Design of Discrete and Hybrid Nonlinear Control Systems

Q4 Engineering
A. R. Gaiduk
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引用次数: 0

Abstract

In this article the new method of discrete control systems design for nonlinear plants with differentiable nonlinearities is suggested. The increasing demands on the quality of control processes and the widespread use of computer technology provide ample opportunities for the design and implementation of digital control systems. However, discrete models of control plants are needed to solve this problem. In the case of linear plants, such models are created on the basis of z-transformation, Euler or Tustin formulas. In the case of nonlinear plants, these transformations are not applicable, so a large number of approximate discretization methods have been developed to date. Euler and Runge-Kutt transformations are used for these purposes most often, but they lead to satisfactory results only with very small period of discretization. In the case of automatic control systems, this requires the use of digital automation tools with very high speed, which is often economically impractical. Methods of discretization with a long period were most often developed on the basis of decomposition into series of the right-hand sides of the differential equations, transformed on Euler. Here, firstly, the problem of selecting the number of the series members, which to be retained arises, and secondly, already in the third or fourth order of the plant, the calculating ratios turn out to be extremely complex. The discretization method suggested below differs in that it is not the equations of nonlinear plants in the Cauchy form that are discretized, but the corresponding quasilinear model. In this case, a modified trapezoid method is used, and the discretization purpose is not the most accurate approximation of the original equations of the plant, but the stability of a closed nonlinear control system with rather big period. This system is designed using the algebraic polynomial-matrix method for designing of the nonlinear control systems. As a result, a hybrid nonlinear system with fairly simple algebraic calculation expressions is formed. The suggested approach makes it possible to create the control systems for nonlinear controlled plants using conventional computational automation tools.
离散和混合非线性控制系统的设计
本文提出了具有可微非线性的非线性对象的离散控制系统设计的新方法。对控制过程质量要求的不断提高和计算机技术的广泛应用为数字控制系统的设计和实施提供了充分的机会。然而,为了解决这一问题,需要离散控制对象模型。在线性工厂的情况下,这样的模型是基于z变换,欧拉或Tustin公式创建的。在非线性对象的情况下,这些变换是不适用的,所以大量的近似离散化方法已经发展到今天。欧拉和龙格-库特变换最常用于这些目的,但它们只能在很小的离散周期内得到令人满意的结果。在自动控制系统的情况下,这需要使用速度非常快的数字自动化工具,这在经济上通常是不切实际的。长周期的离散化方法通常是在微分方程的右边分解成一系列的基础上发展起来的,在欧拉变换上。在这里,首先,产生了选择要保留的系列成员数目的问题;其次,已经在工厂的第三或第四阶,计算比率变得极其复杂。下面提出的离散化方法的不同之处在于不是将柯西形式的非线性植物方程离散化,而是将相应的拟线性模型离散化。在这种情况下,采用了一种改进的梯形法,离散化的目的不是最精确地逼近被控对象的原方程,而是保证一个周期较大的非线性封闭控制系统的稳定性。本系统采用非线性控制系统设计的代数多项式矩阵法进行设计。从而形成了一个代数计算表达式相当简单的混合非线性系统。所提出的方法使得使用传统的计算自动化工具创建非线性被控对象的控制系统成为可能。
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
Mekhatronika, Avtomatizatsiya, Upravlenie
Mekhatronika, Avtomatizatsiya, Upravlenie Engineering-Electrical and Electronic Engineering
CiteScore
0.90
自引率
0.00%
发文量
68
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