TY - JOUR
T1 - Accuracy of physics-based via models for simulation of dense via arrays
AU - Müller, Sebastian
AU - Duan, Xiaomin
AU - Kotzev, Miroslav
AU - Zhang, Yao Jiang
AU - Fan, Jun
AU - Gu, Xiaoxiong
AU - Kwark, Young H.
AU - Rimolo-Donadio, Renato
AU - Brüns, Heinz Dietrich
AU - Schuster, Christian
PY - 2012
Y1 - 2012
N2 - This paper studies the accuracy of the physics-based via model, specifically when applied to dense via arrays. The physics-based model uses Greens functions for cylindrical waves in radial waveguides to model the via return current paths and the coupling between vias. The effects of approximations made in this model are studied with regard to four types of modes based on an eigenmode expansion for the radial waveguide. It is found that for the mode conversion in the vicinity of the via, an accurate consideration of nonpropagating modes becomes critical with an increasing cavity height. For the interaction between vias in dense arrays, anisotropic modes have an impact for small pitches, whereas the coupling by nonpropagating modes is small for practical printed circuit board dimensions. For a data rate of 20 Gb/s, conclusions with regard to the applicability of the physics-based via model to a multilayer structure are drawn. For 80-mil pitch, a good agreement to full-wave results can be observed. Measurements have been carried out to validate this finding. For 40-mil pitch, the accuracy of the physics-based via model is not sufficient for data rates of 20 Gb/s or higher.
AB - This paper studies the accuracy of the physics-based via model, specifically when applied to dense via arrays. The physics-based model uses Greens functions for cylindrical waves in radial waveguides to model the via return current paths and the coupling between vias. The effects of approximations made in this model are studied with regard to four types of modes based on an eigenmode expansion for the radial waveguide. It is found that for the mode conversion in the vicinity of the via, an accurate consideration of nonpropagating modes becomes critical with an increasing cavity height. For the interaction between vias in dense arrays, anisotropic modes have an impact for small pitches, whereas the coupling by nonpropagating modes is small for practical printed circuit board dimensions. For a data rate of 20 Gb/s, conclusions with regard to the applicability of the physics-based via model to a multilayer structure are drawn. For 80-mil pitch, a good agreement to full-wave results can be observed. Measurements have been carried out to validate this finding. For 40-mil pitch, the accuracy of the physics-based via model is not sufficient for data rates of 20 Gb/s or higher.
KW - Mode conversion
KW - Parallel plates
KW - Physics-based via model
KW - Power distribution network
KW - Printed circuit board (PCB)
KW - Signal integrity
UR - http://www.scopus.com/inward/record.url?scp=84867879419&partnerID=8YFLogxK
U2 - 10.1109/TEMC.2012.2192123
DO - 10.1109/TEMC.2012.2192123
M3 - Artículo
AN - SCOPUS:84867879419
SN - 0018-9375
VL - 54
SP - 1125
EP - 1136
JO - IEEE Transactions on Electromagnetic Compatibility
JF - IEEE Transactions on Electromagnetic Compatibility
IS - 5
M1 - 6193423
ER -