Adaptive Inverse Controller Design Based on the Fuzzy C-Regression Model (FCRM) and Back Propagation (BP) Algorithm

Information-An International Interdisciplinary Journal Pub Date : 2019-11-29 DOI:10.3390/INFO10120377

Shixiang Zhong

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引用次数: 1

Abstract

Establishing an accurate inverse model is a key problem in the design of adaptive inverse controllers. Most real objects have nonlinear characteristics, so mathematical expression of an inverse model cannot be obtained in most situation. A Takagi–Sugeno(T-S)fuzzy model can approximate real objects with high precision, and is often applied in the modeling of nonlinear systems. Since the consequent parameters of T-S fuzzy models are linear expressions, this paper firstly uses a fuzzy c-regression model (FCRM) clustering algorithm to establish inverse fuzzy model. As the least mean square (LMS) algorithm is only used to adjust consequent parameters of the T-S fuzzy model in the process of parameter adjustment, the premise parameters are fixed and unchanged in the process of adjustment. In this paper, the back propagation (BP) algorithm is applied to adjust the premise and consequent parameters of the T-S fuzzy model, simultaneously online. The simulation results show that the error between the system output controlled by proposed adaptive inverse controller and the desired output is smaller, also the system stability can be maintained when the system output has disturbances.

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基于模糊c回归模型(FCRM)和反向传播(BP)算法的自适应逆控制器设计

建立精确的逆模型是自适应逆控制器设计中的关键问题。大多数实际物体都具有非线性特性，因此在大多数情况下无法得到逆模型的数学表达式。Takagi-Sugeno (T-S)模糊模型能以较高的精度逼近真实物体，常用于非线性系统的建模。由于T-S模糊模型的后续参数为线性表达式，本文首先采用模糊c回归模型(FCRM)聚类算法建立逆模糊模型。由于在参数调整过程中仅使用最小均方算法对T-S模糊模型的后续参数进行调整，因此在调整过程中前提参数是固定不变的。本文采用反向传播(BP)算法对T-S模糊模型的前提参数和后续参数进行在线同步调整。仿真结果表明，所提出的自适应逆控制器控制的系统输出与期望输出之间的误差较小，且在系统输出存在扰动时仍能保持系统的稳定性。

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Information-An International Interdisciplinary Journal 工程技术-工程：综合

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审稿时长

8.3 months