Competent and uncomplicated PID control algorithm design expressions for controlling second order systems

Mohamed S. Soliman
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Abstract

Proportional-integral-derivative (PID) control algorithm with its various forms, namely P (proportional), PI (proportional-integral), PD (proportional-derivative), PID, and compensators, is considered the most applied and widely used control algorithms in industry; this is because of its simple construction, robustness and capabilities to achieve desired control over plant performance. Designing PID algorithm is accomplished with a compromise to result in an overall system responds with acceptable levels of stability, response fastness, smoothness and costs. Various PID design methodologies and expressions have been introduced in text and literature,each has its advantages, disadvantages and limitations. In the present work, a new, efficient, simple, easy to apply and linear expressions for PID algorithmP-. PI, PD, and PID modes design are derived and presented. Expressions are derived based on relating parameters of both controller and plant. The expressions are intended to control the behavior of second order systems and approximated as such systems, such that it responds with acceptable stability level, minimum possible overshoot, oscillations and steady state error. To further improve the resulted response, only one tuning parameter α, is introduced To test, analyze, and evaluate the design expressions, MATLAB/Simulink software was used. A simulation model was built by integrating the next sub-models; PID control algorithm modes, drive with limitation and saturation blocks, sensor, desired output signal generator and finally various forms of second order systems. The simulation model was developed and refined to be as close as possible to real life conditions and processing. Studying the recorded testing, graphical and numerical results show that the suggested expressions are being simple and easy to apply, and also efficient in providing better control over controlled system’s behavior in terms of response measures and performance indices.Moreover, expressions are efficient to speed up response and eliminate or reduce overshoot, rise time and settling time. Studying results show that, the overall system responds with acceptable fast response, in most cases without overshoot, oscillation and with minimum steady state error and better ISE and IAE indices values.
二阶系统的有效且简单的PID控制算法设计表达式
比例-积分-导数(PID)控制算法有多种形式,即P(比例)、PI(比例-积分)、PD(比例-导数)、PID和补偿器,被认为是工业中应用最多、应用最广泛的控制算法;这是因为其结构简单,坚固耐用,并且能够实现对工厂性能的预期控制。PID算法的设计是通过妥协来完成的,从而使整个系统的响应具有可接受的稳定性、响应速度、平滑度和成本水平。各种PID设计方法和表达在文本和文献中都有介绍,每种方法都有其优点,缺点和局限性。本文提出了一种新的、高效、简单、易于应用和线性表达的PID算法。推导并给出了PI、PD和PID模式的设计。根据控制器和对象的相关参数推导了表达式。这些表达式旨在控制二阶系统的行为,并近似为这样的系统,使其响应具有可接受的稳定水平,最小可能的超调,振荡和稳态误差。为了进一步改善结果的响应,只引入一个调谐参数α,使用MATLAB/Simulink软件对设计表达式进行测试、分析和评价。通过对各子模型的整合,建立仿真模型;PID控制算法模式,带限制和饱和块驱动,传感器,期望输出信号发生器,最后是各种形式的二阶系统。仿真模型的发展和完善,以尽可能接近真实的生活条件和处理。通过对试验记录的研究,图形和数值结果表明,所提出的表达式简单、易于应用,并且在响应度量和性能指标方面能够更好地控制被控系统的行为。此外,表达式可以有效地加快响应速度,消除或减少超调、上升时间和沉降时间。研究结果表明,系统整体响应速度快,大多数情况下无超调、振荡,稳态误差最小,ISE和IAE指标值较好。
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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