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F85451968
HelmholtzVFLagrangeApproximant.py
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Sun, Sep 29, 08:15
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4 KB
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text/x-python
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Tue, Oct 1, 08:15 (1 d, 23 h)
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21184258
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R6746 RationalROMPy
HelmholtzVFLagrangeApproximant.py
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#!/usr/bin/env python3
import
numpy
as
np
from
context
import
FenicsHelmholtzEngine
as
HFEngine
from
context
import
FenicsHelmholtzScatteringEngine
as
HFSEngine
from
context
import
FenicsHelmholtzScatteringAugmentedEngine
as
HFSAEngine
from
context
import
FenicsHSEngine
as
HSEngine
from
context
import
FenicsHSAugmentedEngine
as
HSAEngine
from
context
import
ROMApproximantLagrangeVF
as
VF
testNo
=
4
if
testNo
==
1
:
params
=
{
'N'
:
4
,
'M'
:
3
,
'S'
:
5
,
'polyBasis'
:
'CHEBYSHEV'
,
'POD'
:
True
}
z0s
=
[
10
+
.
5j
,
14
+
.
5j
]
z0
=
np
.
mean
(
z0s
)
ztar
=
11
from
FEniCS_snippets
import
SquareHomogeneousBubble
boundary
,
mesh
,
forcingTerm
=
SquareHomogeneousBubble
(
kappa
=
12
**
.
5
,
theta
=
np
.
pi
/
3
,
n
=
40
)
solver
=
HFEngine
(
mesh
=
mesh
,
wavenumber
=
z0
**.
5
,
forcingTerm
=
forcingTerm
,
FEDegree
=
3
,
DirichletBoundary
=
boundary
,
DirichletDatum
=
0
)
plotter
=
HSEngine
(
solver
.
V
)
approx
=
VF
(
solver
,
plotter
,
mus
=
z0s
,
w
=
np
.
real
(
z0
**.
5
),
approxParameters
=
params
)
approx
.
plotApp
(
ztar
,
name
=
'u_RB'
)
approx
.
plotHF
(
ztar
,
name
=
'u_HF'
)
approx
.
plotErr
(
ztar
,
name
=
'err'
)
appErr
,
solNorm
=
approx
.
approxError
(
ztar
),
approx
.
HFNorm
(
ztar
)
print
((
'SolNorm:
\t
{}
\n
Err:
\t
{}
\n
ErrRel:
\t
{}'
)
.
format
(
solNorm
,
appErr
,
np
.
divide
(
appErr
,
solNorm
)))
print
(
'
\n
Poles VF:'
)
print
(
approx
.
getPoles
())
############
elif
testNo
==
2
:
params
=
{
'N'
:
9
,
'M'
:
8
,
'S'
:
10
,
'polyBasis'
:
'CHEBYSHEV'
,
'POD'
:
True
}
z0s
=
np
.
power
([
3.85
+
.
15j
,
4.15
+
.
15j
],
2.
)
z0
=
np
.
mean
(
z0s
)
ztar
=
4
**
2.
from
FEniCS_snippets
import
SquareTransmissionDirichlet
boundary
,
mesh
,
n
,
u0
=
SquareTransmissionDirichlet
(
nT
=
2
,
nB
=
1
,
theta
=
np
.
pi
*
45
/
180
,
kappa
=
4.
,
n
=
50
)
solver
=
HFEngine
(
mesh
=
mesh
,
wavenumber
=
z0
**.
5
,
refractionIndex
=
n
,
FEDegree
=
3
,
DirichletBoundary
=
boundary
,
DirichletDatum
=
u0
)
plotter
=
HSEngine
(
solver
.
V
)
approx
=
VF
(
solver
,
plotter
,
mus
=
z0s
,
w
=
np
.
real
(
z0
**.
5
),
approxParameters
=
params
,
plotSnap
=
'ALL'
)
approx
.
plotApp
(
ztar
,
name
=
'u_VF'
)
approx
.
plotHF
(
ztar
,
name
=
'u_HF'
)
approx
.
plotErr
(
ztar
,
name
=
'err'
)
appErr
,
solNorm
=
approx
.
approxError
(
ztar
),
approx
.
HFNorm
(
ztar
)
print
((
'SolNorm:
\t
{}
\n
Err:
\t
{}
\n
ErrRel:
\t
{}'
)
.
format
(
solNorm
,
appErr
,
np
.
divide
(
appErr
,
solNorm
)))
print
(
'
\n
Poles VF:'
)
print
(
approx
.
getPoles
())
############
elif
testNo
in
[
3
,
4
]:
params
=
{
'N'
:
40
,
'M'
:
39
,
'S'
:
45
,
'polyBasis'
:
'CHEBYSHEV'
,
'POD'
:
True
}
k0s
=
[
0
,
8
]
k0
=
np
.
mean
(
k0s
)
ktar
=
4.5
from
FEniCS_snippets
import
SquareScatteringTB
bdrD
,
bdrN
,
mesh
,
forcingTerm
=
SquareScatteringTB
(
kappa
=
4
,
theta
=
np
.
pi
/
2
,
n
=
40
)
if
testNo
==
3
:
solver
=
HFSEngine
(
mesh
=
mesh
,
wavenumber
=
k0
,
FEDegree
=
3
,
forcingTerm
=
forcingTerm
,
DirichletBoundary
=
bdrD
,
RobinBoundary
=
bdrN
)
plotter
=
HSEngine
(
solver
.
V
)
else
:
solver
=
HFSAEngine
(
mesh
=
mesh
,
wavenumber
=
k0
,
FEDegree
=
3
,
forcingTerm
=
forcingTerm
,
DirichletBoundary
=
bdrD
,
RobinBoundary
=
bdrN
)
plotter
=
HSAEngine
(
solver
.
V
,
2
)
approx
=
VF
(
solver
,
plotter
,
mus
=
k0s
,
approxParameters
=
params
)
approx
.
plotApp
(
ktar
,
name
=
'u_VF'
)
approx
.
plotHF
(
ktar
,
name
=
'u_HF'
)
approx
.
plotErr
(
ktar
,
name
=
'err'
)
appErr
,
solNorm
=
approx
.
approxError
(
ktar
),
approx
.
HFNorm
(
ktar
)
print
((
'SolNorm:
\t
{}
\n
Err:
\t
{}
\n
ErrRel:
\t
{}'
)
.
format
(
solNorm
,
appErr
,
np
.
divide
(
appErr
,
solNorm
)))
print
(
'
\n
Poles VF:'
)
print
(
approx
.
getPoles
())
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