一阶时滞系统控制的简单有效的PID算法设计方法

Mohamed S. Soliman
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引用次数: 0

摘要

工业中的许多过程具有延迟时间或称为滞后行为的缓慢非周期动态特征。此外,工业中的许多工厂都是由近似于低阶系统的高阶系统在数学上描述的,最常见的是,这些过程和系统在数学上被描述为一阶时滞系统(FOSTD),也称为一阶加死时间(FOPDT)。时间延迟的存在会导致性能的降低和限制,而且还会导致不稳定。在这种情况下,反馈控制算法的设计成为一项困难而繁琐的任务。本文提出了一种高效、简单、线性且易于应用的设计表达式,用于设计连续PID(比例-积分-导数)控制算法模式,以控制FOPDT系统的行为。设计表达式旨在克服时滞的负面影响,简化控制算法的设计过程,帮助设计者以简单易行的方式使系统稳定、响应速度中等、无超调、振荡和误差或误差最小。为了测试和评估推导表达式的正确性、适用性和效率,应用MATLAB/Simulink软件开发了精细化的软件仿真模型,模拟真实生活值,并返回评估过程所需的最大数值和图形数据。此外,仿真模型中还使用了各种FOSTD系统的类型和形式,特别是具有小、中、大时间常数、直流增益和时间延迟的系统、不稳定系统、变延迟系统。此外,为了评估建议设计表达式的效率,将结果与两种设计方法应用时的结果进行了比较;世界知名的齐格勒尼科尔斯方法和MATLAB/Simulink自调谐PID块。数值和图形测试结果分析表明,应用所提表达式设计的控制算法,不仅可以简化设计过程,而且可以有效地使系统处于控制状态,提高控制系统的性能,加快响应速度,减少超调量,使误差最小,还可以稳定不稳定的对象。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Simple and efficient PID algorithm design method for controlling first order systems with a time delay
Many processes in industry are characterized by delay time or by slow aperiodic dynamics called lag behavior. In addition, many plants in the industry are described mathematically by higher order systems that are approximated with the lower order systems, most frequently such processes and systems are described mathematically as first-order-systems-with time-delay (FOSTD), also called first-order-plus-dead-time (FOPDT). The presence of time delays causes degradation and limitation of achieving desired performance, moreover, it can induce instability. In such cases, design of feedback control algorithm becomes difficult and tedious task. The present work suggests an efficient, simple, linear, and easy to apply design expressions for designing continuous PID (proportional-integral-derivative) control algorithm modes to control the behavior of FOPDT systems. The design expressions are intended to overcome negative effects of time delay presence, as well as, to simplify the control algorithm design process and help designer, in easy and simple way, to get system under control with acceptable system stability, medium fastness of response and without or with minimum possible overshoot, oscillation and error. For testing and evaluating the correctness, applicability and efficiency of the derived expressions, MATLAB/Simulink software was applied to develop refined software simulation model that simulates real life values and returns maximum needed numerical and graphical data for assessment process. In addition, various FOSTD systems’ types and forms were used in the simulation model, in particular, systems with small, medium and large time constants, DC gains, and time delay, unstable systems, systems with variable delay. Furthermore, to assess the efficiency of suggested design expressions, the resulted overall system response were compared with resulted responses when two design methods were applied; worldwide known Ziegler Nichols method and MATLAB/Simulink auto-tuned PID block. Analysis of numerical and graphical testing results, show that, The designed control algorithm applying the suggested expressions can, not only simplify the design process, but also, efficient for successful in getting system under control and improving controlling system performance, speeding up response, reduce overshoot, and minimize error, but also stabilize an unstable plants.
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