Multi-Objective Optimal Design of a PID Sliding Mode Controller With Three Different Reaching Laws

IF 1 Q4 AUTOMATION & CONTROL SYSTEMS

Mechatronic Systems and Control Pub Date : 2019-11-26 DOI:10.1115/dscc2019-8990

Xiaotian Xu, Y. Sardahi, Almuatazbellah M. Boker

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引用次数: 1

Abstract

Sliding mode controllers (SMCs) are well-known nonlinear control techniques. The design of a SMC involves the selection of a sliding mode surface and reaching law. The constant, exponential, and power rate reaching laws are the most widely used. Selecting a reaching law is often based on the desired reaching time; that is how fast the state trajectory approaches the switching manifold. However, the selection of a reaching law does not only affect the reaching time (tr) but also other design specifications such as the settling time (ts), overshoot (Mp), and tracking error (JIAE). Indeed, the design of a closed-loop system usually involves multiple and often conflicting objectives. Therefore, a multi-objective optimal design approach that takes into consideration all the design requirements should be adopted. Furthermore, a systematic study is needed to evaluate and compare the performance of a SMC controller under these reaching laws in multi-objective settings. To this end, the problems of designing a PID (Proportional-Integral-Derivative) sliding mode controller applied to linear and nonlinear dynamic systems using the three reaching laws are formulated as multi-objective optimization problems (MOPs). The objective space includes tr, Mp, ts, and JIAE and the parameter space consists of the design gains of the reaching laws and the sliding mode surface. The non-dominated sorting genetic algorithm (NSGA – II) is used to solve the optimization problem. The solution of the MOP is a Pareto front of optimal design points. Therefore, comparing three Pareto fronts is not a straightforward task. As a result, sections of the Pareto fronts that satisfy some legitimate constraints on the objective space are extracted. Then, a comparison among these sections is conducted graphically. The results show that the exponential rate reaching law outperforms the other two laws in most of the objectives under investigation.

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三种不同趋近律的PID滑模控制器的多目标优化设计

滑模控制器(SMCs)是众所周知的非线性控制技术。滑模控制器的设计涉及滑模曲面的选择和逼近律的选择。常数定律、指数定律和功率趋近定律是最广泛使用的。选择到达法通常是基于期望的到达时间;这就是状态轨迹接近开关流形的速度。然而，趋近律的选择不仅会影响趋近时间(tr)，还会影响其他设计指标，如沉降时间(ts)、超调量(Mp)和跟踪误差(JIAE)。实际上，闭环系统的设计通常涉及多个且经常相互冲突的目标。因此，应采用兼顾所有设计要求的多目标优化设计方法。此外，还需要进行系统的研究来评估和比较多目标环境下这些趋近律下SMC控制器的性能。为此，利用三个趋近律设计适用于线性和非线性动态系统的PID(比例-积分-导数)滑模控制器的问题被表述为多目标优化问题(MOPs)。目标空间包括tr、Mp、ts和JIAE，参数空间由趋近律和滑模曲面的设计增益组成。采用非支配排序遗传算法(NSGA - II)求解优化问题。MOP的解是Pareto前沿的最优设计点。因此，比较三个帕累托前沿并不是一项简单的任务。因此，在客观空间中满足某些合法约束的帕累托前沿部分被提取出来。然后，对这些部分进行图形化比较。结果表明，在大多数研究目标中，指数趋近律优于其他两种定律。

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来源期刊

Mechatronic Systems and Control AUTOMATION & CONTROL SYSTEMS-

CiteScore

1.40

自引率

66.70%

发文量

期刊介绍： This international journal publishes both theoretical and application-oriented papers on various aspects of mechatronic systems, modelling, design, conventional and intelligent control, and intelligent systems. Application areas of mechatronics may include robotics, transportation, energy systems, manufacturing, sensors, actuators, and automation. Techniques of artificial intelligence may include soft computing (fuzzy logic, neural networks, genetic algorithms/evolutionary computing, probabilistic methods, etc.). Techniques may cover frequency and time domains, linear and nonlinear systems, and deterministic and stochastic processes. Hybrid techniques of mechatronics that combine conventional and intelligent methods are also included. First published in 1972, this journal originated with an emphasis on conventional control systems and computer-based applications. Subsequently, with rapid advances in the field and in view of the widespread interest and application of soft computing in control systems, this latter aspect was integrated into the journal. Now the area of mechatronics is included as the main focus. A unique feature of the journal is its pioneering role in bridging the gap between conventional systems and intelligent systems, with an equal emphasis on theory and practical applications, including system modelling, design and instrumentation. It appears four times per year.