A Neural Hysteresis Model for Smart-Materials-Based Actuators

机译：基于智能材料的执行器的神经滞后模型

获取原文

页面导航

摘要
著录项
相似文献
相关主题

摘要

In this paper, a constraint factor (CF) is presented. The CF and an odd m-order polynomial form a new hysteretic operator (HO) together. And then, an expanded input space is constructed based on the proposed HO. In the expanded input and output spaces, the one-to-multiple mapping of hysteresis is transformed into a one-to-one mapping so that a neural network can be used to develop a neural hysteresis model. The model parameters are computed by using the least square method. Finally, the neural hysteresis model is employed to approximate a real data from a magnetostrictive actuator in an experiment. The experimental results demonstrate the proposed approach is effective.

机译：在本文中，提出了一个约束因子（CF）。 CF和奇数阶m多项式一起形成一个新的滞后算子（HO）。然后，基于提出的HO构造扩展的输入空间。在扩展的输入和输出空间中，将磁滞的一对多映射转换为一对一映射，以便可以使用神经网络来开发神经磁滞模型。通过使用最小二乘法计算模型参数。最后，在实验中，采用神经滞后模型来估算来自磁致伸缩执行器的真实数据。实验结果表明该方法是有效的。

著录项

来源
《International conference on intelligent robotics and applications》|2016年|663-671|共9页
会议地点
作者
Yu Shen; Lianwei Ma; Jinrong Li; Xiuyu Zhang; Xinlong Zhao; Hui Zheng;
展开▼
作者单位

展开▼
会议组织
原文格式 PDF
正文语种
中图分类
关键词
Hysteresis; Hysteretic operator (HO); Constraint factor (CF); Smart materials; Neural networks;

机译：磁滞磁滞算子（HO）;约束因子（CF）;智能材料;神经网络;

相似文献

外文文献
中文文献
专利

1. Neural networks dynamic hysteresis model for piezoceramic actuator based on hysteresis operator of first-order differential equation [J] . Dang XJ, Tan YH Physica, B. Condensed Matter . 2005,第1a4期

机译：基于一阶微分方程滞后算子的压电陶瓷执行器神经网络动态滞后模型
2. Hysteresis modeling and tracking control for piezoelectric stack actuators using neural-Preisach model [J] . Chen Yuansheng, Huang Qinbin, Wang Hao, International journal of applied electromagnetics and mechanics . 2019,第3期

机译：用神经预震模型压电叠层执行器的滞后模型及跟踪控制
3. Neural network hysteresis modeling with an improved Preisach model for piezoelectric actuators [J] . Weiping Guo, Diantong Liu, Wei Wang Engineering Computations . 2012,第3a4期

机译：改进的Preisach模型用于压电执行器的神经网络滞后建模
4. A Neural Hysteresis Model for Smart-Materials-Based Actuators [C] . Yu Shen, Lianwei Ma, Jinrong Li, International Conference on Intelligent Robotics and Applications . 2016

机译：基于智能材料的执行器的神经滞后模型
5. Generalized Prandtl-Ishlinskii hysteresis model and its analytical inverse for compensation of hysteresis in smart actuators. [D] . Al Janaideh, Mohammed. 2009

机译：广义Prandtl-Ishlinskii滞后模型及其解析逆，用于补偿智能执行器中的滞后。
6. Modeling and Compensation for Asymmetrical and Dynamic Hysteresis of Piezoelectric Actuators Using a Dynamic Delay Prandtl–Ishlinskii Model [O] . Wen Wang, Fuming Han, Zhanfeng Chen, 2021

机译：使用动态延迟普兰特-Ishlinskii模型的压电执行器不对称和动态滞后的建模与补偿
7. Modeling and Identification of Rate Dependent Hysteresis in Piezoelectric Actuated Nano-Stage: A Gray Box Neural Network Based Approach [O] . Khubab Ahmed, Peng Yan 2021

机译：压电驱动纳米级速率依赖滞后的建模与识别：基于灰盒神经网络的方法

A Neural Hysteresis Model for Smart-Materials-Based Actuators

摘要

著录项

相似文献

相关主题

期刊订阅