The Use of Kramers-Kronig Relations for Verification of Quality of Ferrite Magnetic Spectra

IF 0.5 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC Electrical Control and Communication Engineering Pub Date : 2015-12-01 DOI:10.1515/ecce-2015-0009

N. Ponomarenko, T. Solovjova, J. Grizans

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引用次数: 5

Abstract

Abstract The complex initial permeability (CIP) as a function of frequency is one of the main properties of ferrites. This characteristic (CIP) is measured experimentally, therefore there can be found noisy, doubtful or incomplete parts of the spectrum. Thus there is a need for a method of evaluation of quality of CIP. In this article for evaluation of the quality of experimental CIP spectra of polycrystalline ferrite materials the KKR (Kramers-Kronig relations) are used. In order to apply KKR to experimentally measured data (i.e. data with finite limits) the method of transforming these integral relations into summation relations with finite limits is developed and described. This method can be used only for CIP given over the wide frequency rage, so that the imaginary part of CIP is fully presented. Using KKR with the help of CIP spectra model (based on the effects coming from polycrystal grain sizes and defects distribution) partly removes aforementioned limit. Thus with the help of the model we can also make CIP spectra reconstruction (in cases when CIP is noisy or incomplete) and CIP spectra decomposition.

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用Kramers-Kronig关系验证铁氧体磁谱的质量

复初始磁导率(CIP)是铁氧体的主要性能之一，是频率的函数。该特性(CIP)是通过实验测量的，因此可以发现频谱中有噪声、可疑或不完整的部分。因此，需要一种CIP质量评价方法。本文利用KKR (Kramers-Kronig关系)对多晶铁氧体材料的实验CIP光谱质量进行评价。为了将KKR应用于实验测量数据(即具有有限极限的数据)，开发并描述了将这些积分关系转换为具有有限极限的求和关系的方法。该方法只适用于给定较宽频率范围内的CIP，从而使CIP的虚部得到充分呈现。利用KKR和CIP光谱模型(基于多晶晶粒尺寸和缺陷分布的影响)部分消除了上述限制。利用该模型还可以对CIP光谱进行重构(当CIP有噪声或不完全时)和CIP光谱分解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Electrical Control and Communication Engineering ENGINEERING, ELECTRICAL & ELECTRONIC-

自引率

14.30%

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审稿时长

12 weeks