A Parallel Block Iterative Method for the Hydrodynamic Device Model


Journal Article

Block iterative methods are applied to hydrodynamic simulations of a one-dimensional (1-D) submicrometer semiconductor device. We show that block successive under-relaxation (SUR) converges with a fixed relaxation factor ω = 0.13 for simulations at 300 K and ω = 0.04 at 77 K. To demonstrate the robustness of the block iterative method, we present numerical simulations of a steady-state electron shock wave in Si at 300 K for a 0.1-μm channel and at 77 K for a 1.0-μm channel. The block SUR method is parallelizable if each diagonal block solve can be done efficiently in parallel. Using chaotic relaxation and the preconditioned conjugate gradient method for the parallel diagonal block solves, we obtain a parallel speed up of approximately 2.5 on 10 processors of a Butterfly GP-1000. The 1-D simulations serve as a numerical laboratory for developing methods that will be essential for computational efficiency in two-dimensional (2-D) problems. © 1991 IEEE

Full Text

Cited Authors

  • Gardner, CL; Rose, DJ; Lanzkron, PJ

Published Date

  • January 1, 1991

Published In

Volume / Issue

  • 10 / 9

Start / End Page

  • 1187 - 1192

Electronic International Standard Serial Number (EISSN)

  • 1937-4151

International Standard Serial Number (ISSN)

  • 0278-0070

Digital Object Identifier (DOI)

  • 10.1109/43.85765

Citation Source

  • Scopus