便携式机箱内部PCB间微带线的耦合特性分析

doi:10.16180/j.cnki.issn1007-7820.2021.03.001

摘要/Abstract

摘要：

针对在便携式机箱狭小内部空间中相接各个模块,承担着信息能量传输交换功能PCB上的微带线存在电磁耦合干扰问题,提出了基于模型化简的建模仿真分析方法。文中将机箱模型建模并基于微绕理论简化模型,结合机箱内部PCB及其上微带线的电磁特征建模,并在微带线上添加相应的时钟信号激励和负载,实现了不用PCB间微带线的耦合特性仿真分析。结果表明,当与干扰PCB相对空间位置为垂直或平行时,微带线的耦合电压峰值分别为1.3 mV和0.5 mV,整体变化趋势与时钟信号上升下降沿相关;垂直和平行PCB上的耦合电压分别呈正相关和负相关关系。

关键词: 微带线, 电磁耦合特性, 模型化简, 时域响应特性, 傅里叶变换, 时钟信号, 时域有限差分

Abstract:

A modeling and simulation analysis method based on model simplification is proposed to solve the problem of electromagnetic coupling interference in the microstrip line of PCB, which is connected to each module in the small interior of the portable chassis and is responsible for the function of information energy transmission and exchange. In this paper, the chassis model is modeled and simplified according to the micro-winding theory. Combined with the electromagnetic model modeling of the PCB inside the chassis and the microstrip line on it, and the adding of corresponding clock signal excitation and load on the microstrip line,the simulation analysis of the coupling characteristics of the microstrip line without PCB is realized. The results show that when the relative spatial position of the interference PCB is perpendicular or parallel, the coupling voltage peaks of the microstrip line are 1.3 mv and 0.5 mv, respectively. The overall change trend is related to the rising and falling edge of clock signal, and the coupling voltage on the vertical and parallel PCB is positively and negatively correlated, respectively.

Key words: microstrip line, electromagnetic coupling characteristics, model simplification, time-domain response characteristics, the Fourier transform, clock signal, finite difference time domain

中图分类号:

TN751.1

吴其霖,谭康伯,路宏敏. 便携式机箱内部PCB间微带线的耦合特性分析[J]. 电子科技, 2021, 34(3): 1-5.

WU Qilin,TAN Kangbo,LU Hongmin. Analysis of Coupling Characteristics of Microstrip Line on PCB inside Portable Chassis[J]. Electronic Science and Technology, 2021, 34(3): 1-5.

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