中引入动态时变参数,提出一种连续的鲁棒饱和协同控制器。由于在本文算法作用下的闭环协同系统是非自治的,通过合理地利用Barbalat引理分析了状态的收敛性。仿真结果表明了所提控制方案的有效性。 The attitude coordination control problem for formation flying satellites associated with time-varying reference attitude tracking subject to control input saturation is investigated in this paper. According to different cases, three kinds of continuous and bounded coordination controllers are proposed with the novel use of hyperbolic tangent functions. Firstly, an ideal saturated coordination controller is presented in the absence of external disturbances and parametric uncertainty. Furthermore, taking account of unavailability of measurements of angular velocities, passive filters are applied to the angularvelocity-free feedback saturated coordination controller design. When external disturbances and parametric uncertainty exist, by introducing some dynamic time-varying parameters in the hyperbolic tangent functions, a continuous robust saturated coordination controller is proposed. Due to the fact that the closed-loop coordination systems under these algorithms are nonautonomous, Barbalat's lemma is utilized properly for convergence analysis of states. Simulation results are provided to show the effectiveness of the proposed control schemes.
作者 张保群 宋申民 陈兴林
机构地区 哈尔滨工业大学控制理论与制导技术研究中心
出处 《航空学报》 EI CAS CSCD 北大核心 2011年第9期1644-1655,共12页 Acta Aeronautica et Astronautica Sinica
基金 国家"863"计划~~
关键词 编队飞行 姿态协同 控制输入饱和 无角速度反馈 鲁棒控制 formation flying attitude coordination control input saturation angular-velocity-free feedback robust control
分类号 V448.2 [航空宇航科学与技术—飞行器设计]
  • 相关文献

参考文献16

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二级参考文献21

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共引文献16

同被引文献28

  • 1Shahravi M, Kabganian M. Attitude tracking and vibra- tion of suppression of flexible spacecraft using implicit adaptive control law. Proceedings of the 2005 American Control Conference, 2005: 913-918.
  • 2Boskovic J D, Li S M, Mehra R K. Robust adaptive varia- ble structure control of spacecraft under control input sat- uration. Journal of Guidance, Control, and Dynamics, Z001, 24(1): 14 22.
  • 3Boskovic J D, Li S M, Mehra R K. Robust tracking con- trol design for spacecraft under control input saturation. Journal of Guidance, Control, and Dynamics, 2004, 27 (4) = 627-633.
  • 4I.u K F, Xia Y Q, Zhu Z, et al. Sliding mode attitude tracking of rigid spacecraft with disturbances. Journal of the Fracklin Institute, 2012, 349(2): 413 440.
  • 5Delavari H, Ghaderi R, Ranjbar A, et al. Fuzzy fractional order sliding mode controller for nonlinear systems. Com- munications in Nonlinear Science and Numerical Simula- tion, 2010, 15(4): 963 978.
  • 6Zhang B T, Pi Y G, Luo Y. control based on parameters Fractional order sliding-mode auto-tuning for velocity con- trol of permanent magnet synchronous motor. ISA Trans actions, 2012, 51(5) 649 656.
  • 7Efe M O, Kasnakoglu C. A fractional adaptation law for sliding mode control. International Journal of Adaptive Control and Signal Processing, 2008, 22(10): 968-986.
  • 8Ere M O. A sufficient condition for checking the attrac- tiveness of a sliding manifold in fractional order sliding mode control. Asian Journal of Control, 2012, 14 (4) .- 1118 1122.
  • 9Dadras S, Momeni H R. Fractional terminal sliding mode control design for a class of dynamical systems with uncer- tainty. Communications in Nonlinear Science and Numeri- cal Simulation, 2012, 17(1) 367-377.
  • 10Chen D Y, Zhang R F, Sprott J C, et al. Synchronization between integer-order chaotic systems and a class of [fac- tional-order chaotic systems via sliding mode control. Choas, 2012, 22(2)= 023130(1-9).

引证文献3

二级引证文献32

航空学报
2011年 第9期

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