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dynamic_solver.py
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Mon, Nov 25, 19:54
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rAKA akantu
dynamic_solver.py
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__copyright__
=
(
"Copyright (©) 2016-2023 EPFL (Ecole Polytechnique Fédérale de Lausanne)"
"Laboratory (LSMS - Laboratoire de Simulation en Mécanique des Solides)"
)
__license__
=
"LGPLv3"
__copyright__
=
(
"Copyright (©) 2016-2023 EPFL (Ecole Polytechnique Fédérale de Lausanne)"
"Laboratory (LSMS - Laboratoire de Simulation en Mécanique des Solides)"
)
__license__
=
"LGPLv3"
__copyright__
=
(
"Copyright (©) 2016-2023 EPFL (Ecole Polytechnique Fédérale de Lausanne)"
"Laboratory (LSMS - Laboratoire de Simulation en Mécanique des Solides)"
)
__license__
=
"LGPLv3"
__copyright__
=
(
"Copyright (©) 2016-2023 EPFL (Ecole Polytechnique Fédérale de Lausanne)"
"Laboratory (LSMS - Laboratoire de Simulation en Mécanique des Solides)"
)
__license__
=
"LGPLv3"
__copyright__
=
(
"Copyright (©) 2016-2023 EPFL (Ecole Polytechnique Fédérale de Lausanne)"
"Laboratory (LSMS - Laboratoire de Simulation en Mécanique des Solides)"
)
__license__
=
"LGPLv3"
__copyright__
=
"Copyright (©) 2016-2023 EPFL (Ecole Polytechnique Fédérale"
\
" de Lausanne) Laboratory (LSMS - Laboratoire de Simulation"
\
" en Mécanique des Solides)"
__license__
=
"LGPLv3"
__copyright__
=
"Copyright (©) 2016-2023 EPFL (Ecole Polytechnique Fédérale"
\
" de Lausanne) Laboratory (LSMS - Laboratoire de Simulation"
\
" en Mécanique des Solides)"
__license__
=
"LGPLv3"
__copyright__
=
"Copyright (©) 2016-2023 EPFL (Ecole Polytechnique Fédérale"
\
" de Lausanne) Laboratory (LSMS - Laboratoire de Simulation"
\
" en Mécanique des Solides)"
__license__
=
"LGPLv3"
""" dynamic_solver.py: dynamic solver for test purposes"""
# ------------------------------------------------------------------------------
__author__
=
"Nicolas Richart"
__credits__
=
[
"Nicolas Richart <nicolas.richart@epfl.ch>"
,
]
__copyright__
=
"Copyright (©) 2016-2021 EPFL (Ecole Polytechnique Fédérale"
\
" de Lausanne) Laboratory (LSMS - Laboratoire de Simulation"
\
" en Mécanique des Solides)"
__license__
=
"LGPLv3"
# ------------------------------------------------------------------------------
import
copy
import
numpy.linalg
as
npl
import
scipy.sparse
as
sp
import
scipy.sparse.linalg
as
spl
from
.
import
export
from
.
import
fe
@export
class
DynamicSolver
(
fe
.
Solver
):
def
__init__
(
self
,
model
,
**
kwargs
):
opt
=
copy
.
copy
(
kwargs
)
self
.
_delta_t
=
opt
.
pop
(
"delta_t"
,
0.001
)
self
.
_alpha
=
opt
.
pop
(
"alpha"
,
1.
/
2.
)
self
.
_beta
=
opt
.
pop
(
"beta"
,
1.
/
2.
)
self
.
_type
=
opt
.
pop
(
"type"
,
'disp'
)
self
.
_tolerance
=
opt
.
pop
(
"tolerance"
,
1e-10
)
self
.
_max_nloops
=
opt
.
pop
(
"max_iterations"
,
100
)
self
.
_model
=
model
self
.
_J
=
sp
.
csr_matrix
(
self
.
_model
.
K
.
shape
)
self
.
_coeff
=
{
'disp'
:
{
'disp'
:
1.
,
'velo'
:
1.
/
(
self
.
_alpha
*
self
.
_delta_t
),
'acce'
:
1.
/
(
self
.
_alpha
*
self
.
_beta
*
self
.
_delta_t
**
2
)},
# NOQA: E501
'velo'
:
{
'disp'
:
self
.
_alpha
*
self
.
_delta_t
,
'velo'
:
1.
,
'acce'
:
1.
/
(
self
.
_beta
*
self
.
_delta_t
)},
'acce'
:
{
'disp'
:
self
.
_alpha
*
self
.
_beta
*
self
.
_delta_t
**
2
,
# NOQA: E501
'velo'
:
self
.
_beta
*
self
.
_delta_t
,
'acce'
:
1.
}}
def
_assembleResidual
(
self
):
self
.
_r
=
self
.
_model
.
f_ext
-
self
.
_model
.
f_int
-
\
self
.
_model
.
M
*
self
.
_model
.
a
C
=
self
.
_model
.
C
if
C
is
not
None
:
self
.
_r
-=
C
*
self
.
_model
.
v
def
_predictor
(
self
):
self
.
_model
.
u
+=
self
.
_delta_t
*
self
.
_model
.
v
+
\
self
.
_delta_t
**
2
/
2.
*
self
.
_model
.
a
self
.
_model
.
v
+=
self
.
_delta_t
*
self
.
_model
.
a
def
_corrector
(
self
,
delta_
):
self
.
_model
.
u
+=
self
.
_coeff
[
self
.
_type
][
'disp'
]
*
delta_
self
.
_model
.
v
+=
self
.
_coeff
[
self
.
_type
][
'velo'
]
*
delta_
self
.
_model
.
a
+=
self
.
_coeff
[
self
.
_type
][
'acce'
]
*
delta_
def
_assembleJacobian
(
self
):
K
=
self
.
_model
.
K
e
=
self
.
_coeff
[
self
.
_type
][
'disp'
]
self
.
_J
=
e
*
K
C
=
self
.
_model
.
C
if
C
is
not
None
:
d
=
self
.
_coeff
[
self
.
_type
][
'velo'
]
self
.
_J
+=
d
*
C
M
=
self
.
_model
.
M
if
M
is
not
None
:
c
=
self
.
_coeff
[
self
.
_type
][
'acce'
]
self
.
_J
+=
c
*
M
self
.
_model
.
applyDirichletBC
()
self
.
_zero_rows
(
self
.
_J
,
self
.
_model
.
blocked
)
def
solveStep
(
self
):
self
.
_predictor
()
self
.
_nloops
=
0
converged
=
False
while
not
converged
:
self
.
_assembleJacobian
()
self
.
_assembleResidual
()
delta_
=
spl
.
spsolve
(
self
.
_J
,
self
.
_r
)
self
.
_corrector
(
delta_
)
self
.
_nloops
+=
1
error
=
npl
.
norm
(
delta_
)
converged
=
error
<
self
.
_tolerance
or
\
self
.
_nloops
>
self
.
_max_nloops
print
(
"{0} {1} -> {2}"
.
format
(
error
,
self
.
_nloops
,
converged
))
if
self
.
_nloops
>=
self
.
_max_nloops
:
raise
ValueError
(
'The solver did not converge'
)
@property
def
nloops
(
self
):
return
self
.
_nloops
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