An approximate block Newton method for coupled iterations of nonlinear solvers: Theory and conjugate heat transfer applications

Andrew Yeckel; Lisa Lun; Jeffrey J. Derby

doi:10.1016/j.jcp.2009.08.003

An approximate block Newton method for coupled iterations of nonlinear solvers: Theory and conjugate heat transfer applications

Andrew Yeckel, Lisa Lun, Jeffrey J. Derby

Chemical Engineering and Materials Science

Research output: Contribution to journal › Article › peer-review

24 Scopus citations

Abstract

A new, approximate block Newton (ABN) method is derived and tested for the coupled solution of nonlinear models, each of which is treated as a modular, black box. Such an approach is motivated by a desire to maintain software flexibility without sacrificing solution efficiency or robustness. Though block Newton methods of similar type have been proposed and studied, we present a unique derivation and use it to sort out some of the more confusing points in the literature. In particular, we show that our ABN method behaves like a Newton iteration preconditioned by an inexact Newton solver derived from subproblem Jacobians. The method is demonstrated on several conjugate heat transfer problems modeled after melt crystal growth processes. These problems are represented by partitioned spatial regions, each modeled by independent heat transfer codes and linked by temperature and flux matching conditions at the boundaries common to the partitions. Whereas a typical block Gauss-Seidel iteration fails about half the time for the model problem, quadratic convergence is achieved by the ABN method under all conditions studied here. Additional performance advantages over existing methods are demonstrated and discussed.

Original language	English (US)
Pages (from-to)	8566-8588
Number of pages	23
Journal	Journal of Computational Physics
Volume	228
Issue number	23
DOIs	https://doi.org/10.1016/j.jcp.2009.08.003
State	Published - Dec 10 2009

Bibliographical note

Funding Information:
This work has been supported in part by a seed grant from the Minnesota Supercomputing Institute and by the Department of Energy, National Nuclear Security Administration , under Award Numbers DE-FG52-06NA27498 and DE-FG52-08NA28768 , the content of which does not necessarily reflect the position or policy of the United States Government, and no official endorsement should be inferred. Andrew Yeckel gives thanks to Fraunhofer Gesellschaft for financial support through a PROF.X 2 scholarship, to Jochen Friedrich for hosting his stay at the Crystal Growth Laboratory at Fraunhofer IISB, and to Thomas Jung for advice on research direction at a critical juncture.

Keywords

Approximate Newton methods
Block Gauss-Seidel methods
Crystal growth
Modular iterations
Multiphysics coupling
Multiscale coupling

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title = "An approximate block Newton method for coupled iterations of nonlinear solvers: Theory and conjugate heat transfer applications",

abstract = "A new, approximate block Newton (ABN) method is derived and tested for the coupled solution of nonlinear models, each of which is treated as a modular, black box. Such an approach is motivated by a desire to maintain software flexibility without sacrificing solution efficiency or robustness. Though block Newton methods of similar type have been proposed and studied, we present a unique derivation and use it to sort out some of the more confusing points in the literature. In particular, we show that our ABN method behaves like a Newton iteration preconditioned by an inexact Newton solver derived from subproblem Jacobians. The method is demonstrated on several conjugate heat transfer problems modeled after melt crystal growth processes. These problems are represented by partitioned spatial regions, each modeled by independent heat transfer codes and linked by temperature and flux matching conditions at the boundaries common to the partitions. Whereas a typical block Gauss-Seidel iteration fails about half the time for the model problem, quadratic convergence is achieved by the ABN method under all conditions studied here. Additional performance advantages over existing methods are demonstrated and discussed.",

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An approximate block Newton method for coupled iterations of nonlinear solvers: Theory and conjugate heat transfer applications

Abstract

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Keywords

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