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首页> 外文期刊>Mathematical Problems in Engineering >Chaos Suppression of an Electrically Actuated Microresonator Based on Fractional-Order Nonsingular Fast Terminal Sliding Mode Control
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Chaos Suppression of an Electrically Actuated Microresonator Based on Fractional-Order Nonsingular Fast Terminal Sliding Mode Control

机译:基于分数阶非奇异快速终端滑模控制的电动微谐振器的混沌抑制

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摘要

This paper focuses on chaos suppression strategy of a microresonator actuated by two symmetrical electrodes. Dynamic behavior of this system under the case where the origin is the only stable equilibrium is investigated first. Numerical simulations reveal that system may exhibit chaotic motion under certain excitation conditions. Then, bifurcation diagrams versus amplitude or frequency of AC excitation are drawn to grasp system dynamics nearby its natural frequency. Results show that the vibration is complex and may exhibit period-doubling bifurcation, chaotic motion, or dynamic pull-in instability. For the suppression of chaos, a novel control algorithm, based on an integer-order nonsingular fast terminal sliding mode and a fractional-order switching law, is proposed. Fractional Lyapunov Stability Theorem is used to guarantee the asymptotic stability of the system. Finally, numerical results with both fractional-order and integer-order control laws show that our proposed control law is effective in controlling chaos with system uncertainties and external disturbances.
机译:本文重点研究了由两个对称电极驱动的微谐振器的混沌抑制策略。首先研究在原点是唯一稳定平衡的情况下该系统的动力学行为。数值模拟表明,在某些激励条件下,系统可能表现出混沌运动。然后,绘制了关于交流激励幅度或频率的分叉图,以掌握其固有频率附近的系统动力学。结果表明,振动是复杂的,并且可能表现出倍增的分叉,混沌运动或动态拉入不稳定性。为了抑制混沌,提出了一种基于整数阶非奇异快速终端滑模和分数阶切换定律的控制算法。分数次Lyapunov稳定性定理用于保证系统的渐近稳定性。最后,分数阶和整数阶控制律的数值结果表明,我们提出的控制律对于控制具有系统不确定性和外部干扰的混沌是有效的。

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  • 来源
    《Mathematical Problems in Engineering 》 |2017年第2017期| 6564316.1-6564316.12| 共12页
  • 作者

    Han Jianxin; Zhang Qichang; Wang Wei; Jin Gang; Qi Houjun; Li Qiu;

  • 作者单位

    Tianjin Univ Technol & Educ, Tianjin Key Lab High Speed Cutting & Precis Machi, Tianjin 300222, Peoples R China;

    Tianjin Univ, Sch Mech Engn, Dept Mech, Tianjin 300072, Peoples R China|Tianjin Univ, Tianjin Key Lab Nonlinear Dynam & Control, Tianjin 300072, Peoples R China;

    Tianjin Univ, Sch Mech Engn, Dept Mech, Tianjin 300072, Peoples R China|Tianjin Univ, Tianjin Key Lab Nonlinear Dynam & Control, Tianjin 300072, Peoples R China;

    Tianjin Univ Technol & Educ, Tianjin Key Lab High Speed Cutting & Precis Machi, Tianjin 300222, Peoples R China;

    Tianjin Univ Technol & Educ, Tianjin Key Lab High Speed Cutting & Precis Machi, Tianjin 300222, Peoples R China;

    Tianjin Univ Technol & Educ, Tianjin Key Lab High Speed Cutting & Precis Machi, Tianjin 300222, Peoples R China;

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