#*------------------------------------------------------------------------------*
#* JAX-FLUIDS - *
#* *
#* A fully-differentiable CFD solver for compressible two-phase flows. *
#* Copyright (C) 2022 Deniz A. Bezgin, Aaron B. Buhendwa, Nikolaus A. Adams *
#* *
#* This program is free software: you can redistribute it and/or modify *
#* it under the terms of the GNU General Public License as published by *
#* the Free Software Foundation, either version 3 of the License, or *
#* (at your option) any later version. *
#* *
#* This program is distributed in the hope that it will be useful, *
#* but WITHOUT ANY WARRANTY; without even the implied warranty of *
#* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
#* GNU General Public License for more details. *
#* *
#* You should have received a copy of the GNU General Public License *
#* along with this program. If not, see <https://www.gnu.org/licenses/>. *
#* *
#*------------------------------------------------------------------------------*
#* *
#* CONTACT *
#* *
#* deniz.bezgin@tum.de // aaron.buhendwa@tum.de // nikolaus.adams@tum.de *
#* *
#*------------------------------------------------------------------------------*
#* *
#* Munich, April 15th, 2022 *
#* *
#*------------------------------------------------------------------------------*
from functools import partial
from typing import List
import jax
import jax.numpy as jnp
from jaxfluids.stencils.spatial_reconstruction import SpatialReconstruction
[docs]
class ALDM_WENO3(SpatialReconstruction):
"""ALDM_WENO3
Implementation details provided in parent class.
"""
def __init__(self, nh: int, inactive_axis: List):
super(ALDM_WENO3, self).__init__(nh=nh, inactive_axis=inactive_axis)
self.dr_ = [
[0.0, 1.0],
[1.0, 0.0],
]
self.cr_ = [
[[-0.5, 1.5], [0.5, 0.5]],
[[0.5, 0.5], [1.5, -0.5]],
]
self._stencil_size = 6
self._slices = [
[
[ jnp.s_[..., self.n-2+j:-self.n-1+j, self.nhy, self.nhz],
jnp.s_[..., self.n-1+j:-self.n+j, self.nhy, self.nhz],
jnp.s_[..., self.n+j:-self.n+1+j, self.nhy, self.nhz], ],
[ jnp.s_[..., self.nhx, self.n-2+j:-self.n-1+j, self.nhz],
jnp.s_[..., self.nhx, self.n-1+j:-self.n+j, self.nhz],
jnp.s_[..., self.nhx, self.n+j:-self.n+1+j, self.nhz], ],
[ jnp.s_[..., self.nhx, self.nhy, self.n-2+j:-self.n-1+j,],
jnp.s_[..., self.nhx, self.nhy, self.n-1+j:-self.n+j, ],
jnp.s_[..., self.nhx, self.nhy, self.n+j:-self.n+1+j, ], ],
] for j in range(2)]
[docs]
def reconstruct_xi(self, primes: jnp.ndarray, axis: int, j: int, dx: float = None, fs=0) -> jnp.ndarray:
s1_ = self._slices[j][axis]
beta_0 = (primes[s1_[1]] - primes[s1_[0]]) * (primes[s1_[1]] - primes[s1_[0]])
beta_1 = (primes[s1_[2]] - primes[s1_[1]]) * (primes[s1_[2]] - primes[s1_[1]])
one_beta_0_sq = 1.0 / ((self.eps + beta_0) * (self.eps + beta_0))
one_beta_1_sq = 1.0 / ((self.eps + beta_1) * (self.eps + beta_1))
alpha_0 = self.dr_[j][0] * one_beta_0_sq
alpha_1 = self.dr_[j][1] * one_beta_1_sq
one_alpha = 1.0 / (alpha_0 + alpha_1)
omega_0 = alpha_0 * one_alpha
omega_1 = alpha_1 * one_alpha
p_0 = self.cr_[j][0][0] * primes[s1_[0]] + self.cr_[j][0][1] * primes[s1_[1]]
p_1 = self.cr_[j][1][0] * primes[s1_[1]] + self.cr_[j][1][1] * primes[s1_[2]]
cell_state_xi_j = omega_0 * p_0 + omega_1 * p_1
return cell_state_xi_j