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Add two-sided Zalesak-type IDP subcell limiting #1648

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1a2eb00
Add two-sided limiting for conservative variables
bennibolm Sep 26, 2023
ab9e5d9
Fix visualization routines
bennibolm Sep 26, 2023
534f148
Add bounds calculation for BoundaryConditionDirichlet
bennibolm Sep 26, 2023
9b0eee9
Reduce cfl in elixir
bennibolm Sep 26, 2023
3e6f7f8
Fix test
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d7dcb75
Merge branch 'main' into subcell-limiting-minmax
bennibolm Oct 12, 2023
de23b58
Add comment about subcell limiting with non-conforming meshes
bennibolm Oct 13, 2023
96be070
Remove subcell visualization
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fb4d876
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2d8b49d
Remove @unpack
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Add comment to `News.md`
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2d7ce45
Fix source for sedov blast setup; Formatting
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Reduce allocations
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39b39b6
Replace construction of Symbols
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Merge branch 'main' into subcell-limiting-minmax
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535f520
Add bounds check for local limiting
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5b2b888
Implement suggestions
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Fix format
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Merge branch 'main' into subcell-limiting-minmax
sloede Oct 25, 2023
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Merge branch 'main' into subcell-limiting-minmax
bennibolm Nov 2, 2023
6d01643
Add subcell allocation tests; Add changes to minmax limiter
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306fb19
Undo changes in elixirs
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5adf14c
Implement suggestions
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29ed6ce
Skip positivity limiting if local limiting is more restrictive
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Merge branch 'main' into subcell-limiting-minmax
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Pass variables as strings instead of ints
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Merge branch 'main' into subcell-limiting-minmax
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Fix unit test
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Merge branch 'main' into subcell-limiting-minmax
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Merge branch 'main' into subcell-limiting-minmax
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3 changes: 2 additions & 1 deletion NEWS.md
Original file line number Diff line number Diff line change
Expand Up @@ -12,7 +12,8 @@ for human readability.
- Non-uniform `TreeMesh` available for hyperbolic-parabolic equations.
- Capability to set truly discontinuous initial conditions in 1D.
- Wetting and drying feature and examples for 1D and 2D shallow water equations
- Subcell positivity limiting support for conservative variables in 2D for `TreeMesh`
- Subcell (positivity and local min/max) limiting support for conservative variables
in 2D for `TreeMesh`

#### Changed

Expand Down
96 changes: 96 additions & 0 deletions examples/tree_2d_dgsem/elixir_euler_blast_wave_sc_subcell.jl
Original file line number Diff line number Diff line change
@@ -0,0 +1,96 @@

using OrdinaryDiffEq
using Trixi

###############################################################################
# semidiscretization of the compressible Euler equations

equations = CompressibleEulerEquations2D(1.4)

"""
initial_condition_blast_wave(x, t, equations::CompressibleEulerEquations2D)

A medium blast wave taken from
- Sebastian Hennemann, Gregor J. Gassner (2020)
A provably entropy stable subcell shock capturing approach for high order split form DG
[arXiv: 2008.12044](https://arxiv.org/abs/2008.12044)
"""
function initial_condition_blast_wave(x, t, equations::CompressibleEulerEquations2D)
# Modified From Hennemann & Gassner JCP paper 2020 (Sec. 6.3) -> "medium blast wave"
# Set up polar coordinates
inicenter = SVector(0.0, 0.0)
x_norm = x[1] - inicenter[1]
y_norm = x[2] - inicenter[2]
r = sqrt(x_norm^2 + y_norm^2)
phi = atan(y_norm, x_norm)
sin_phi, cos_phi = sincos(phi)

# Calculate primitive variables
rho = r > 0.5 ? 1.0 : 1.1691
v1 = r > 0.5 ? 0.0 : 0.1882 * cos_phi
v2 = r > 0.5 ? 0.0 : 0.1882 * sin_phi
p = r > 0.5 ? 1.0E-3 : 1.245

return prim2cons(SVector(rho, v1, v2, p), equations)
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end
initial_condition = initial_condition_blast_wave

boundary_condition = BoundaryConditionDirichlet(initial_condition)

surface_flux = flux_lax_friedrichs
volume_flux = flux_ranocha
basis = LobattoLegendreBasis(3)
limiter_idp = SubcellLimiterIDP(equations, basis;
local_minmax_variables_cons=[1])
volume_integral = VolumeIntegralSubcellLimiting(limiter_idp;
volume_flux_dg=volume_flux,
volume_flux_fv=surface_flux)
solver = DGSEM(basis, surface_flux, volume_integral)

coordinates_min = (-2.0, -2.0)
coordinates_max = ( 2.0, 2.0)
mesh = TreeMesh(coordinates_min, coordinates_max,
initial_refinement_level=6,
n_cells_max=10_000,
periodicity=false)


semi = SemidiscretizationHyperbolic(mesh, equations, initial_condition, solver,
boundary_conditions=boundary_condition)


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

tspan = (0.0, 2.0)
ode = semidiscretize(semi, tspan)

summary_callback = SummaryCallback()

analysis_interval = 100
analysis_callback = AnalysisCallback(semi, interval=analysis_interval)

alive_callback = AliveCallback(analysis_interval=analysis_interval)

save_solution = SaveSolutionCallback(interval=100,
save_initial_solution=true,
save_final_solution=true,
solution_variables=cons2prim)

stepsize_callback = StepsizeCallback(cfl=0.3)
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callbacks = CallbackSet(summary_callback,
analysis_callback, alive_callback,
save_solution,
stepsize_callback)


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

stage_callbacks = (SubcellLimiterIDPCorrection(),)

sol = Trixi.solve(ode, Trixi.SimpleSSPRK33(stage_callbacks=stage_callbacks);
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
92 changes: 92 additions & 0 deletions examples/tree_2d_dgsem/elixir_euler_sedov_blast_wave_sc_subcell.jl
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Original file line number Diff line number Diff line change
@@ -0,0 +1,92 @@

using OrdinaryDiffEq
using Trixi

###############################################################################
# semidiscretization of the compressible Euler equations
gamma = 1.4
equations = CompressibleEulerEquations2D(gamma)

"""
initial_condition_sedov_blast_wave(x, t, equations::CompressibleEulerEquations2D)

The Sedov blast wave setup based on Flash
- https://flash.rochester.edu/site/flashcode/user_support/flash_ug_devel/node187.html#SECTION010114000000000000000
"""
function initial_condition_sedov_blast_wave(x, t, equations::CompressibleEulerEquations2D)
# Set up polar coordinates
inicenter = SVector(0.0, 0.0)
x_norm = x[1] - inicenter[1]
y_norm = x[2] - inicenter[2]
r = sqrt(x_norm^2 + y_norm^2)

# Setup based on https://flash.rochester.edu/site/flashcode/user_support/flash_ug_devel/node187.html#SECTION010114000000000000000
r0 = 0.21875 # = 3.5 * smallest dx (for domain length=4 and max-ref=6)
# r0 = 0.5 # = more reasonable setup
E = 1.0
p0_inner = 3 * (equations.gamma - 1) * E / (3 * pi * r0^2)
p0_outer = 1.0e-5 # = true Sedov setup
# p0_outer = 1.0e-3 # = more reasonable setup

# Calculate primitive variables
rho = 1.0
v1 = 0.0
v2 = 0.0
p = r > r0 ? p0_outer : p0_inner

return prim2cons(SVector(rho, v1, v2, p), equations)
end
initial_condition = initial_condition_sedov_blast_wave

surface_flux = flux_lax_friedrichs
volume_flux = flux_chandrashekar
basis = LobattoLegendreBasis(3)
limiter_idp = SubcellLimiterIDP(equations, basis;
local_minmax_variables_cons=[1])
volume_integral = VolumeIntegralSubcellLimiting(limiter_idp;
volume_flux_dg=volume_flux,
volume_flux_fv=surface_flux)
solver = DGSEM(basis, surface_flux, volume_integral)

coordinates_min = (-2.0, -2.0)
coordinates_max = ( 2.0, 2.0)
mesh = TreeMesh(coordinates_min, coordinates_max,
initial_refinement_level=3,
n_cells_max=100_000)

semi = SemidiscretizationHyperbolic(mesh, equations, initial_condition, solver)


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

tspan = (0.0, 3.0)
ode = semidiscretize(semi, tspan)

summary_callback = SummaryCallback()

analysis_interval = 1000
analysis_callback = AnalysisCallback(semi, interval=analysis_interval)

alive_callback = AliveCallback(analysis_interval=analysis_interval)

save_solution = SaveSolutionCallback(interval=1000,
save_initial_solution=true,
save_final_solution=true,
solution_variables=cons2prim)

stepsize_callback = StepsizeCallback(cfl=0.6)
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callbacks = CallbackSet(summary_callback,
analysis_callback, alive_callback,
stepsize_callback,
save_solution)
###############################################################################
# run the simulation

stage_callbacks = (SubcellLimiterIDPCorrection(),)

sol = Trixi.solve(ode, Trixi.SimpleSSPRK33(stage_callbacks=stage_callbacks);
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
Original file line number Diff line number Diff line change
@@ -0,0 +1,139 @@
using OrdinaryDiffEq
using Trixi

###############################################################################
# semidiscretization of the compressible Euler multicomponent equations

# 1) Dry Air 2) Helium + 28% Air
equations = CompressibleEulerMulticomponentEquations2D(gammas = (1.4, 1.648),
gas_constants = (0.287, 1.578))

"""
initial_condition_shock_bubble(x, t, equations::CompressibleEulerMulticomponentEquations2D{5, 2})

A shock-bubble testcase for multicomponent Euler equations
- Ayoub Gouasmi, Karthik Duraisamy, Scott Murman
Formulation of Entropy-Stable schemes for the multicomponent compressible Euler equations
[arXiv: 1904.00972](https://arxiv.org/abs/1904.00972)
"""
function initial_condition_shock_bubble(x, t, equations::CompressibleEulerMulticomponentEquations2D{5, 2})
# bubble test case, see Gouasmi et al. https://arxiv.org/pdf/1904.00972
# other reference: https://www.researchgate.net/profile/Pep_Mulet/publication/222675930_A_flux-split_algorithm_applied_to_conservative_models_for_multicomponent_compressible_flows/links/568da54508aeaa1481ae7af0.pdf
# typical domain is rectangular, we change it to a square, as Trixi can only do squares
(; gas_constants) = equations

# Positivity Preserving Parameter, can be set to zero if scheme is positivity preserving
delta = 0.03

# Region I
rho1_1 = delta
rho2_1 = 1.225 * gas_constants[1]/gas_constants[2] - delta
v1_1 = zero(delta)
v2_1 = zero(delta)
p_1 = 101325

# Region II
rho1_2 = 1.225-delta
rho2_2 = delta
v1_2 = zero(delta)
v2_2 = zero(delta)
p_2 = 101325

# Region III
rho1_3 = 1.6861 - delta
rho2_3 = delta
v1_3 = -113.5243
v2_3 = zero(delta)
p_3 = 159060

# Set up Region I & II:
inicenter = SVector(zero(delta), zero(delta))
x_norm = x[1] - inicenter[1]
y_norm = x[2] - inicenter[2]
r = sqrt(x_norm^2 + y_norm^2)

if (x[1] > 0.50)
# Set up Region III
rho1 = rho1_3
rho2 = rho2_3
v1 = v1_3
v2 = v2_3
p = p_3
elseif (r < 0.25)
# Set up Region I
rho1 = rho1_1
rho2 = rho2_1
v1 = v1_1
v2 = v2_1
p = p_1
else
# Set up Region II
rho1 = rho1_2
rho2 = rho2_2
v1 = v1_2
v2 = v2_2
p = p_2
end

return prim2cons(SVector(v1, v2, p, rho1, rho2), equations)
end
initial_condition = initial_condition_shock_bubble

surface_flux = flux_lax_friedrichs
volume_flux = flux_ranocha
basis = LobattoLegendreBasis(3)

limiter_idp = SubcellLimiterIDP(equations, basis;
local_minmax_variables_cons=[(i+3 for i in eachcomponent(equations))...])
volume_integral = VolumeIntegralSubcellLimiting(limiter_idp;
volume_flux_dg=volume_flux,
volume_flux_fv=surface_flux)

solver = DGSEM(basis, surface_flux, volume_integral)

coordinates_min = (-2.25, -2.225)
coordinates_max = ( 2.20, 2.225)
mesh = TreeMesh(coordinates_min, coordinates_max,
initial_refinement_level=3,
n_cells_max=1_000_000)

semi = SemidiscretizationHyperbolic(mesh, equations, initial_condition, solver)


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

tspan = (0.0, 0.01)
ode = semidiscretize(semi, tspan)

summary_callback = SummaryCallback()

analysis_interval = 300
analysis_callback = AnalysisCallback(semi, interval=analysis_interval,
extra_analysis_integrals=(Trixi.density,))

alive_callback = AliveCallback(analysis_interval=analysis_interval)

save_solution = SaveSolutionCallback(interval=600,
save_initial_solution=true,
save_final_solution=true,
solution_variables=cons2prim)

stepsize_callback = StepsizeCallback(cfl=0.5)
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callbacks = CallbackSet(summary_callback,
analysis_callback,
alive_callback,
save_solution,
stepsize_callback)


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

stage_callbacks = (SubcellLimiterIDPCorrection(),)

sol = Trixi.solve(ode, Trixi.SimpleSSPRK33(stage_callbacks=stage_callbacks);
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
Original file line number Diff line number Diff line change
Expand Up @@ -20,7 +20,7 @@ function initial_condition_shock_bubble(x, t, equations::CompressibleEulerMultic
# bubble test case, see Gouasmi et al. https://arxiv.org/pdf/1904.00972
# other reference: https://www.researchgate.net/profile/Pep_Mulet/publication/222675930_A_flux-split_algorithm_applied_to_conservative_models_for_multicomponent_compressible_flows/links/568da54508aeaa1481ae7af0.pdf
# typical domain is rectangular, we change it to a square, as Trixi can only do squares
@unpack gas_constants = equations
(; gas_constants) = equations

# Positivity Preserving Parameter, can be set to zero if scheme is positivity preserving
delta = 0.03
Expand Down Expand Up @@ -137,4 +137,4 @@ stage_callbacks = (SubcellLimiterIDPCorrection(),)
sol = Trixi.solve(ode, Trixi.SimpleSSPRK33(stage_callbacks=stage_callbacks);
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
summary_callback() # print the timer summary
6 changes: 3 additions & 3 deletions src/callbacks_stage/subcell_limiter_idp_correction_2d.jl
Original file line number Diff line number Diff line change
Expand Up @@ -6,9 +6,9 @@
#! format: noindent

function perform_idp_correction!(u, dt, mesh::TreeMesh2D, equations, dg, cache)
@unpack inverse_weights = dg.basis
@unpack antidiffusive_flux1, antidiffusive_flux2 = cache.antidiffusive_fluxes
@unpack alpha1, alpha2 = dg.volume_integral.limiter.cache.subcell_limiter_coefficients
(; antidiffusive_flux1, antidiffusive_flux2) = cache.antidiffusive_fluxes
(; inverse_weights) = dg.basis
(; alpha1, alpha2) = dg.volume_integral.limiter.cache.subcell_limiter_coefficients

@threaded for element in eachelement(dg, cache)
# Sign switch as in apply_jacobian!
Expand Down
6 changes: 6 additions & 0 deletions src/solvers/dg.jl
Original file line number Diff line number Diff line change
Expand Up @@ -181,6 +181,12 @@ end
A subcell limiting volume integral type for DG methods based on subcell blending approaches
with a low-order FV method. Used with limiter [`SubcellLimiterIDP`](@ref).

!!! note
Subcell limiting methods are not fully functional on non-conforming meshes. This is
mainly because the implementation assumes that low- and high-order schemes have the same
surface terms, which is not guaranteed for non-conforming meshes. The low-order scheme
with a high-order mortar is not invariant domain preserving.

!!! warning "Experimental implementation"
This is an experimental feature and may change in future releases.
"""
Expand Down
12 changes: 12 additions & 0 deletions src/solvers/dgsem_tree/dg_2d_subcell_limiters.jl
Original file line number Diff line number Diff line change
Expand Up @@ -190,4 +190,16 @@ end

return nothing
end

@inline function get_boundary_outer_state(u_inner, cache, t,
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boundary_condition::BoundaryConditionDirichlet,
orientation_or_normal, direction, equations,
dg, indices...)
(; node_coordinates) = cache.elements

x = get_node_coords(node_coordinates, equations, dg, indices...)
u_outer = boundary_condition.boundary_value_function(x, t, equations)

return u_outer
end
end # @muladd
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