Page Menu
Home
c4science
Search
Configure Global Search
Log In
Files
F91374288
test_material_linear_elastic1.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
Sun, Nov 10, 11:44
Size
8 KB
Mime Type
text/x-c
Expires
Tue, Nov 12, 11:44 (2 d)
Engine
blob
Format
Raw Data
Handle
22234385
Attached To
rMUSPECTRE µSpectre
test_material_linear_elastic1.cc
View Options
/**
* @file test_material_linear_elastic1.cc
*
* @author Till Junge <till.junge@epfl.ch>
*
* @date 28 Nov 2017
*
* @brief Tests for the large-strain, objective Hooke's law, implemented in
* the convenient strategy (i.e., using MaterialMuSpectre), also used
* to test parts of MaterialLinearElastic2
*
* Copyright © 2017 Till Junge
*
* µSpectre is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License as
* published by the Free Software Foundation, either version 3, or (at
* your option) any later version.
*
* µSpectre 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
* General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with GNU Emacs; see the file COPYING. If not, write to the
* Free Software Foundation, Inc., 59 Temple Place - Suite 330,
* Boston, MA 02111-1307, USA.
*/
#include <type_traits>
#include <boost/mpl/list.hpp>
#include <boost/range/combine.hpp>
#include "materials/material_linear_elastic1.hh"
#include "materials/material_linear_elastic2.hh"
#include "tests.hh"
#include "tests/test_goodies.hh"
#include "common/field_collection.hh"
#include "common/iterators.hh"
namespace
muSpectre
{
BOOST_AUTO_TEST_SUITE
(
material_linear_elastic_1
);
template
<
class
Mat_t
>
struct
MaterialFixture
{
using
Mat
=
Mat_t
;
constexpr
static
Real
lambda
{
2
},
mu
{
1.5
};
constexpr
static
Real
young
{
mu
*
(
3
*
lambda
+
2
*
mu
)
/
(
lambda
+
mu
)};
constexpr
static
Real
poisson
{
lambda
/
(
2
*
(
lambda
+
mu
))};
MaterialFixture
()
:
mat
(
"Name"
,
young
,
poisson
){};
constexpr
static
Dim_t
sdim
{
Mat_t
::
sdim
()};
constexpr
static
Dim_t
mdim
{
Mat_t
::
mdim
()};
Mat_t
mat
;
};
template
<
class
Mat_t
>
struct
has_internals
{
constexpr
static
bool
value
{
false
};};
template
<
Dim_t
DimS
,
Dim_t
DimM
>
struct
has_internals
<
MaterialLinearElastic2
<
DimS
,
DimM
>>
{
constexpr
static
bool
value
{
true
};
};
using
mat_list
=
boost
::
mpl
::
list
<
MaterialFixture
<
MaterialLinearElastic1
<
twoD
,
twoD
>>
,
MaterialFixture
<
MaterialLinearElastic1
<
twoD
,
threeD
>>
,
MaterialFixture
<
MaterialLinearElastic1
<
threeD
,
threeD
>>
,
MaterialFixture
<
MaterialLinearElastic2
<
twoD
,
twoD
>>
,
MaterialFixture
<
MaterialLinearElastic2
<
twoD
,
threeD
>>
,
MaterialFixture
<
MaterialLinearElastic2
<
threeD
,
threeD
>>>
;
BOOST_FIXTURE_TEST_CASE_TEMPLATE
(
test_constructor
,
Fix
,
mat_list
,
Fix
)
{
BOOST_CHECK_EQUAL
(
"Name"
,
Fix
::
mat
.
get_name
());
auto
&
mat
{
Fix
::
mat
};
auto
sdim
{
Fix
::
sdim
};
auto
mdim
{
Fix
::
mdim
};
BOOST_CHECK_EQUAL
(
sdim
,
mat
.
sdim
());
BOOST_CHECK_EQUAL
(
mdim
,
mat
.
mdim
());
}
BOOST_FIXTURE_TEST_CASE_TEMPLATE
(
test_add_pixel
,
Fix
,
mat_list
,
Fix
)
{
auto
&
mat
{
Fix
::
mat
};
constexpr
Dim_t
sdim
{
Fix
::
sdim
};
testGoodies
::
RandRange
<
size_t
>
rng
;;
const
Dim_t
nb_pixel
{
7
},
box_size
{
17
};
using
Ccoord
=
Ccoord_t
<
sdim
>
;
for
(
Dim_t
i
=
0
;
i
<
nb_pixel
;
++
i
)
{
Ccoord
c
;
for
(
Dim_t
j
=
0
;
j
<
sdim
;
++
j
)
{
c
[
j
]
=
rng
.
randval
(
0
,
box_size
);
}
if
(
!
has_internals
<
typename
Fix
::
Mat
>::
value
)
{
BOOST_CHECK_NO_THROW
(
mat
.
add_pixel
(
c
));
}
}
BOOST_CHECK_NO_THROW
(
mat
.
initialise
());
}
template
<
class
Mat_t
>
struct
MaterialFixtureFilled:
public
MaterialFixture
<
Mat_t
>
{
using
Mat
=
Mat_t
;
constexpr
static
Dim_t
box_size
{
3
};
MaterialFixtureFilled
()
:
MaterialFixture
<
Mat_t
>
(){
using
Ccoord
=
Ccoord_t
<
Mat_t
::
sdim
()
>
;
Ccoord
cube
{
CcoordOps
::
get_cube
<
Mat_t
::
sdim
()
>
(
box_size
)};
CcoordOps
::
Pixels
<
Mat_t
::
sdim
()
>
pixels
(
cube
);
for
(
auto
pixel:
pixels
)
{
this
->
mat
.
add_pixel
(
pixel
);
}
this
->
mat
.
initialise
();
};
};
using
mat_fill
=
boost
::
mpl
::
list
<
MaterialFixtureFilled
<
MaterialLinearElastic1
<
twoD
,
twoD
>>
,
MaterialFixtureFilled
<
MaterialLinearElastic1
<
twoD
,
threeD
>>
,
MaterialFixtureFilled
<
MaterialLinearElastic1
<
threeD
,
threeD
>>>
;
BOOST_FIXTURE_TEST_CASE_TEMPLATE
(
test_evaluate_law
,
Fix
,
mat_fill
,
Fix
)
{
constexpr
auto
cube
{
CcoordOps
::
get_cube
<
Fix
::
sdim
>
(
Fix
::
box_size
)};
auto
&
mat
{
Fix
::
mat
};
using
FC_t
=
GlobalFieldCollection
<
Fix
::
sdim
,
Fix
::
mdim
>
;
FC_t
globalfields
;
auto
&
F
{
make_field
<
typename
Fix
::
Mat
::
StrainField_t
>
(
"Transformation Gradient"
,
globalfields
)};
auto
&
P1
=
make_field
<
typename
Fix
::
Mat
::
StressField_t
>
(
"Nominal Stress1"
,
globalfields
);
// to be computed alone
auto
&
P2
=
make_field
<
typename
Fix
::
Mat
::
StressField_t
>
(
"Nominal Stress2"
,
globalfields
);
// to be computed with tangent
auto
&
K
=
make_field
<
typename
Fix
::
Mat
::
TangentField_t
>
(
"Tangent Moduli"
,
globalfields
);
// to be computed with tangent
auto
&
Pr
=
make_field
<
typename
Fix
::
Mat
::
StressField_t
>
(
"Nominal Stress reference"
,
globalfields
);
auto
&
Kr
=
make_field
<
typename
Fix
::
Mat
::
TangentField_t
>
(
"Tangent Moduli reference"
,
globalfields
);
// to be computed with tangent
globalfields
.
initialise
(
cube
);
static_assert
(
std
::
is_same
<
decltype
(
P1
),
typename
Fix
::
Mat
::
StressField_t
&>::
value
,
"oh oh"
);
static_assert
(
std
::
is_same
<
decltype
(
F
),
typename
Fix
::
Mat
::
StrainField_t
&>::
value
,
"oh oh"
);
static_assert
(
std
::
is_same
<
decltype
(
P1
),
decltype
(
P2
)
&>::
value
,
"oh oh"
);
static_assert
(
std
::
is_same
<
decltype
(
K
),
typename
Fix
::
Mat
::
TangentField_t
&>::
value
,
"oh oh"
);
static_assert
(
std
::
is_same
<
decltype
(
Pr
),
decltype
(
P1
)
&>::
value
,
"oh oh"
);
static_assert
(
std
::
is_same
<
decltype
(
Kr
),
decltype
(
K
)
&>::
value
,
"oh oh"
);
using
traits
=
MaterialMuSpectre_traits
<
typename
Fix
::
Mat
>
;
{
// block to contain not-constant gradient map
typename
traits
::
StressMap_t
grad_map
(
globalfields
[
"Transformation Gradient"
]);
for
(
auto
F_:
grad_map
)
{
F_
.
setRandom
();
}
grad_map
[
0
]
=
grad_map
[
0
].
Identity
();
// identifiable gradients for debug
grad_map
[
1
]
=
1.2
*
grad_map
[
1
].
Identity
();
// ditto
}
//compute stresses using material
mat
.
compute_stresses
(
globalfields
[
"Transformation Gradient"
],
globalfields
[
"Nominal Stress1"
],
Formulation
::
finite_strain
);
//compute stresses and tangent moduli using material
BOOST_CHECK_THROW
(
mat
.
compute_stresses_tangent
(
globalfields
[
"Transformation Gradient"
],
globalfields
[
"Nominal Stress2"
],
globalfields
[
"Nominal Stress2"
],
Formulation
::
finite_strain
),
std
::
runtime_error
);
mat
.
compute_stresses_tangent
(
globalfields
[
"Transformation Gradient"
],
globalfields
[
"Nominal Stress2"
],
globalfields
[
"Tangent Moduli"
],
Formulation
::
finite_strain
);
typename
traits
::
StrainMap_t
Fmap
(
globalfields
[
"Transformation Gradient"
]);
typename
traits
::
StressMap_t
Pmap_ref
(
globalfields
[
"Nominal Stress reference"
]);
typename
traits
::
TangentMap_t
Kmap_ref
(
globalfields
[
"Tangent Moduli reference"
]);
for
(
auto
tup:
akantu
::
zip
(
Fmap
,
Pmap_ref
,
Kmap_ref
))
{
auto
F_
=
std
::
get
<
0
>
(
tup
);
auto
P_
=
std
::
get
<
1
>
(
tup
);
auto
K_
=
std
::
get
<
2
>
(
tup
);
std
::
tie
(
P_
,
K_
)
=
testGoodies
::
objective_hooke_explicit
<
Fix
::
mdim
>
(
Fix
::
lambda
,
Fix
::
mu
,
F_
);
}
typename
traits
::
StressMap_t
Pmap_1
(
globalfields
[
"Nominal Stress1"
]);
for
(
auto
tup:
akantu
::
zip
(
Pmap_ref
,
Pmap_1
))
{
auto
P_r
=
std
::
get
<
0
>
(
tup
);
auto
P_1
=
std
::
get
<
1
>
(
tup
);
Real
error
=
(
P_r
-
P_1
).
norm
();
BOOST_CHECK_LT
(
error
,
tol
);
}
typename
traits
::
StressMap_t
Pmap_2
(
globalfields
[
"Nominal Stress2"
]);
typename
traits
::
TangentMap_t
Kmap
(
globalfields
[
"Tangent Moduli"
]);
for
(
auto
tup:
akantu
::
zip
(
Pmap_ref
,
Pmap_2
,
Kmap_ref
,
Kmap
))
{
auto
P_r
=
std
::
get
<
0
>
(
tup
);
auto
P
=
std
::
get
<
1
>
(
tup
);
Real
error
=
(
P_r
-
P
).
norm
();
BOOST_CHECK_LT
(
error
,
tol
);
auto
K_r
=
std
::
get
<
2
>
(
tup
);
auto
K
=
std
::
get
<
3
>
(
tup
);
error
=
(
K_r
-
K
).
norm
();
BOOST_CHECK_LT
(
error
,
tol
);
}
}
BOOST_AUTO_TEST_SUITE_END
();
}
// muSpectre
Event Timeline
Log In to Comment