Reduced Order PEEC Modeling for EMC Problems via Mixed Arnoldi Algorithm and Padé Approximation

Zhen Fei Song; Ming Xie

doi:10.4028/www.scientific.net/AMM.543-547.475

Paper Titles

The Motion Planning Research of Bionic Worming Crawling
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A Low-Power 1Kb PCRAM Chip with Elevated Write Performance
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Research of Case-Based Teaching of Electrical and Electronic Technology
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Design of an Initialization Circuit Used in Phase Change Memory Chip
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Reduced Order PEEC Modeling for EMC Problems via Mixed Arnoldi Algorithm and Padé Approximation
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Research of Storage Failure Mechanism on JZX-10M Aeronautic Sealed Relay
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Post-Silicon Energy Optimization on Voltage-Frequency Island Based 3-D Multi-Core SoCs
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Review on External System Equivalent Method of Power Systems Electromagnetic Transients Simulation
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The Analysis of Electromagnetic Field of ±800kV DC Transmission Line
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 543-547Reduced Order PEEC Modeling for EMC Problems via...

Reduced Order PEEC Modeling for EMC Problems via Mixed Arnoldi Algorithm and Padé Approximation

Abstract:

The Partial Element Equivalent Circuit (PEEC) method is a 3-D full-wave modeling method suitable for combined electromagnetic and circuit analysis, and now is one of the promising numerical methods for Electromagnetic Compatibility (EMC) modeling. Model order reduction (MOR) techniques provide a feasibility to approximate complex circuit models with compact reduced-order models, and have great potentials to improve the computational efficiency for complex modeling problems. An effective MOR technique basing on mixed Arnoldi algorithm and Padé approximation for the PEEC modeling is introduced in this paper. Numerical simulations of a typical coupled micro-strip line EMC problem indicate the effectiveness of the proposed methods.