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rMUSPECTRE µSpectre
test_material_evaluator.cc
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/**
* @file test_material_evaluator.cc
*
* @author Till Junge <till.junge@altermail.ch>
*
* @date 13 Jan 2019
*
* @brief tests for the material evaluator mechanism
*
* Copyright © 2019 Till Junge
*
* µSpectre 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, 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 Lesser General Public License
* along with µSpectre; see the file COPYING. If not, write to the
* Free Software Foundation, Inc., 59 Temple Place - Suite 330,
* Boston, MA 02111-1307, USA.
*
* Additional permission under GNU GPL version 3 section 7
*
* If you modify this Program, or any covered work, by linking or combining it
* with proprietary FFT implementations or numerical libraries, containing parts
* covered by the terms of those libraries' licenses, the licensors of this
* Program grant you additional permission to convey the resulting work.
*/
#include "tests.hh"
#include "common/T4_map_proxy.hh"
#include "materials/material_linear_elastic2.hh"
#include "materials/material_evaluator.hh"
#include "Eigen/Dense"
namespace
muSpectre
{
BOOST_AUTO_TEST_SUITE
(
material_evaluator_tests
);
/* ---------------------------------------------------------------------- */
BOOST_AUTO_TEST_CASE
(
without_per_pixel_data
)
{
using
Mat_t
=
MaterialLinearElastic1
<
twoD
,
twoD
>
;
constexpr
Real
Young
{
210e9
};
constexpr
Real
Poisson
{
.33
};
auto
mat_eval
=
Mat_t
::
make_evaluator
(
Young
,
Poisson
);
auto
&
mat
=
*
std
::
get
<
0
>
(
mat_eval
);
auto
&
evaluator
=
std
::
get
<
1
>
(
mat_eval
);
using
T2_t
=
Eigen
::
Matrix
<
Real
,
twoD
,
twoD
>
;
using
T4_t
=
T4Mat
<
Real
,
twoD
>
;
const
T2_t
F
{(
T2_t
::
Random
()
-
(
T2_t
::
Ones
()
*
.5
))
*
1e-4
+
T2_t
::
Identity
()};
const
T2_t
eps
{
.5
*
((
F
-
T2_t
::
Identity
())
+
(
F
-
T2_t
::
Identity
()).
transpose
())};
/*
* at this point, the evaluator has been created, but the underlying
* material still has zero pixels. Evaluation is not yet possible, and
* trying to do so has to fail with an explicit error message
*/
BOOST_CHECK_THROW
(
evaluator
.
evaluate_stress
(
eps
,
Formulation
::
small_strain
),
std
::
runtime_error
);
mat
.
add_pixel
({});
const
T2_t
sigma
{
evaluator
.
evaluate_stress
(
eps
,
Formulation
::
small_strain
)};
const
T2_t
P
{
evaluator
.
evaluate_stress
(
F
,
Formulation
::
finite_strain
)};
auto
J
{
F
.
determinant
()};
auto
P_reconstruct
{
J
*
sigma
*
F
.
inverse
().
transpose
()};
auto
error_comp
{[](
const
auto
&
a
,
const
auto
&
b
)
{
return
(
a
-
b
).
norm
()
/
(
a
+
b
).
norm
();
}};
auto
error
{
error_comp
(
P
,
P_reconstruct
)};
constexpr
Real
small_strain_tol
{
1e-3
};
if
(
not
(
error
<=
small_strain_tol
))
{
std
::
cout
<<
"F ="
<<
std
::
endl
<<
F
<<
std
::
endl
;
std
::
cout
<<
"ε ="
<<
std
::
endl
<<
eps
<<
std
::
endl
;
std
::
cout
<<
"P ="
<<
std
::
endl
<<
P
<<
std
::
endl
;
std
::
cout
<<
"σ ="
<<
std
::
endl
<<
sigma
<<
std
::
endl
;
std
::
cout
<<
"P_reconstructed ="
<<
std
::
endl
<<
P_reconstruct
<<
std
::
endl
;
}
BOOST_CHECK_LE
(
error
,
small_strain_tol
);
T2_t
sigma2
,
P2
;
T4_t
C
,
K
;
std
::
tie
(
sigma2
,
C
)
=
evaluator
.
evaluate_stress_tangent
(
eps
,
Formulation
::
small_strain
);
std
::
tie
(
P2
,
K
)
=
evaluator
.
evaluate_stress_tangent
(
F
,
Formulation
::
finite_strain
);
error
=
error_comp
(
sigma2
,
sigma
);
BOOST_CHECK_LE
(
error
,
tol
);
error
=
error_comp
(
P2
,
P
);
BOOST_CHECK_LE
(
error
,
tol
);
error
=
error_comp
(
C
,
K
);
if
(
not
(
error
<=
small_strain_tol
))
{
std
::
cout
<<
"F ="
<<
std
::
endl
<<
F
<<
std
::
endl
;
std
::
cout
<<
"ε ="
<<
std
::
endl
<<
eps
<<
std
::
endl
;
std
::
cout
<<
"P ="
<<
std
::
endl
<<
P
<<
std
::
endl
;
std
::
cout
<<
"σ ="
<<
std
::
endl
<<
sigma
<<
std
::
endl
;
std
::
cout
<<
"K ="
<<
std
::
endl
<<
K
<<
std
::
endl
;
std
::
cout
<<
"C ="
<<
std
::
endl
<<
C
<<
std
::
endl
;
}
BOOST_CHECK_LE
(
error
,
small_strain_tol
);
mat
.
add_pixel
({
1
});
/*
* Now, the material has two pixels, and evaluating it would be ambiguous.
* It should fail with an explicit error message
*/
BOOST_CHECK_THROW
(
evaluator
.
evaluate_stress
(
eps
,
Formulation
::
small_strain
),
std
::
runtime_error
);
}
/* ---------------------------------------------------------------------- */
BOOST_AUTO_TEST_CASE
(
with_per_pixel_data
)
{
using
Mat_t
=
MaterialLinearElastic2
<
twoD
,
twoD
>
;
constexpr
Real
Young
{
210e9
};
constexpr
Real
Poisson
{
.33
};
auto
mat_eval
{
Mat_t
::
make_evaluator
(
Young
,
Poisson
)};
auto
&
mat
{
*
std
::
get
<
0
>
(
mat_eval
)};
auto
&
evaluator
{
std
::
get
<
1
>
(
mat_eval
)};
using
T2_t
=
Eigen
::
Matrix
<
Real
,
twoD
,
twoD
>
;
using
T4_t
=
T4Mat
<
Real
,
twoD
>
;
const
T2_t
F
{(
T2_t
::
Random
()
-
(
T2_t
::
Ones
()
*
.5
))
*
1e-4
+
T2_t
::
Identity
()};
const
T2_t
eps
{
.5
*
((
F
-
T2_t
::
Identity
())
+
(
F
-
T2_t
::
Identity
()).
transpose
())};
BOOST_CHECK_THROW
(
evaluator
.
evaluate_stress
(
eps
,
Formulation
::
small_strain
),
std
::
runtime_error
);
T2_t
eigen_strain
{[](
auto
x
)
{
return
1e-4
*
(
x
+
x
.
transpose
());
}(
T2_t
::
Random
()
-
T2_t
::
Ones
()
*
.5
)};
mat
.
add_pixel
({},
eigen_strain
);
const
T2_t
sigma
{
evaluator
.
evaluate_stress
(
eps
,
Formulation
::
small_strain
)};
const
T2_t
P
{
evaluator
.
evaluate_stress
(
F
,
Formulation
::
finite_strain
)};
auto
J
{
F
.
determinant
()};
auto
P_reconstruct
{
J
*
sigma
*
F
.
inverse
().
transpose
()};
auto
error_comp
{[](
const
auto
&
a
,
const
auto
&
b
)
{
return
(
a
-
b
).
norm
()
/
(
a
+
b
).
norm
();
}};
auto
error
{
error_comp
(
P
,
P_reconstruct
)};
constexpr
Real
small_strain_tol
{
1e-3
};
if
(
not
(
error
<=
small_strain_tol
))
{
std
::
cout
<<
"F ="
<<
std
::
endl
<<
F
<<
std
::
endl
;
std
::
cout
<<
"ε ="
<<
std
::
endl
<<
eps
<<
std
::
endl
;
std
::
cout
<<
"P ="
<<
std
::
endl
<<
P
<<
std
::
endl
;
std
::
cout
<<
"σ ="
<<
std
::
endl
<<
sigma
<<
std
::
endl
;
std
::
cout
<<
"P_reconstructed ="
<<
std
::
endl
<<
P_reconstruct
<<
std
::
endl
;
}
BOOST_CHECK_LE
(
error
,
small_strain_tol
);
T2_t
sigma2
,
P2
;
T4_t
C
,
K
;
std
::
tie
(
sigma2
,
C
)
=
evaluator
.
evaluate_stress_tangent
(
eps
,
Formulation
::
small_strain
);
std
::
tie
(
P2
,
K
)
=
evaluator
.
evaluate_stress_tangent
(
F
,
Formulation
::
finite_strain
);
error
=
error_comp
(
sigma2
,
sigma
);
BOOST_CHECK_LE
(
error
,
tol
);
error
=
error_comp
(
P2
,
P
);
BOOST_CHECK_LE
(
error
,
tol
);
error
=
error_comp
(
C
,
K
);
if
(
not
(
error
<=
small_strain_tol
))
{
std
::
cout
<<
"F ="
<<
std
::
endl
<<
F
<<
std
::
endl
;
std
::
cout
<<
"ε ="
<<
std
::
endl
<<
eps
<<
std
::
endl
;
std
::
cout
<<
"P ="
<<
std
::
endl
<<
P
<<
std
::
endl
;
std
::
cout
<<
"σ ="
<<
std
::
endl
<<
sigma
<<
std
::
endl
;
std
::
cout
<<
"K ="
<<
std
::
endl
<<
K
<<
std
::
endl
;
std
::
cout
<<
"C ="
<<
std
::
endl
<<
C
<<
std
::
endl
;
}
BOOST_CHECK_LE
(
error
,
small_strain_tol
);
}
/* ---------------------------------------------------------------------- */
BOOST_AUTO_TEST_CASE
(
tangent_estimation
)
{
using
Mat_t
=
MaterialLinearElastic1
<
twoD
,
twoD
>
;
constexpr
Real
Young
{
210e9
};
constexpr
Real
Poisson
{
.33
};
auto
mat_eval
=
Mat_t
::
make_evaluator
(
Young
,
Poisson
);
auto
&
mat
=
*
std
::
get
<
0
>
(
mat_eval
);
auto
&
evaluator
=
std
::
get
<
1
>
(
mat_eval
);
using
T2_t
=
Eigen
::
Matrix
<
Real
,
twoD
,
twoD
>
;
using
T4_t
=
T4Mat
<
Real
,
twoD
>
;
const
T2_t
F
{(
T2_t
::
Random
()
-
(
T2_t
::
Ones
()
*
.5
))
*
1e-4
+
T2_t
::
Identity
()};
const
T2_t
eps
{
.5
*
((
F
-
T2_t
::
Identity
())
+
(
F
-
T2_t
::
Identity
()).
transpose
())};
BOOST_CHECK_THROW
(
evaluator
.
evaluate_stress
(
eps
,
Formulation
::
small_strain
),
std
::
runtime_error
);
mat
.
add_pixel
({});
T2_t
sigma
,
P
;
T4_t
C
,
K
;
std
::
tie
(
sigma
,
C
)
=
evaluator
.
evaluate_stress_tangent
(
eps
,
Formulation
::
small_strain
);
std
::
tie
(
P
,
K
)
=
evaluator
.
evaluate_stress_tangent
(
F
,
Formulation
::
finite_strain
);
constexpr
Real
linear_step
{
1.
};
constexpr
Real
nonlin_step
{
1.e-6
};
T4_t
C_estim
{
evaluator
.
estimate_tangent
(
eps
,
Formulation
::
small_strain
,
linear_step
)};
T4_t
K_estim
{
evaluator
.
estimate_tangent
(
F
,
Formulation
::
finite_strain
,
nonlin_step
)};
auto
error_comp
{[](
const
auto
&
a
,
const
auto
&
b
)
{
return
(
a
-
b
).
norm
()
/
(
a
+
b
).
norm
();
}};
constexpr
Real
finite_diff_tol
{
1e-9
};
Real
error
{
error_comp
(
K
,
K_estim
)};
if
(
not
(
error
<=
finite_diff_tol
))
{
std
::
cout
<<
"K ="
<<
std
::
endl
<<
K
<<
std
::
endl
;
std
::
cout
<<
"K_estim ="
<<
std
::
endl
<<
K_estim
<<
std
::
endl
;
}
BOOST_CHECK_LE
(
error
,
finite_diff_tol
);
error
=
error_comp
(
C
,
C_estim
);
if
(
not
(
error
<=
tol
))
{
std
::
cout
<<
"centred difference:"
<<
std
::
endl
;
std
::
cout
<<
"C ="
<<
std
::
endl
<<
C
<<
std
::
endl
;
std
::
cout
<<
"C_estim ="
<<
std
::
endl
<<
C_estim
<<
std
::
endl
;
}
BOOST_CHECK_LE
(
error
,
tol
);
C_estim
=
evaluator
.
estimate_tangent
(
eps
,
Formulation
::
small_strain
,
linear_step
,
FiniteDiff
::
forward
);
error
=
error_comp
(
C
,
C_estim
);
if
(
not
(
error
<=
tol
))
{
std
::
cout
<<
"forward difference:"
<<
std
::
endl
;
std
::
cout
<<
"C ="
<<
std
::
endl
<<
C
<<
std
::
endl
;
std
::
cout
<<
"C_estim ="
<<
std
::
endl
<<
C_estim
<<
std
::
endl
;
}
BOOST_CHECK_LE
(
error
,
tol
);
C_estim
=
evaluator
.
estimate_tangent
(
eps
,
Formulation
::
small_strain
,
linear_step
,
FiniteDiff
::
backward
);
error
=
error_comp
(
C
,
C_estim
);
if
(
not
(
error
<=
tol
))
{
std
::
cout
<<
"backward difference:"
<<
std
::
endl
;
std
::
cout
<<
"C ="
<<
std
::
endl
<<
C
<<
std
::
endl
;
std
::
cout
<<
"C_estim ="
<<
std
::
endl
<<
C_estim
<<
std
::
endl
;
}
BOOST_CHECK_LE
(
error
,
tol
);
}
BOOST_AUTO_TEST_SUITE_END
();
}
// namespace muSpectre
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