Performance and Scalability of Hierarchical Hybrid Multigrid Solvers for Stokes Systems

Gmeiner, Björn; Rüde, Ulrich; Stengel, Holger; Waluga, Christian; Wohlmuth, Barbara

doi:10.1137/130941353

Cited by 61 publications

(77 citation statements)

References 36 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In the case of the block‐diagonal preconditioner with symmetric pointwise Gauss–Seidel relaxation, the preconditioner is symmetric and positive‐definite, and thus, we use the minimal residual method as the Krylov method; for the other preconditioners, we use the generalized minimal residual (GMRES) method . The solvers were all implemented in Trilinos , and the finite‐element discretization was implemented using FEniCS .Remark As this paper focuses on geometric multigrid methods, it could be possible to implement the resulting algorithms in a matrix‐free way using fixed operator stencils on uniform meshes or patches (e.g., ). For all examples, we explicitly form and store all of the matrices involved and report timings including computation of Galerkin coarse‐grid operators in the setup phase.…”

Section: Numerical Resultsmentioning

confidence: 99%

“…As this paper focuses on geometric multigrid methods, it could be possible to implement the resulting algorithms in a matrix-free way using fixed operator stencils on uniform meshes or patches (e.g., [34]). For all examples, we explicitly form and store all of the matrices involved and report timings including computation of Galerkin coarse-grid operators in the setup phase.…”

Section: Remarkmentioning

confidence: 99%

See 1 more Smart Citation

Preconditioning a mass‐conserving discontinuous Galerkin discretization of the Stokes equations

Adler

Benson

MacLachlan

2016

Numerical Linear Algebra App

View full text Add to dashboard Cite

SUMMARYThe incompressible. Stokes equations are a widely used model of viscous or tightly confined flow in which convection effects are negligible. In order to strongly enforce the conservation of mass at the element scale, special discretization techniques must be employed. In this paper, we consider a discontinuous Galerkin approximation in which the velocity field is H.div; /-conforming and divergence-free, based on the Brezzi, Douglas, and Marini finite-element space, with complementary space (P 0 ) for the pressure. Because of the saddle-point structure and the nature of the resulting variational formulation, the linear systems can be difficult to solve. Therefore, specialized preconditioning strategies are required in order to efficiently solve these systems. We compare the effectiveness of two families of preconditioners for saddle-point systems when applied to the resulting matrix problem. Specifically, we consider block-factorization techniques, in which the velocity block is preconditioned using geometric multigrid, as well as fully coupled monolithic multigrid methods. We present parameter study data and a serial timing comparison, and we show that a monolithic multigrid preconditioner using Braess-Sarazin style relaxation provides the fastest time to solution for the test problem considered.

show abstract

Section: Numerical Resultsmentioning

confidence: 99%

Section: Remarkmentioning

confidence: 99%

Preconditioning a mass‐conserving discontinuous Galerkin discretization of the Stokes equations

Adler

Benson

MacLachlan

2016

Numerical Linear Algebra App

View full text Add to dashboard Cite

show abstract

“…Based on a similar approach, HHG was designed as a multigrid library with excellent efficiency for scalar elliptic problems [2,10] and for Stokes flow [3,11,12]. The largest published results reach up to 10 13 degrees of freedom (DoFs) [3], exceeding the capability of alternative approaches by several orders of magnitude.…”

Section: Motivationmentioning

confidence: 99%

“…Unstructured meshes have the advantage of geometric flexibility, however, the implementation is often less efficient and can at this time not reach simulation sizes as e. g. demonstrated in [3,11,12]. Structured meshes support matrix-free methods that can be used to save memory and memory access bandwidth.…”

Section: Related Workmentioning

confidence: 99%

A Scalable and Modular Software Architecture for Finite Elements on Hierarchical Hybrid Grids

Kohl¹,

Thönnes²,

Drzisga³

et al. 2019

From Parallel to Emergent Computing

Self Cite

View full text Add to dashboard Cite

In this article, a new generic higher-order finite-element framework for massively parallel simulations is presented. The modular software architecture is carefully designed to exploit the resources of modern and future supercomputers. Combining an unstructured topology with structured grid refinement facilitates high geometric adaptability and matrix-free multigrid implementations with excellent performance. Different abstraction levels and fully distributed data structures additionally ensure high flexibility, extensibility, and scalability. The software concepts support sophisticated load balancing and flexibly combining finite element spaces. Example scenarios with coupled systems of PDEs show the applicability of the concepts to performing geophysical simulations.

show abstract

“…Thirdly, they might be more efficient than higher order elements, which results in denser matrices. This is especially true on supercomputers and for non-linear applications [16,34]. Furthermore, ice-sheet modeling usually involves data with high uncertainty so that a elements may outperform higher order elements for any realistic accuracy requirement.…”

Section: Introductionmentioning

confidence: 99%

Stabilized equal low-order finite elements in ice sheet modeling – accuracy and robustness

Helanow

Ahlkrona

2018

Comput Geosci

View full text Add to dashboard Cite

We investigate the accuracy and robustness of one of the most common methods used in glaciology for finite element discretization of the p-Stokes equations: linear equal order finite elements with Galerkin least-squares (GLS) stabilization on anisotropic meshes. Furthermore, we compare the results to other stabilized methods. We find that the vertical velocity component is more sensitive to the choice of GLS stabilization parameter than horizontal velocity. Additionally, the accuracy of the vertical velocity component is especially important since errors in this component can cause ice surface instabilities and propagate into future ice volume predictions. If the element cell size is set to the minimum edge length and the stabilization parameter is allowed to vary non-linearly with viscosity, the GLS stabilization parameter found in literature is a good choice on simple domains. However, near ice margins the standard parameter choice may result in significant oscillations in the vertical component of the surface velocity. For these reasons, other stabilization techniques, in particular the interior penalty method, result in better accuracy and are less sensitive to the choice of stabilization parameter. During this work, we also discovered that the manufactured solutions often used to evaluate errors in glaciology are not reliable due to high artificial surface forces at singularities. We perform our numerical experiments in both FEniCS and Elmer/Ice.

show abstract

Performance and Scalability of Hierarchical Hybrid Multigrid Solvers for Stokes Systems

Cited by 61 publications

References 36 publications

Preconditioning a mass‐conserving discontinuous Galerkin discretization of the Stokes equations

Preconditioning a mass‐conserving discontinuous Galerkin discretization of the Stokes equations

A Scalable and Modular Software Architecture for Finite Elements on Hierarchical Hybrid Grids

Stabilized equal low-order finite elements in ice sheet modeling – accuracy and robustness

Contact Info

Product

Resources

About