系统设计了多目标增强遗传算法优化的分数阶PID控制器，用于无传感器直流无刷电机驱动

IF 0.8 4区工程技术 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

Circuit World Pub Date : 2021-08-10 DOI:10.1108/cw-07-2020-0137

Vanchinathan Kumarasamy, Valluvan KarumanchettyThottam Ramasamy, Gnanavel Chinnaraj

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引用次数: 10

摘要

目的本文提出了一种基于分数阶比例积分微分（FOPID）控制器的无传感器无刷直流电机速度控制的新系统设计，该控制器采用多目标增强遗传算法（EGA）。该方案提供了良好的动态和静态响应，低计算负担，鲁棒的速度控制。设计/方法论/方法EGA是一种受元启发式启发的算法，用于解决非线性问题，如突然的负载扰动、建模误差、功率波动、稳定性差、瞬态过程的最长时间、静态和动态误差。传统遗传算法（CGA）和改进遗传算法（MGA）在解决上述问题方面不是很有效。因此，提出了一种多目标EGA优化FOPID（EGA-FOPID）控制器，用于无传感器无刷直流电机在各种条件下的速度控制，如恒载条件、变负载条件、变设定速度（Ns）条件、积分条件和控制器参数不确定性。发现该多目标EGA-FOPID控制器的系统设计是在MATLAB 2020a中使用Simulink模型实现的，用于无刷直流电机的最优速度控制。观察并评估了EGA-FOPID控制器的总体性能，包括计算负担、时间积分性能指标、瞬态和稳态特性。硬件实验结果证实，所提出的EGA-FOPID控制器能够以最小的努力精确地将无刷直流电机的转速改变到期望的范围。研究局限性/含义传统的实时问题，如非线性特性、可控性和稳定性差。实际意义很明显，在这三个智能控制器中，EGA优化的FOPID控制器通过最小化时域参数、性能指标误差和收敛时间来提高性能。同时，给出了所提出的EGA-FOPID控制器的硬件实验装置和结果。通过对上述三种智能优化算法的比较，验证了所提控制器的有效性。很明显，在这三个智能控制器中，EGA优化的FOPID控制器通过最小化时域参数、性能指标误差和收敛时间来提高性能。同时，给出了所提出的EGA-FOPID控制器的硬件实验装置和结果。

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Systematic design of multi-objective enhanced genetic algorithm optimized fractional order PID controller for sensorless brushless DC motor drive

Purpose The puspose of this paper, a novel systematic design of fractional order proportional integral derivative (FOPID) controller-based speed control of sensorless brushless DC (BLDC) motor using multi-objective enhanced genetic algorithm (EGA). This scheme provides an excellent dynamic and static response, low computational burden, the robust speed control. Design/methodology/approach The EGA is a meta-heuristic-inspired algorithm for solving non-linearity problems such as sudden load disturbances, modeling errors, power fluctuations, poor stability, the maximum time of transient processes, static and dynamic errors. The conventional genetic algorithm (CGA) and modified genetic algorithm (MGA) are not very effective in solving the above-mentioned problems. Hence, a multi-objective EGA optimized FOPID (EGA-FOPID) controller is proposed for speed control of sensorless BLDC motor under various conditions such as constant load conditions, varying load conditions, varying set speed (Ns) conditions, integrated conditions and controller parameters uncertainty. Findings This systematic design of the multi-objective EGA-FOPID controller is implemented in MATLAB 2020a with Simulink models for optimal speed control of the BLDC motor. The overall performance of the EGA-FOPID controller is observed and evaluated for computational burden, time integral performance indexes, transient and steady-state characteristics. The hardware experiment results confirm that the proposed EGA-FOPID controller can precisely change the BLDC motor speed is desired range with minimal effort. Research limitations/implications The conventional real time issues such as nonlinearity characteristics, poor controllability and stability. Practical implications It is clearly evident that out of these three intelligent controllers, the EGA optimized FOPID controller gives enhanced performance by minimizing the time domain parameters, performance Indices error and convergence time. Also, the hardware experimental setup and the results of the proposed EGA-FOPID controller are presented. Originality/value It shows the effectiveness of the proposed controllers is completely verified by comparing the above three intelligent optimization algorithms. It is clearly evident that out of these three intelligent controllers, the EGA optimized FOPID controller gives enhanced performance by minimizing the time domain parameters, performance Indices error and convergence time. Also, the hardware experimental setup and the results of the proposed EGA-FOPID controller are presented.

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来源期刊

Circuit World 工程技术-材料科学：综合

CiteScore

2.60

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Circuit World is a platform for state of the art, technical papers and editorials in the areas of electronics circuit, component, assembly, and product design, manufacture, test, and use, including quality, reliability and safety. The journal comprises the multidisciplinary study of the various theories, methodologies, technologies, processes and applications relating to todays and future electronics. Circuit World provides a comprehensive and authoritative information source for research, application and current awareness purposes. Circuit World covers a broad range of topics, including: • Circuit theory, design methodology, analysis and simulation • Digital, analog, microwave and optoelectronic integrated circuits • Semiconductors, passives, connectors and sensors • Electronic packaging of components, assemblies and products • PCB design technologies and processes (controlled impedance, high-speed PCBs, laminates and lamination, laser processes and drilling, moulded interconnect devices, multilayer boards, optical PCBs, single- and double-sided boards, soldering and solderable finishes) • Design for X (including manufacturability, quality, reliability, maintainability, sustainment, safety, reuse, disposal) • Internet of Things (IoT).