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Add one-sided limiting for nonlinear variables to tutorial #1934

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May 15, 2024
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Add one-sided limiting for nonlinear variables to tutorial #1934

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53d20c2
Add one-sided limiting for nonlinear variables to tutorial
bennibolm May 8, 2024
11303c3
Add docstring; link to documentation in tutorial
bennibolm May 14, 2024
9739869
Merge branch 'main' into tutorial_subcell_local_nonlinear
bennibolm May 14, 2024
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8 changes: 7 additions & 1 deletion docs/literate/src/files/subcell_shock_capturing.jl
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Expand Up @@ -96,7 +96,8 @@ positivity_variables_nonlinear = [pressure]

# ### Local bounds
# Second, Trixi.jl supports the limiting with local bounds for conservative variables using a
# two-sided Zalesak-type limiter ([Zalesak, 1979](https://doi.org/10.1016/0021-9991(79)90051-2)).
# two-sided Zalesak-type limiter ([Zalesak, 1979](https://doi.org/10.1016/0021-9991(79)90051-2))
# and for general non-linear variables using a one-sided Newton-bisection algorithm.
# They allow to avoid spurious oscillations within the global bounds and to improve the
# shock-capturing capabilities of the method. The corresponding numerical admissibility conditions
# are frequently formulated as local maximum or minimum principles. The local bounds are computed
Expand All @@ -108,6 +109,11 @@ positivity_variables_nonlinear = [pressure]
# the following.
local_twosided_variables_cons = ["rho"]

# To limit non-linear variables locally, pass the variable function combined with the requested
# bound (`min` or `max`) as a tuple. For instance, to impose a lower local bound on the modified
# specific entropy [`Trixi.entropy_guermond_etal`](@ref), use
local_onesided_variables_nonlinear = [(Trixi.entropy_guermond_etal, min)]

# ## Exemplary simulation
# How to set up a simulation using the IDP limiting becomes clearer when looking at an exemplary
# setup. This will be a simplified version of `tree_2d_dgsem/elixir_euler_blast_wave_sc_subcell.jl`.
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14 changes: 12 additions & 2 deletions src/equations/compressible_euler_2d.jl
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Expand Up @@ -2018,8 +2018,18 @@ end
return cons2entropy(u, equations)
end

# Calculate the modified specific entropy of Guermond et al. (2019): s_0 = p * rho^(-gamma) / (gamma-1).
# Note: This is *not* the "conventional" specific entropy s = ln(p / rho^(gamma)).
@doc raw"""
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entropy_guermond_etal(u, equations::CompressibleEulerEquations2D)

Calculate the modified specific entropy of Guermond et al. (2019):
```math
s_0 = p * \rho^{-\gamma} / (\gamma-1).
```
Note: This is *not* the "conventional" specific entropy ``s = ln(p / \rho^\gamma)``.
- Guermond at al. (2019)
Invariant domain preserving discretization-independent schemes and convex limiting for hyperbolic systems.
[DOI: 10.1016/j.cma.2018.11.036](https://doi.org/10.1016/j.cma.2018.11.036)
"""
@inline function entropy_guermond_etal(u, equations::CompressibleEulerEquations2D)
rho, rho_v1, rho_v2, rho_e = u

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