Application of Jacobi-Davidson algorithm to 2-D eigen-mode problems in printable electronics

Application of Jacobi-Davidson algorithm to 2-D eigen-mode problems in printable electronics

Thin nano-particle conductors of the order of micrometer in thickness are typical for printable electronics technology. A two-dimensional (2-D) eigenmode solver based on Jacobi-Davidson algorithm is applied to printable transmission lines to evaluate the conductor loss. Efficient preconditioning for...

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Bibliographic Details
Published in:2009 International Conference on Electromagnetics in Advanced Applications pp. 122 - 125
Main Authors: Makinen, R., Sillanpaa, H., Ostman, K., Palukuru, V., Pynttari, V., Kanerva, T., Hagberg, J., Lepisto, T., Jantunen, H.
Format: Conference Proceeding
Language:English
Published: IEEE 01-09-2009
Subjects:
Conducting materials
Conductivity
Conductors
Dielectric materials
Jacobian matrices
Manufacturing processes
Propagation losses
Transmission line matrix methods
Two dimensional displays
Wideband
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Summary:Thin nano-particle conductors of the order of micrometer in thickness are typical for printable electronics technology. A two-dimensional (2-D) eigenmode solver based on Jacobi-Davidson algorithm is applied to printable transmission lines to evaluate the conductor loss. Efficient preconditioning for the interior solver is utilized to treat poorly-conditioned complex system matrix arising from the fine discretization of conductors required to accurately model the conductor loss. The solver can be used to determine the required layer thickness and conductivity for a desired line loss as well as to the analysis of wide-band material characterization results. The approach is used to determine actual material parameters from wide-band extraction results for inkjet-printed dielectric and nano-silver conductor.
ISBN:9781424433858
1424433851
DOI:10.1109/ICEAA.2009.5297582