|
Digital
Library of the European Council for Modelling
and Simulation |
Title: |
Application Of Genetic Optimization Algorithms To
Lumped Circuit Modelling Of Coupled Planar Coils |
Authors: |
Jennifer
Schuett, Lars Nolle, Jens Werner |
Published in: |
(2017).ECMS 2017 Proceedings
Edited by: Zita Zoltay Paprika, Péter Horák, Kata Váradi, Péter Tamás
Zwierczyk, Ágnes Vidovics-Dancs, János Péter Rádics European Council for Modeling and Simulation. doi:10.7148/2017 ISBN:
978-0-9932440-4-9/ ISBN:
978-0-9932440-5-6 (CD) 31st European Conference on Modelling and
Simulation, Budapest, Hungary, May 23rd
– May 26th, 2017 |
Citation
format: |
Jennifer
Schuett, Lars Nolle, Jens Werner (2017). Application Of Genetic Optimization
Algorithms To Lumped Circuit Modelling Of Coupled Planar Coils, ECMS 2017
Proceedings Edited by: Zita Zoltay Paprika, Péter Horák, Kata Váradi, Péter
Tamás Zwierczyk, Ágnes Vidovics-Dancs, János Péter Rádics European
Council for Modeling and Simulation. doi:
10.7148/2017-0262 |
DOI: |
https://doi.org/10.7148/2017-0262 |
Abstract: |
In
portable electronic devices, like smart phones, coupled planar coils are
often used as common mode flters (CMF). The purpose of these CMF is to
suppress electromagnetic interference (EMI) between wireless communications systems
(e.g. WIFI) and digital highspeed interfaces (e.g. USB3). A designer of such
an electronic device usually carries out a signal integrity (SI) analysis,
using models of the system components. There are two alternative ways of
modelling the CMF: One is based on matrices (called S-parameters) that
describe the behaviour in the frequency domain and are either derived from
measurements or simulation tools. The other is using a representation based
on lumped circuit networks. In this work, a lumped network is generated manually
based on expert knowledge. The advantage of this approach is the reduced
number of only passive network components compared to traditional methods
that produce much larger networks comprising of many active and passive
devices. On the other hand, suitable component values of the lumped network need
to be found so that the network exhibits the same frequency response as the
physical device. Since there are many interacting parameters to be tuned,
this cannot be achieved manually. Hence, a genetic algorithm is applied to
this optimisation problem. Two sets of experiments were carried out and a
sensitivity analysis has been conducted. It has been shown that the proposed
method is capable of finding near optimal solutions within reasonable computation
time. |
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