Yongsu Kong scite author profile

This paper presents an approach to design a delay-dependent non-fragile H ∞ /L 2 -L ∞ static output feedback (SOF) controller for active suspension with input time-delay. The control problem of quartercar active suspension with actuator time-delay is formulated to a H ∞ /L 2 -L ∞ control problem. By employing a delay-dependent Lyapunov function, new existence conditions of delay-dependent nonfragile SOF H ∞ controller and L 2 -L ∞ controller are derived, respectively, in terms of the feasibility of bilinear matrix inequalities (BMIs). Then, a procedure based on linear matrix inequality optimisation and a hybrid algorithm of the particle swarm optimisation and differential evolution is used to solve an optimisation problem with BMI constraints. Design and simulation results of non-fragile H ∞ /L 2 -L ∞ controller for active suspension show that the designed controller not only can achieve the optimal performance and stability of the closed-loop system in spite of the existence of the actuator time-delay, but also has significantly improved the non-fragility characteristics over controller perturbations.

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Robust non‐fragile H_∞ ∕ L₂ − L_∞control of uncertain linear system with time‐delay and application to vehicle active suspension

Kong

Zhao

Yang

et al. 2014

Intl J Robust & Nonlinear

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SummaryThis paper presents an approach to design robust non‐fragile H ∞ ∕ L2 − L ∞ static output feedback controller, considering actuator time‐delay and the controller gain variations, and it is applied to design vehicle active suspension. According to suspension design requirements, the H ∞ and L2 − L ∞ norms are used, respectively, to reflect ride comfort and time‐domain hard constraints. By employing a delay‐dependent Lyapunov function, existence conditions of delay‐dependent robust non‐fragile static output feedback H ∞ controller and L2 − L ∞ controller are derived, respectively, in terms of the feasibility of bilinear matrix inequalities. Then, a new procedure based on LMI optimization and a hybrid algorithm of the particle swarm optimization and differential evolution is used to solve an optimization problem with bilinear matrix inequality constraints. Simulation results show that the designed active suspension system still can guarantee their own performance in spite of the existence of the model uncertainties, the actuator time‐delay and the controller gain variations. Copyright © 2014 John Wiley & Sons, Ltd.

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Static output feedback control for active suspension using PSO-DE/LMI approach

Kong

Zhao

Yang

et al. 2012

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Tracking control of ball and plate system using a improved PSO on-line training PID neural network

Han

Tian

Kong

et al. 2012

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Robust PID optimal tuning of a Delta parallel robot based on a hybrid optimization algorithm of particle swarm optimization and differential evolution

Pak¹,

Kong²,

Ri³

2022

Robotica

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In this paper, we propose an approach to tune optimal parameters of a robust PID controller by means of computed torque control (CTC) strategy for trajectory tracking of a Delta parallel robot, using a hybrid optimization algorithm of Particle Swarm Optimization (PSO) and differential evolution (DE). It differs from previous works that they propose robust PID controller parameters tuning based on conventional gradient-based optimization algorithms and apply them to process control. First, we reduce the tuning problem of a robust PID controller with CTC strategy satisfying requirements including robustness and disturbance attenuation to an optimization problem with nonlinear constraints by considering the nonlinear dynamic model of a Delta parallel robot. Second, we set up the design characteristics for the trajectory tracking of a Delta parallel robot. Then, we propose a robust PID controller in a way of obtaining the global optimization solution of the nonlinear optimization problem by running a PSO-DE hybrid optimization algorithm of finding the global optimal solution by maintaining the diversity of swarm during evolution based on the evolution of cognitive experience. Simulation and experimental results demonstrate that the proposed controller outperforms previous works with respect to robust performance and active disturbance attenuation when it is applied to tracking control of a Delta parallel robot.

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Yongsu Kong

Non-fragile multi-objective static output feedback control of vehicle active suspension with time-delay

Robust non‐fragile H_∞ ∕ L₂ − L_∞control of uncertain linear system with time‐delay and application to vehicle active suspension

Static output feedback control for active suspension using PSO-DE/LMI approach

Tracking control of ball and plate system using a improved PSO on-line training PID neural network

Robust PID optimal tuning of a Delta parallel robot based on a hybrid optimization algorithm of particle swarm optimization and differential evolution

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Yongsu Kong

Non-fragile multi-objective static output feedback control of vehicle active suspension with time-delay

Robust non‐fragile H ∞ ∕ L2 − L ∞ control of uncertain linear system with time‐delay and application to vehicle active suspension

Static output feedback control for active suspension using PSO-DE/LMI approach

Tracking control of ball and plate system using a improved PSO on-line training PID neural network

Robust PID optimal tuning of a Delta parallel robot based on a hybrid optimization algorithm of particle swarm optimization and differential evolution

Contact Info

Product

Resources

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Robust non‐fragile H_∞ ∕ L₂ − L_∞control of uncertain linear system with time‐delay and application to vehicle active suspension