Design for Integrated Planar Spiral Inductor for MEMS

Q3 Computer Science

Periodica polytechnica Electrical engineering and computer science Pub Date : 2023-06-21 DOI:10.3311/ppee.21666

Y. Benhadda, M. Derkaoui, K. Mendaz, Hayet Kharbouch, P. Spitéri

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引用次数: 0

Abstract

The main aim of this paper is to present the new design of an integrated planar spiral inductor with a new structure of an underpass to obtain a high inductance, high quality factor and minimum losses into winding and magnetic core. The performance of this structure dependent on the geometrical, electrical parameters and material properties. These parameters are calculated at 350 MHz and this is the high frequency used for MEMS applications. Furthermore, thermal analysis in inductor from finite difference method is described. The heat transfer model is based on heat conduction and heat convection. Moreover, the heat source is calculated by different losses. In addition, the simulation results from 3D finite element method using software also been presented in this paper. It is based on both the classical heat equation and certain condition limits. However, a new design of an underpass has been proposed where a via is fabricated with a circular layer. The input and output of the spiral are implanted in the same direction. In addition, the magnetic core is the solution to decrease the temperature. Finally, the results of the finite difference method are compared with simulation results from finite element method. The good agreement between the results is obtained. The proposed via and a core magnetic are responsible for enhancement the thermal behavior in integrated inductor. The result shows that the temperature of the air core inductor and magnetic core inductor could be 53 °C and 33 °C, respectively.

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MEMS集成平面螺旋电感的设计

本文的主要目的是提出一种集成平面螺旋电感器的新设计，该电感器具有新的通道结构，以获得高电感、高品质因数和最小的绕组和磁芯损耗。这种结构的性能取决于几何、电气参数和材料特性。这些参数是在350MHz下计算的，这是用于MEMS应用的高频。此外，还介绍了用有限差分法对电感的热分析。传热模型基于热传导和热对流。此外，热源是通过不同的损失来计算的。此外，本文还介绍了利用软件进行三维有限元模拟的结果。它基于经典的热方程和某些条件限制。然而，已经提出了一种新的地下通道设计，其中通孔是用圆形层制造的。螺旋的输入和输出是在同一方向上植入的。此外，磁芯是降低温度的解决方案。最后，将有限差分法的结果与有限元法的模拟结果进行了比较。结果之间取得了良好的一致性。所提出的过孔和核心磁体负责增强集成电感器中的热行为。结果表明，空心电感和磁芯电感的温度分别为53°C和33°C。

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

Periodica polytechnica Electrical engineering and computer science Engineering-Electrical and Electronic Engineering

CiteScore

2.60

自引率

0.00%

发文量

期刊介绍： The main scope of the journal is to publish original research articles in the wide field of electrical engineering and informatics fitting into one of the following five Sections of the Journal: (i) Communication systems, networks and technology, (ii) Computer science and information theory, (iii) Control, signal processing and signal analysis, medical applications, (iv) Components, Microelectronics and Material Sciences, (v) Power engineering and mechatronics, (vi) Mobile Software, Internet of Things and Wearable Devices, (vii) Solid-state lighting and (viii) Vehicular Technology (land, airborne, and maritime mobile services; automotive, radar systems; antennas and radio wave propagation).