基于混沌引力搜索算法的双转子系统非线性PID控制器性能评价

J. Sivadasan, J. Roscia Jeya Shiney
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引用次数: 0

摘要

本文提出了一种新的基于混沌引力搜索算法(CGSA)的非线性PID控制方案,并通过实验室直升机模型双旋翼系统进行了验证。在这项工作中,CGSA被用作一种基于随机的全局优化算法,用于双转子系统的控制器设计。CGSA中使用的精细混沌搜索过程在迭代过程中基于当前最佳解获得最优解。本文中控制器设计的目标是稳定具有大量交叉耦合的双转子系统,以达到选定的位置并有效地遵循所需的轨迹。将非线性函数添加到PID控制器结构中可以启动更好的误差跟踪,并有助于在不断变化的输入条件下平滑输出。设计目标是实现双转子系统角位移的非线性PID控制方案,并将积分平方误差(ISE)最小化作为算法中的适应度函数。通过考虑ISE的最佳、最差、平均和标准偏差来分析控制器的统计性能。在这项工作中,考虑同时控制桨距角和偏航角,以消除两个转子之间的耦合效应。从仿真结果可以看出,所提出的工作显示出比其他进化计算技术更好的性能。结果还表明,根据TRMS330-10模型,所提出的基于CGSA的调谐对于具有标准参考轨迹的两自由度MIMO控制具有优势。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Performance evaluation of a non linear PID controller using chaotic gravitational search algorithm for a twin rotor system

Performance evaluation of a non linear PID controller using chaotic gravitational search algorithm for a twin rotor system

A novel strategy using a chaotic gravitational search algorithm (CGSA) based nonlinear PID control scheme, which is validated through a laboratory helicopter model called the twin rotor system, is presented in this paper. In this work, CGSA is used as a stochastic based global optimization algorithm for controller design in the twin rotor system adopted. The fine chaotic search process used in CGSA obtains the optimal solution in the iterative process based on the current best solution. The goal of the controller design in this paper is to stabilize the twin rotor system with considerable cross couplings to reach the selected position and follow the desired trajectory effectively. The addition of nonlinear functions to the PID controller structure initiates better error tracking and facilitates smooth output under changing input conditions. The design objective is to implement a nonlinear PID control scheme for the angular displacements of the twin rotor system with minimization of the integral square error (ISE) as the fitness function in the algorithm. The statistical performance of the controller is analyzed by considering the best, worst, mean, and standard deviations of ISE. In this work, simultaneous control of pitch and yaw angles is considered to get rid of the coupling effect between the two rotors. From the simulation results it is observed that the proposed work shows better performance than the other evolutionary computation techniques. The results also indicate the advantage of the proposed CGSA based tuning for the two degree of freedom MIMO control with standard reference trajectories as per the TRMS330-10 model.

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