Coupling of Partitioned Physics Codes with Quasi-Newton Methods

Rob Haelterman; Alfred Bogaers; Joris Degroote; Silviu Cracana

Coupling of Partitioned Physics Codes with Quasi-Newton Methods

Rob Haelterman
, Alfred Bogaers
, Joris Degroote
, Silviu Cracana

Modelling and Digital Sciences
University of Ghent
Technical Military Academy

Résultats de recherche: Chapitre dans un livre, un rapport, des actes de conférences › Contribution à une conférence › Revue par des pairs

1 Citation (Scopus)

Résumé

Many physics problems can only be studied by coupling various numerical codes, each modeling a subaspect of the physics problem that is addressed. Often, each of these codes needs to be considered as a black box, either because the codes were written by different programmers, are proprietary software or are legacy code that can only be modified with major effort. Running these black boxes one after another, until convergence is reached, is a standard solution technique. It is easy to implement but comes at the cost of slow or even conditional convergence. A recent interpretation of this approach as a root-finding problem has opened the door to acceleration techniques based on quasi-Newton methods. These quasi-Newton methods can easily be “strapped onto” the original iterative loop without the need to modify the underlying code and with little extra computational cost. In this paper we analyze the performance of ten acceleration techniques that can be applied to accelerate the convergence of a non-linear Gauss-Seidel iteration, on three different multi-physics problems. The methods range from the very well known Broyden method to the arcane Eirola-Nevanlinna method. A switching strategy that was mooted a number of years ago for Broyden’s method, and was claimed to give promising results, but then fell by the wayside, is also considered. For the first time, this idea has been generalized to a wider class of quasi-Newton methods.

langue originale	Anglais
titre	Proceedings of the International MultiConference of Engineers and Computer Scientists 2017, IMECS 2017
rédacteurs en chef	Oscar Castillo, S. I. Ao, Craig Douglas, David Dagan Feng, A. M. Korsunsky
Editeur	Newswood Limited
Pages	750-755
Nombre de pages	6
ISBN (Electronique)	9789881404770
état	Publié - 2017
Evénement	2017 International MultiConference of Engineers and Computer Scientists, IMECS 2017 - Hong Kong, Hong-Kong Durée: 15 mars 2017 → 17 mars 2017

Série de publications

Nom	Lecture Notes in Engineering and Computer Science
Volume	2228
ISSN (imprimé)	2078-0958

Une conférence

Une conférence	2017 International MultiConference of Engineers and Computer Scientists, IMECS 2017
Pays/Territoire	Hong-Kong
La ville	Hong Kong
période	15/03/17 → 17/03/17

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Contient cette citation

Haelterman, R., Bogaers, A., Degroote, J., & Cracana, S. (2017). Coupling of Partitioned Physics Codes with Quasi-Newton Methods. Dans O. Castillo, S. I. Ao, C. Douglas, D. D. Feng, & A. M. Korsunsky (eds.), Proceedings of the International MultiConference of Engineers and Computer Scientists 2017, IMECS 2017 (p. 750-755). (Lecture Notes in Engineering and Computer Science; Vol 2228). Newswood Limited.

Haelterman, Rob ; Bogaers, Alfred ; Degroote, Joris et al. / Coupling of Partitioned Physics Codes with Quasi-Newton Methods. Proceedings of the International MultiConference of Engineers and Computer Scientists 2017, IMECS 2017. Editeur / Oscar Castillo ; S. I. Ao ; Craig Douglas ; David Dagan Feng ; A. M. Korsunsky. Newswood Limited, 2017. p. 750-755 (Lecture Notes in Engineering and Computer Science).

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title = "Coupling of Partitioned Physics Codes with Quasi-Newton Methods",

abstract = "Many physics problems can only be studied by coupling various numerical codes, each modeling a subaspect of the physics problem that is addressed. Often, each of these codes needs to be considered as a black box, either because the codes were written by different programmers, are proprietary software or are legacy code that can only be modified with major effort. Running these black boxes one after another, until convergence is reached, is a standard solution technique. It is easy to implement but comes at the cost of slow or even conditional convergence. A recent interpretation of this approach as a root-finding problem has opened the door to acceleration techniques based on quasi-Newton methods. These quasi-Newton methods can easily be “strapped onto” the original iterative loop without the need to modify the underlying code and with little extra computational cost. In this paper we analyze the performance of ten acceleration techniques that can be applied to accelerate the convergence of a non-linear Gauss-Seidel iteration, on three different multi-physics problems. The methods range from the very well known Broyden method to the arcane Eirola-Nevanlinna method. A switching strategy that was mooted a number of years ago for Broyden{\textquoteright}s method, and was claimed to give promising results, but then fell by the wayside, is also considered. For the first time, this idea has been generalized to a wider class of quasi-Newton methods.",

keywords = "Iterative methods, Partitioned methods, Quasi-Newton",

author = "Rob Haelterman and Alfred Bogaers and Joris Degroote and Silviu Cracana",

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Haelterman, R, Bogaers, A, Degroote, J & Cracana, S 2017, Coupling of Partitioned Physics Codes with Quasi-Newton Methods. Dans O Castillo, SI Ao, C Douglas, DD Feng & AM Korsunsky (eds), Proceedings of the International MultiConference of Engineers and Computer Scientists 2017, IMECS 2017. Lecture Notes in Engineering and Computer Science, VOL. 2228, Newswood Limited, p. 750-755, 2017 International MultiConference of Engineers and Computer Scientists, IMECS 2017, Hong Kong, Hong-Kong, 15/03/17.

Coupling of Partitioned Physics Codes with Quasi-Newton Methods. / Haelterman, Rob; Bogaers, Alfred; Degroote, Joris et al.
Proceedings of the International MultiConference of Engineers and Computer Scientists 2017, IMECS 2017. Ed. / Oscar Castillo; S. I. Ao; Craig Douglas; David Dagan Feng; A. M. Korsunsky. Newswood Limited, 2017. p. 750-755 (Lecture Notes in Engineering and Computer Science; Vol 2228).

Résultats de recherche: Chapitre dans un livre, un rapport, des actes de conférences › Contribution à une conférence › Revue par des pairs

TY - GEN

T1 - Coupling of Partitioned Physics Codes with Quasi-Newton Methods

AU - Haelterman, Rob

AU - Bogaers, Alfred

AU - Degroote, Joris

AU - Cracana, Silviu

PY - 2017

Y1 - 2017

N2 - Many physics problems can only be studied by coupling various numerical codes, each modeling a subaspect of the physics problem that is addressed. Often, each of these codes needs to be considered as a black box, either because the codes were written by different programmers, are proprietary software or are legacy code that can only be modified with major effort. Running these black boxes one after another, until convergence is reached, is a standard solution technique. It is easy to implement but comes at the cost of slow or even conditional convergence. A recent interpretation of this approach as a root-finding problem has opened the door to acceleration techniques based on quasi-Newton methods. These quasi-Newton methods can easily be “strapped onto” the original iterative loop without the need to modify the underlying code and with little extra computational cost. In this paper we analyze the performance of ten acceleration techniques that can be applied to accelerate the convergence of a non-linear Gauss-Seidel iteration, on three different multi-physics problems. The methods range from the very well known Broyden method to the arcane Eirola-Nevanlinna method. A switching strategy that was mooted a number of years ago for Broyden’s method, and was claimed to give promising results, but then fell by the wayside, is also considered. For the first time, this idea has been generalized to a wider class of quasi-Newton methods.

AB - Many physics problems can only be studied by coupling various numerical codes, each modeling a subaspect of the physics problem that is addressed. Often, each of these codes needs to be considered as a black box, either because the codes were written by different programmers, are proprietary software or are legacy code that can only be modified with major effort. Running these black boxes one after another, until convergence is reached, is a standard solution technique. It is easy to implement but comes at the cost of slow or even conditional convergence. A recent interpretation of this approach as a root-finding problem has opened the door to acceleration techniques based on quasi-Newton methods. These quasi-Newton methods can easily be “strapped onto” the original iterative loop without the need to modify the underlying code and with little extra computational cost. In this paper we analyze the performance of ten acceleration techniques that can be applied to accelerate the convergence of a non-linear Gauss-Seidel iteration, on three different multi-physics problems. The methods range from the very well known Broyden method to the arcane Eirola-Nevanlinna method. A switching strategy that was mooted a number of years ago for Broyden’s method, and was claimed to give promising results, but then fell by the wayside, is also considered. For the first time, this idea has been generalized to a wider class of quasi-Newton methods.

KW - Iterative methods

KW - Partitioned methods

KW - Quasi-Newton

UR - https://www.scopus.com/pages/publications/85027963343

M3 - Conference contribution

AN - SCOPUS:85027963343

T3 - Lecture Notes in Engineering and Computer Science

SP - 750

EP - 755

BT - Proceedings of the International MultiConference of Engineers and Computer Scientists 2017, IMECS 2017

A2 - Castillo, Oscar

A2 - Ao, S. I.

A2 - Douglas, Craig

A2 - Feng, David Dagan

A2 - Korsunsky, A. M.

PB - Newswood Limited

T2 - 2017 International MultiConference of Engineers and Computer Scientists, IMECS 2017

Y2 - 15 March 2017 through 17 March 2017

ER -

Haelterman R, Bogaers A, Degroote J, Cracana S. Coupling of Partitioned Physics Codes with Quasi-Newton Methods. Dans Castillo O, Ao SI, Douglas C, Feng DD, Korsunsky AM, rédacteurs en chef, Proceedings of the International MultiConference of Engineers and Computer Scientists 2017, IMECS 2017. Newswood Limited. 2017. p. 750-755. (Lecture Notes in Engineering and Computer Science).

Coupling of Partitioned Physics Codes with Quasi-Newton Methods

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