Inductive coupling matrix of a multiconductor system for a winding-on-core prototype
(2014) 2014 International Symposium on Electromagnetic Compatibility (EMC'14)- Abstract
- Broadband circuit models for electric machines are
effective means to understand, predict, and control the
phenomenon of conducted Electromagnetic Interference (EMI)
from immunity/susceptibility perspective. These models should
cover the capacitive and inductive coupling behavior of the
component along the frequency range of interest. Circuit models
used under generic SPICE simulation softwares are very helpful
for design-related and troubleshooting activities. In this paper
the inductive coupling for a winding on a laminated ferromagnetic
core prototype has been investigated and analyzed with
the aid of freely-available FEMM software... (More) - Broadband circuit models for electric machines are
effective means to understand, predict, and control the
phenomenon of conducted Electromagnetic Interference (EMI)
from immunity/susceptibility perspective. These models should
cover the capacitive and inductive coupling behavior of the
component along the frequency range of interest. Circuit models
used under generic SPICE simulation softwares are very helpful
for design-related and troubleshooting activities. In this paper
the inductive coupling for a winding on a laminated ferromagnetic
core prototype has been investigated and analyzed with
the aid of freely-available FEMM software package.
Inductive coupling analysis resulted in the generation of a
complex-numbered inductive coupling matrix expressing a
certain wiring arrangement. This is achieved by automatically
generating the desired geometry and assigning boundary
conditions for the problem under FEMM through Lua scripting
language and then solving for magneto-static and time-harmonic
magnetic cases for both self- and mutual- inductances for every
conductor in the multi-conductor system. Post-Processing of the
solutions is performed and the results are linked back to
MATLAB® and stored in a matrix format.
The inductive coupling of the winding turns, along with the
capacitive coupling, forms the resulting SPICE circuit model
which is compared against prototype measurements taken by
Rhode & Schwarz (R&S®) vector network analyzer. (Less)
Please use this url to cite or link to this publication:
https://lup.lub.lu.se/record/4350970
- author
- Abdallah, Fadi LU and Alaküla, Mats LU
- organization
- publishing date
- 2014
- type
- Contribution to conference
- publication status
- submitted
- subject
- conference name
- 2014 International Symposium on Electromagnetic Compatibility (EMC'14)
- conference dates
- 2014-05-12
- language
- English
- LU publication?
- yes
- id
- ef32d86a-13a6-46a0-8809-c8f3fd713b55 (old id 4350970)
- date added to LUP
- 2016-04-04 14:38:43
- date last changed
- 2018-11-21 21:21:29
@misc{ef32d86a-13a6-46a0-8809-c8f3fd713b55, abstract = {{Broadband circuit models for electric machines are<br/><br> effective means to understand, predict, and control the<br/><br> phenomenon of conducted Electromagnetic Interference (EMI)<br/><br> from immunity/susceptibility perspective. These models should<br/><br> cover the capacitive and inductive coupling behavior of the<br/><br> component along the frequency range of interest. Circuit models<br/><br> used under generic SPICE simulation softwares are very helpful<br/><br> for design-related and troubleshooting activities. In this paper<br/><br> the inductive coupling for a winding on a laminated ferromagnetic<br/><br> core prototype has been investigated and analyzed with<br/><br> the aid of freely-available FEMM software package.<br/><br> Inductive coupling analysis resulted in the generation of a<br/><br> complex-numbered inductive coupling matrix expressing a<br/><br> certain wiring arrangement. This is achieved by automatically<br/><br> generating the desired geometry and assigning boundary<br/><br> conditions for the problem under FEMM through Lua scripting<br/><br> language and then solving for magneto-static and time-harmonic<br/><br> magnetic cases for both self- and mutual- inductances for every<br/><br> conductor in the multi-conductor system. Post-Processing of the<br/><br> solutions is performed and the results are linked back to<br/><br> MATLAB® and stored in a matrix format.<br/><br> The inductive coupling of the winding turns, along with the<br/><br> capacitive coupling, forms the resulting SPICE circuit model<br/><br> which is compared against prototype measurements taken by<br/><br> Rhode & Schwarz (R&S®) vector network analyzer.}}, author = {{Abdallah, Fadi and Alaküla, Mats}}, language = {{eng}}, title = {{Inductive coupling matrix of a multiconductor system for a winding-on-core prototype}}, year = {{2014}}, }