Multicriteria Parametric Optimization of Nonlinear Robust Control with Two Degrees of Freedom by a Discrete-Continuous Plant

Q4 Engineering

Journal of Mechanical Engineering Pub Date : 2023-09-30 DOI:10.15407/pmach2023.03.042

Borys I. Kuznetsov, Ihor V. Bovdui, Olena V. Voloshko, Tetyana B. Nikitina, Borys B. Kobylianskyi

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引用次数: 0

Abstract

A multicriteria parametric optimization of nonlinear robust control with two degrees of freedom by a discrete-continuous plant has been developed to increase accuracy and reduce sensitivity to uncertain plant parameters. Such plants are mounted on a moving base, on which sensors for angles, angular velocities and angular accelerations are installed. To increase the accuracy of control, systems with two degrees of freedom, which include control with feedback and a closed-loop, and with direct connections and open-loop control of the setting and disturbing effects, are used. The multicriteria optimization of nonlinear robust control with two degrees of freedom by a discrete-continuous plant is reduced to the solution of the Hamilton-Jacobi-Isaacs equations. The robust control target vector is calculated as a solution of a zero-sum antagonistic vector game. The vector payoffs of this game are direct indexes performance vector presented in the system in different modes of its operation. The calculation of the vector payoffs of this game is related to the simulation of the synthesized nonlinear system for different operating modes of the system, input signals and values of the plant parameters. The solutions of this vector game are calculated on the basis of the system of Pareto-optimal solutions, taking into account the binary relations of preferences, on the basis of the stochastic metaheuristic of Archimedes optimization algorithm by several swarms. Thanks to the synthesis of nonlinear robust control with two degrees of freedom by a discrete-continuous object, it is shown that the use of synthesized controllers made it possible to increase the accuracy of control of an electromechanical system with distributed parameters of the mechanical part to reduce the time of transient processes by 1.5–2 times, reduce dispersion of errors by 1.3 times and reduce the sensitivity of the system to changes in the plant parameters in comparison with typical controllers used in existing systems. Further improvement of control accuracy is restrained by energy limitations of executive mechanisms and information limitations of measuring devices.

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离散连续对象二自由度非线性鲁棒控制的多准则参数优化

为了提高控制精度，降低对不确定对象参数的敏感性，提出了一种离散连续对象二自由度非线性鲁棒控制的多准则参数优化方法。这种装置安装在一个移动的基座上，基座上安装了测量角度、角速度和角加速度的传感器。为了提高控制的精度，采用了两自由度系统，包括反馈控制和闭环控制，以及直接连接和开环控制的整定和扰动效应。将离散连续对象的二自由度非线性鲁棒控制多准则优化问题简化为Hamilton-Jacobi-Isaacs方程的求解。鲁棒控制目标向量是一个零和对抗向量博弈的解。该博弈的收益向量是系统在不同运行模式下表现出来的直接指标性能向量。该博弈的矢量收益计算涉及到对系统不同运行模式、输入信号和电厂参数值的综合非线性系统进行仿真。该矢量对策的解是在pareto最优解系统的基础上，考虑到二元偏好关系，在阿基米德优化算法的随机元启发式的基础上计算的。通过对离散连续对象的二自由度非线性鲁棒控制的综合，表明综合控制器的使用可以提高机械部分参数分布的机电系统的控制精度，将瞬态过程的时间缩短1.5-2倍。与现有系统中使用的典型控制器相比，将误差分散减少1.3倍，并降低系统对工厂参数变化的灵敏度。控制精度的进一步提高受到执行机构能量限制和测量装置信息限制的制约。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Mechanical Engineering Engineering-Mechanical Engineering

CiteScore

1.00

自引率

0.00%

发文量

审稿时长

16 weeks

期刊介绍： Journal of Mechanical Engineering (formerly known as Journal of Faculty of Mechanical Engineering) or JMechE, is an international journal which provides a forum for researchers and academicians worldwide to publish the research findings and the educational methods they are engaged in. This Journal acts as a link for the mechanical engineering community for rapid dissemination of their academic pursuits. The journal is published twice a year, in June and December, which discusses the progress of Mechanical Engineering advancement.