Inductance Formula for Rectangular Planar Spiral Inductors with Rectangular Conductor Cross Section

IF 0.8 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC Advanced Electromagnetics Pub Date : 2020-02-07 DOI:10.7716/aem.v9i1.1346
H. Aebischer
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引用次数: 9

Abstract

In modern technology, inductors are often shaped in the form of planar spiral coils, as in radio frequency integrated circuits (RFIC’s), 13.56 MHz radio frequency identification (RFID), near field communication (NFC), telemetry, and wireless charging devices, where the coils must be designed to a specified inductance. In many cases, the direct current (DC) inductance is a good approximation. Some approximate formulae for the DC inductance of planar spiral coils with rectangular conductor cross section are known from the literature. They can simplify coil design considerably. But they are almost exclusively limited to square coils. This paper derives a formula for rectangular planar spiral coils with an aspect ratio not exceeding a value between 2.5 and 4.0, depending on the number of turns, and having a cross-sectional aspect ratio of height to width not exceeding unity. It is valid for any dimension and inductance range. The formula lowers the overall maximum error from hitherto 28 % down to 5.6 %. For specific application areas like RFIC’s and RFID antennas, it is possible to reduce the domain of definition, with the result that the formula lowers the maximum error from so far 18 % down to 2.6 %. This was tested systematically on close to 140000 coil designs of exactly known inductance. To reduce the number of dimensions of the parameter space, dimensionless parameters are introduced. The formula was also tested against measurements taken on 16 RFID antennas manufactured as PCB’s. The derivation is based on the idea of treating the conductor segments of all turns as if they were parallel conductors of a single-turn coil. It allows the inductance to be calculated with the help of mean distances between two arbitrary points anywhere within the total cross section of the coil. This leads to compound mean distances that are composed of two types of elementary ones, firstly, between a single rectangle and itself, and secondly, between two displaced congruent rectangles. For these elementary mean distances, exact expressions are derived. Those for the arithmetic mean distance (AMD) and one for the arithmetic mean square distance (AMSD) seem to be new. The paper lists the source code of a MATLAB® function to implement the formula on a computer, together with numerical examples. Further, the code for solving a coil design problem with constraints as it arises in practical engineering is presented, and an example problem is solved.
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矩形导体截面矩形平面螺旋电感器的电感公式
在现代技术中,电感器通常以平面螺旋线圈的形式形成,如射频集成电路(RFIC), 13.56 MHz射频识别(RFID),近场通信(NFC),遥测和无线充电设备,其中线圈必须设计为特定的电感。在许多情况下,直流(DC)电感是一个很好的近似值。从文献中已知了导体截面为矩形的平面螺旋线圈直流电感的一些近似公式。它们可以大大简化线圈设计。但它们几乎完全局限于方形线圈。本文导出了矩形平面螺旋线圈的公式,其纵横比不超过2.5至4.0之间的值,取决于匝数,且截面纵横比不超过1。它适用于任何尺寸和电感范围。该公式将总体最大误差从目前的28%降低到5.6%。对于特定的应用领域,如RFIC和RFID天线,可以减少定义域,其结果是公式将最大误差从目前的18%降低到2.6%。这是系统地测试了近140000线圈设计的确切已知的电感。为了减少参数空间的维数,引入了无量纲参数。该公式还与16个PCB制造的RFID天线的测量结果进行了测试。这个推导是基于把所有匝数的导体段看作是单匝线圈的平行导体的思想。它允许电感在线圈总横截面内任意两个点之间的平均距离的帮助下计算。这导致复合平均距离由两种类型的基本距离组成,第一种是单个矩形与自身之间的距离,第二种是两个位移相等矩形之间的距离。对于这些初等平均距离,导出了精确表达式。算术平均距离(AMD)和算术均方距离(AMSD)似乎是新的。本文列出了在计算机上实现该公式的MATLAB®函数的源代码,并给出了数值示例。在此基础上,给出了实际工程中带约束的线圈设计问题的求解规范,并给出了一个算例。
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来源期刊
Advanced Electromagnetics
Advanced Electromagnetics ENGINEERING, ELECTRICAL & ELECTRONIC-
CiteScore
2.40
自引率
12.50%
发文量
33
审稿时长
10 weeks
期刊介绍: Advanced Electromagnetics, is electronic peer-reviewed open access journal that publishes original research articles as well as review articles in all areas of electromagnetic science and engineering. The aim of the journal is to become a premier open access source of high quality research that spans the entire broad field of electromagnetics from classic to quantum electrodynamics.
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