印制板上感应电流的数值解

R. Manke, P. Wong, T. Cooprider, J. Lebaric
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I t is assumed that there is no field variation with respect to one coordinate, the one in the direction of propagation, such that problem can be treated as two-dimensional (2-D). This is the s,o-called quasi-TEM approximation for inhomogeneous domains. Typical configuration we have analyzed involves, a dielectric substrate of known permittivity with two narrow PEC strips and a wider PEC ground plane. One strip is \"active\" with a known potential difference imposed between the strip andl the ground plane, as if the strip were driven by an ideal voltage source. The current on the active strip is not known, and depeinds on the impedance that the strip presents to the source. The other strip is \"quiet\"and neither its induced potential nor its induced current are known. The physical proximity of the quiet strip alters the current on the active strip and a current and a potential are induced on the quiet strip. The two strips are either in the same plane (\"cdgc coupling\"), or one of the strips is \"buried\" in the substr;ite. iis c;in bc the case with niulti-layered boards. 'l'lic induced current on the qiiiel strip is noriiwlized to the current on the active strip to obtain the \"induced current cocflicient\". Similarly, the induced volliige coefficient isdefined as the ratio of~t ie iritlucctl potenti:il on thc quiet strip to he potential ofthc xtivc strip. The two coefficients depend on the spacing between the strips, and decrease monotonically as the spacing is increased. We have investigated the dependence of these coefficients on the position and spacing of the strips. Nu me rical Tech n i a Standard Finite Difference technique is employed to calculated the potentials on a cross-section. A uniform, square FD grid is ussuined. Laplace's equation is solved in 2-D, subject to a simulated open-boundary condition and a known potential on the active strip. Since we have used well-known FD equations for the potentials, the FD details will be omitted. The system of FD equations, with proper source and boundary conditions, is solved for the unknown potentials. The potential solution is then used to find the electric field as the negative gradient of the potential. Electric field and the intrinsic impedance of the medium are used to find the magnetic field. In our calculations we selected a square computational grid with 31 by 31 nodes. The TGT is implemented for the outermost layer of the (31 by 31) computational grid. The particular TGT implementation we selected is for a grid \"compression\" of 101 to 31, which means that our calculations on a 3 I by 3 1 grid with the TGT give the same result as would calculations on a 101 by 101 grid with Dirichlet (zero potential) boundary condition for the outermost layer. The use of TGT allows for significant savings of computer memory and time. 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引用次数: 0

摘要

将有限D@rence(FD)技术应用于四次透射电镜电磁场中,计算了印制板上导线上的感应电流,并对其进行了可视化。Tioti ~i1电场和磁场矢量。该代码是在MATLAB环境下开发的,允许可移植性和不同平台之间的交换。他经营的是m&t。利用透明网格终端(TGT)技术模拟开边界条件。感应电流数据和矢量图给出了几种几何形状涉及印刷布线板的位置不同,相对于彼此。目的是计算在印刷线路板(PWB)的平行走线上产生的电流和电位,并将电场和磁场分布可视化。离子用于压水板横截面。假设在传播方向的一个坐标上不存在场的变化,这样问题就可以被看作是二维的。这是非齐次域的准瞬变电磁法近似。我们所分析的典型结构包括一个介电常数已知的介质衬底,具有两个窄的PEC带和一个更宽的PEC接平面。一个条带是“有源”的,在条带和地平面之间施加已知的电位差,就好像条带是由理想电压源驱动的。有源带上的电流是未知的,它取决于带对源的阻抗。另一条带是“安静的”,它的感应电势和感应电流都不知道。安静带的物理接近改变了有源带上的电流,并且在安静带上感应电流和电位。两个条带要么在同一平面上(“cdgc耦合”),要么其中一个条带“埋”在子条带中。在BC中采用多层板的情况。将感应电流归一化为有源带上的电流,得到感应电流系数。同样地,感应电压系数定义为静带上的电流电位与静带电位之比。这两个系数取决于条带之间的间距,并随着间距的增加而单调减小。我们研究了这些系数与条带位置和间距的关系。用标准有限差分技术计算了截面上的电势。通常使用统一的方形FD网格。在模拟开边界条件和已知有源带电位的条件下,求解二维拉普拉斯方程。由于我们使用了众所周知的FD方程来表示势,因此FD的细节将被省略。在适当的源和边界条件下,求解了未知势的FD方程组。然后用势解求出作为势负梯度的电场。利用电场和介质的本征阻抗来求磁场。在我们的计算中,我们选择了一个31 × 31节点的方形计算网格。TGT是在(31 × 31)计算网格的最外层实现的。我们选择的特定TGT实现适用于101到31的网格“压缩”,这意味着我们在带有TGT的3i × 31网格上的计算结果与最外层具有Dirichlet(零势)边界条件的101 × 101网格上的计算结果相同。使用TGT可以显著节省计算机内存和时间。我们模拟开放边界条件的方法,我们称之为TGT,(据我们所知)是新的,将在接下来讨论。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Numerical Solution Of Induced Currents On Printed Wiring Boards
Finite D@rence(FD) technique is applied to qirusi-TEM electronlagtietic fields to calculate induced currents on purullel truces of a printed wiring board and visualize c.ro.ss-sec.tioti~i1 electric und magnetic field vectors. The cwiipirter code was developed fo r iise in a MATLAB environnient, allowing portability and' exchange between various p1atforni.s running M A T U B . Open-boundary conditions are siniulated irsing Transparent Grid Termination (TGT) technique. Induced current data and vector plots are given for severul geometries involving printed wiring board truces positioned differently with respect to each other. Introduction The objectives are to calculate cuments and potentials induced on parallel traces of a printed wiring board (PWB) and visualize the electric and magnetic field clistribut.ions for PWB cross-sections. I t is assumed that there is no field variation with respect to one coordinate, the one in the direction of propagation, such that problem can be treated as two-dimensional (2-D). This is the s,o-called quasi-TEM approximation for inhomogeneous domains. Typical configuration we have analyzed involves, a dielectric substrate of known permittivity with two narrow PEC strips and a wider PEC ground plane. One strip is "active" with a known potential difference imposed between the strip andl the ground plane, as if the strip were driven by an ideal voltage source. The current on the active strip is not known, and depeinds on the impedance that the strip presents to the source. The other strip is "quiet"and neither its induced potential nor its induced current are known. The physical proximity of the quiet strip alters the current on the active strip and a current and a potential are induced on the quiet strip. The two strips are either in the same plane ("cdgc coupling"), or one of the strips is "buried" in the substr;ite. iis c;in bc the case with niulti-layered boards. 'l'lic induced current on the qiiiel strip is noriiwlized to the current on the active strip to obtain the "induced current cocflicient". Similarly, the induced volliige coefficient isdefined as the ratio of~t ie iritlucctl potenti:il on thc quiet strip to he potential ofthc xtivc strip. The two coefficients depend on the spacing between the strips, and decrease monotonically as the spacing is increased. We have investigated the dependence of these coefficients on the position and spacing of the strips. Nu me rical Tech n i a Standard Finite Difference technique is employed to calculated the potentials on a cross-section. A uniform, square FD grid is ussuined. Laplace's equation is solved in 2-D, subject to a simulated open-boundary condition and a known potential on the active strip. Since we have used well-known FD equations for the potentials, the FD details will be omitted. The system of FD equations, with proper source and boundary conditions, is solved for the unknown potentials. The potential solution is then used to find the electric field as the negative gradient of the potential. Electric field and the intrinsic impedance of the medium are used to find the magnetic field. In our calculations we selected a square computational grid with 31 by 31 nodes. The TGT is implemented for the outermost layer of the (31 by 31) computational grid. The particular TGT implementation we selected is for a grid "compression" of 101 to 31, which means that our calculations on a 3 I by 3 1 grid with the TGT give the same result as would calculations on a 101 by 101 grid with Dirichlet (zero potential) boundary condition for the outermost layer. The use of TGT allows for significant savings of computer memory and time. The way we simulate open boundary condition, which we refer to as the TGT, is (to our best knowledge) new and will be addressed next.
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