Your search keyword '"Chris Mirabito"' showing total 3 results

1. Fully coupled methods for multiphase morphodynamics

Author

Joannes J. Westerink, Craig Michoski, Chris Mirabito, Damrongsak Wirasaet, Ethan J. Kubatko, and Clint Dawson

Subjects

Engineering, business.industry, Numerical analysis, System of linear equations, Symbolic computation, Finite element method, Discontinuous Galerkin method, Convergence (routing), Dissipative system, Applied mathematics, Geotechnical engineering, business, Shallow water equations, Water Science and Technology

Abstract

We present numerical methods for a system of equations consisting of the two dimensional Saint–Venant shallow water equations (SWEs) fully coupled to a completely generalized Exner formulation of hydrodynamically driven sediment discharge. This formulation is implemented by way of a discontinuous Galerkin (DG) finite element method, using a Roe Flux for the advective components and the unified form for the dissipative components. We implement a number of Runge–Kutta time integrators, including a family of strong stability preserving (SSP) schemes, and Runge–Kutta Chebyshev (RKC) methods. A brief discussion is provided regarding implementational details for generalizable computer algebra tokenization using arbitrary algebraic fluxes. We then run numerical experiments to show standard convergence rates, and discuss important mathematical and numerical nuances that arise due to prominent features in the coupled system, such as the emergence of nondifferentiable and sharp zero crossing functions, radii of convergence in manufactured solutions, and nonconservative product (NCP) formalisms. Finally we present a challenging application model concerning hydrothermal venting across metalliferous muds in the presence of chemical reactions occurring in low pH environments.

Published

2013

2. Dynamic p-enrichment schemes for multicomponent reactive flows

Author

Clinton N Dawson, Damrongsak Wirasaet, Ethan J. Kubatko, Craig Michoski, Chris Mirabito, and Joannes J. Westerink

Subjects

geography, geography.geographical_feature_category, 65Mxx, 65Nxx, 80A30, 80A32, 35-XX, 76-XX, 65-XX, 76Vxx, 76Rxx, Scalar (mathematics), Fluid Dynamics (physics.flu-dyn), Environmental engineering, FOS: Physical sciences, Physics - Fluid Dynamics, 010103 numerical & computational mathematics, Local variation, Inlet, 01 natural sciences, 6. Clean water, 010101 applied mathematics, Discontinuous Galerkin method, Applied mathematics, 0101 mathematics, Data flow model, Water Science and Technology, Mathematics

Abstract

We present a family of p-enrichment schemes. These schemes may be separated into two basic classes: the first, called \emph{fixed tolerance schemes}, rely on setting global scalar tolerances on the local regularity of the solution, and the second, called \emph{dioristic schemes}, rely on time-evolving bounds on the local variation in the solution. Each class of $p$-enrichment scheme is further divided into two basic types. The first type (the Type I schemes) enrich along lines of maximal variation, striving to enhance stable solutions in "areas of highest interest." The second type (the Type II schemes) enrich along lines of maximal regularity in order to maximize the stability of the enrichment process. Each of these schemes are tested over a pair of model problems arising in coastal hydrology. The first is a contaminant transport model, which addresses a declinature problem for a contaminant plume with respect to a bay inlet setting. The second is a multicomponent chemically reactive flow model of estuary eutrophication arising in the Gulf of Mexico., Comment: 29 pages, 7 figures, 3 tables

Published

2011

3. Discontinuous Galerkin methods for modeling Hurricane storm surge

Author

Ethan J. Kubatko, Nishant Panda, Corey J. Trahan, Craig Michoski, Joannes J. Westerink, Chris Mirabito, and Clint Dawson

Subjects

Meteorology, Discontinuous Galerkin method, Wind stress, Storm surge, Storm, Tropical cyclone, Surge, Shallow water equations, Finite element method, Water Science and Technology

Abstract

Storm surge due to hurricanes and tropical storms can result in significant loss of life, property damage, and long-term damage to coastal ecosystems and landscapes. Computer modeling of storm surge can be used for two primary purposes: forecasting of surge as storms approach land for emergency planning and evacuation of coastal populations, and hindcasting of storms for determining risk, development of mitigation strategies, coastal restoration and sustainability. Storm surge is modeled using the shallow water equations, coupled with wind forcing and in some events, models of wave energy. In this paper, we will describe a depth-averaged (2D) model of circulation in spherical coordinates. Tides, riverine forcing, atmospheric pressure, bottom friction, the Coriolis effect and wind stress are all important for characterizing the inundation due to surge. The problem is inherently multi-scale, both in space and time. To model these problems accurately requires significant investments in acquiring high-fidelity input (bathymetry, bottom friction characteristics, land cover data, river flow rates, levees, raised roads and railways, etc.), accurate discretization of the computational domain using unstructured finite element meshes, and numerical methods capable of capturing highly advective flows, wetting and drying, and multi-scale features of the solution. The discontinuous Galerkin (DG) method appears to allow for many of the features necessary to accurately capture storm surge physics. The DG method was developed for modeling shocks and advection-dominated flows on unstructured finite element meshes. It easily allows for adaptivity in both mesh (h) and polynomial order (p) for capturing multi-scale spatial events. Mass conservative wetting and drying algorithms can be formulated within the DG method. In this paper, we will describe the application of the DG method to hurricane storm surge. We discuss the general formulation, and new features which have been added to the model to better capture surge in complex coastal environments. These features include modifications to the method to handle spherical coordinates and maintain still flows, improvements in the stability post-processing (i.e. slope-limiting), and the modeling of internal barriers for capturing overtopping of levees and other structures. We will focus on applications of the model to recent events in the Gulf of Mexico, including Hurricane Ike.

Published

2011