Mass conservation of the unified continuous and discontinuous element-based Galerkin methods on dynamically adaptive grids with application to atmospheric simulations

Kopera, Michal A.; Giraldo, Francis X.

doi:10.1016/j.jcp.2015.05.010

Cited by 16 publications

(13 citation statements)

References 22 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In addition, in the atmospheric sciences DG-FE methods have also been applied to non-hydrostatic modelling. For example, the studies of Restelli and Giraldo (2009), Kelly and Giraldo (2012), Kopera and Giraldo (2015), Abdi and Giraldo (2016), and Abdi et al (2017) consider the compressible Euler equations where a non-hydrostatic pressure is obtained from the equation of state. In contrast to the majority of this prior work, the multi-layer nonhydrostatic modelling approach we employ here does not solve the 3D equations, but rather adopts an edge-based approach (following zStelling and Zijlema (2003)) to handle the inter-layer connections associated with the vertical velocities at the layer interfaces.…”

Section: And Thementioning

confidence: 99%

Multi-layer non-hydrostatic free surface modelling using the discontinuous Galerkin method

2019

View full text Add to dashboard Cite

A multi-layer non-hydrostatic version of the unstructured mesh, discontinuous Galerkin finite element based coastal ocean model, Thetis, is developed. This is accomplished using the PDE solver framework, Firedrake, which is used to automatically produce the code for the discretised model equations in a rapid and efficient manner. The motivation for this work is a need to accurately simulate dispersive nearshore free surface processes. In order to resolve both frequency dispersion and non-linear effects accurately, additional non-hydrostatic terms are included in the layer-integrated hydrostatic equations, producing a form similar to the layered non-linear shallow water equations, but with extra vertical velocities at the layer interfaces. An implementation process is adopted to easily handle the inter-layer connection, i.e. the governing equations are transformed into a depth-integrated system through the introduction of depth-averaged variables. The model is verified and validated through comparisons against several idealised and experimentally-based test cases. All the comparisons demonstrate good agreement, showing that the developed non-hydrostatic model has excellent capabilities in representing coastal wave phenomena including shoaling, refraction and diffraction of dispersive short waves, as well as propagation, run-up and inundation of non-linear tsunami waves.

show abstract

Section: And Thementioning

confidence: 99%

Multi-layer non-hydrostatic free surface modelling using the discontinuous Galerkin method

2019

View full text Add to dashboard Cite

show abstract

“…We briefly outline our method of handling such non-conforming meshes and restrict ourselves to the analysis of balanced non-conforming grids, in which only one "hanging node" is permitted at each interface. We refer the reader to [25][26][27] for the details of the presented mesh refinement procedures.…”

Section: Non-conforming Meshesmentioning

confidence: 99%

Discontinuous Galerkin scheme for the spherical shallow water equations with applications to tsunami modeling and prediction

Bonev

Hesthaven

Giraldo

et al. 2018

Journal of Computational Physics

Self Cite

View full text Add to dashboard Cite

We present a novel high-order discontinuous Galerkin discretization for the spherical shallow water equations, able to handle wetting/drying and non-conforming, curved meshes in a well-balanced manner. This requires a well-balanced discretization, that cannot rely on exact quadrature, due to the curved mesh. Using the strong form of the discontinuous Galerkin discretization, we achieve a splitting of the well-balanced condition into individual problems for the flux and volume terms, which has significant advantages: It allows for the construction of non-conforming, well-balanced flux discretizations, i.e. we can perform nonconforming mesh refinement while preserving the well-balanced property of the scheme. More importantly, this approach enables the development of a new method for handling wet/dry transitions. In contrast to other wetting/drying methods, it is well-balanced and able to handle wetting/drying robustly at any polynomial order, without the introduction of physical model assumptions such as viscosity, artificial porosity or cancellation of gravity. We perform a series of one-dimensional tests and analyze the properties of our scheme. In order to validate our method for the simulation of large-scale tsunami events on the rotating sphere, we perform numerical simulations of the 2011 Tohoku tsunami and compare our results to real-world buoy data. The method is able to predict arrival times and wave amplitudes accurately even over long distances. This indicates that our method accurately captures all physical phenomena relevant to the long-term evolution of tsunami waves.

show abstract

“…An application of the pointwise-matching scheme to geophysical simulations can be found in [258]. In [185], Kopera and Giraldo presented a unified framwework including both CG and DG methods, as well as integral projection (for DG) and pointwise-matching (for CG) schemes for non-conforming interfaces and found that similar mass conservation properties can be obtained for both configurations.…”

Section: Mortar Elements For Dg and Application To Atmospheric Simulamentioning

confidence: 99%

“…28 presents schematics for both methods, the actual implementation in the code may di er. Details of CG interpolation method implementation is presented in [185], along with a unified implementation of the CG/DG method.…”

Section: Perform the Time-stepˆq T = Rhsmentioning

confidence: 99%

A Review of Element-Based Galerkin Methods for Numerical Weather Prediction: Finite Elements, Spectral Elements, and Discontinuous Galerkin

Marras

Kelly²,

Moragues

et al. 2015

Arch Computat Methods Eng

Self Cite

View full text Add to dashboard Cite

Numerical Weather Prediction (NWP) is in a period of transition. As resolutions increase, global models are moving towards fully nonhydrostatic dynamical cores, with the local and global models using the same governing equations; therefore we have reached a point where it will be necessary to use a single model for both applications. The new dynamical cores at the heart of these unified models are designed to scale e ciently on clusters with hundreds of thousands or even millions of CPU cores and GPUs. Operational and research NWP codes currently use a wide range of numerical methods: finite di erences, spectral transform, finite volumes and, increasingly, finite/spectral elements and discontinuous Galerkin, which constitute element-based Galerkin (EBG) methods. Due to their important role in this transition, will EBGs be the dominant power behind NWP in the next 10 years, or will they just be one of many methods to choose from? One decade after the review of numerical methods for atmospheric modeling by Steppeler et al. (2003) [Review of numerical methods for nonhydrostatic weather prediction models Meteorol. Atmos. Phys. 82, 2003], this review discusses EBG methods as a viable numerical approach for the next-generation NWP models. One well-known weakness of EBG methods is the generation of unphysical oscillations in advection-dominated flows; special attention is hence devoted to dissipation-based stabilization methods. Since EBGs are geometrically flexible and allow both conforming and non-conforming meshes, as well as grid adaptivity, this review is concluded with a short overview of how mesh generation and dynamic mesh refinement are becoming as important for atmospheric modeling as they have been for engineering applications for many years.

show abstract

Mass conservation of the unified continuous and discontinuous element-based Galerkin methods on dynamically adaptive grids with application to atmospheric simulations

Cited by 16 publications

References 22 publications

Multi-layer non-hydrostatic free surface modelling using the discontinuous Galerkin method

Multi-layer non-hydrostatic free surface modelling using the discontinuous Galerkin method

Discontinuous Galerkin scheme for the spherical shallow water equations with applications to tsunami modeling and prediction

A Review of Element-Based Galerkin Methods for Numerical Weather Prediction: Finite Elements, Spectral Elements, and Discontinuous Galerkin

Contact Info

Product

Resources

About