Experimental Verification of Lead-Lag Compensators on a Twin Rotor System

IF 0.5 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC Electrical Control and Communication Engineering Pub Date : 2018-12-01 DOI:10.2478/ecce-2018-0020

Meryem Deniz, E. Tatlicioglu, Alper Bayrak

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引用次数: 2

Abstract

Abstract Twin rotor system is a laboratory setup resembling a simplified helicopter model that moves along both horizontal and vertical axes. The literature on control of twin rotor systems reflects a good amount of research on designing PID controllers and their extensions considering several aspects, as well as onsome nonlinear controllers. However, there is almost no previous work on design of lag-lead type compensators for twin rotor systems. In this study, by considering this open research problem, lag and lead type compensators are designed and then experimentally verified on the twin rotor system. Specifically, first, lag and lag-lag compensators are designed to obtain a reduced steady state error as compared with proportional controllers. Secondly, lead compensation is discussed to obtain a reduced overshoot. Finally, lag-lead compensators are designed to make use of their favorable properties. All compensators are applied to the twin rotor system in our laboratory. From experimental studies, it was observed that steady state error was reduced when a lag compensator was used in conjunction with a lead compensator.

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超前滞后补偿器在双转子系统中的实验验证

摘要双旋翼系统是一个实验室设置类似于一个简化的直升机模型，沿水平和垂直轴移动。双转子系统控制方面的文献反映了对PID控制器的设计及其从几个方面的扩展进行了大量的研究，以及对一些非线性控制器的研究。然而，对于双转子系统的滞后导联式补偿器的设计，目前尚无相关研究。本研究针对这一开放性研究问题，设计了滞后型和超前型补偿器，并在双转子系统上进行了实验验证。具体来说，首先，与比例控制器相比，滞后和滞后补偿器被设计为获得更小的稳态误差。其次，讨论了引线补偿以减小超调量。最后，设计了滞后超前补偿器，充分利用了滞后超前补偿器的优点。所有补偿器均应用于本实验室的双转子系统。从实验研究中可以观察到，当滞后补偿器与超前补偿器结合使用时，稳态误差减小。

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

Electrical Control and Communication Engineering ENGINEERING, ELECTRICAL & ELECTRONIC-

自引率

14.30%

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审稿时长

12 weeks