Presentation is loading. Please wait.

Presentation is loading. Please wait.

Simulating Changing Basin Morphology Using Shoreline Tracking and the Water Wave Equations Jared Barber Program in Applied Mathematics, University of Arizona.

Published byJanel Carson Modified over 9 years ago

Similar presentations

Presentation on theme: "Simulating Changing Basin Morphology Using Shoreline Tracking and the Water Wave Equations Jared Barber Program in Applied Mathematics, University of Arizona."— Presentation transcript:

1 Simulating Changing Basin Morphology Using Shoreline Tracking and the Water Wave Equations Jared Barber Program in Applied Mathematics, University of Arizona Collaborators: Juan M. Restrepo, James M. Hyman, Brad Weir

2 Applications Shoreline Erosion Shoreline Erosion Wave Runup Wave Runup Wave Setup and Setdown Wave Setup and Setdown Flooding and Draining Flooding and Draining Water/Ice dynamics (w/land) Water/Ice dynamics (w/land)

3 Numerical Goals Solving SWWE Solving SWWE Encompasses all numerical difficulties Encompasses all numerical difficulties Simplified sediment dynamics model Simplified sediment dynamics model Multiply-connected domains Multiply-connected domains Efficiency and flexibility for 1, 2, and 3-d Efficiency and flexibility for 1, 2, and 3-d Bottom topography erosion-wet and dry sand Bottom topography erosion-wet and dry sand Conservative Solver Conservative Solver Convergent Convergent

4 Background-Others Leveque (2006, unpublished)-Riemann Solver FVM Leveque (2006, unpublished)-Riemann Solver FVM Brocchini et al (2001)-Piston Problem at shore Brocchini et al (2001)-Piston Problem at shore Y. Uchiyama (2004)-POM Y. Uchiyama (2004)-POM Prasad and Svendsen (2003)-SHORECIRC Prasad and Svendsen (2003)-SHORECIRC Toro (1992)-WAF method Toro (1992)-WAF method

5 Background-Shallow Water Wave Equations u Assume: Assume: SWWE: SWWE: Conservative Eqns Conservative Eqns Add in ρ Add in ρ Mass and Momentum Mass and Momentum

6 Lagrangian Shoreline Tracking and Changing h(x,t) First Equation in Lagrangian Coords for shoreline First Equation in Lagrangian Coords for shoreline Use other shoreline eqns: Use other shoreline eqns: Add in eqn for h (p=0, numerically satisfactory): Add in eqn for h (p=0, numerically satisfactory):

7 Integration Process

8 Find

9 Integration Process Find ODE integrate u s eqn.

10 Integration Process Find ODE integrate u s eqn. Integrate SWWE with FVM-LF

11 Integration Process Find ODE integrate u s eqn. Integrate SWWE with FVM-LF Integrate h(x,t) eqn

12 Integration Process Find ODE integrate u s eqn. Integrate SWWE with FVM-LF Integrate h(x,t) eqn Make necessary mesh adjustments

13 Results-CG LF: 32 cells-Works Well-Copies Real thing

14 Results-Islands Works Well-Adaptive/Robust

15 Results-Changing h Works Well-Able to incorporate changing h

16 Improvements/Future Work Converges to Analytical Solutions Converges to Analytical Solutions Highly adaptive/Robust-appearing and disappearing islands Highly adaptive/Robust-appearing and disappearing islands Efficient and energy and mass conserving Efficient and energy and mass conserving Boundary discontinuities: Implement dry sand dynamics Boundary discontinuities: Implement dry sand dynamics Moving Mesh-ODE and FVM Integration, Interpolation Moving Mesh-ODE and FVM Integration, Interpolation Generalize to 2-d Generalize to 2-d Able to incorporate other phenomena (h) Able to incorporate other phenomena (h)

17 Thanks Ocean Sciences Conference Ocean Sciences Conference Juan Restrepo, Brad Weir - Collaborators Juan Restrepo, Brad Weir - Collaborators

Download ppt "Simulating Changing Basin Morphology Using Shoreline Tracking and the Water Wave Equations Jared Barber Program in Applied Mathematics, University of Arizona."

Similar presentations

Modeling Basics: 4. Numerical ODE Solving In Excel 5. Solving ODEs in Mathematica By Peter Woolf University of Michigan Michigan Chemical Process Dynamics.

Modeling Basics: 4. Numerical ODE Solving In Excel 5. Solving ODEs in Mathematica By Peter Woolf University of Michigan Michigan Chemical Process Dynamics.
Reinaldo Garcia, PhD A proposal for testing two-dimensional models to use in the National Flood Insurance Program.

Reinaldo Garcia, PhD A proposal for testing two-dimensional models to use in the National Flood Insurance Program.
Coupling Continuum Model and Smoothed Particle Hydrodynamics Methods for Reactive Transport Yilin Fang, Timothy D Scheibe and Alexandre M Tartakovsky Pacific.

Coupling Continuum Model and Smoothed Particle Hydrodynamics Methods for Reactive Transport Yilin Fang, Timothy D Scheibe and Alexandre M Tartakovsky Pacific.
Tides Dynamic Theory of Tides Ideal Open Ocean Tide Theory Adds in Coriolis effect and actual depth and shape of ocean basins Tidal energy reflects of.

Tides Dynamic Theory of Tides Ideal Open Ocean Tide Theory Adds in Coriolis effect and actual depth and shape of ocean basins Tidal energy reflects of.
P. N. Vinayachandran Centre for Atmospheric and Oceanic Sciences (CAOS) Indian Institute of Science (IISc) Bangalore 560 012 Summer.

P. N. Vinayachandran Centre for Atmospheric and Oceanic Sciences (CAOS) Indian Institute of Science (IISc) Bangalore Summer.
Introduction to numerical simulation of fluid flows

Introduction to numerical simulation of fluid flows
A Bezier Based Approach to Unstructured Moving Meshes ALADDIN and Sangria Gary Miller David Cardoze Todd Phillips Noel Walkington Mark Olah Miklos Bergou.

A Bezier Based Approach to Unstructured Moving Meshes ALADDIN and Sangria Gary Miller David Cardoze Todd Phillips Noel Walkington Mark Olah Miklos Bergou.
Peyman Mostaghimi, Martin Blunt, Branko Bijeljic 11 th January 2010, Pore-scale project meeting Direct Numerical Simulation of Transport Phenomena on Pore-space.

Peyman Mostaghimi, Martin Blunt, Branko Bijeljic 11 th January 2010, Pore-scale project meeting Direct Numerical Simulation of Transport Phenomena on Pore-space.
ASCI/Alliances Center for Astrophysical Thermonuclear Flashes Simulating Self-Gravitating Flows with FLASH P. M. Ricker, K. Olson, and F. X. Timmes Motivation:

ASCI/Alliances Center for Astrophysical Thermonuclear Flashes Simulating Self-Gravitating Flows with FLASH P. M. Ricker, K. Olson, and F. X. Timmes Motivation:
National Center for Earth-surface Dynamics Modeling physical and ecological dynamics of channel systems that shape Earth’s surface Moving boundary problems.

National Center for Earth-surface Dynamics Modeling physical and ecological dynamics of channel systems that shape Earth’s surface Moving boundary problems.
COUPLED MODELING River – Delta Plain to Longshore Transport Irina Overeem Andrew Ashton Eric Hutton.

COUPLED MODELING River – Delta Plain to Longshore Transport Irina Overeem Andrew Ashton Eric Hutton.
X y ocean 2L L Island Recharge Problem ocean well R= 0.00305 ft/d T= 10,000 ft 2 /day.

X y ocean 2L L Island Recharge Problem ocean well R= ft/d T= 10,000 ft 2 /day.
Modeling Fluid Phenomena -Vinay Bondhugula (25 th & 27 th April 2006)

Modeling Fluid Phenomena -Vinay Bondhugula (25 th & 27 th April 2006)
Island Recharge Problem

Island Recharge Problem
Non-hydrostatic algorithm and dynamics in ROMS Yuliya Kanarska, Alexander Shchepetkin, Alexander Shchepetkin, James C. McWilliams, IGPP, UCLA.

Non-hydrostatic algorithm and dynamics in ROMS Yuliya Kanarska, Alexander Shchepetkin, Alexander Shchepetkin, James C. McWilliams, IGPP, UCLA.
An example moving boundary problem Dry porous media Saturated porous media x = 0 x = s(t) h(0) = L Fixed Head If water head remains at fixed value L at.

An example moving boundary problem Dry porous media Saturated porous media x = 0 x = s(t) h(0) = L Fixed Head If water head remains at fixed value L at.
Numerical simulation of water erosion models and some physical models in image processing Gloria Haro Ortega December 2003 Universitat Pompeu Fabra.

Numerical simulation of water erosion models and some physical models in image processing Gloria Haro Ortega December 2003 Universitat Pompeu Fabra.
Modeling, Simulating and Rendering Fluids Thanks to Ron Fediw et al, Jos Stam, Henrik Jensen, Ryan.

Modeling, Simulating and Rendering Fluids Thanks to Ron Fediw et al, Jos Stam, Henrik Jensen, Ryan.
Two-Fluid Effective-Field Equations. Mathematical Issues Non-conservative: –Uniqueness of Discontinuous solution? –Pressure oscillations Non-hyperbolic.

Two-Fluid Effective-Field Equations. Mathematical Issues Non-conservative: –Uniqueness of Discontinuous solution? –Pressure oscillations Non-hyperbolic.
Modelling Flow through Fractures in Porous Media Holzbecher Ekkehard Wong LiWah Litz Marie-Sophie Georg-August-University Göttingen, Geological Sciences,

Modelling Flow through Fractures in Porous Media Holzbecher Ekkehard Wong LiWah Litz Marie-Sophie Georg-August-University Göttingen, Geological Sciences,

Similar presentations

Ads by Google