PARTITIONED TIME STEPPING FOR A PARABOLIC TWO DOMAIN PROBLEM

There have been many numerical simulations but few analytical results of stability and accuracy of algorithms for computational modeling of fluid-fluid and fluid-structure interaction problems, where two domains corresponding to different fluids (ocean-atmosphere) or a fluid and deformable solid (bl...

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Bibliographic Details
Published in:SIAM journal on numerical analysis 2009-01, Vol.47 (5), p.3526-3549
Main Authors: CONNORS, JEFFREY M., HOWELL, JASON S., LAYTON, WILLIAM J.
Format: Article
Language:English
Subjects:
Algorithms
Approximation
Boundary conditions
Computational fluid dynamics
Decomposition methods
Energy
Error rates
Fluid flow
Fluid-structure interaction
Fluids
Heat equation
Heat equations
Hilbert spaces
Inner products
Interfaces
Iterative methods
Lagrange multiplier
Lagrange multipliers
Mathematical models
Methods
Numerical analysis
Perceptron convergence procedure
Stability
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Summary:There have been many numerical simulations but few analytical results of stability and accuracy of algorithms for computational modeling of fluid-fluid and fluid-structure interaction problems, where two domains corresponding to different fluids (ocean-atmosphere) or a fluid and deformable solid (blood flow) are separated by an interface. As a simplified model of the first examples, this report considers two heat equations in $\Omega _{1},\Omega _{2}\subset {\Bbb R}^{2}$ adjoined by an interface $I=\Omega _{1},\Omega _{2}\subset {\Bbb R}$ . The heat equations are coupled by a condition that allows energy to pass back and forth across the interface I while preserving the total global energy of the monolithic, coupled problem. To compute approximate solutions to the above problem only using subdomain solvers, two first-order in time, fully discrete methods are presented. The methods consist of an implicit-explicit approach, in which the action across I is lagged, and a partitioned method based on passing interface values back and forth across I. Stability and convergence results are derived for both schemes. Numerical experiments that support the theoretical results are presented.
ISSN:0036-1429
1095-7170
DOI:10.1137/080740891