Page Menu
Home
c4science
Search
Configure Global Search
Log In
Files
F93593299
phasefield.cc
No One
Temporary
Actions
Download File
Edit File
Delete File
View Transforms
Subscribe
Mute Notifications
Award Token
Subscribers
None
File Metadata
Details
File Info
Storage
Attached
Created
Sat, Nov 30, 00:32
Size
10 KB
Mime Type
text/x-c
Expires
Mon, Dec 2, 00:32 (2 d)
Engine
blob
Format
Raw Data
Handle
22666283
Attached To
rAKA akantu
phasefield.cc
View Options
/**
* Copyright (©) 2020-2023 EPFL (Ecole Polytechnique Fédérale de Lausanne)
* Laboratory (LSMS - Laboratoire de Simulation en Mécanique des Solides)
*
* This file is part of Akantu
*
* Akantu is free software: you can redistribute it and/or modify it under the
* terms of the GNU Lesser General Public License as published by the Free
* Software Foundation, either version 3 of the License, or (at your option) any
* later version.
*
* Akantu 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 Akantu. If not, see <http://www.gnu.org/licenses/>.
*/
/* -------------------------------------------------------------------------- */
#include "phasefield.hh"
#include "aka_common.hh"
#include "phase_field_model.hh"
#include "random_internal_field.hh"
/* -------------------------------------------------------------------------- */
namespace akantu {
/* -------------------------------------------------------------------------- */
PhaseField::PhaseField(PhaseFieldModel & model, const ID & id,
const ID & fe_engine_id)
: Parent(model, id, model.getSpatialDimension(), _ek_regular, fe_engine_id),
g_c(this->registerInternal<Real, DefaultRandomInternalField>(
"g_c", 1, fe_engine_id)),
damage_on_qpoints(this->registerInternal("damage", 1, fe_engine_id)),
gradd(this->registerInternal("grad_d", spatial_dimension, fe_engine_id)),
phi(this->registerInternal("phi", 1, fe_engine_id)),
strain(this->registerInternal(
"strain", spatial_dimension * spatial_dimension, fe_engine_id)),
driving_force(this->registerInternal("driving_force", 1, fe_engine_id)),
driving_energy(this->registerInternal("driving_energy", spatial_dimension,
fe_engine_id)),
damage_energy(this->registerInternal(
"damage_energy", spatial_dimension * spatial_dimension,
fe_engine_id)),
damage_energy_density(
this->registerInternal("damage_energy_density", 1, fe_engine_id)),
dissipated_energy(
this->registerInternal("dissipated_energy", 1, fe_engine_id)) {
this->phi.initializeHistory();
this->registerParam("l0", l0, Real(0.), _pat_parsable | _pat_readable,
"length scale parameter");
this->registerParam("gc", g_c, _pat_parsable | _pat_readable,
"critical local fracture energy density");
this->registerParam("E", E, _pat_parsable | _pat_readable, "Young's modulus");
this->registerParam("nu", nu, _pat_parsable | _pat_readable, "Poisson ratio");
this->registerParam("isotropic", isotropic, true,
_pat_parsable | _pat_readable,
"Use isotropic formulation");
}
/* -------------------------------------------------------------------------- */
void PhaseField::updateInternalParameters() {
this->lambda = this->nu * this->E / ((1 + this->nu) * (1 - 2 * this->nu));
this->mu = this->E / (2 * (1 + this->nu));
Parent::updateInternalParameters();
}
/* -------------------------------------------------------------------------- */
void PhaseField::computeAllDrivingForces(GhostType ghost_type) {
auto & damage = handler.getDamage();
auto & fem = this->getFEEngine();
for (const auto & type : this->getElementFilter().elementTypes(
this->spatial_dimension, ghost_type)) {
auto & elem_filter = this->getElementFilter(type, ghost_type);
if (elem_filter.empty()) {
continue;
}
// compute the damage on quadrature points
auto & damage_interpolated = damage_on_qpoints(type, ghost_type);
fem.interpolateOnIntegrationPoints(damage, damage_interpolated, 1, type,
ghost_type);
auto & gradd_vect = gradd(type, _not_ghost);
/// compute @f$\nabla u@f$
fem.gradientOnIntegrationPoints(damage, gradd_vect, 1, type, ghost_type,
elem_filter);
computeDrivingForce(type, ghost_type);
}
AKANTU_DEBUG_OUT();
}
/* -------------------------------------------------------------------------- */
void PhaseField::assembleInternalForces(GhostType ghost_type) {
Array<Real> & internal_force = handler.getInternalForce();
auto & fem = this->getFEEngine();
for (auto type : getElementFilter().elementTypes(_ghost_type = ghost_type)) {
auto & elem_filter = getElementFilter(type, ghost_type);
if (elem_filter.empty()) {
continue;
}
auto nb_nodes_per_element = Mesh::getNbNodesPerElement(type);
auto & driving_force_vect = driving_force(type, ghost_type);
Array<Real> nt_driving_force(0, nb_nodes_per_element);
fem.computeNtb(driving_force_vect, nt_driving_force, type, ghost_type,
elem_filter);
Array<Real> int_nt_driving_force(0, nb_nodes_per_element);
fem.integrate(nt_driving_force, int_nt_driving_force, nb_nodes_per_element,
type, ghost_type, elem_filter);
handler.getDOFManager().assembleElementalArrayLocalArray(
int_nt_driving_force, internal_force, type, ghost_type, -1,
elem_filter);
// damage_energy_on_qpoints = gc*l0 = scalar
auto & driving_energy_vect = driving_energy(type, ghost_type);
Array<Real> bt_driving_energy(0, nb_nodes_per_element);
fem.computeBtD(driving_energy_vect, bt_driving_energy, type, ghost_type,
elem_filter);
Array<Real> int_bt_driving_energy(0, nb_nodes_per_element);
fem.integrate(bt_driving_energy, int_bt_driving_energy,
nb_nodes_per_element, type, ghost_type, elem_filter);
handler.getDOFManager().assembleElementalArrayLocalArray(
int_bt_driving_energy, internal_force, type, ghost_type, -1,
elem_filter);
}
}
/* -------------------------------------------------------------------------- */
void PhaseField::assembleStiffnessMatrix(GhostType ghost_type) {
AKANTU_DEBUG_INFO("Assemble the new stiffness matrix");
auto & fem = this->getFEEngine();
for (auto type :
getElementFilter().elementTypes(spatial_dimension, ghost_type)) {
auto & elem_filter = getElementFilter(type, ghost_type);
if (elem_filter.empty()) {
return;
}
auto nb_element = elem_filter.size();
auto nb_nodes_per_element = Mesh::getNbNodesPerElement(type);
auto nb_quadrature_points = fem.getNbIntegrationPoints(type, ghost_type);
auto nt_b_n = std::make_unique<Array<Real>>(
nb_element * nb_quadrature_points,
nb_nodes_per_element * nb_nodes_per_element, "N^t*b*N");
auto bt_d_b = std::make_unique<Array<Real>>(
nb_element * nb_quadrature_points,
nb_nodes_per_element * nb_nodes_per_element, "B^t*D*B");
// damage_energy_density_on_qpoints = gc/l0 + phi = scalar
auto & damage_energy_density_vect = damage_energy_density(type, ghost_type);
// damage_energy_on_qpoints = gc*l0 = scalar
auto & damage_energy_vect = damage_energy(type, ghost_type);
fem.computeBtDB(damage_energy_vect, *bt_d_b, 2, type, ghost_type,
elem_filter);
fem.computeNtbN(damage_energy_density_vect, *nt_b_n, type, ghost_type,
elem_filter);
/// compute @f$ K_{\grad d} = \int_e \mathbf{N}^t * \mathbf{w} *
/// \mathbf{N}@f$
auto K_n = std::make_unique<Array<Real>>(
nb_element, nb_nodes_per_element * nb_nodes_per_element, "K_n");
fem.integrate(*nt_b_n, *K_n, nb_nodes_per_element * nb_nodes_per_element,
type, ghost_type, elem_filter);
handler.getDOFManager().assembleElementalMatricesToMatrix(
"K", "damage", *K_n, type, _not_ghost, _symmetric, elem_filter);
/// compute @f$ K_{\grad d} = \int_e \mathbf{B}^t * \mathbf{W} *
/// \mathbf{B}@f$
auto K_b = std::make_unique<Array<Real>>(
nb_element, nb_nodes_per_element * nb_nodes_per_element, "K_b");
fem.integrate(*bt_d_b, *K_b, nb_nodes_per_element * nb_nodes_per_element,
type, ghost_type, elem_filter);
handler.getDOFManager().assembleElementalMatricesToMatrix(
"K", "damage", *K_b, type, _not_ghost, _symmetric, elem_filter);
}
}
/* -------------------------------------------------------------------------- */
void PhaseField::computeDissipatedEnergyByElements() {
const Array<Real> & damage = handler.getDamage();
auto & fem = this->getFEEngine();
for (auto type :
getElementFilter().elementTypes(spatial_dimension, _not_ghost)) {
Array<Idx> & elem_filter = getElementFilter(type, _not_ghost);
if (elem_filter.empty()) {
continue;
}
Array<Real> & damage_interpolated = damage_on_qpoints(type, _not_ghost);
// compute the damage on quadrature points
fem.interpolateOnIntegrationPoints(damage, damage_interpolated, 1, type,
_not_ghost);
Array<Real> & gradd_vect = gradd(type, _not_ghost);
/// compute @f$\nabla u@f$
fem.gradientOnIntegrationPoints(damage, gradd_vect, 1, type, _not_ghost,
elem_filter);
computeDissipatedEnergy(type);
}
}
/* -------------------------------------------------------------------------- */
void PhaseField::computeDissipatedEnergy(ElementType /*unused*/) {
AKANTU_TO_IMPLEMENT();
}
/* -------------------------------------------------------------------------- */
PhaseFieldFactory & PhaseField::getFactory() {
return PhaseFieldFactory::getInstance();
}
/* -------------------------------------------------------------------------- */
Real PhaseField::getEnergy(const ID & energy_id) {
if (energy_id != "dissipated") {
return 0.;
}
Real edis = 0.;
auto & fem = this->getFEEngine();
computeDissipatedEnergyByElements();
/// integrate the dissipated energy for each type of elements
for (auto type :
getElementFilter().elementTypes(spatial_dimension, _not_ghost)) {
edis += fem.integrate(dissipated_energy(type, _not_ghost), type, _not_ghost,
getElementFilter(type, _not_ghost));
}
return edis;
}
/* -------------------------------------------------------------------------- */
Real PhaseField::getEnergy(const ID & energy_id, const Element & element) {
if (energy_id != "dissipated") {
return 0.;
}
auto & fem = this->getFEEngine();
Vector<Real> edis_on_quad_points(fem.getNbIntegrationPoints(element.type));
computeDissipatedEnergyByElement(element.type, element.element,
edis_on_quad_points);
return fem.integrate(edis_on_quad_points, element);
}
/* -------------------------------------------------------------------------- */
void PhaseField::beforeSolveStep() {
this->savePreviousState();
this->computeAllDrivingForces(_not_ghost);
}
} // namespace akantu
Event Timeline
Log In to Comment