滞回非线性单作用气缸基于预测的快速力控制。

IF 6.3 2区计算机科学 Q1 AUTOMATION & CONTROL SYSTEMS

ISA transactions Pub Date : 2025-03-01 DOI:10.1016/j.isatra.2025.01.026

Hongliang Hua , Jing Zhang , Che Zhao , Zhilin Wu , Jie Song , Zhenqiang Liao

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引用次数: 0

摘要

滞回特性广泛地影响着各种工业应用中气动系统的性能和可靠性。解决这一挑战可以显著提高系统的效率和精度。考虑到单作用气缸的滞回特性，提出了一种快速准确的控制单作用气缸作动力的方法。为了实现这些目标，引入了一种基于神经网络预测的比例-积分-微分（NNP-PID）控制策略，用于快速预测和精确控制作动力。通过控制实验，阐明了所提出的NNP-PID策略的快速控制机理，并对其性能进行了评价。实验结果表明，所建立的神经网络预测模型在8位微控制器上运行的计算成本为1.22 ms，满足实时控制要求。与传统的比例-积分-微分（PID）控制器相比，NNP-PID控制器将控制超调量、上升时间、稳定时间和稳态误差分别降低了约17.5% %、65.9% %、19.8% %和46.4% %。

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Prediction-based rapid force control of a single-acting pneumatic cylinder under hysteresis nonlinearity

Hysteresis characteristics widely affects the performance and reliability of pneumatic systems across various industrial applications. Addressing this challenge can significantly enhance system efficiency and precision. This paper aims to develop a rapid and accurate method for controlling the actuating force of a Single-Acting Pneumatic Cylinder (SAPC), considering hysteresis characteristic. To achieve these objectives, a Neural-Network-Prediction-based Proportional-Integral-Differential (NNP-PID) control strategy is introduced for the rapid prediction and precise control of the actuating force. Control experiments were conducted to elucidate the rapid control mechanism of the proposed NNP-PID strategy and assess its performance. Experimental results indicate that the developed neural network prediction model operates with a computational cost of 1.22 ms on an 8-bit microcontroller, thus meeting real-time control requirements. Compared to a conventional Proportional-Integral-Differential (PID) controller, the NNP-PID controller reduced control overshoot, rise time, settling time, and steady-state error by approximately 17.5 %, 65.9 %, 19.8 %, and 46.4 %, respectively.

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来源期刊

ISA transactions 工程技术-工程：综合

CiteScore

11.70

自引率

12.30%

发文量

824

审稿时长

4.4 months

期刊介绍： ISA Transactions serves as a platform for showcasing advancements in measurement and automation, catering to both industrial practitioners and applied researchers. It covers a wide array of topics within measurement, including sensors, signal processing, data analysis, and fault detection, supported by techniques such as artificial intelligence and communication systems. Automation topics encompass control strategies, modelling, system reliability, and maintenance, alongside optimization and human-machine interaction. The journal targets research and development professionals in control systems, process instrumentation, and automation from academia and industry.