线性压电致动器的建模与控制

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS

ACS Applied Bio Materials Pub Date : 2024-01-31 DOI:10.3390/act13020055

Huaiyong Li, Yujian Tong, Chong Li

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引用次数: 0

摘要

为改善压电致动器的输出位移，提出了一种基于多级放大机构的线性压电致动器，具有体积小、推力大、分辨率高、精度高和响应速度快等特点。然而，固有的非线性特性（如滞后和蠕变）会严重影响压电致动器的输出精度，并可能导致系统不稳定。因此，我们建立了一个高度拟合的复杂非线性滞后数学模型。在反向传播神经网络中引入了 Play 算子，并使用遗传算法（GA）来降低神经网络模型拟合陷入局部最小值的概率。此外，还构建了模拟和实验测试平台。结果表明，在 150 V 的驱动电压和 1 Hz 的驱动频率下，致动器的最大位移为 558.3 μm。压电致动器的复杂 GA-BP 神经网络模型不仅建模精度高，而且解决了随机性强和收敛速度慢的问题。与其他控制算法相比，GA-BP 模糊 PID 控制的控制精度更高。

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Modeling and Control of a Linear Piezoelectric Actuator

To improve the output displacement of piezoelectric actuators, a linear piezoelectric actuator based on a multistage amplifying mechanism with a small volume, large thrust, high resolution, high precision, and fast response speed is proposed. However, inherent nonlinear characteristics, such as hysteresis and creep, significantly affect the output accuracy of piezoelectric actuators and may cause system instability. Therefore, a complex nonlinear hysteresis mathematical model with a high degree of fit was established. A Play operator was introduced into the backpropagation neural network, and a genetic algorithm (GA) was used to reduce the probability of the fitting of the neural network model falling into a local minimum. Moreover, simulation and experimental test platforms were constructed. The results showed that the maximum displacement of the actuator was 558.3 μm under a driving voltage of 150 V and a driving frequency of 1 Hz. The complex GA-BP neural network model of the piezoelectric actuator not only exhibited high modeling accuracy but also solved the problems of strong randomness and slow convergence. Compared with other control algorithms, the GA-BP fuzzy PID control exhibited higher control precision.

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来源期刊

ACS Applied Bio Materials Chemistry-Chemistry (all)

CiteScore

9.40

自引率

2.10%

发文量

464

期刊介绍： ACS Applied Bio Materials is an interdisciplinary journal publishing original research covering all aspects of biomaterials and biointerfaces including and beyond the traditional biosensing, biomedical and therapeutic applications. The journal is devoted to reports of new and original experimental and theoretical research of an applied nature that integrates knowledge in the areas of materials, engineering, physics, bioscience, and chemistry into important bio applications. The journal is specifically interested in work that addresses the relationship between structure and function and assesses the stability and degradation of materials under relevant environmental and biological conditions.