A Robust Approach for the Analysis of EMI/EMC Problems With Nonlinear Circuit Loads

The analysis of electromagnetic coupling in nonlinear circuit simulations requires a bidirectional, fully consistent approach. Nonlinear responses of semiconductor devices in electronic circuit components can change the impedances seen at circuit nodes, changing the boundary conditions encountered by impressed electromagnetic fields and, thus, changing the characteristics of the energy coupled from these external fields into that circuit. It is important to include the coupling in the circuit simulation self-consistently because this allows us to accurately predict the responses to various EMI/EMC problems of interest. It is also important to predict circuit responses efficiently because that opens the door to statistical applications for the technique being used. In this paper, we review a technique that we have developed called A Thevenin Equivalent Network Approach. This approach is shown to be quite robust in that it is computationally efficient; it can be implemented in a variety of commonly available circuit solving codes; it already includes a few additional techniques required to enhance its implementation in those codes; and it is quite accurate.

[1]  P. R. Barnes,et al.  A Multiconductor Model for Determining the Response of Power Transmission and Distribution Lines to a High Altitude Electromagnetic Pulse (HEMP) , 1989, IEEE Power Engineering Review.

[2]  F. Tesche,et al.  Analysis of antennas and scatterers with nonlinear loads , 1976 .

[3]  Clayton R. Paul,et al.  Analysis of Multiconductor Transmission Lines , 1994 .

[4]  V. Rizzoli,et al.  General electromagnetic compatibility analysis for nonlinear microwave integrated circuits , 2004, 2004 IEEE MTT-S International Microwave Symposium Digest (IEEE Cat. No.04CH37535).

[5]  T.K. Sarkar,et al.  Time-domain response of multiconductor transmission lines , 1987, Proceedings of the IEEE.

[6]  L. D. Bacon,et al.  LineCAP (Line/Circuit Analysis Program): Cross-coupling on PC (printed circuit) board traces including discontinuities and circuit elements , 1989 .

[7]  G. A. E. Vandenbosch,et al.  Efficient Reciprocity-Based Algorithm to Predict Worst Case Induced Disturbances on Multiconductor Transmission Lines due to Incoming Plane Waves , 2013, IEEE Transactions on Electromagnetic Compatibility.

[8]  G. Spadacini,et al.  Closed-form transmission line model for radiated susceptibility in metallic enclosures , 2005, IEEE Transactions on Electromagnetic Compatibility.

[9]  Eric R. Keiter,et al.  The Xyce Parallel Electronic Simulator - An Overview , 2000 .

[10]  M. Morgan,et al.  Basic Statistical Concepts for Analysis of Random Cable Coupling Problems , 1978, IEEE Transactions on Electromagnetic Compatibility.

[11]  J.L. Volakis,et al.  Hybrid $S$-Parameters for Transmission Line Networks With Linear/Nonlinear Load Terminations Subject to Arbitrary Excitations , 2007, IEEE Transactions on Microwave Theory and Techniques.