#
# RBniCS 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 Lesser General Public License for more details.
#
# You should have received a copy of the GNU Lesser General Public License
# along with RBniCS. If not, see <http://www.gnu.org/licenses/>.
#

import hashlib
from rbnics.backends import assign, copy, Function, LinearSolver, product, sum, transpose
from rbnics.problems.base import LinearProblem, ParametrizedDifferentialProblem
from rbnics.utils.cache import Cache

StokesOptimalControlProblem_Base = LinearProblem(
    ParametrizedDifferentialProblem)


class StokesOptimalControlProblem(StokesOptimalControlProblem_Base):
    """
    The problem to be solved is
        min {J(y, u) = 1/2 m(v - v_d, v - v_d) + 1/2 n(u, u)}
        y = (v, p) in Y = (V, P), u in U
        s.t.
        a(v, phi) + b(phi, p) = c(u, phi) + <f, phi>    for all phi in V
        b(v, xi)              = <l, xi>                 for all xi  in P
        
    This class will solve the following optimality conditions:
        m(v, psi)                         + a*(psi, w) + b*(psi, q) = <g, psi>     for all psi in V
                                            b*(w, pi )              = 0            for all pi  in P
                                n(u, tau) - c*(tau, w)              = 0            for all tau in U
Пример #2
0
# Copyright (C) 2015-2020 by the RBniCS authors
#
# This file is part of RBniCS.
#
# SPDX-License-Identifier: LGPL-3.0-or-later

from rbnics.problems.base import LinearProblem, ParametrizedDifferentialProblem
from rbnics.backends import product, sum, transpose

EllipticProblem_Base = LinearProblem(ParametrizedDifferentialProblem)


# Base class containing the definition of elliptic problems
class EllipticProblem(EllipticProblem_Base):

    # Default initialization of members
    def __init__(self, V, **kwargs):
        # Call to parent
        EllipticProblem_Base.__init__(self, V, **kwargs)

        # Form names for elliptic problems
        self.terms = ["a", "f", "s"]
        self.terms_order = {"a": 2, "f": 1, "s": 1}
        self.components = ["u"]

    class ProblemSolver(EllipticProblem_Base.ProblemSolver):
        def matrix_eval(self):
            problem = self.problem
            return sum(
                product(problem.compute_theta("a"), problem.operator["a"]))
Пример #3
0
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# RBniCS 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 Lesser General Public License for more details.
#
# You should have received a copy of the GNU Lesser General Public License
# along with RBniCS. If not, see <http://www.gnu.org/licenses/>.
#

from rbnics.problems.base import LinearProblem, ParametrizedDifferentialProblem
from rbnics.backends import product, sum

GeostrophicProblem_Base = LinearProblem(ParametrizedDifferentialProblem)


class GeostrophicProblem(GeostrophicProblem_Base):
    # Default initialization of members
    def __init__(self, V, **kwargs):
        # Call to parent
        GeostrophicProblem_Base.__init__(self, V, **kwargs)

        # Form names for geostrophic problems
        self.terms = ["a", "f"]
        self.terms_order = {"a": 2, "f": 1}
        self.components = ["psi", "q"]

    # Perform a truth solve
    class ProblemSolver(GeostrophicProblem_Base.ProblemSolver):
Пример #4
0
#
# RBniCS 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 Lesser General Public License for more details.
#
# You should have received a copy of the GNU Lesser General Public License
# along with RBniCS. If not, see <http://www.gnu.org/licenses/>.
#

import hashlib
from rbnics.problems.base import LinearProblem, ParametrizedDifferentialProblem
from rbnics.backends import assign, copy, Function, LinearSolver, product, sum
from rbnics.utils.cache import Cache

StokesProblem_Base = LinearProblem(ParametrizedDifferentialProblem)

# Base class containing the definition of saddle point problems
class StokesProblem(StokesProblem_Base):
    
    # Default initialization of members
    def __init__(self, V, **kwargs):
        # Call to parent
        StokesProblem_Base.__init__(self, V, **kwargs)
        
        # Form names for saddle point problems
        self.terms = [
            "a", "b", "bt", "f", "g",
            # Auxiliary terms for supremizer enrichment
            "bt_restricted"
        ]
Пример #5
0
# Copyright (C) 2015-2021 by the RBniCS authors
#
# This file is part of RBniCS.
#
# SPDX-License-Identifier: LGPL-3.0-or-later

from rbnics.problems.base import LinearProblem, ParametrizedDifferentialProblem
from rbnics.backends import product, sum, transpose

GeostrophicOptimalControlProblem_Base = LinearProblem(ParametrizedDifferentialProblem)


class GeostrophicOptimalControlProblem(GeostrophicOptimalControlProblem_Base):

    """
    The problem to be solved is
            min {J(y_psi, u) = 1/2 m(y_psi - y_d, y_psi - y_d) + 1/2 n(u, u)}
            (y_psi, y_q) in YxY,  y_d in Y, u in U
            s.t.
            a((y_psi, y_q), (z_psi, z_q)) = c(u, z_psi) + <f, z_q>    for all (z_psi, z_q) in YxY

    This class will solve the following optimality conditions:
            m(y_psi, z_q) + a*((p_psi, p_q), (z_psi, z_q)) = <g, z_q>     for all (z_psi, z_q) in YxY
            n(u, v) - c*(v, ppsi)                          = 0            for all v in U
            a((y_psi, y_q), (q_psi, q_q))- c(u, q_psi)     = <f, q_q>     for all (q_psi, q_q) in YxY

    and compute the cost functional
            J(y_psi, u) = 1/2 m(y_psi, y_psi) + 1/2 n(u, u) - <g, y_psi> + 1/2 h

    where
            a*(., .) is the adjoint of a