Self-Resonance in Ortho-Cyclical Multilayer Air-Core Inductors: Analytical Techniques and Optimization

IF 2.5 3区计算机科学 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Transactions on Electromagnetic Compatibility Pub Date : 2024-10-08 DOI:10.1109/TEMC.2024.3452495

Arun Dilip Khilnani;Lu Wan;Danny Robert Seeley;Mark Sumner;David.W.P. Thomas;Flavia Grassi

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Abstract

A multilayer air-core inductor's operational frequency limit can be known beforehand if its first self-resonance frequency can be predicted. The self-resonance frequency is due to the electrostatic capacitance stored between the turns and layers of the inductor. This article presents an analytical technique to predict the first self-resonance frequency specifically for an ortho-cyclically wound multilayer air-core inductor through electrostatic field segregations. The static capacitances between the inductor's turns and layers are segregated into vertical and horizontal electrostatic field components, and are further aggregated to predict the first self-resonance frequency. Further, a multiobjective optimization technique using the pareto-optimal fronts through key parameter variations for inductor design is presented. The analytical technique is verified with acceptable results using prototype inductors. This analytical technique and optimization can be applied in designing ortho-cyclically wound multilayer air-core inductors for low and high frequency applications.

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正交循环多层空芯电感器中的自谐振：分析技术与优化

如果能预测多层空芯电感的第一自谐振频率，就可以预先知道多层空芯电感的工作频率极限。自谐振频率是由于电感匝和层之间存储的静电电容造成的。本文提出了一种利用静电场分离预测正交循环缠绕多层空芯电感第一次自共振频率的分析方法。电感匝和层之间的静电电容被划分为垂直和水平静电场分量，并进一步聚集以预测第一自谐振频率。在此基础上，提出了一种基于关键参数变化的帕累托最优前沿的多目标优化技术。使用原型电感器验证了分析技术的可接受结果。该分析技术和优化方法可用于设计低、高频应用的正交循环缠绕多层空芯电感器。

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来源期刊

IEEE Transactions on Electromagnetic Compatibility 工程技术-电信学

CiteScore

4.80

自引率

19.00%

发文量

235

审稿时长

2.3 months

期刊介绍： IEEE Transactions on Electromagnetic Compatibility publishes original and significant contributions related to all disciplines of electromagnetic compatibility (EMC) and relevant methods to predict, assess and prevent electromagnetic interference (EMI) and increase device/product immunity. The scope of the publication includes, but is not limited to Electromagnetic Environments; Interference Control; EMC and EMI Modeling; High Power Electromagnetics; EMC Standards, Methods of EMC Measurements; Computational Electromagnetics and Signal and Power Integrity, as applied or directly related to Electromagnetic Compatibility problems; Transmission Lines; Electrostatic Discharge and Lightning Effects; EMC in Wireless and Optical Technologies; EMC in Printed Circuit Board and System Design.