File Metadata

Created: Sun, Jun 2, 08:29

phasefield_exponential.hh
View Options

	/**
	* @file phasefield_exponential.hh
	*
	* @author Mohit Pundir <mohit.pundir@epfl.ch>
	*
	* @date creation: Fri Jun 18 2020
	* @date last modification: Mon Jan 29 2020
	*
	* @brief Phasefield law for approximating discrete crack as an exponential
	*
	* @section LICENSE
	*
	* Copyright (©) 2010-2018 EPFL (Ecole Polytechnique Fédérale de Lausanne)
	* Laboratory (LSMS - Laboratoire de Simulation en Mécanique des Solides)
	*
	* 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 "aka_common.hh"
	#include "phasefield.hh"
	/* -------------------------------------------------------------------------- */

	#ifndef __AKANTU_PHASEFIELD_EXPONENTIAL_HH__
	#define __AKANTU_PHASEFIELD_EXPONENTIAL_HH__

	namespace akantu {
	class PhaseFieldExponential : public PhaseField {
	/* ------------------------------------------------------------------------ */
	/* Constructors/Destructors */
	/* ------------------------------------------------------------------------ */
	public:
	PhaseFieldExponential(PhaseFieldModel & model, const ID & id = "" );

	~PhaseFieldExponential() override = default;

	/* ------------------------------------------------------------------------ */
	/* Methods */
	/* ------------------------------------------------------------------------ */
	protected:
	void computePhiOnQuad(const Matrix<Real> &, Real &, Real &);

	void computeDrivingForce(const ElementType & , GhostType ) override;

	inline void computeDrivingForceOnQuad(const Real &, Real &);

	inline void computeDamageEnergyDensityOnQuad(const Real &, Real &);


	public:

	void updateInternalParameters() override;
	};


	/* -------------------------------------------------------------------------- */
	inline void PhaseFieldExponential:: computeDrivingForceOnQuad(const Real & phi_quad,
	Real & driving_force_quad){
	driving_force_quad = 2.0 * phi_quad;
	}

	/* -------------------------------------------------------------------------- */
	inline void PhaseFieldExponential::computeDamageEnergyDensityOnQuad(const Real & phi_quad,
	Real & dam_energy_quad) {
	dam_energy_quad = 2.0 * phi_quad + this->g_c/this->l0;
	}

	/* -------------------------------------------------------------------------- */
	inline void PhaseFieldExponential::computePhiOnQuad(const Matrix<Real> & strain_quad,
	Real & phi_quad, Real & phi_hist_quad) {

	Matrix<Real> strain_plus(spatial_dimension, spatial_dimension);
	Matrix<Real> strain_minus(spatial_dimension, spatial_dimension);
	Matrix<Real> strain_dir(spatial_dimension, spatial_dimension);
	Matrix<Real> strain_diag_plus(spatial_dimension, spatial_dimension);
	Matrix<Real> strain_diag_minus(spatial_dimension, spatial_dimension);

	Vector<Real> strain_values(spatial_dimension);

	Real trace_plus, trace_minus;

	strain_plus.zero();
	strain_minus.zero();
	strain_dir.zero();
	strain_values.zero();
	strain_diag_plus.zero();
	strain_diag_minus.zero();

	strain_quad.eig(strain_values, strain_dir);

	for (UInt i = 0; i < spatial_dimension; i++) {
	strain_diag_plus(i, i) = std::max(Real(0.), strain_values(i));
	strain_diag_minus(i, i) = std::min(Real(0.), strain_values(i));
	}

	Matrix<Real> mat_tmp(spatial_dimension, spatial_dimension);
	Matrix<Real> sigma_plus(spatial_dimension, spatial_dimension);
	Matrix<Real> sigma_minus(spatial_dimension, spatial_dimension);

	mat_tmp.mul<false, true>(strain_diag_plus, strain_dir);
	strain_plus.mul<false, false>(strain_dir, mat_tmp);
	mat_tmp.mul<false, true>(strain_diag_minus, strain_dir);
	strain_minus.mul<false, true>(strain_dir, mat_tmp);

	trace_plus = std::max(Real(0.), strain_quad.trace());
	trace_minus = std::min(Real(0.), strain_quad.trace());

	for (UInt i = 0; i < spatial_dimension; i++) {
	for (UInt j = 0; j < spatial_dimension; j++) {
	sigma_plus(i, j) =
	(i == j) * lambda * trace_plus + 2 * mu * strain_plus(i, j);
	sigma_minus(i, j) =
	(i == j) * lambda * trace_minus + 2 * mu * strain_minus(i, j);
	}
	}

	phi_quad = 0.5 * sigma_plus.doubleDot(strain_quad);
	if (phi_quad < phi_hist_quad)
	phi_quad = phi_hist_quad;
	}

	}

	#endif

phasefield_exponential.hh
No OneTemporary
Actions

File Metadata

phasefield_exponential.hh
View Options

Event Timeline

phasefield_exponential.hhNo OneTemporaryActions

File Metadata

phasefield_exponential.hhView Options

Event Timeline

phasefield_exponential.hh
No OneTemporary
Actions

phasefield_exponential.hh
View Options