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电感式位移传感器的优化

Optimization of an Inductive Displacement Transducer.

作者信息

Mociran Bogdan, Gliga Marian

机构信息

Faculty of Electrical Engineering, Technical University of Cluj-Napoca, 28 Memorandumului Street, 400114 Cluj-Napoca, Romania.

出版信息

Sensors (Basel). 2023 Sep 28;23(19):8152. doi: 10.3390/s23198152.

DOI:10.3390/s23198152
PMID:37836982
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10574894/
Abstract

This paper presents the optimization of an inductive displacement transducer or linear variable differential transformer (LVDT). The method integrates design software (SolidWorks 2023), simulation tools (COMSOL Multiphysics), and MATLAB. The optimization phase utilizes the non-dominated sorting genetic algorithm (NSGA)-II and -III to fine-tune the geometry configuration by adjusting six inner parameters corresponding to the dimension of the interior components of the LVDT, thus aiming to improve the overall performance of the device. The outcomes of this study reveal a significant achievement in LVDT enhancement. By employing the proposed methodology, the operational range of the LVDT was effectively doubled, extending it from its initial 8 (mm) to 16 (mm). This expansion in the operational range was achieved without compromising measurement accuracy, as all error values for the working range of 0-16 (mm) (NSGA-II with a maximum final relative error of 2.22% and NSGA-III with 2.44%) remained below the imposed 3% limit. This research introduces a new concept in LVDT optimization, capitalizing on the combined power of NSGA-II and NSGA-III algorithms. The integration of these advanced algorithms, along with the interconnection between design, simulation, and programming tools, distinguishes this work from conventional approaches. This study fulfilled its initial objectives and generated quantifiable results. It introduced novel internal configurations that substantially improved the LVDT's performance. These achievements underscore the validity and potential of the proposed methodology in advancing LVDT technology, with promising implications for a wide range of engineering applications.

摘要

本文介绍了一种感应式位移传感器或线性可变差动变压器(LVDT)的优化方法。该方法集成了设计软件(SolidWorks 2023)、仿真工具(COMSOL Multiphysics)和MATLAB。优化阶段利用非支配排序遗传算法(NSGA)-II和-III,通过调整与LVDT内部组件尺寸对应的六个内部参数来微调几何配置,从而旨在提高设备的整体性能。本研究的结果表明在LVDT性能提升方面取得了显著成果。通过采用所提出的方法,LVDT的工作范围有效地扩大了一倍,从最初的8(mm)扩展到16(mm)。在不影响测量精度的情况下实现了工作范围的扩大,因为0-16(mm)工作范围内的所有误差值(NSGA-II的最大最终相对误差为2.22%,NSGA-III为2.44%)均保持在规定的3%限制以下。本研究引入了LVDT优化的新概念,利用了NSGA-II和NSGA-III算法的联合力量。这些先进算法的集成,以及设计、仿真和编程工具之间的相互连接,使这项工作有别于传统方法。本研究实现了其初始目标并产生了可量化的结果。它引入了显著改善LVDT性能的新颖内部配置。这些成果强调了所提出方法在推进LVDT技术方面的有效性和潜力,对广泛的工程应用具有广阔的前景。

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本文引用的文献

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Sensors (Basel). 2022 May 12;22(10):3674. doi: 10.3390/s22103674.