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test_solid_mechanics_model_material_eigenstrain.cc
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rAKA akantu
test_solid_mechanics_model_material_eigenstrain.cc
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/**
* @file test_solid_mechanics_model_material_eigenstrain.cc
*
* @author Aurelia Isabel Cuba Ramos <aurelia.cubaramos@epfl.ch>
* @author Nicolas Richart <nicolas.richart@epfl.ch>
*
* @date creation: Sat Apr 16 2011
* @date last modification: Wed Aug 12 2015
*
* @brief test the internal field prestrain
*
* @section LICENSE
*
* Copyright (©) 2010-2012, 2014, 2015 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 "mesh_utils.hh"
#include "non_linear_solver.hh"
#include "solid_mechanics_model.hh"
/* -------------------------------------------------------------------------- */
using
namespace
akantu
;
Real
alpha
[
3
][
4
]
=
{{
0.01
,
0.02
,
0.03
,
0.04
},
{
0.05
,
0.06
,
0.07
,
0.08
},
{
0.09
,
0.10
,
0.11
,
0.12
}};
/* -------------------------------------------------------------------------- */
template
<
ElementType
type
>
static
Matrix
<
Real
>
prescribed_strain
()
{
UInt
spatial_dimension
=
ElementClass
<
type
>::
getSpatialDimension
();
Matrix
<
Real
>
strain
(
spatial_dimension
,
spatial_dimension
);
for
(
UInt
i
=
0
;
i
<
spatial_dimension
;
++
i
)
{
for
(
UInt
j
=
0
;
j
<
spatial_dimension
;
++
j
)
{
strain
(
i
,
j
)
=
alpha
[
i
][
j
+
1
];
}
}
return
strain
;
}
template
<
ElementType
type
>
static
Matrix
<
Real
>
prescribed_stress
(
Matrix
<
Real
>
prescribed_eigengradu
)
{
UInt
spatial_dimension
=
ElementClass
<
type
>::
getSpatialDimension
();
Matrix
<
Real
>
stress
(
spatial_dimension
,
spatial_dimension
);
// plane strain in 2d
Matrix
<
Real
>
strain
(
spatial_dimension
,
spatial_dimension
);
Matrix
<
Real
>
pstrain
;
pstrain
=
prescribed_strain
<
type
>
();
Real
nu
=
0.3
;
Real
E
=
2.1e11
;
Real
trace
=
0
;
/// symetric part of the strain tensor
for
(
UInt
i
=
0
;
i
<
spatial_dimension
;
++
i
)
for
(
UInt
j
=
0
;
j
<
spatial_dimension
;
++
j
)
strain
(
i
,
j
)
=
0.5
*
(
pstrain
(
i
,
j
)
+
pstrain
(
j
,
i
));
// elastic strain is equal to elastic strain minus the eigenstrain
strain
-=
prescribed_eigengradu
;
for
(
UInt
i
=
0
;
i
<
spatial_dimension
;
++
i
)
trace
+=
strain
(
i
,
i
);
Real
lambda
=
nu
*
E
/
((
1
+
nu
)
*
(
1
-
2
*
nu
));
Real
mu
=
E
/
(
2
*
(
1
+
nu
));
if
(
spatial_dimension
==
1
)
{
stress
(
0
,
0
)
=
E
*
strain
(
0
,
0
);
}
else
{
for
(
UInt
i
=
0
;
i
<
spatial_dimension
;
++
i
)
for
(
UInt
j
=
0
;
j
<
spatial_dimension
;
++
j
)
{
stress
(
i
,
j
)
=
(
i
==
j
)
*
lambda
*
trace
+
2
*
mu
*
strain
(
i
,
j
);
}
}
return
stress
;
}
/* -------------------------------------------------------------------------- */
/* -------------------------------------------------------------------------- */
int
main
(
int
argc
,
char
*
argv
[])
{
initialize
(
"material_elastic_plane_strain.dat"
,
argc
,
argv
);
UInt
dim
=
3
;
const
ElementType
element_type
=
_tetrahedron_4
;
Matrix
<
Real
>
prescribed_eigengradu
(
dim
,
dim
);
prescribed_eigengradu
.
set
(
0.1
);
/// load mesh
Mesh
mesh
(
dim
);
mesh
.
read
(
"cube_3d_tet_4.msh"
);
/// declaration of model
SolidMechanicsModel
model
(
mesh
);
/// model initialization
model
.
initFull
(
_analysis_method
=
_static
);
// model.getNewSolver("static", _tsst_static, _nls_newton_raphson_modified);
auto
&
solver
=
model
.
getNonLinearSolver
(
"static"
);
solver
.
set
(
"threshold"
,
2e-4
);
solver
.
set
(
"max_iterations"
,
2
);
solver
.
set
(
"convergence_type"
,
_scc_residual
);
const
Array
<
Real
>
&
coordinates
=
mesh
.
getNodes
();
Array
<
Real
>
&
displacement
=
model
.
getDisplacement
();
Array
<
bool
>
&
boundary
=
model
.
getBlockedDOFs
();
MeshUtils
::
buildFacets
(
mesh
);
mesh
.
createBoundaryGroupFromGeometry
();
// Loop over (Sub)Boundar(ies)
for
(
GroupManager
::
const_element_group_iterator
it
(
mesh
.
element_group_begin
());
it
!=
mesh
.
element_group_end
();
++
it
)
{
for
(
const
auto
&
n
:
it
->
second
->
getNodeGroup
())
{
std
::
cout
<<
"Node "
<<
n
<<
std
::
endl
;
for
(
UInt
i
=
0
;
i
<
dim
;
++
i
)
{
displacement
(
n
,
i
)
=
alpha
[
i
][
0
];
for
(
UInt
j
=
0
;
j
<
dim
;
++
j
)
{
displacement
(
n
,
i
)
+=
alpha
[
i
][
j
+
1
]
*
coordinates
(
n
,
j
);
}
boundary
(
n
,
i
)
=
true
;
}
}
}
/* ------------------------------------------------------------------------ */
/* Apply eigenstrain in each element */
/* ------------------------------------------------------------------------ */
Array
<
Real
>
&
eigengradu_vect
=
model
.
getMaterial
(
0
).
getInternal
<
Real
>
(
"eigen_grad_u"
)(
element_type
);
auto
eigengradu_it
=
eigengradu_vect
.
begin
(
dim
,
dim
);
auto
eigengradu_end
=
eigengradu_vect
.
end
(
dim
,
dim
);
for
(;
eigengradu_it
!=
eigengradu_end
;
++
eigengradu_it
)
{
*
eigengradu_it
=
prescribed_eigengradu
;
}
/* ------------------------------------------------------------------------ */
/* Static solve */
/* ------------------------------------------------------------------------ */
model
.
solveStep
();
std
::
cout
<<
"Converged in "
<<
Int
(
solver
.
get
(
"nb_iterations"
))
<<
" ("
<<
Real
(
solver
.
get
(
"error"
))
<<
")"
<<
std
::
endl
;
/* ------------------------------------------------------------------------ */
/* Checks */
/* ------------------------------------------------------------------------ */
const
Array
<
Real
>
&
stress_vect
=
model
.
getMaterial
(
0
).
getStress
(
element_type
);
auto
stress_it
=
stress_vect
.
begin
(
dim
,
dim
);
auto
stress_end
=
stress_vect
.
end
(
dim
,
dim
);
Matrix
<
Real
>
presc_stress
;
presc_stress
=
prescribed_stress
<
element_type
>
(
prescribed_eigengradu
);
Real
stress_tolerance
=
1e-13
;
for
(;
stress_it
!=
stress_end
;
++
stress_it
)
{
const
auto
&
stress
=
*
stress_it
;
Matrix
<
Real
>
diff
(
dim
,
dim
);
diff
=
stress
;
diff
-=
presc_stress
;
Real
stress_error
=
diff
.
norm
<
L_inf
>
()
/
stress
.
norm
<
L_inf
>
();
if
(
stress_error
>
stress_tolerance
)
{
std
::
cerr
<<
"stress error: "
<<
stress_error
<<
" > "
<<
stress_tolerance
<<
std
::
endl
;
std
::
cerr
<<
"stress: "
<<
stress
<<
std
::
endl
<<
"prescribed stress: "
<<
presc_stress
<<
std
::
endl
;
return
EXIT_FAILURE
;
}
// else {
// std::cerr << "stress error: " << stress_error
// << " < " << stress_tolerance << std::endl;
// }
}
finalize
();
return
EXIT_SUCCESS
;
}
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