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andrewwinters5000 authored Apr 2, 2024
2 parents c819826 + 35126fb commit 7e728ea
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using OrdinaryDiffEq
using Trixi
using TrixiShallowWater

###############################################################################
# Semidiscretization of the multilayer shallow water equations with three layers

equations = ShallowWaterMultiLayerEquations1D(gravity_constant = 10.0,
rhos = (0.9, 1.0, 1.1))

initial_condition = initial_condition_convergence_test

###############################################################################
# Get the DG approximation space

volume_flux = (flux_ersing_etal, flux_nonconservative_ersing_etal)
solver = DGSEM(polydeg = 3,
surface_flux = (flux_ersing_etal, flux_nonconservative_ersing_etal),
volume_integral = VolumeIntegralFluxDifferencing(volume_flux))

###############################################################################
# Get the TreeMesh and setup a periodic mesh

coordinates_min = 0.0
coordinates_max = sqrt(2.0)
mesh = TreeMesh(coordinates_min, coordinates_max,
initial_refinement_level = 4,
n_cells_max = 10_000,
periodicity = true)

# create the semi discretization object
semi = SemidiscretizationHyperbolic(mesh, equations, initial_condition, solver,
source_terms = source_terms_convergence_test)

###############################################################################
# ODE solvers, callbacks etc.

tspan = (0.0, 1.0)
ode = semidiscretize(semi, tspan)

summary_callback = SummaryCallback()

analysis_interval = 500
analysis_callback = AnalysisCallback(semi, interval = analysis_interval)

alive_callback = AliveCallback(analysis_interval = analysis_interval)

save_solution = SaveSolutionCallback(interval = 500,
save_initial_solution = true,
save_final_solution = true)

callbacks = CallbackSet(summary_callback, analysis_callback, alive_callback, save_solution)

###############################################################################
# run the simulation

# use a Runge-Kutta method with automatic (error based) time step size control
sol = solve(ode, RDPK3SpFSAL49(), abstol = 1.0e-8, reltol = 1.0e-8,
save_everystep = false, callback = callbacks);
summary_callback() # print the timer summary
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using OrdinaryDiffEq
using Trixi
using TrixiShallowWater

###############################################################################
# Semidiscretization of the multilayer shallow water equations for a dam break
# test with a discontinuous bottom topography function to test entropy conservation

equations = ShallowWaterMultiLayerEquations1D(gravity_constant = 9.81,
rhos = (0.85, 0.9, 1.0))

# Initial condition of a dam break with a discontinuous water heights and bottom topography.
# Works as intended for TreeMesh1D with `initial_refinement_level=5`. If the mesh
# refinement level is changed the initial condition below may need changed as well to
# ensure that the discontinuities lie on an element interface.
function initial_condition_dam_break(x, t, equations::ShallowWaterMultiLayerEquations1D)
v = [0.0, 0.0, 0.0]

# Set the discontinuity
if x[1] <= 10.0
H = [6.0, 4.0, 2.0]
b = 0.0
else
H = [5.5, 3.5, 1.5]
b = 0.5
end

return prim2cons(SVector(H..., v..., b), equations)
end

initial_condition = initial_condition_dam_break

###############################################################################
# Get the DG approximation space

volume_flux = (flux_ersing_etal, flux_nonconservative_ersing_etal)
solver = DGSEM(polydeg = 3,
surface_flux = (flux_ersing_etal, flux_nonconservative_ersing_etal),
volume_integral = VolumeIntegralFluxDifferencing(volume_flux))

###############################################################################
# Get the TreeMesh and setup a non-periodic mesh

coordinates_min = 0.0
coordinates_max = 20.0
mesh = TreeMesh(coordinates_min, coordinates_max,
initial_refinement_level = 5,
n_cells_max = 10000,
periodicity = false)

boundary_condition = boundary_condition_slip_wall

# create the semidiscretization object
semi = SemidiscretizationHyperbolic(mesh, equations, initial_condition, solver,
boundary_conditions = boundary_condition)

###############################################################################
# ODE solvers

tspan = (0.0, 0.4)
ode = semidiscretize(semi, tspan)

###############################################################################
# Callbacks

summary_callback = SummaryCallback()

analysis_interval = 500
analysis_callback = AnalysisCallback(semi, interval = analysis_interval,
save_analysis = false,
extra_analysis_integrals = (energy_total,
energy_kinetic,
energy_internal))

stepsize_callback = StepsizeCallback(cfl = 1.0)

alive_callback = AliveCallback(analysis_interval = analysis_interval)

save_solution = SaveSolutionCallback(interval = 500,
save_initial_solution = true,
save_final_solution = true)

callbacks = CallbackSet(summary_callback, analysis_callback, alive_callback, save_solution)

###############################################################################
# run the simulation

# use a Runge-Kutta method with automatic (error based) time step size control
sol = solve(ode, RDPK3SpFSAL49(), abstol = 1.0e-8, reltol = 1.0e-8,
save_everystep = false, callback = callbacks);
summary_callback() # print the timer summary
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using OrdinaryDiffEq
using Trixi
using TrixiShallowWater

###############################################################################
# Semidiscretization of the multilayer shallow water equations for a dam break
# test with a discontinuous bottom topography function for an entropy stable flux

equations = ShallowWaterMultiLayerEquations1D(gravity_constant = 9.81,
rhos = (0.85, 0.9, 1.0))

# Initial condition of a dam break with a discontinuous water heights and bottom topography.
# Works as intended for TreeMesh1D with `initial_refinement_level=5`. If the mesh
# refinement level is changed the initial condition below may need changed as well to
# ensure that the discontinuities lie on an element interface.
function initial_condition_dam_break(x, t, equations::ShallowWaterMultiLayerEquations1D)
v = [0.0, 0.0, 0.0]

# Set the discontinuity
if x[1] <= 10.0
H = [6.0, 4.0, 2.0]
b = 0.0
else
H = [5.5, 3.5, 1.5]
b = 0.5
end

return prim2cons(SVector(H..., v..., b), equations)
end

initial_condition = initial_condition_dam_break

###############################################################################
# Get the DG approximation space

volume_flux = (flux_ersing_etal, flux_nonconservative_ersing_etal)
solver = DGSEM(polydeg = 3,
surface_flux = (FluxPlusDissipation(flux_ersing_etal,
DissipationLocalLaxFriedrichs()),
flux_nonconservative_ersing_etal),
volume_integral = VolumeIntegralFluxDifferencing(volume_flux))

###############################################################################
# Get the TreeMesh and setup a non-periodic mesh

coordinates_min = 0.0
coordinates_max = 20.0
mesh = TreeMesh(coordinates_min, coordinates_max,
initial_refinement_level = 5,
n_cells_max = 10000,
periodicity = false)

boundary_condition = boundary_condition_slip_wall

# create the semidiscretization object
semi = SemidiscretizationHyperbolic(mesh, equations, initial_condition, solver,
boundary_conditions = boundary_condition)

###############################################################################
# ODE solvers

tspan = (0.0, 0.4)
ode = semidiscretize(semi, tspan)

###############################################################################
# Callbacks

summary_callback = SummaryCallback()

analysis_interval = 500
analysis_callback = AnalysisCallback(semi, interval = analysis_interval,
save_analysis = false,
extra_analysis_integrals = (energy_total,
energy_kinetic,
energy_internal))

stepsize_callback = StepsizeCallback(cfl = 1.0)

alive_callback = AliveCallback(analysis_interval = analysis_interval)

save_solution = SaveSolutionCallback(interval = 500,
save_initial_solution = true,
save_final_solution = true)

callbacks = CallbackSet(summary_callback, analysis_callback, alive_callback, save_solution)

###############################################################################
# run the simulation

# use a Runge-Kutta method with automatic (error based) time step size control
sol = solve(ode, RDPK3SpFSAL49(), abstol = 1.0e-8, reltol = 1.0e-8,
save_everystep = false, callback = callbacks);
summary_callback() # print the timer summary
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using OrdinaryDiffEq
using Trixi
using TrixiShallowWater

###############################################################################
# Semidiscretization of the multilayer shallow water equations to test well-balancedness

equations = ShallowWaterMultiLayerEquations1D(gravity_constant = 1.0, H0 = 0.7,
rhos = (0.8, 0.9, 1.0))

"""
initial_condition_fjordholm_well_balanced(x, t, equations::ShallowWaterMultiLayerEquations1D)
Initial condition to test well balanced with a bottom topography adapted from Fjordholm
- Ulrik Skre Fjordholm (2012)
Energy conservative and stable schemes for the two-layer shallow water equations.
[DOI: 10.1142/9789814417099_0039](https://doi.org/10.1142/9789814417099_0039)
"""
function initial_condition_fjordholm_well_balanced(x, t,
equations::ShallowWaterMultiLayerEquations1D)
inicenter = 0.5
x_norm = x[1] - inicenter
r = abs(x_norm)

H = [0.7, 0.6, 0.5]
v = [0.0, 0.0, 0.0]
b = r <= 0.1 ? 0.2 * (cos(10 * pi * (x[1] - 0.5)) + 1) : 0.0

return prim2cons(SVector(H..., v..., b), equations)
end

initial_condition = initial_condition_fjordholm_well_balanced

###############################################################################
# Get the DG approximation space

volume_flux = (flux_ersing_etal, flux_nonconservative_ersing_etal)
solver = DGSEM(polydeg = 3,
surface_flux = (flux_ersing_etal, flux_nonconservative_ersing_etal),
volume_integral = VolumeIntegralFluxDifferencing(volume_flux))

###############################################################################
# Get the TreeMesh and setup a periodic mesh

coordinates_min = 0.0
coordinates_max = 1.0
mesh = TreeMesh(coordinates_min, coordinates_max,
initial_refinement_level = 4,
n_cells_max = 10_000,
periodicity = true)

# create the semi discretization object
semi = SemidiscretizationHyperbolic(mesh, equations, initial_condition, solver)

###############################################################################
# ODE solvers, callbacks etc.

tspan = (0.0, 10.0)
ode = semidiscretize(semi, tspan)

summary_callback = SummaryCallback()

analysis_interval = 1000
analysis_callback = AnalysisCallback(semi, interval = analysis_interval,
save_analysis = false,
extra_analysis_integrals = (lake_at_rest_error,))

stepsize_callback = StepsizeCallback(cfl = 1.0)

alive_callback = AliveCallback(analysis_interval = analysis_interval)

save_solution = SaveSolutionCallback(interval = 1000,
save_initial_solution = true,
save_final_solution = true)

callbacks = CallbackSet(summary_callback, analysis_callback, alive_callback, save_solution,
stepsize_callback)

###############################################################################
# run the simulation

sol = solve(ode, CarpenterKennedy2N54(williamson_condition = false),
dt = 1.0, # solve needs some value here but it will be overwritten by the stepsize_callback
save_everystep = false, callback = callbacks);
summary_callback() # print the timer summary
12 changes: 7 additions & 5 deletions src/TrixiShallowWater.jl
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Expand Up @@ -8,7 +8,7 @@ using Trixi
# Import additional symbols that are not exported by Trixi.jl
using Trixi: get_node_vars, set_node_vars!, waterheight
using MuladdMacro: @muladd
using StaticArrays: SVector, @SMatrix
using StaticArrays: SVector, @SMatrix, MVector
using Static: True, False
using LinearAlgebra: norm

Expand All @@ -19,15 +19,17 @@ include("solvers/indicators.jl")

# Export types/functions that define the public API of TrixiShallowWater.jl
export ShallowWaterEquationsWetDry1D, ShallowWaterEquationsWetDry2D,
ShallowWaterTwoLayerEquations1D, ShallowWaterTwoLayerEquations2D
ShallowWaterTwoLayerEquations1D, ShallowWaterTwoLayerEquations2D,
ShallowWaterMultiLayerEquations1D

export hydrostatic_reconstruction_chen_noelle, flux_nonconservative_chen_noelle,
min_max_speed_chen_noelle,
flux_hll_chen_noelle
min_max_speed_chen_noelle, flux_hll_chen_noelle,
flux_ersing_etal, flux_es_ersing_etal

export flux_es_ersing_etal
export nlayers, eachlayer

export PositivityPreservingLimiterShallowWater

export IndicatorHennemannGassnerShallowWater

end
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