Interface flux recovery framework for constructing partitioned heterogeneous time‐integration methods

Interface flux recovery framework for constructing partitioned heterogeneous time‐integration methods

A common approach for the development of partitioned schemes employing different time integrators on different subdomains is to lag the coupling terms in time. This can lead to accuracy issues, especially in multistage methods. In this article, we present a novel framework for partitioned heterogene...

Full description

Saved in:
Bibliographic Details
Published in:Numerical methods for partial differential equations Vol. 39; no. 5; pp. 3572 - 3593
Main Authors: Sockwell, K. Chad, Bochev, Pavel, Peterson, Kara, Kuberry, Paul
Format: Journal Article
Language:English
Published: Hoboken, USA John Wiley & Sons, Inc 01-09-2023
Wiley Subscription Services, Inc
Wiley Blackwell (John Wiley & Sons)
Subjects:
Accuracy
Approximation
Boundary conditions
coupled air‐sea system
Coupling
Estimates
heterogeneous time integration
Integrators
Mathematical analysis
partitioned methods
Polynomials
time‐consistent schemes
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:A common approach for the development of partitioned schemes employing different time integrators on different subdomains is to lag the coupling terms in time. This can lead to accuracy issues, especially in multistage methods. In this article, we present a novel framework for partitioned heterogeneous time‐integration methods, which allows the coupling of arbitrary multistage and multistep methods without reducing their order of accuracy. At the core of our approach are accurate estimates of the interface flux obtained from the Schur complement of an auxiliary monolithic system. We use these estimates to construct a polynomial‐in‐time approximation of the interface flux over the current time coupling window. This approximation provides the interface boundary conditions necessary to decouple the subdomain problems at any point within the coupling window. In so doing our framework enables a flexible choice of time‐integrators for the individual subproblems without compromising the time‐accuracy at the coupled problem level. This feature is the main distinction between our framework and other approaches. To demonstrate the framework, we construct a family of partitioned heterogeneous time‐integration methods, combining multistage and multistep methods, for a simplified tracer transport component of the coupled air‐sea system in Earth system models. We report numerical tests evaluating accuracy and flux conservation for different pairs of time‐integrators from the explicit Runge‐Kutta and Adams‐Moulton families.
Bibliography:Funding information
K. Chad Sockwell, the lead author of this article, passed away unexpectedly in May of 2022. He was a great friend, brimming with ideas and a contagious enthusiasm for his research. He is dearly missed and we appreciate his very significant contribution to this work.
U.S. Department of Energy, Grant/Award Numbers: DE‐NA0003525; DE‐SC‐0000230927
USDOE
DE‐NA0003525; DE‐SC‐0000230927
ISSN:0749-159X
1098-2426
DOI:10.1002/num.23015