element_class_structural.hh
No OneTemporary
Actions

Subscribers

None

File Metadata

Created: Wed, Dec 4, 23:12

element_class_structural.hh
View Options

	/**
	* Copyright (©) 2013-2023 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 "aka_iterators.hh"
	#include "element_class.hh" // NOLINT(pp_including_mainfile_in_preamble)
	/* -------------------------------------------------------------------------- */

	#ifndef AKANTU_ELEMENT_CLASS_STRUCTURAL_HH_
	#define AKANTU_ELEMENT_CLASS_STRUCTURAL_HH_

	namespace akantu {

	/// Macro to generate the InterpolationProperty structures for different
	/// interpolation types
	#define AKANTU_DEFINE_STRUCTURAL_INTERPOLATION_TYPE_PROPERTY( \
	itp_type, itp_geom_type, ndof, nb_stress, nb_dnds_cols) \
	template <> struct InterpolationProperty<itp_type> { \
	static constexpr InterpolationKind kind{_itk_structural}; \
	static constexpr Int nb_nodes_per_element{ \
	InterpolationProperty<itp_geom_type>::nb_nodes_per_element}; \
	static constexpr InterpolationType itp_geometry_type{itp_geom_type}; \
	static constexpr Int natural_space_dimension{ \
	InterpolationProperty<itp_geom_type>::natural_space_dimension}; \
	static constexpr Int nb_degree_of_freedom{ndof}; \
	static constexpr Int nb_stress_components{nb_stress}; \
	static constexpr Int dnds_columns{nb_dnds_cols}; \
	} // namespace akantu

	/// Macro to generate the element class structures for different structural
	/// element types
	/* -------------------------------------------------------------------------- */
	#define AKANTU_DEFINE_STRUCTURAL_ELEMENT_CLASS_PROPERTY( \
	elem_type, geom_type, interp_type, parent_el_type, sp, gauss_int_type, \
	min_int_order) \
	template <> struct ElementClassProperty<elem_type> { \
	static constexpr GeometricalType geometrical_type{geom_type}; \
	static constexpr InterpolationType interpolation_type{interp_type}; \
	static constexpr ElementType parent_element_type{parent_el_type}; \
	static constexpr ElementKind element_kind{_ek_structural}; \
	static constexpr Int spatial_dimension{sp}; \
	static constexpr GaussIntegrationType gauss_integration_type{ \
	gauss_int_type}; \
	static constexpr Int polynomial_degree{min_int_order}; \
	}

	/* -------------------------------------------------------------------------- */
	AKANTU_DEFINE_STRUCTURAL_INTERPOLATION_TYPE_PROPERTY(_itp_bernoulli_beam_2,
	_itp_lagrange_segment_2, 3,
	2, 6);

	AKANTU_DEFINE_STRUCTURAL_INTERPOLATION_TYPE_PROPERTY(_itp_bernoulli_beam_3,
	_itp_lagrange_segment_2, 6,
	4, 6);

	AKANTU_DEFINE_STRUCTURAL_ELEMENT_CLASS_PROPERTY(_bernoulli_beam_2,
	_gt_segment_2,
	_itp_bernoulli_beam_2,
	_segment_2, 2, _git_segment, 3);

	AKANTU_DEFINE_STRUCTURAL_ELEMENT_CLASS_PROPERTY(_bernoulli_beam_3,
	_gt_segment_2,
	_itp_bernoulli_beam_3,
	_segment_2, 3, _git_segment, 3);
	/* -------------------------------------------------------------------------- */
	AKANTU_DEFINE_STRUCTURAL_INTERPOLATION_TYPE_PROPERTY(
	_itp_discrete_kirchhoff_triangle_18, _itp_lagrange_triangle_3, 6, 6, 21);

	AKANTU_DEFINE_STRUCTURAL_ELEMENT_CLASS_PROPERTY(
	_discrete_kirchhoff_triangle_18, _gt_triangle_3,
	_itp_discrete_kirchhoff_triangle_18, _triangle_3, 3, _git_triangle, 2);
	/* -------------------------------------------------------------------------- */

	/* -------------------------------------------------------------------------- */
	template <InterpolationType interpolation_type>
	class InterpolationElement<interpolation_type, _itk_structural> {
	public:
	using interpolation_property = InterpolationProperty<interpolation_type>;

	/// compute the shape values for a given point in natural coordinates
	template <class D1, class D2, class D3>
	static inline void computeShapes(const Eigen::MatrixBase<D1> & natural_coord,
	const Eigen::MatrixBase<D2> & real_coord,
	Eigen::MatrixBase<D3> & N);

	/// compute the shape values for a given set of points in natural coordinates
	template <class D1, class D2, class D3>
	static inline void computeShapes(const Eigen::MatrixBase<D1> & Xs,
	const Eigen::MatrixBase<D2> & x,
	const Eigen::MatrixBase<D3> & T,
	TensorBase<Real, 3> & Ns) {

	Matrix<Real> N(Ns.size(0), Ns.size(1));
	for (auto && data : zip(Xs, Ns)) {
	auto && X = std::get<0>(data);
	auto && N_T = std::get<1>(data);

	computeShapes(X, x, N);

	N_T = N * T;
	}
	}

	template <class D1, class D2, class D3>
	static inline void computeShapesMass(const Eigen::MatrixBase<D1> & Xs,
	const Eigen::MatrixBase<D2> & x,
	const Eigen::MatrixBase<D3> & T,
	TensorBase<Real, 3> & Ns) {
	for (int i = 0; i < Xs.cols(); ++i) {
	auto N_T = Ns(i);

	Matrix<Real> N(interpolation_property::nb_degree_of_freedom, N_T.cols());
	computeShapes(Xs(i), x, N);

	N_T = N.block(0, 0, N_T.rows(), N_T.cols()) * T;
	}
	}

	/// compute shape derivatives (input is dxds) for a set of points
	template <class D>
	static inline void computeShapeDerivatives(const TensorBase<Real, 3> & Js,
	const TensorBase<Real, 3> & DNDSs,
	const Eigen::MatrixBase<D> & R,
	TensorBase<Real, 3> & Bs) {
	for (Int i = 0; i < Js.size(2); ++i) {
	auto && DNDX = Js(i).inverse() * DNDSs(i);
	auto && B_R = Bs(i);
	Matrix<Real> B(B_R.rows(), B_R.cols());
	arrangeInVoigt(DNDX, B);
	B_R = B * R;
	}
	}

	/**
	* compute @f$ B_{ij} = \frac{\partial N_j}{\partial S_i} @f$ the variation of
	* shape functions along with variation of natural coordinates on a given set
	* of points in natural coordinates
	*/
	template <typename D1, typename D2>
	static inline void computeDNDS(const Eigen::MatrixBase<D1> & Xs,
	const Eigen::MatrixBase<D2> & xs,
	TensorBase<Real, 3> & dnds) {
	for (auto && data : zip(Xs, dnds)) {
	computeDNDS(std::get<0>(data), xs, std::get<1>(data));
	}
	}

	/**
	* compute @f$ B_{ij} = \frac{\partial N_j}{\partial S_i} @f$ the variation of
	* shape functions along with
	* variation of natural coordinates on a given point in natural
	* coordinates
	*/
	template <typename D1, typename D2, typename D3>
	static inline void computeDNDS(const Eigen::MatrixBase<D1> & Xs,
	const Eigen::MatrixBase<D2> & xs,
	Eigen::MatrixBase<D3> & dnds);

	/**
	* arrange B in Voigt notation from DNDS
	*/
	template <class D1, class D2>
	static inline void arrangeInVoigt(const Eigen::MatrixBase<D1> & dnds,
	Eigen::MatrixBase<D2> & B) {
	// Default implementation assumes dnds is already in Voigt notation
	B = dnds;
	}

	public:
	static inline constexpr auto getNbNodesPerInterpolationElement() {
	return interpolation_property::nb_nodes_per_element;
	}

	static inline constexpr auto getShapeSize() {
	return interpolation_property::nb_nodes_per_element *
	interpolation_property::nb_degree_of_freedom *
	interpolation_property::nb_degree_of_freedom;
	}
	static inline constexpr auto getShapeIndependantSize() {
	return interpolation_property::nb_nodes_per_element *
	interpolation_property::nb_degree_of_freedom *
	interpolation_property::nb_stress_components;
	}
	static inline constexpr auto getShapeDerivativesSize() {
	return interpolation_property::nb_nodes_per_element *
	interpolation_property::nb_degree_of_freedom *
	interpolation_property::nb_stress_components;
	}
	static inline constexpr auto getNaturalSpaceDimension() {
	return interpolation_property::natural_space_dimension;
	}
	static inline constexpr auto getNbDegreeOfFreedom() {
	return interpolation_property::nb_degree_of_freedom;
	}
	static inline constexpr auto getNbStressComponents() {
	return interpolation_property::nb_stress_components;
	}
	};

	/* -------------------------------------------------------------------------- */
	/* ElementClass for structural elements */
	/* -------------------------------------------------------------------------- */
	template <ElementType element_type>
	class ElementClass<element_type, _ek_structural>
	: public GeometricalElement<
	ElementClassProperty<element_type>::geometrical_type>,
	public InterpolationElement<
	ElementClassProperty<element_type>::interpolation_type> {
	protected:
	using geometrical_element =
	GeometricalElement<ElementClassProperty<element_type>::geometrical_type>;
	using interpolation_element = InterpolationElement<
	ElementClassProperty<element_type>::interpolation_type>;
	using parent_element =
	ElementClass<ElementClassProperty<element_type>::parent_element_type>;

	public:
	template <class D1, class D2, class D3>
	static inline void
	computeRotationMatrix(Eigen::MatrixBase<D1> & /R/,
	const Eigen::MatrixBase<D2> & /X/,
	const Eigen::MatrixBase<D3> & /extra_normal/) {
	AKANTU_TO_IMPLEMENT();
	}

	/// compute jacobian (or integration variable change factor) for a given point
	template <typename D1, typename D2, typename D3>
	static inline void computeJMat(const Eigen::MatrixBase<D1> & natural_coords,
	const Eigen::MatrixBase<D2> & Xs,
	Eigen::MatrixBase<D3> & J) {
	Matrix<Real> dnds(Xs.rows(), Xs.cols());
	parent_element::computeDNDS(natural_coords, dnds);
	J = dnds * Xs.transpose();
	}

	template <typename D1, typename D2>
	static inline void computeJMat(const Eigen::MatrixBase<D1> & Xs,
	const Eigen::MatrixBase<D2> & xs,
	Tensor3<Real> & Js) {
	for (auto && data : zip(Xs, Js)) {
	computeJMat(std::get<0>(data), xs, std::get<1>(data));
	}
	}

	template <typename D1, typename D2, typename D3,
	std::enable_if_t<aka::is_vector_v<D3>> * = nullptr>
	static inline void computeJacobian(const Eigen::MatrixBase<D1> & Xs,
	const Eigen::MatrixBase<D2> & xs,
	Eigen::MatrixBase<D3> & jacobians) {
	using itp = typename interpolation_element::interpolation_property;
	Tensor3<Real> Js(itp::natural_space_dimension, itp::natural_space_dimension,
	Xs.cols());
	computeJMat(Xs, xs, Js);
	for (auto && data : zip(jacobians, Js)) {
	std::get<0>(data) = std::get<1>(data).determinant();
	}
	}

	template <typename D1, typename D2>
	static inline void computeRotation(const Eigen::MatrixBase<D1> & xs,
	Eigen::MatrixBase<D2> & R);

	public:
	static constexpr AKANTU_GET_MACRO_AUTO_NOT_CONST(Kind, _ek_structural);
	static constexpr AKANTU_GET_MACRO_AUTO_NOT_CONST(P1ElementType, _not_defined);
	static constexpr AKANTU_GET_MACRO_AUTO_NOT_CONST(FacetType, _not_defined);
	static constexpr auto getFacetType(__attribute__((unused)) Int t = 0) {
	return _not_defined;
	}
	static constexpr AKANTU_GET_MACRO_AUTO_NOT_CONST(
	SpatialDimension, ElementClassProperty<element_type>::spatial_dimension);
	static constexpr auto getFacetTypes() {
	return ElementClass<_not_defined>::getFacetTypes();
	}
	};

	} // namespace akantu

	/* -------------------------------------------------------------------------- */
	#include "element_class_hermite_inline_impl.hh" // NOLINT
	/* keep order */
	#include "element_class_bernoulli_beam_inline_impl.hh" // NOLINT(unused-includes)
	#include "element_class_kirchhoff_shell_inline_impl.hh" // NOLINT(unused-includes)
	/* -------------------------------------------------------------------------- */

	#endif /* AKANTU_ELEMENT_CLASS_STRUCTURAL_HH_ */

element_class_structural.hhNo OneTemporaryActions

File Metadata

element_class_structural.hhView Options

Event Timeline

element_class_structural.hh
No OneTemporary
Actions

element_class_structural.hh
View Options