A new partitioned algorithm for explicit elastodynamics based on variational flux recovery
Abstract not provided.
Publications
A Novel Partitioned Approach for Reduced Order Model—Finite Element Model (ROM-FEM) and ROM-ROM Coupling
Earth and Space 2022
Partitioned methods allow one to build a simulation capability for coupled problems by reusing existing single-component codes. In so doing, partitioned methods can shorten code development and validation times for multiphysics and multiscale applications. In this work, we consider a scenario in which one or more of the “codes” being coupled are projection-based reduced order models (ROMs), introduced to lower the computational cost associated with a particular component. We simulate this scenario by considering a model interface problem that is discretized independently on two non-overlapping subdomains. Here we then formulate a partitioned scheme for this problem that allows the coupling between a ROM “code” for one of the subdomains with a finite element model (FEM) or ROM “code” for the other subdomain. The ROM “codes” are constructed by performing proper orthogonal decomposition (POD) on a snapshot ensemble to obtain a low-dimensional reduced order basis, followed by a Galerkin projection onto this basis. The ROM and/or FEM “codes” on each subdomain are then coupled using a Lagrange multiplier representing the interface flux. To partition the resulting monolithic problem, we first eliminate the flux through a dual Schur complement. Application of an explicit time integration scheme to the transformed monolithic problem decouples the subdomain equations, allowing their independent solution for the next time step. We show numerical results that demonstrate the proposed method’s efficacy in achieving both ROM-FEM and ROM-ROM coupling.
A Numerical Compact Photocurrent Model and its Implementation via Xyce-PyMi
Abstract not provided.
A Partitioned Method for Explicit Elastodynamics Based on a Generalized Dual Schur Complement
Abstract not provided.
A Performance Portable Discrete Element Sea Ice Model for Earth System Modeling
Abstract not provided.
A variational flux recovery approach for elastodynamics problems with interfaces
PANACM 2015 - 1st Pan-American Congress on Computational Mechanics, in conjunction with the 11th Argentine Congress on Computational Mechanics, MECOM 2015
We present a new explicit algorithm for linear elastodynamic problems with material interfaces. The method discretizes the governing equations independently on each material subdomain and then connects them by exchanging forces and masses across the material interface. Variational flux recovery techniques provide the force and mass approximations. The new algorithm has attractive computational properties. It allows different discretizations on each material subdomain and enables partitioned solution of the discretized equations. The method passes a linear patch test and recovers the solution of a monolithic discretization of the governing equations when interface grids match.
A variational force recovery approach for elastodynamics problems with interfaces
Abstract not provided.
A virtual control coupling approach for problems with non-coincident discrete interfaces
Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)
Independent meshing of subdomains separated by an interface can lead to spatially non-coincident discrete interfaces. We present an optimization-based coupling method for such problems, which does not require a common mesh refinement of the interface, has optimal H1 convergence rates, and passes a patch test. The method minimizes the mismatch of the state and normal stress extensions on discrete interfaces subject to the subdomain equations, while interface “fluxes” provide virtual Neumann controls.
A virtual control, mesh-free coupling method for non-coincident interfaces
Proceedings of the 6th European Conference on Computational Mechanics: Solids, Structures and Coupled Problems, ECCM 2018 and 7th European Conference on Computational Fluid Dynamics, ECFD 2018
We present an optimization approach with two controls for coupling elliptic partial differential equations posed on subdomains sharing an interface that is discretized independently on each subdomain, introducing gaps and overlaps. We use two virtual Neumann controls, one defined on each discrete interface, thereby eliminating the need for a virtual common refinement interface mesh. Global flux conservation is achieved by including the square of the difference of the total flux on each interface in the objective. We use Generalized Moving Least Squares (GMLS) reconstruction to evaluate and compare the subdomain solution and gradients at quadrature points used in the cost functional. The resulting method recovers globally linear solutions and shows optimal L2-norm and H1-norm convergence.
Advances in the Approximation Theory for Functional Reconstructions Using GMLS and Applications to Meshless Discretization of Differential Equations
Abstract not provided.
Advances in the Approximation Theory for Generalized Moving Least Squares
Abstract not provided.
Advances in the Approximation Theory of Generalized Moving Least Squares
Abstract not provided.
An embedded Python model interpreter for XyceTM (Xyce-PyMi)
This is the documentation for the Xyce-PyMi embedded Python model interpreter in Xyce.
An explicit partitioned elastodynamics method based on Lagrange Multipliers
Abstract not provided.
An optimization-based approach to mesh tying and transmission problems
Abstract not provided.
An optimization-based approach to mesh tying and transmission problems
Abstract not provided.
An Optimization-Based Globally Flux-Conserving Coupling of Problems with Spatially Non-Coincident Interface Discretizations
Abstract not provided.
Analysis of a Fluid-Structure Interaction Problem Decoupled by Optimal Control
Abstract not provided.
Automated Discovery of DOminaNt physics Informed Surrogates (ADDONIS) Framework
Abstract not provided.
Bridging the gap: from algorithm development to mission impact a partitioned elastodynamics example
Abstract not provided.
Bulk-Interface-Flux-Recovery (Bulk-IFR) Method for Coupling the Atmosphere-Ocean Interface
Abstract not provided.
Bulk-Interface-Flux-Recovery (Bulk-IFR) Methodfor Coupling the Atmosphere-Ocean Interface
Abstract not provided.
Compadre Toolkit
Abstract not provided.
Compatible meshfree discretization of surface PDEs
Computational Particle Mechanics
Meshfree discretization of surface partial differential equations is appealing, due to their ability to naturally adapt to deforming motion of the underlying manifold. In this work, we consider an existing scheme proposed by Liang et al. reinterpreted in the context of generalized moving least squares (GMLS), showing that existing numerical analysis from the GMLS literature applies to their scheme. With this interpretation, their approach may then be unified with recent work developing compatible meshfree discretizations for the div-grad problem in Rd. Informally, this is analogous to an extension of collocated finite differences to staggered finite difference methods, but in the manifold setting and with unstructured nodal data. In this way, we obtain a compatible meshfree discretization of elliptic problems on manifolds which is naturally stable for problems with material interfaces, without the need to introduce numerical dissipation or local enrichment near the interface. We provide convergence studies illustrating the high-order convergence and stability of the approach for manufactured solutions and for an adaptation of the classical five-strip benchmark to a cylindrical manifold.
Compatible meshless methods for DPEs
Abstract not provided.
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