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Liu Dezi
csst_msc_sim
Commits
883b7a77
Commit
883b7a77
authored
Nov 29, 2021
by
Fang Yuedong
Browse files
bug fixed
parent
e82a5dcc
Changes
392
Show whitespace changes
Inline
Side-by-side
ObservationSim/Config/Config.py
View file @
883b7a77
...
@@ -23,6 +23,7 @@ def ConfigDir(config, work_dir=None, data_dir=None):
...
@@ -23,6 +23,7 @@ def ConfigDir(config, work_dir=None, data_dir=None):
path_dict
[
"cat_dir"
]
=
os
.
path
.
join
(
path_dict
[
"data_dir"
],
config
[
"input_path"
][
"cat_dir"
])
path_dict
[
"cat_dir"
]
=
os
.
path
.
join
(
path_dict
[
"data_dir"
],
config
[
"input_path"
][
"cat_dir"
])
# PSF data directory
# PSF data directory
path_dict
[
"psf_dir"
]
=
os
.
path
.
join
(
path_dict
[
"data_dir"
],
config
[
"psf_setting"
][
"psf_dir"
])
path_dict
[
"psf_dir"
]
=
os
.
path
.
join
(
path_dict
[
"data_dir"
],
config
[
"psf_setting"
][
"psf_dir"
])
path_dict
[
"fd_path"
]
=
os
.
path
.
join
(
path_dict
[
"data_dir"
],
config
[
"psf_setting"
][
"fd_path"
])
# SED catalog directory
# SED catalog directory
# TODO: SED_dir is deprecated
# TODO: SED_dir is deprecated
path_dict
[
"SED_dir"
]
=
os
.
path
.
join
(
path_dict
[
"data_dir"
],
"imageSims/Catalog/SEDObject"
)
path_dict
[
"SED_dir"
]
=
os
.
path
.
join
(
path_dict
[
"data_dir"
],
"imageSims/Catalog/SEDObject"
)
...
...
ObservationSim/Instrument/Chip/Chip.py
View file @
883b7a77
...
@@ -65,7 +65,7 @@ class Chip(FocalPlane):
...
@@ -65,7 +65,7 @@ class Chip(FocalPlane):
self
.
_getCRdata
()
self
.
_getCRdata
()
# Define the sensor
# Define the sensor
if
config
[
"ins_effects"
][
"bright_fatter"
]
==
True
:
if
config
[
"ins_effects"
][
"bright_fatter"
]
==
True
and
self
.
survey_type
==
"photometric"
:
self
.
sensor
=
galsim
.
SiliconSensor
(
strength
=
config
[
"ins_effects"
][
"df_strength"
],
treering_func
=
treering_func
)
self
.
sensor
=
galsim
.
SiliconSensor
(
strength
=
config
[
"ins_effects"
][
"df_strength"
],
treering_func
=
treering_func
)
else
:
else
:
self
.
sensor
=
galsim
.
Sensor
()
self
.
sensor
=
galsim
.
Sensor
()
...
...
ObservationSim/ObservationSim.py
View file @
883b7a77
...
@@ -26,7 +26,7 @@ class Observation(object):
...
@@ -26,7 +26,7 @@ class Observation(object):
# if we want to apply field distortion?
# if we want to apply field distortion?
if
self
.
config
[
"ins_effects"
][
"field_dist"
]
==
True
:
if
self
.
config
[
"ins_effects"
][
"field_dist"
]
==
True
:
self
.
fd_model
=
FieldDistortion
()
self
.
fd_model
=
FieldDistortion
(
fdModel_path
=
self
.
path_dict
[
"fd_path"
]
)
else
:
else
:
self
.
fd_model
=
None
self
.
fd_model
=
None
...
@@ -59,7 +59,7 @@ class Observation(object):
...
@@ -59,7 +59,7 @@ class Observation(object):
if
self
.
config
[
"psf_setting"
][
"psf_model"
]
==
"Gauss"
:
if
self
.
config
[
"psf_setting"
][
"psf_model"
]
==
"Gauss"
:
psf_model
=
PSFGauss
(
chip
=
chip
)
psf_model
=
PSFGauss
(
chip
=
chip
)
elif
self
.
config
[
"psf_setting"
][
"psf_model"
]
==
"Interp"
:
elif
self
.
config
[
"psf_setting"
][
"psf_model"
]
==
"Interp"
:
psf_model
=
PSFInterp
(
chip
=
chip
)
psf_model
=
PSFInterp
(
chip
=
chip
,
PSF_data_file
=
self
.
path_dict
[
"psf_dir"
]
)
else
:
else
:
print
(
"unrecognized PSF model type!!"
,
flush
=
True
)
print
(
"unrecognized PSF model type!!"
,
flush
=
True
)
...
@@ -78,7 +78,7 @@ class Observation(object):
...
@@ -78,7 +78,7 @@ class Observation(object):
if
chip
.
survey_type
==
"photometric"
:
if
chip
.
survey_type
==
"photometric"
:
sky_map
=
None
sky_map
=
None
elif
chip
.
survey_type
==
"spectroscopic"
:
elif
chip
.
survey_type
==
"spectroscopic"
:
sky_map
=
calculateSkyMap_split_g
(
xLen
=
chip
.
npix_x
,
yLen
=
chip
.
npix_y
,
blueLimit
=
filt
.
blue_limit
,
redLimit
=
filt
.
red_limit
,
skyfn
=
path_dict
[
"sky_file"
],
conf
=
chip
.
sls_conf
,
pixelSize
=
chip
.
pix_scale
,
isAlongY
=
0
)
sky_map
=
calculateSkyMap_split_g
(
xLen
=
chip
.
npix_x
,
yLen
=
chip
.
npix_y
,
blueLimit
=
filt
.
blue_limit
,
redLimit
=
filt
.
red_limit
,
skyfn
=
self
.
path_dict
[
"sky_file"
],
conf
=
chip
.
sls_conf
,
pixelSize
=
chip
.
pix_scale
,
isAlongY
=
0
)
if
pointing_type
==
'MS'
:
if
pointing_type
==
'MS'
:
# Load catalogues and templates
# Load catalogues and templates
...
...
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp.py
deleted
100644 → 0
View file @
e82a5dcc
import
galsim
import
numpy
as
np
import
os
import
time
import
copy
# import psfConfig as mypy
import
PSF.PSFInterp.psfConfig
as
mypy
npsf
=
900
#***# 30*30
LOG_DEBUG
=
False
#***#
class
PSFInterp
(
object
):
# def __init__(self, PSF_data=None, params=None, PSF_data_file=None):
def
__init__
(
self
,
chip
,
PSF_data
=
None
,
PSF_data_file
=
None
,
sigSpin
=
0.
,
psfRa
=
0.15
):
"""
The PSF data matrix is either given by a object parameter or read in from a file.
Parameters:
PSF_data: The PSF data matrix object
params: Other parameters?
PSF_data_file: The file for PSF data matrix (optional).
"""
if
LOG_DEBUG
:
print
(
'==================================================='
)
print
(
'DEBUG: psf module for csstSim '
\
+
time
.
strftime
(
"(%Y-%m-%d %H:%M:%S)"
,
time
.
localtime
()),
flush
=
True
)
print
(
'==================================================='
)
self
.
sigSpin
=
sigSpin
self
.
sigGauss
=
psfRa
# 80% light radius
# iccd = 1 #***#
# iccd = chip.chipID
iccd
=
int
(
chip
.
getChipLabel
(
chipID
=
chip
.
chipID
))
if
PSF_data_file
==
None
:
PSF_data_file
=
'/data/simudata/CSSOSDataProductsSims/data/csstPSFdata/CSSOS_psf_ciomp_30X30'
self
.
nwave
=
self
.
_getPSFwave
(
iccd
,
PSF_data_file
)
if
LOG_DEBUG
:
print
(
'nwave-{:} on ccd-{:}::'
.
format
(
self
.
nwave
,
iccd
),
flush
=
True
)
self
.
PSF_data
=
self
.
_loadPSF
(
iccd
,
PSF_data_file
)
self
.
itpPSF_data
=
self
.
_preprocessPSF
()
if
LOG_DEBUG
:
print
(
'self.PSF_data & self.itpPSF_data ... ok'
,
flush
=
True
)
if
LOG_DEBUG
:
print
(
'Preparing self.[psfMat,cen_col,cen_row] for psfMaker ... '
,
end
=
''
,
flush
=
True
)
ngy
,
ngx
=
self
.
itpPSF_data
[
0
][
0
][
'psfMat'
].
shape
self
.
psfMat
=
np
.
zeros
([
self
.
nwave
,
npsf
,
ngy
,
ngx
])
self
.
cen_col
=
np
.
zeros
([
self
.
nwave
,
npsf
])
self
.
cen_row
=
np
.
zeros
([
self
.
nwave
,
npsf
])
for
iwave
in
range
(
self
.
nwave
):
for
ipsf
in
range
(
npsf
):
self
.
psfMat
[
iwave
,
ipsf
,
:,
:]
=
self
.
itpPSF_data
[
iwave
][
ipsf
][
'psfMat'
]
self
.
cen_col
[
iwave
,
ipsf
]
=
self
.
itpPSF_data
[
iwave
][
ipsf
][
'imgMaxPosx_ccd'
]
self
.
cen_row
[
iwave
,
ipsf
]
=
self
.
itpPSF_data
[
iwave
][
ipsf
][
'imgMaxPosy_ccd'
]
if
LOG_DEBUG
:
print
(
'ok'
,
flush
=
True
)
def
_getPSFwave
(
self
,
iccd
,
PSF_data_file
):
"""
Get # of sampling waves on iccd
Parameters:
iccd: The chip of i-th ccd
PSF_data_file: The file for PSF data matrix
Returns:
nwave: The number of the sampling waves
"""
strs
=
os
.
listdir
(
PSF_data_file
+
'/ccd{:}'
.
format
(
iccd
))
nwave
=
0
for
_
in
strs
:
if
'wave_'
in
_
:
nwave
+=
1
return
nwave
def
_loadPSF
(
self
,
iccd
,
PSF_data_file
):
"""
load psf-matrix on iccd
Parameters:
iccd: The chip of i-th ccd
PSF_data_file: The file for PSF data matrix
Returns:
psfSet: The matrix of the csst-psf
"""
psfSet
=
[]
for
ii
in
range
(
self
.
nwave
):
iwave
=
ii
+
1
if
LOG_DEBUG
:
print
(
'self._loadPSF: iwave::'
,
iwave
,
flush
=
True
)
psfWave
=
[]
for
jj
in
range
(
npsf
):
ipsf
=
jj
+
1
psfInfo
=
mypy
.
LoadPSF
(
iccd
,
iwave
,
ipsf
,
PSF_data_file
,
CalcPSFsize
=
False
,
InputMaxPixelPos
=
True
)
psfWave
.
append
(
psfInfo
)
psfSet
.
append
(
psfWave
)
if
LOG_DEBUG
:
print
(
'psfSet has been loaded:'
,
flush
=
True
)
print
(
'psfSet[iwave][ipsf][keys]:'
,
psfSet
[
0
][
0
].
keys
(),
flush
=
True
)
return
psfSet
def
_preprocessPSF
(
self
):
"""
Preprocessing psf-matrix
Parameters:
Returns:
itpPSF_data: The matrix of the preprocessed csst-psf
"""
itpPSF_data
=
copy
.
deepcopy
(
self
.
PSF_data
)
for
iwave
in
range
(
self
.
nwave
):
for
ipsf
in
range
(
npsf
):
psfMat
=
self
.
PSF_data
[
iwave
][
ipsf
][
'psfMat'
]
psfMatX
=
mypy
.
psfCentering
(
psfMat
,
CenteringMode
=
1
)
itpPSF_data
[
iwave
][
ipsf
][
'psfMat'
]
=
psfMatX
return
itpPSF_data
def
_findWave
(
self
,
bandpass
):
for
iwave
in
range
(
self
.
nwave
):
bandwave
=
self
.
PSF_data
[
iwave
][
0
][
'wavelength'
]
if
bandpass
.
blue_limit
<
bandwave
and
bandwave
<
bandpass
.
red_limit
:
return
iwave
return
-
1
def
get_PSF
(
self
,
chip
,
pos_img
,
bandpass
,
pixSize
=
0.037
,
galsimGSObject
=
True
):
"""
Get the PSF at a given image position
Parameters:
chip: A 'Chip' object representing the chip we want to extract PSF from.
pos_img: A 'galsim.Position' object representing the image position.
bandpass: A 'galsim.Bandpass' object representing the wavelength range.
pixSize: The pixels size of psf matrix
Returns:
PSF: A 'galsim.GSObject'.
"""
# iccd = 1 #***# #chip.chipID
# iccd = chip.chipID
iccd
=
int
(
chip
.
getChipLabel
(
chipID
=
chip
.
chipID
))
# iwave = 1 #***# #self.findWave(bandpass)
iwave
=
self
.
_findWave
(
bandpass
)
if
iwave
==
-
1
:
print
(
"!!!PSF bandpass does not match."
)
exit
()
PSFMat
=
self
.
psfMat
[
iwave
]
cen_col
=
self
.
cen_col
[
iwave
]
cen_row
=
self
.
cen_row
[
iwave
]
# print('shape:', cen_col.shape)
# px = pos_img[0]
# py = pos_img[1]
px
=
pos_img
.
x
py
=
pos_img
.
y
imPSF
=
mypy
.
psfMaker_IDW
(
px
,
py
,
PSFMat
,
cen_col
,
cen_row
,
IDWindex
=
2
,
OnlyNeighbors
=
True
)
if
galsimGSObject
:
img
=
galsim
.
ImageF
(
imPSF
,
scale
=
pixSize
)
self
.
psf
=
galsim
.
InterpolatedImage
(
img
)
dx
=
px
-
chip
.
cen_pix_x
dy
=
py
-
chip
.
cen_pix_y
return
self
.
PSFspin
(
x
=
dx
,
y
=
dy
)
return
imPSF
def
PSFspin
(
self
,
x
,
y
):
"""
The PSF profile at a given image position relative to the axis center
Parameters:
theta : spin angles in a given exposure in unit of [arcsecond]
dx, dy: relative position to the axis center in unit of [pixels]
Return:
Spinned PSF: g1, g2 and axis ratio 'a/b'
"""
a2Rad
=
np
.
pi
/
(
60.0
*
60.0
*
180.0
)
ff
=
self
.
sigGauss
*
0.107
*
(
1000.0
/
10.0
)
# in unit of [pixels]
rc
=
np
.
sqrt
(
x
*
x
+
y
*
y
)
cpix
=
rc
*
(
self
.
sigSpin
*
a2Rad
)
beta
=
(
np
.
arctan2
(
y
,
x
)
+
np
.
pi
/
2
)
ell
=
cpix
**
2
/
(
2.0
*
ff
**
2
+
cpix
**
2
)
#ell *= 10.0
qr
=
np
.
sqrt
((
1.0
+
ell
)
/
(
1.0
-
ell
))
#psfShape = galsim.Shear(e=ell, beta=beta)
#g1, g2 = psfShape.g1, psfShape.g2
#qr = np.sqrt((1.0+ell)/(1.0-ell))
#return ell, beta, qr
PSFshear
=
galsim
.
Shear
(
e
=
ell
,
beta
=
beta
*
galsim
.
radians
)
return
self
.
psf
.
shear
(
PSFshear
),
PSFshear
if
__name__
==
'__main__'
:
psfPath
=
'/data/simudata/CSSOSDataProductsSims/data/csstPSFdata/CSSOS_psf_ciomp_30X30'
#psfPath = '/data/simudata/CSSOSDataProductsSims/data/csstPSFdata/CSSOS_psf_ciomp'
psfCSST
=
PSFInterp
(
PSF_data_file
=
psfPath
)
iwave
=
1
ipsf
=
665
pos_img
=
[
psfCSST
.
cen_col
[
iwave
,
ipsf
],
psfCSST
.
cen_row
[
iwave
,
ipsf
]]
img
=
psfCSST
.
get_PSF
(
1
,
pos_img
,
iwave
,
galsimGSObject
=
False
)
#plot check-1
import
matplotlib.pyplot
as
plt
fig
=
plt
.
figure
(
figsize
=
(
18
,
5
))
ax
=
plt
.
subplot
(
1
,
3
,
1
)
plt
.
imshow
(
img
)
plt
.
colorbar
()
ax
=
plt
.
subplot
(
1
,
3
,
2
)
imgx
=
psfCSST
.
itpPSF_data
[
iwave
][
ipsf
][
'psfMat'
]
imgx
/=
np
.
sum
(
imgx
)
plt
.
imshow
(
imgx
)
plt
.
colorbar
()
ax
=
plt
.
subplot
(
1
,
3
,
3
)
plt
.
imshow
(
img
-
imgx
)
plt
.
colorbar
()
plt
.
savefig
(
'test/figs/test.jpg'
)
#plot check-2: 注意图像坐标和全局坐标
fig
=
plt
.
figure
(
figsize
=
(
8
,
8
),
dpi
=
200
)
img
=
psfCSST
.
PSF_data
[
iwave
][
ipsf
][
'psfMat'
]
npix
=
img
.
shape
[
0
]
dng
=
105
imgg
=
img
[
dng
:
-
dng
,
dng
:
-
dng
]
plt
.
imshow
(
imgg
)
imgX
=
psfCSST
.
PSF_data
[
iwave
][
ipsf
][
'image_x'
]
#in mm
imgY
=
psfCSST
.
PSF_data
[
iwave
][
ipsf
][
'image_y'
]
#in mm
deltX
=
psfCSST
.
PSF_data
[
iwave
][
ipsf
][
'centroid_x'
]
#in mm
deltY
=
psfCSST
.
PSF_data
[
iwave
][
ipsf
][
'centroid_y'
]
#in mm
maxX
=
psfCSST
.
PSF_data
[
iwave
][
ipsf
][
'max_x'
]
maxY
=
psfCSST
.
PSF_data
[
iwave
][
ipsf
][
'max_y'
]
cenPix_X
=
npix
/
2
+
deltX
/
0.005
cenPix_Y
=
npix
/
2
-
deltY
/
0.005
maxPix_X
=
npix
/
2
+
maxX
/
0.005
-
1
maxPix_Y
=
npix
/
2
-
maxY
/
0.005
-
1
plt
.
plot
([
cenPix_X
-
dng
],[
cenPix_Y
-
dng
],
'rx'
,
ms
=
20
)
plt
.
plot
([
maxPix_X
-
dng
],[
maxPix_Y
-
dng
],
'b+'
,
ms
=
20
)
from
scipy
import
ndimage
y
,
x
=
ndimage
.
center_of_mass
(
img
)
plt
.
plot
([
x
-
dng
],[
y
-
dng
],
'rx'
,
ms
=
10
,
mew
=
2
)
x
,
y
=
mypy
.
findMaxPix
(
img
)
plt
.
plot
([
x
-
dng
],[
y
-
dng
],
'b+'
,
ms
=
10
,
mew
=
2
)
plt
.
savefig
(
'test/figs/test.jpg'
)
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp_v2/PSFConfig.py
deleted
100644 → 0
View file @
e82a5dcc
import
sys
from
itertools
import
islice
import
numpy
as
np
import
matplotlib.pyplot
as
plt
import
scipy.io
#from scipy.io import loadmat
from
scipy
import
ndimage
import
ctypes
import
galsim
from
PSF.PSFInterp.PSFUtil
import
*
###加载PSF信息###
def
LoadPSF
(
iccd
,
iwave
,
ipsf
,
psfPath
,
psfSampleSize
=
5
,
InputMaxPixelPos
=
False
,
PSFCentroidWgt
=
False
):
"""
load psf informations from psf matrix.
Parameters:
iccd (int): ccd number [1,30].
iwave(int): wave-index [1,4].
ipsf (int): psf number [1, 100].
psfPath (int): path to psf matrix
psfSampleSize (float-optional): psf size in microns.
InputMaxPixelPos(bool-optional): only True for 30*30 psf-matrix
Returns:
psfInfo (dirctionary)
"""
if
iccd
not
in
np
.
linspace
(
1
,
30
,
30
,
dtype
=
'int'
):
print
(
'Error - iccd should be in [1, 30].'
)
sys
.
exit
()
if
iwave
not
in
np
.
linspace
(
1
,
4
,
4
,
dtype
=
'int'
):
print
(
'Error - iwave should be in [1, 4].'
)
sys
.
exit
()
if
ipsf
not
in
np
.
linspace
(
1
,
900
,
900
,
dtype
=
'int'
):
print
(
'Error - ipsf should be in [1, 900].'
)
sys
.
exit
()
psfInfo
=
{}
fpath
=
psfPath
+
'/'
+
'ccd{:}'
.
format
(
iccd
)
+
'/'
+
'wave_{:}'
.
format
(
iwave
)
#获取ipsf矩阵
if
not
PSFCentroidWgt
:
##读取PSF原数据
fpathMat
=
fpath
+
'/'
+
'5_psf_array'
+
'/'
+
'psf_{:}.mat'
.
format
(
ipsf
)
data
=
scipy
.
io
.
loadmat
(
fpathMat
)
psfInfo
[
'psfMat'
]
=
data
[
'psf'
]
if
PSFCentroidWgt
:
##读取PSFCentroidWgt
ffpath
=
psfPath
+
'_proc/'
+
'ccd{:}'
.
format
(
iccd
)
+
'/'
+
'wave_{:}'
.
format
(
iwave
)
ffpathMat
=
ffpath
+
'/'
+
'5_psf_array'
+
'/'
+
'psf_{:}_centroidWgt.mat'
.
format
(
ipsf
)
data
=
scipy
.
io
.
loadmat
(
ffpathMat
)
psfInfo
[
'psfMat'
]
=
data
[
'psf'
]
#获取ipsf波长
fpathWave
=
fpath
+
'/'
+
'1_wavelength.txt'
f
=
open
(
fpathWave
,
'r'
)
wavelength
=
np
.
float
(
f
.
readline
())
f
.
close
()
psfInfo
[
'wavelength'
]
=
wavelength
#获取ipsf位置
fpathCoordinate
=
fpath
+
'/'
+
'4_PSF_coordinate.txt'
f
=
open
(
fpathCoordinate
,
'r'
)
header
=
f
.
readline
()
for
line
in
islice
(
f
,
ipsf
-
1
,
ipsf
):
line
=
line
.
strip
()
columns
=
line
.
split
()
f
.
close
()
icol
=
0
psfInfo
[
'field_x'
]
=
float
(
columns
[
icol
])
#deg, 视场采样位置
icol
+=
1
psfInfo
[
'field_y'
]
=
float
(
columns
[
icol
])
#deg
icol
+=
1
psfInfo
[
'centroid_x'
]
=
float
(
columns
[
icol
])
#mm, psf质心相对主光线的偏移量
icol
+=
1
psfInfo
[
'centroid_y'
]
=
float
(
columns
[
icol
])
#mm
icol
+=
1
if
InputMaxPixelPos
==
True
:
psfInfo
[
'max_x'
]
=
float
(
columns
[
icol
])
#mm, max pixel postion
icol
+=
1
psfInfo
[
'max_y'
]
=
float
(
columns
[
icol
])
#mm
icol
+=
1
psfInfo
[
'image_x'
]
=
float
(
columns
[
icol
])
#mm, 主光线位置
icol
+=
1
psfInfo
[
'image_y'
]
=
float
(
columns
[
icol
])
#mm
nrows
,
ncols
=
psfInfo
[
'psfMat'
].
shape
psfPos
=
psfPixelLayout
(
nrows
,
ncols
,
psfInfo
[
'image_y'
],
psfInfo
[
'image_x'
],
pixSizeInMicrons
=
5.0
)
imgMaxPix_x
,
imgMaxPix_y
=
findMaxPix
(
psfInfo
[
'psfMat'
])
psfInfo
[
'imgMaxPosx_ccd'
]
=
psfPos
[
0
,
imgMaxPix_y
,
imgMaxPix_x
]
#cx, psf最大值位置, in mm
psfInfo
[
'imgMaxPosy_ccd'
]
=
psfPos
[
1
,
imgMaxPix_y
,
imgMaxPix_x
]
#cy
if
PSFCentroidWgt
:
#if ipsf == 1:
#print('Check:', psfInfo['centroid_x'], psfInfo['centroid_y'], data['cx'][0][0], data['cy'][0][0])
psfInfo
[
'centroid_x'
]
=
data
[
'cx'
][
0
][
0
]
#mm, psfCentroidWgt质心相对主光线的偏移量
psfInfo
[
'centroid_y'
]
=
data
[
'cy'
][
0
][
0
]
#mm
return
psfInfo
###加载PSF矩阵信息###
def
LoadPSFset
(
iccd
,
iwave
,
npsf
,
psfPath
,
psfSampleSize
=
5
,
InputMaxPixelPos
=
False
,
PSFCentroidWgt
=
False
):
"""
load psfSet for interpolation
Parameters:
iccd, iwave, psfPath: # of ccd/wave and path for psfs
npsf: 100 or 900 for different psf matrixes
Returns:
PSFMat (numpy.array): images
cen_col, cen_row (numpy.array, numpy.array): position of psf center in the view field
"""
psfSet
=
[]
for
ipsf
in
range
(
1
,
npsf
+
1
):
psfInfo
=
LoadPSF
(
iccd
,
iwave
,
ipsf
,
psfPath
,
InputMaxPixelPos
=
InputMaxPixelPos
,
PSFCentroidWgt
=
PSFCentroidWgt
)
psfSet
.
append
(
psfInfo
)
ngy
,
ngx
=
psfSet
[
0
][
'psfMat'
].
shape
PSFMat
=
np
.
zeros
([
npsf
,
ngy
,
ngx
])
cen_col
=
np
.
zeros
(
npsf
)
cen_row
=
np
.
zeros
(
npsf
)
FieldPos
=
False
for
ipsf
in
range
(
npsf
):
iPSFMat
=
psfSet
[
ipsf
][
'psfMat'
]
PSFMat
[
ipsf
,
:,
:]
=
psfTailor
(
iPSFMat
,
apSizeInArcsec
=
2.5
)
if
FieldPos
==
True
:
cen_col
[
ipsf
]
=
psfSet
[
ipsf
][
'field_x'
]
#cx
cen_row
[
ipsf
]
=
psfSet
[
ipsf
][
'field_y'
]
#cy
if
FieldPos
==
False
:
cen_col
[
ipsf
]
=
psfSet
[
ipsf
][
'image_x'
]
+
psfSet
[
ipsf
][
'centroid_x'
]
#cx
cen_row
[
ipsf
]
=
psfSet
[
ipsf
][
'image_y'
]
+
psfSet
[
ipsf
][
'centroid_y'
]
#cy
#cen_col[ipsf] = psfSet[ipsf]['imgMaxPosx_ccd'] #cx --- to be updated
#cen_row[ipsf] = psfSet[ipsf]['imgMaxPosy_ccd'] #cy
#cen_col[ipsf] = psfSet[ipsf]['image_x']
#cen_row[ipsf] = psfSet[ipsf]['image_y']
return
psfSet
,
PSFMat
,
cen_col
,
cen_row
###插值PSF图像-IDW方法###
def
psfMaker_IDW
(
px
,
py
,
PSFMat
,
cen_col
,
cen_row
,
IDWindex
=
2
,
OnlyNeighbors
=
True
,
hoc
=
None
,
hoclist
=
None
,
PSFCentroidWgt
=
False
):
"""
psf interpolation by IDW
Parameters:
px, py (float, float): position of the target
PSFMat (numpy.array): image
cen_col, cen_row (numpy.array, numpy.array): potions of the psf centers
IDWindex (int-optional): the power index of IDW
OnlyNeighbors (bool-optional): only neighbors are used for psf interpolation
Returns:
psfMaker (numpy.array)
"""
minimum_psf_weight
=
1e-8
ref_col
=
px
ref_row
=
py
ngy
,
ngx
=
PSFMat
[
0
,
:,
:].
shape
npsf
=
PSFMat
[:,
:,
:].
shape
[
0
]
psfWeight
=
np
.
zeros
([
npsf
])
if
OnlyNeighbors
==
True
:
if
hoc
is
None
:
neigh
=
findNeighbors
(
px
,
py
,
cen_col
,
cen_row
,
dr
=
5.
,
dn
=
4
,
OnlyDistance
=
False
)
if
hoc
is
not
None
:
#hoc,hoclist = findNeighbors_hoclist(cen_col, cen_row)
neigh
=
findNeighbors_hoclist
(
cen_col
,
cen_row
,
tx
=
px
,
ty
=
py
,
dn
=
4
,
hoc
=
hoc
,
hoclist
=
hoclist
)
#print("neigh:", neigh)
neighFlag
=
np
.
zeros
(
npsf
)
neighFlag
[
neigh
]
=
1
for
ipsf
in
range
(
npsf
):
if
OnlyNeighbors
==
True
:
if
neighFlag
[
ipsf
]
!=
1
:
continue
dist
=
np
.
sqrt
((
ref_col
-
cen_col
[
ipsf
])
**
2
+
(
ref_row
-
cen_row
[
ipsf
])
**
2
)
if
IDWindex
==
1
:
psfWeight
[
ipsf
]
=
dist
if
IDWindex
==
2
:
psfWeight
[
ipsf
]
=
dist
**
2
if
IDWindex
==
3
:
psfWeight
[
ipsf
]
=
dist
**
3
if
IDWindex
==
4
:
psfWeight
[
ipsf
]
=
dist
**
4
psfWeight
[
ipsf
]
=
max
(
psfWeight
[
ipsf
],
minimum_psf_weight
)
psfWeight
[
ipsf
]
=
1.
/
psfWeight
[
ipsf
]
psfWeight
/=
np
.
sum
(
psfWeight
)
psfMaker
=
np
.
zeros
((
ngy
,
ngx
),
dtype
=
'float64'
)
for
ipsf
in
range
(
npsf
):
if
OnlyNeighbors
==
True
:
if
neighFlag
[
ipsf
]
!=
1
:
continue
iPSFMat
=
PSFMat
[
ipsf
,
:,
:].
copy
()
#if not PSFCentroidWgt:
# iPSFMat = psfCentering(iPSFMat, CenteringMode=2)
#iPSFMat = psfCentering_FFT(iPSFMat)
#if PSFCentroidWgt:
ipsfWeight
=
psfWeight
[
ipsf
]
psfMaker
+=
iPSFMat
*
ipsfWeight
#print("ipsf, ipsfWeight:", ipsf, ipsfWeight)
psfMaker
/=
np
.
nansum
(
psfMaker
)
return
psfMaker
###TEST###
if
__name__
==
'__main__'
:
iccd
=
1
iwave
=
1
ipsf
=
1
npsf
=
100
psfPath
=
'/data/simudata/CSSOSDataProductsSims/data/csstPSFdata/CSSOS_psf_ciomp'
a
,
b
,
c
,
d
=
LoadPSFset
(
iccd
,
iwave
,
npsf
,
psfPath
,
InputMaxPixelPos
=
False
)
psfSet
=
a
print
(
'psfSet has been loaded.'
)
print
(
'Usage: psfSet[i][keys]'
)
print
(
'psfSet.keys:'
,
psfSet
[
0
].
keys
())
print
(
c
[
0
:
10
])
print
(
d
[
0
:
10
])
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp_v2/PSFInterp.py
deleted
100644 → 0
View file @
e82a5dcc
'''
PSF interpolation for CSST-Sim
NOTE: [iccd, iwave, ipsf] are counted from 1 to n, but [tccd, twave, tpsf] are counted from 0 to n-1
'''
import
galsim
import
numpy
as
np
import
os
import
time
import
copy
import
PSF.PSFInterp.PSFConfig
as
myConfig
import
PSF.PSFInterp.PSFUtil
as
myUtil
from
PSF.PSFModel
import
PSFModel
LOG_DEBUG
=
False
#***#
NPSF
=
900
#***# 30*30
iccdTest
=
1
#***#
class
PSFInterp
(
PSFModel
):
# def __init__(self, PSF_data=None, params=None, PSF_data_file=None):
def
__init__
(
self
,
chip
,
PSF_data
=
None
,
PSF_data_file
=
None
,
sigSpin
=
0.
,
psfRa
=
0.15
):
"""
The PSF data matrix is either given by a object parameter or read in from a file.
Parameters:
PSF_data: The PSF data matrix object
params: Other parameters?
PSF_data_file: The file for PSF data matrix (optional).
"""
if
LOG_DEBUG
:
print
(
'==================================================='
)
print
(
'DEBUG: psf module for csstSim '
\
+
time
.
strftime
(
"(%Y-%m-%d %H:%M:%S)"
,
time
.
localtime
()),
flush
=
True
)
print
(
'==================================================='
)
self
.
sigSpin
=
sigSpin
self
.
sigGauss
=
psfRa
# 80% light radius
self
.
iccd
=
int
(
chip
.
getChipLabel
(
chipID
=
chip
.
chipID
))
if
PSF_data_file
==
None
:
PSF_data_file
=
'/data/simudata/CSSOSDataProductsSims/data/csstPSFdata/CSSOS_psf_ciomp_30X30'
self
.
nwave
=
self
.
_getPSFwave
(
self
.
iccd
,
PSF_data_file
)
self
.
PSF_data
=
self
.
_loadPSF
(
self
.
iccd
,
PSF_data_file
)
if
LOG_DEBUG
:
print
(
'nwave-{:} on ccd-{:}::'
.
format
(
self
.
nwave
,
self
.
iccd
),
flush
=
True
)
print
(
'self.PSF_data ... ok'
,
flush
=
True
)
print
(
'Preparing self.[psfMat,cen_col,cen_row] for psfMaker ... '
,
end
=
''
,
flush
=
True
)
ngy
,
ngx
=
self
.
PSF_data
[
0
][
0
][
'psfMat'
].
shape
self
.
psfMat
=
np
.
zeros
([
self
.
nwave
,
NPSF
,
ngy
,
ngx
])
self
.
cen_col
=
np
.
zeros
([
self
.
nwave
,
NPSF
])
self
.
cen_row
=
np
.
zeros
([
self
.
nwave
,
NPSF
])
self
.
hoc
=
[]
self
.
hoclist
=
[]
for
twave
in
range
(
self
.
nwave
):
for
tpsf
in
range
(
NPSF
):
#psfMatX = myUtil.psfTailor(self.PSF_data[twave][tpsf]['psfMat'], apSizeInArcsec=2.5)
self
.
psfMat
[
twave
,
tpsf
,
:,
:]
=
self
.
PSF_data
[
twave
][
tpsf
][
'psfMat'
]
self
.
cen_col
[
twave
,
tpsf
]
=
self
.
PSF_data
[
twave
][
tpsf
][
'image_x'
]
+
self
.
PSF_data
[
twave
][
tpsf
][
'centroid_x'
]
self
.
cen_row
[
twave
,
tpsf
]
=
self
.
PSF_data
[
twave
][
tpsf
][
'image_y'
]
+
self
.
PSF_data
[
twave
][
tpsf
][
'centroid_y'
]
#hoclist on twave for neighborsFinding
hoc
,
hoclist
=
myUtil
.
findNeighbors_hoclist
(
self
.
cen_col
[
twave
],
self
.
cen_row
[
twave
])
self
.
hoc
.
append
(
hoc
)
self
.
hoclist
.
append
(
hoclist
)
if
LOG_DEBUG
:
print
(
'ok'
,
flush
=
True
)
def
_getPSFwave
(
self
,
iccd
,
PSF_data_file
):
"""
Get # of sampling waves on iccd
Parameters:
iccd: The chip of i-th ccd
PSF_data_file: The file for PSF data matrix
Returns:
nwave: The number of the sampling waves
"""
strs
=
os
.
listdir
(
PSF_data_file
+
'/ccd{:}'
.
format
(
iccd
))
nwave
=
0
for
_
in
strs
:
if
'wave_'
in
_
:
nwave
+=
1
return
nwave
def
_loadPSF
(
self
,
iccd
,
PSF_data_file
):
"""
load psf-matrix on iccd
Parameters:
iccd: The chip of i-th ccd
PSF_data_file: The file for PSF data matrix
Returns:
psfSet: The matrix of the csst-psf
"""
psfSet
=
[]
for
ii
in
range
(
self
.
nwave
):
iwave
=
ii
+
1
if
LOG_DEBUG
:
print
(
'self._loadPSF: iwave::'
,
iwave
,
flush
=
True
)
psfWave
=
[]
for
jj
in
range
(
NPSF
):
ipsf
=
jj
+
1
psfInfo
=
myConfig
.
LoadPSF
(
iccd
,
iwave
,
ipsf
,
PSF_data_file
,
InputMaxPixelPos
=
True
,
PSFCentroidWgt
=
True
)
psfWave
.
append
(
psfInfo
)
psfSet
.
append
(
psfWave
)
if
LOG_DEBUG
:
print
(
'psfSet has been loaded:'
,
flush
=
True
)
print
(
'psfSet[iwave][ipsf][keys]:'
,
psfSet
[
0
][
0
].
keys
(),
flush
=
True
)
return
psfSet
def
_preprocessPSF
(
self
):
"""
Preprocessing psf-matrix
Parameters:
Returns:
itpPSF_data: The matrix of the preprocessed csst-psf
"""
'''
#old version (discarded)
itpPSF_data = copy.deepcopy(self.PSF_data)
for twave in range(self.nwave):
for tpsf in range(NPSF):
psfMat = self.PSF_data[twave][tpsf]['psfMat']
psf_image_x = self.PSF_data[twave][tpsf]['image_x']
psf_image_y = self.PSF_data[twave][tpsf]['image_y']
#psfMatX= myUtil.psfCentering(psfMat, CenteringMode=1)
#itpPSF_data[twave][tpsf]['psfMat'] = psfMatX
#img, cxt, cyt = myUtil.psfCentering_wgt(psfMat, psf_image_x, psf_image_y)
#itpPSF_data[twave][tpsf]['psfMat'] = img
#itpPSF_data[twave][tpsf]['centroid_x'] = cxt
#itpPSF_data[twave][tpsf]['centroid_y'] = cyt
return itpPSF_data
'''
pass
def
_findWave
(
self
,
bandpass
):
for
twave
in
range
(
self
.
nwave
):
bandwave
=
self
.
PSF_data
[
twave
][
0
][
'wavelength'
]
if
bandpass
.
blue_limit
<
bandwave
and
bandwave
<
bandpass
.
red_limit
:
return
twave
return
-
1
def
get_PSF
(
self
,
chip
,
pos_img
,
bandpass
,
pixSize
=
0.037
,
galsimGSObject
=
True
,
folding_threshold
=
5.e-3
):
"""
Get the PSF at a given image position
Parameters:
chip: A 'Chip' object representing the chip we want to extract PSF from.
pos_img: A 'galsim.Position' object representing the image position.
bandpass: A 'galsim.Bandpass' object representing the wavelength range.
pixSize: The pixels size of psf matrix
Returns:
PSF: A 'galsim.GSObject'.
"""
assert
self
.
iccd
==
int
(
chip
.
getChipLabel
(
chipID
=
chip
.
chipID
)),
'ERROR: self.iccd != chip.label'
# twave = bandpass-1 #***# ??? #self.findWave(bandpass) ###twave=iwave-1 as that in NOTE
twave
=
self
.
_findWave
(
bandpass
)
if
twave
==
-
1
:
print
(
"!!!PSF bandpass does not match."
)
exit
()
PSFMat
=
self
.
psfMat
[
twave
]
cen_col
=
self
.
cen_col
[
twave
]
cen_row
=
self
.
cen_row
[
twave
]
# px = pos_img[0]
# py = pos_img[1]
px
=
(
pos_img
.
x
-
chip
.
cen_pix_x
)
*
0.01
py
=
(
pos_img
.
y
-
chip
.
cen_pix_y
)
*
0.01
imPSF
=
myConfig
.
psfMaker_IDW
(
px
,
py
,
PSFMat
,
cen_col
,
cen_row
,
IDWindex
=
2
,
OnlyNeighbors
=
True
,
hoc
=
self
.
hoc
[
twave
],
hoclist
=
self
.
hoclist
[
twave
],
PSFCentroidWgt
=
True
)
#imPSF = myConfig.psfMaker_IDW(px, py, PSFMat, cen_col, cen_row, IDWindex=2, OnlyNeighbors=True, PSFCentroidWgt=True)
if
galsimGSObject
:
img
=
galsim
.
ImageF
(
imPSF
,
scale
=
pixSize
)
gsp
=
galsim
.
GSParams
(
folding_threshold
=
folding_threshold
)
self
.
psf
=
galsim
.
InterpolatedImage
(
img
,
gsparams
=
gsp
)
# dx = px - chip.cen_pix_x
# dy = py - chip.cen_pix_y
return
self
.
PSFspin
(
x
=
px
/
0.01
,
y
=
py
/
0.01
)
return
imPSF
def
PSFspin
(
self
,
x
,
y
):
"""
The PSF profile at a given image position relative to the axis center
Parameters:
theta : spin angles in a given exposure in unit of [arcsecond]
dx, dy: relative position to the axis center in unit of [pixels]
Return:
Spinned PSF: g1, g2 and axis ratio 'a/b'
"""
a2Rad
=
np
.
pi
/
(
60.0
*
60.0
*
180.0
)
ff
=
self
.
sigGauss
*
0.107
*
(
1000.0
/
10.0
)
# in unit of [pixels]
rc
=
np
.
sqrt
(
x
*
x
+
y
*
y
)
cpix
=
rc
*
(
self
.
sigSpin
*
a2Rad
)
beta
=
(
np
.
arctan2
(
y
,
x
)
+
np
.
pi
/
2
)
ell
=
cpix
**
2
/
(
2.0
*
ff
**
2
+
cpix
**
2
)
qr
=
np
.
sqrt
((
1.0
+
ell
)
/
(
1.0
-
ell
))
PSFshear
=
galsim
.
Shear
(
e
=
ell
,
beta
=
beta
*
galsim
.
radians
)
return
self
.
psf
.
shear
(
PSFshear
),
PSFshear
def
testPSFInterp
():
import
time
import
matplotlib.pyplot
as
plt
iccd
=
iccdTest
#[1, 30] for test
iwave
=
1
#[1, 4] for test
npsfB
=
900
psfPathB
=
'/data/simudata/CSSOSDataProductsSims/data/csstPSFdata/CSSOS_psf_ciomp_30X30'
psfCSST
=
PSFInterp
(
PSF_data_file
=
psfPathB
)
### define PSF_data from 30*30
npsfA
=
100
psfPathA
=
'/data/simudata/CSSOSDataProductsSims/data/csstPSFdata/CSSOS_psf_ciomp'
psfSetA
,
PSFMatA
,
cen_colA
,
cen_rowA
=
myConfig
.
LoadPSFset
(
iccd
,
iwave
,
npsfA
,
psfPathA
,
InputMaxPixelPos
=
False
,
PSFCentroidWgt
=
True
)
###load test_data from 10*10
psf_sz
=
np
.
zeros
(
npsfA
)
psf_e1
=
np
.
zeros
(
npsfA
)
psf_e2
=
np
.
zeros
(
npsfA
)
psfMaker_sz
=
np
.
zeros
(
npsfA
)
psfMaker_e1
=
np
.
zeros
(
npsfA
)
psfMaker_e2
=
np
.
zeros
(
npsfA
)
runtimeInterp
=
0
starttime
=
time
.
time
()
for
ipsf
in
range
(
npsfA
):
print
(
'IDW-ipsf: {:4}/100'
.
format
(
ipsf
),
end
=
'
\r
'
,
flush
=
True
)
starttimeInterp
=
time
.
time
()
px
=
cen_colA
[
ipsf
]
py
=
cen_rowA
[
ipsf
]
pos_img
=
[
px
,
py
]
img
=
psfCSST
.
get_PSF
(
iccd
,
pos_img
,
iwave
,
galsimGSObject
=
False
)
###interpolate PSF at[px,py]
endtimeInterp
=
time
.
time
()
runtimeInterp
=
runtimeInterp
+
(
endtimeInterp
-
starttimeInterp
)
imx
=
psfSetA
[
ipsf
][
'psfMat'
]
imy
=
img
cenX
,
cenY
,
sz
,
e1
,
e2
,
REE80
=
myUtil
.
psfSizeCalculator
(
imx
,
CalcPSFcenter
=
True
,
SigRange
=
True
,
TailorScheme
=
2
)
psf_sz
[
ipsf
]
=
sz
psf_e1
[
ipsf
]
=
e1
psf_e2
[
ipsf
]
=
e2
cenX
,
cenY
,
sz
,
e1
,
e2
,
REE80
=
myUtil
.
psfSizeCalculator
(
imy
,
CalcPSFcenter
=
True
,
SigRange
=
True
,
TailorScheme
=
2
)
psfMaker_sz
[
ipsf
]
=
sz
psfMaker_e1
[
ipsf
]
=
e1
psfMaker_e2
[
ipsf
]
=
e2
endtime
=
time
.
time
()
print
(
'run time::'
,
endtime
-
starttime
,
runtimeInterp
)
if
True
:
ell_iccd
=
np
.
zeros
(
npsfA
)
ell_iccd_psfMaker
=
np
.
zeros
(
npsfA
)
fig
=
plt
.
figure
(
figsize
=
(
18
,
5
))
plt
.
subplots_adjust
(
wspace
=
0.1
,
hspace
=
0.1
)
ax
=
plt
.
subplot
(
1
,
3
,
1
)
for
ipsf
in
range
(
npsfA
):
imx
=
cen_colA
[
ipsf
]
imy
=
cen_rowA
[
ipsf
]
plt
.
plot
(
imx
,
imy
,
'b.'
)
ang
=
np
.
arctan2
(
psf_e2
[
ipsf
],
psf_e1
[
ipsf
])
/
2
ell
=
np
.
sqrt
(
psf_e1
[
ipsf
]
**
2
+
psf_e2
[
ipsf
]
**
2
)
ell_iccd
[
ipsf
]
=
ell
ell
*=
50
lcos
=
ell
*
np
.
cos
(
ang
)
lsin
=
ell
*
np
.
sin
(
ang
)
plt
.
plot
([
imx
-
lcos
,
imx
+
lcos
],[
imy
-
lsin
,
imy
+
lsin
],
'b'
,
lw
=
2
)
###########
ang
=
np
.
arctan2
(
psfMaker_e2
[
ipsf
],
psfMaker_e1
[
ipsf
])
/
2
ell
=
np
.
sqrt
(
psfMaker_e1
[
ipsf
]
**
2
+
psfMaker_e2
[
ipsf
]
**
2
)
ell_iccd_psfMaker
[
ipsf
]
=
ell
ell
*=
50
lcos
=
ell
*
np
.
cos
(
ang
)
lsin
=
ell
*
np
.
sin
(
ang
)
plt
.
plot
([
imx
-
lcos
,
imx
+
lcos
],[
imy
-
lsin
,
imy
+
lsin
],
'r'
,
lw
=
1
)
###########
plt
.
gca
().
set_aspect
(
1
)
ax
=
plt
.
subplot
(
1
,
3
,
2
)
tmp
=
plt
.
hist
(
ell_iccd
,
bins
=
8
,
color
=
'b'
,
alpha
=
0.5
)
tmp
=
plt
.
hist
(
ell_iccd_psfMaker
,
bins
=
8
,
color
=
'r'
,
alpha
=
0.5
)
plt
.
annotate
(
'iccd-{:} iwave-{:}'
.
format
(
iccd
,
iwave
),
(
0.55
,
0.85
),
xycoords
=
'axes fraction'
,
fontsize
=
15
)
plt
.
xlabel
(
'ell'
)
plt
.
ylabel
(
'PDF'
)
ax
=
plt
.
subplot
(
1
,
3
,
3
)
dsz
=
(
psfMaker_sz
-
psf_sz
)
/
psf_sz
dsz_hist
=
plt
.
hist
(
dsz
)
plt
.
xlabel
(
'dsz'
)
plt
.
savefig
(
'test/figs/testPSFInterp_30t10_iccd{:}_iwave{:}.pdf'
.
format
(
iccd
,
iwave
))
if
__name__
==
'__main__'
:
if
False
:
psfPath
=
'/data/simudata/CSSOSDataProductsSims/data/csstPSFdata/CSSOS_psf_ciomp_30X30'
#psfPath = '/data/simudata/CSSOSDataProductsSims/data/csstPSFdata/CSSOS_psf_ciomp'
psfCSST
=
PSFInterp
(
PSF_data_file
=
psfPath
)
iwave
=
1
ipsf
=
665
pos_img
=
[
psfCSST
.
cen_col
[
iwave
,
ipsf
],
psfCSST
.
cen_row
[
iwave
,
ipsf
]]
img
=
psfCSST
.
get_PSF
(
1
,
pos_img
,
iwave
,
galsimGSObject
=
False
)
print
(
'haha'
)
if
True
:
testPSFInterp
()
if
False
:
#old version (discarded)
#plot check-1
import
matplotlib.pyplot
as
plt
fig
=
plt
.
figure
(
figsize
=
(
18
,
5
))
ax
=
plt
.
subplot
(
1
,
3
,
1
)
plt
.
imshow
(
img
)
plt
.
colorbar
()
ax
=
plt
.
subplot
(
1
,
3
,
2
)
imgx
=
psfCSST
.
itpPSF_data
[
iwave
][
ipsf
][
'psfMat'
]
imgx
/=
np
.
sum
(
imgx
)
plt
.
imshow
(
imgx
)
plt
.
colorbar
()
ax
=
plt
.
subplot
(
1
,
3
,
3
)
plt
.
imshow
(
img
-
imgx
)
plt
.
colorbar
()
plt
.
savefig
(
'test/figs/test1.jpg'
)
if
False
:
#old version (discarded)
#plot check-2: 注意图像坐标和全局坐标
fig
=
plt
.
figure
(
figsize
=
(
8
,
8
),
dpi
=
200
)
img
=
psfCSST
.
PSF_data
[
iwave
][
ipsf
][
'psfMat'
]
npix
=
img
.
shape
[
0
]
dng
=
105
imgg
=
img
[
dng
:
-
dng
,
dng
:
-
dng
]
plt
.
imshow
(
imgg
)
imgX
=
psfCSST
.
PSF_data
[
iwave
][
ipsf
][
'image_x'
]
#in mm
imgY
=
psfCSST
.
PSF_data
[
iwave
][
ipsf
][
'image_y'
]
#in mm
deltX
=
psfCSST
.
PSF_data
[
iwave
][
ipsf
][
'centroid_x'
]
#in mm
deltY
=
psfCSST
.
PSF_data
[
iwave
][
ipsf
][
'centroid_y'
]
#in mm
maxX
=
psfCSST
.
PSF_data
[
iwave
][
ipsf
][
'max_x'
]
maxY
=
psfCSST
.
PSF_data
[
iwave
][
ipsf
][
'max_y'
]
cenPix_X
=
npix
/
2
+
deltX
/
0.005
cenPix_Y
=
npix
/
2
-
deltY
/
0.005
maxPix_X
=
npix
/
2
+
maxX
/
0.005
-
1
maxPix_Y
=
npix
/
2
-
maxY
/
0.005
-
1
plt
.
plot
([
cenPix_X
-
dng
],[
cenPix_Y
-
dng
],
'rx'
,
ms
=
20
)
plt
.
plot
([
maxPix_X
-
dng
],[
maxPix_Y
-
dng
],
'b+'
,
ms
=
20
)
from
scipy
import
ndimage
y
,
x
=
ndimage
.
center_of_mass
(
img
)
plt
.
plot
([
x
-
dng
],[
y
-
dng
],
'rx'
,
ms
=
10
,
mew
=
4
)
x
,
y
=
myUtil
.
findMaxPix
(
img
)
plt
.
plot
([
x
-
dng
],[
y
-
dng
],
'b+'
,
ms
=
10
,
mew
=
4
)
plt
.
savefig
(
'test/figs/test2.jpg'
)
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp_v2/PSFProcess.py
deleted
100644 → 0
View file @
e82a5dcc
import
os
,
sys
import
numpy
as
np
import
scipy.io
import
mpi4py.MPI
as
MPI
sys
.
path
.
append
(
"/public/home/weichengliang/lnData/CSST_new_framwork/csstPSF"
)
import
PSFConfig
as
myConfig
import
PSFUtil
as
myUtil
def
mkdir
(
path
):
isExists
=
os
.
path
.
exists
(
path
)
if
not
isExists
:
os
.
mkdir
(
path
)
############################################
comm
=
MPI
.
COMM_WORLD
ThisTask
=
comm
.
Get_rank
()
NTasks
=
comm
.
Get_size
()
npsf
=
900
psfPath
=
'/data/simudata/CSSOSDataProductsSims/data/csstPSFdata/CSSOS_psf_ciomp_30X30'
#npsf = 100
#psfPath = '/data/simudata/CSSOSDataProductsSims/data/csstPSFdata/CSSOS_psf_ciomp'
npsfPerTasks
=
int
(
npsf
/
NTasks
)
iStart
=
0
+
npsfPerTasks
*
ThisTask
iEnd
=
npsfPerTasks
+
npsfPerTasks
*
ThisTask
if
ThisTask
==
NTasks
:
iEnd
=
npsf
for
iccd
in
range
(
1
,
31
):
iccdPath
=
psfPath
+
'_proc/ccd{:}'
.
format
(
iccd
)
if
ThisTask
==
0
:
mkdir
(
iccdPath
)
comm
.
barrier
()
for
iwave
in
range
(
1
,
5
):
iwavePath
=
iccdPath
+
'/wave_{:}'
.
format
(
iwave
)
if
ThisTask
==
0
:
mkdir
(
iwavePath
)
comm
.
barrier
()
psfMatPath
=
iwavePath
+
'/5_psf_array'
if
ThisTask
==
0
:
mkdir
(
psfMatPath
)
comm
.
barrier
()
for
ii
in
range
(
iStart
,
iEnd
):
ipsf
=
ii
+
1
if
ThisTask
==
0
:
print
(
'iccd-iwave-ipsf: {:4}{:4}{:4}'
.
format
(
iccd
,
iwave
,
ipsf
),
end
=
'
\r
'
,
flush
=
True
)
#if iccd != 1 or iwave !=1 or ipsf != 1:
# continue
ipsfOutput
=
psfMatPath
+
'/psf_{:}_centroidWgt.mat'
.
format
(
ipsf
)
#ipsfOutput = './psf_{:}_centroidWgt.mat'.format(ipsf)
psfInfo
=
myConfig
.
LoadPSF
(
iccd
,
iwave
,
ipsf
,
psfPath
,
InputMaxPixelPos
=
True
)
ipsfMat
=
psfInfo
[
'psfMat'
]
npix_y
,
npix_x
=
ipsfMat
.
shape
if
npsf
==
100
:
ncut
=
160
if
npsf
==
900
:
ncut
=
200
img
,
cx
,
cy
=
myUtil
.
centroidWgt
(
ipsfMat
,
nt
=
ncut
)
dcx
=
cx
-
npix_x
/
2
#pixel coords -> global coords
dcy
=-
(
cy
-
npix_y
/
2
)
#pixel coords -> global coords
dcx
*=
5e-3
#pixels -> mm
dcy
*=
5e-3
#pixels -> mm
nn
=
256
dn
=
int
((
nn
-
ncut
)
/
2
)
imgt
=
np
.
zeros
([
nn
,
nn
],
dtype
=
np
.
float32
)
imgt
[
dn
:
-
dn
,
dn
:
-
dn
]
=
img
scipy
.
io
.
savemat
(
ipsfOutput
,
{
'cx'
:
dcx
,
'cy'
:
dcy
,
'psf'
:
imgt
})
if
iccd
!=
1
or
iwave
!=
1
or
ipsf
!=
1
:
if
ThisTask
==
0
:
print
(
'CHECK::'
,
dcx
,
dcy
,
psfInfo
[
'centroid_x'
],
psfInfo
[
'centroid_y'
])
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp_v2/PSFUtil.py
deleted
100644 → 0
View file @
e82a5dcc
import
sys
from
itertools
import
islice
import
numpy
as
np
#import matplotlib.pyplot as plt
import
scipy.io
#from scipy.io import loadmat
#import xlrd
from
scipy
import
ndimage
#from scipy.interpolate import RectBivariateSpline
import
scipy.spatial
as
spatial
#from astropy.modeling.models import Ellipse2D
#from astropy.coordinates import Angle
#import matplotlib.patches as mpatches
import
ctypes
#import galsim
###定义PSF像素的全局坐标###
def
psfPixelLayout
(
nrows
,
ncols
,
cenPosRow
,
cenPosCol
,
pixSizeInMicrons
=
5.0
):
"""
convert psf pixels to physical position
Parameters:
nrows, ncols (int, int): psf sampling with [nrows, ncols].
cenPosRow, cenPosCol (float, float): A physical position of the chief ray for a given psf.
pixSizeInMicrons (float-optional): The pixel size in microns from the psf sampling.
Returns:
psfPixelPos (numpy.array-float): [posx, posy] in mm for [irow, icol]
Notes:
1. show positions on ccd, but not position on image only [+/- dy]
"""
psfPixelPos
=
np
.
zeros
([
2
,
nrows
,
ncols
])
if
nrows
%
2
!=
0
:
sys
.
exit
()
if
ncols
%
2
!=
0
:
sys
.
exit
()
cenPix_row
=
nrows
/
2
+
1
#中心主光线对应pixle [由长光定义]
cenPix_col
=
ncols
/
2
+
1
for
irow
in
range
(
nrows
):
for
icol
in
range
(
ncols
):
delta_row
=
((
irow
+
1
)
-
cenPix_row
)
*
pixSizeInMicrons
*
1e-3
delta_col
=
((
icol
+
1
)
-
cenPix_col
)
*
pixSizeInMicrons
*
1e-3
psfPixelPos
[
0
,
irow
,
icol
]
=
cenPosCol
+
delta_col
psfPixelPos
[
1
,
irow
,
icol
]
=
cenPosRow
-
delta_row
#note-1:in CCD全局坐标
return
psfPixelPos
###查找最大pixel位置###
def
findMaxPix
(
img
):
"""
get the pixel position of the maximum-value
Parameters:
img (numpy.array-float): image
Returns:
imgMaxPix_x, imgMaxPix_y (int, int): pixel position in columns & rows
"""
maxIndx
=
np
.
argmax
(
img
)
maxIndx
=
np
.
unravel_index
(
maxIndx
,
np
.
array
(
img
).
shape
)
imgMaxPix_x
=
maxIndx
[
1
]
imgMaxPix_y
=
maxIndx
[
0
]
return
imgMaxPix_x
,
imgMaxPix_y
###查找neighbors位置###
def
findNeighbors
(
tx
,
ty
,
px
,
py
,
dr
=
0.1
,
dn
=
1
,
OnlyDistance
=
True
):
"""
find nearest neighbors by 2D-KDTree
Parameters:
tx, ty (float, float): a given position
px, py (numpy.array, numpy.array): position data for tree
dr (float-optional): distance
dn (int-optional): nearest-N
OnlyDistance (bool-optional): only use distance to find neighbors. Default: True
Returns:
dataq (numpy.array): index
"""
datax
=
px
datay
=
py
tree
=
spatial
.
KDTree
(
list
(
zip
(
datax
.
ravel
(),
datay
.
ravel
())))
dataq
=
[]
rr
=
dr
if
OnlyDistance
==
True
:
dataq
=
tree
.
query_ball_point
([
tx
,
ty
],
rr
)
if
OnlyDistance
==
False
:
while
len
(
dataq
)
<
dn
:
dataq
=
tree
.
query_ball_point
([
tx
,
ty
],
rr
)
rr
+=
dr
dd
=
np
.
hypot
(
datax
[
dataq
]
-
tx
,
datay
[
dataq
]
-
ty
)
ddSortindx
=
np
.
argsort
(
dd
)
dataq
=
np
.
array
(
dataq
)[
ddSortindx
[
0
:
dn
]]
return
dataq
###查找neighbors位置-hoclist###
def
hocBuild
(
partx
,
party
,
nhocx
,
nhocy
,
dhocx
,
dhocy
):
if
np
.
max
(
partx
)
>
nhocx
*
dhocx
:
print
(
'ERROR'
)
sys
.
exit
()
if
np
.
max
(
party
)
>
nhocy
*
dhocy
:
print
(
'ERROR'
)
sys
.
exit
()
npart
=
partx
.
size
hoclist
=
np
.
zeros
(
npart
,
dtype
=
np
.
int32
)
-
1
hoc
=
np
.
zeros
([
nhocy
,
nhocx
],
dtype
=
np
.
int32
)
-
1
for
ipart
in
range
(
npart
):
ix
=
int
(
partx
[
ipart
]
/
dhocx
)
iy
=
int
(
party
[
ipart
]
/
dhocy
)
hoclist
[
ipart
]
=
hoc
[
iy
,
ix
]
hoc
[
iy
,
ix
]
=
ipart
return
hoc
,
hoclist
def
hocFind
(
px
,
py
,
dhocx
,
dhocy
,
hoc
,
hoclist
):
ix
=
int
(
px
/
dhocx
)
iy
=
int
(
py
/
dhocy
)
neigh
=
[]
it
=
hoc
[
iy
,
ix
]
while
it
!=
-
1
:
neigh
.
append
(
it
)
it
=
hoclist
[
it
]
return
neigh
def
findNeighbors_hoclist
(
px
,
py
,
tx
=
None
,
ty
=
None
,
dn
=
4
,
hoc
=
None
,
hoclist
=
None
):
nhocy
=
nhocx
=
20
pxMin
=
np
.
min
(
px
)
pxMax
=
np
.
max
(
px
)
pyMin
=
np
.
min
(
py
)
pyMax
=
np
.
max
(
py
)
dhocx
=
(
pxMax
-
pxMin
)
/
(
nhocx
-
1
)
dhocy
=
(
pyMax
-
pyMin
)
/
(
nhocy
-
1
)
partx
=
px
-
pxMin
+
dhocx
/
2
party
=
py
-
pyMin
+
dhocy
/
2
if
hoc
is
None
:
hoc
,
hoclist
=
hocBuild
(
partx
,
party
,
nhocx
,
nhocy
,
dhocx
,
dhocy
)
return
hoc
,
hoclist
if
hoc
is
not
None
:
tx
=
tx
-
pxMin
+
dhocx
/
2
ty
=
ty
-
pyMin
+
dhocy
/
2
itx
=
int
(
tx
/
dhocx
)
ity
=
int
(
ty
/
dhocy
)
ps
=
[
-
1
,
0
,
1
]
neigh
=
[]
for
ii
in
range
(
3
):
for
jj
in
range
(
3
):
ix
=
itx
+
ps
[
ii
]
iy
=
ity
+
ps
[
jj
]
if
ix
<
0
:
continue
if
iy
<
0
:
continue
if
ix
>
nhocx
-
1
:
continue
if
iy
>
nhocy
-
1
:
continue
#neightt = myUtil.hocFind(ppx, ppy, dhocx, dhocy, hoc, hoclist)
it
=
hoc
[
iy
,
ix
]
while
it
!=
-
1
:
neigh
.
append
(
it
)
it
=
hoclist
[
it
]
#neigh.append(neightt)
#ll = [i for k in neigh for i in k]
if
dn
!=
-
1
:
ptx
=
np
.
array
(
partx
[
neigh
])
pty
=
np
.
array
(
party
[
neigh
])
dd
=
np
.
hypot
(
ptx
-
tx
,
pty
-
ty
)
idx
=
np
.
argsort
(
dd
)
neigh
=
np
.
array
(
neigh
)[
idx
[
0
:
dn
]]
return
neigh
###PSF中心对齐###
def
psfCentering
(
img
,
apSizeInArcsec
=
0.5
,
psfSampleSizeInMicrons
=
5
,
focalLengthInMeters
=
28
,
CenteringMode
=
1
):
"""
centering psf within an aperture
Parameters:
img (numpy.array): image
apSizeInArcsec (float-optional): aperture size in arcseconds.
psfSampleSizeInMicrons (float-optional): psf pixel size in microns.
focalLengthInMeters (float-optional): csst focal length im meters.
CenteringMode (int-optional): how to center psf images
Returns:
imgT (numpy.array)
"""
if
CenteringMode
==
1
:
imgMaxPix_x
,
imgMaxPix_y
=
findMaxPix
(
img
)
if
CenteringMode
==
2
:
y
,
x
=
ndimage
.
center_of_mass
(
img
)
#y-rows, x-cols
imgMaxPix_x
=
int
(
x
)
imgMaxPix_y
=
int
(
y
)
apSizeInMicrons
=
np
.
deg2rad
(
apSizeInArcsec
/
3600.
)
*
focalLengthInMeters
*
1e6
apSizeInPix
=
apSizeInMicrons
/
psfSampleSizeInMicrons
apSizeInPix
=
np
.
int
(
np
.
ceil
(
apSizeInPix
))
imgT
=
np
.
zeros_like
(
img
)
ngy
,
ngx
=
img
.
shape
cy
=
int
(
ngy
/
2
)
cx
=
int
(
ngx
/
2
)
imgT
[
cy
-
apSizeInPix
:
cy
+
apSizeInPix
+
1
,
cx
-
apSizeInPix
:
cx
+
apSizeInPix
+
1
]
=
\
img
[
imgMaxPix_y
-
apSizeInPix
:
imgMaxPix_y
+
apSizeInPix
+
1
,
imgMaxPix_x
-
apSizeInPix
:
imgMaxPix_x
+
apSizeInPix
+
1
]
return
imgT
###插值对齐-fft###
def
psfCentering_FFT
(
image
):
"""
centering psf within an aperture by FFT
"""
ny
,
nx
=
image
.
shape
py
,
px
=
ndimage
.
center_of_mass
(
image
)
dx
=
(
px
-
nx
/
2
)
dy
=
(
py
-
ny
/
2
)
k
=
np
.
zeros
((
nx
,
ny
,
2
),
dtype
=
float
)
fg
=
np
.
fft
.
fft2
(
image
)
ge
=
np
.
zeros_like
(
fg
)
inx
=
int
(
nx
/
2
)
jny
=
int
(
ny
/
2
)
#prepare for the phase multiply matrix
#left bottom
for
i
in
range
(
inx
+
1
):
for
j
in
range
(
jny
+
1
):
k
[
i
][
j
][
0
]
=
i
;
k
[
i
][
j
][
1
]
=
j
;
#top right
for
i
in
range
(
inx
-
1
):
for
j
in
range
(
jny
-
1
):
k
[
i
+
inx
+
1
][
j
+
jny
+
1
][
0
]
=
(
-
(
nx
/
2
-
1
)
+
i
)
k
[
i
+
inx
+
1
][
j
+
jny
+
1
][
1
]
=
(
-
(
ny
/
2
-
1
)
+
j
)
#bottom right
for
i
in
range
(
inx
+
1
):
for
j
in
range
(
jny
-
1
):
k
[
i
][
j
+
jny
+
1
][
0
]
=
i
k
[
i
][
j
+
jny
+
1
][
1
]
=
(
-
(
ny
/
2
-
1
)
+
j
)
#top left
for
i
in
range
(
inx
-
1
):
for
j
in
range
(
int
(
jny
+
1
)):
k
[
i
+
inx
+
1
][
j
][
0
]
=
(
-
(
nx
/
2
-
1
)
+
i
)
k
[
i
+
inx
+
1
][
j
][
1
]
=
j
for
i
in
range
(
nx
):
for
j
in
range
(
ny
):
ge
[
i
][
j
]
=
fg
[
i
][
j
]
*
np
.
exp
(
2.
*
np
.
pi
*
(
dx
*
k
[
i
][
j
][
0
]
/
nx
+
dy
*
k
[
i
][
j
][
1
]
/
ny
)
*
1j
)
get
=
np
.
fft
.
ifft2
(
ge
).
real
return
(
get
)
###图像叠加###
def
psfStack
(
*
psfMat
):
"""
stacked image from the different psfs
Parameters:
*psfMat (numpy.array): the different psfs for stacking
Returns:
img (numpy.array): image
"""
nn
=
len
(
psfMat
)
img
=
np
.
zeros_like
(
psfMat
[
0
])
for
ii
in
range
(
nn
):
img
+=
psfMat
[
ii
]
/
np
.
sum
(
psfMat
[
ii
])
img
/=
np
.
sum
(
img
)
return
img
###计算PSF椭率-接口###
def
psfSizeCalculator
(
psfMat
,
psfSampleSize
=
5
,
CalcPSFcenter
=
True
,
SigRange
=
True
,
TailorScheme
=
2
):
"""
calculate psf size & ellipticity
Parameters:
psfMat (numpy.array): image
psfSampleSize (float-optional): psf size in microns.
CalcPSFcenter (bool-optional): whether calculate psf center. Default: True
SigRange (bool-optional): whether use psf tailor. Default: False
TailorScheme (int-optional): which method for psf tailor. Default: 1
Returns:
cenX, cenY (float, float): the pixel position of the mass center
sz (float): psf size
e1, e2 (float, float): psf ellipticity
REE80 (float): radius of REE80 in arcseconds
"""
psfSampleSize
=
psfSampleSize
*
1e-3
#mm
REE80
=
-
1.0
##encircling 80% energy
if
SigRange
is
True
:
if
TailorScheme
==
1
:
psfMat
=
imSigRange
(
psfMat
,
fraction
=
0.80
)
psfInfo
[
'psfMat'
]
=
psfMat
#set on/off
if
TailorScheme
==
2
:
#img = psfTailor(psfMat, apSizeInArcsec=0.5)
imgX
,
REE80
=
psfEncircle
(
psfMat
)
#psfMat = img
REE80
=
REE80
[
0
]
if
CalcPSFcenter
is
True
:
img
=
psfMat
/
np
.
sum
(
psfMat
)
y
,
x
=
ndimage
.
center_of_mass
(
img
)
#y-rows, x-cols
cenX
=
x
cenY
=
y
if
CalcPSFcenter
is
False
:
cenPix_X
=
psfMat
.
shape
[
1
]
/
2
#90
cenPix_Y
=
psfMat
.
shape
[
0
]
/
2
#90
cenX
=
cenPix_X
+
psfInfo
[
'centroid_x'
]
/
psfSampleSize
cenY
=
cenPix_Y
-
psfInfo
[
'centroid_y'
]
/
psfSampleSize
pixSize
=
1
sz
,
e1
,
e2
=
psfSecondMoments
(
psfMat
,
cenX
,
cenY
,
pixSize
=
pixSize
)
return
cenX
,
cenY
,
sz
,
e1
,
e2
,
REE80
###计算PSF椭率###
def
psfSecondMoments
(
psfMat
,
cenX
,
cenY
,
pixSize
=
1
):
"""
estimate the psf ellipticity by the second moment of surface brightness
Parameters:
psfMat (numpy.array-float): image
cenX, cenY (float, float): pixel position of the psf center
pixSize (float-optional): pixel size
Returns:
sz (float): psf size
e1, e2 (float, float): psf ellipticity
"""
apr
=
0.5
#arcsec, 0.5角秒内测量
fl
=
28.
#meters
pxs
=
5.0
#microns
apr
=
np
.
deg2rad
(
apr
/
3600.
)
*
fl
*
1e6
apr
=
apr
/
pxs
apr
=
np
.
int
(
np
.
ceil
(
apr
))
I
=
psfMat
ncol
=
I
.
shape
[
1
]
nrow
=
I
.
shape
[
0
]
w
=
0.0
w11
=
0.0
w12
=
0.0
w22
=
0.0
for
icol
in
range
(
ncol
):
for
jrow
in
range
(
nrow
):
x
=
icol
*
pixSize
-
cenX
y
=
jrow
*
pixSize
-
cenY
rr
=
np
.
sqrt
(
x
*
x
+
y
*
y
)
wgt
=
0.0
if
rr
<=
apr
:
wgt
=
1.0
w
+=
I
[
jrow
,
icol
]
*
wgt
w11
+=
x
*
x
*
I
[
jrow
,
icol
]
*
wgt
w12
+=
x
*
y
*
I
[
jrow
,
icol
]
*
wgt
w22
+=
y
*
y
*
I
[
jrow
,
icol
]
*
wgt
w11
/=
w
w12
/=
w
w22
/=
w
sz
=
w11
+
w22
e1
=
(
w11
-
w22
)
/
sz
e2
=
2.0
*
w12
/
sz
return
sz
,
e1
,
e2
###计算REE80###
def
psfEncircle
(
img
,
fraction
=
0.8
,
psfSampleSizeInMicrons
=
5
,
focalLengthInMeters
=
28
):
"""
psf tailor within a given percentage.
Parameters:
img (numpy.array-float): image
fraction (float-optional): a percentage for psf tailor.
psfSampleSizeInMicrons (float-optional): psf pixel size in microns.
focalLengthInMeters (float-optional): csst focal length im meters.
Returns:
img*wgt (numpy.array-float): image
REE80 (float): radius of REE80 in arcseconds.
"""
#imgMaxPix_x, imgMaxPix_y = findMaxPix(img)
y
,
x
=
ndimage
.
center_of_mass
(
img
)
#y-rows, x-cols
imgMaxPix_x
=
int
(
x
)
imgMaxPix_y
=
int
(
y
)
im1
=
img
.
copy
()
im1size
=
im1
.
shape
dis
=
np
.
zeros_like
(
img
)
for
irow
in
range
(
im1size
[
0
]):
for
icol
in
range
(
im1size
[
1
]):
dx
=
icol
-
imgMaxPix_x
dy
=
irow
-
imgMaxPix_y
dis
[
irow
,
icol
]
=
np
.
hypot
(
dx
,
dy
)
nn
=
im1size
[
1
]
*
im1size
[
0
]
disX
=
dis
.
reshape
(
nn
)
disXsortId
=
np
.
argsort
(
disX
)
imgX
=
img
.
reshape
(
nn
)
imgY
=
imgX
[
disXsortId
]
psfFrac
=
np
.
cumsum
(
imgY
)
/
np
.
sum
(
imgY
)
ind
=
np
.
where
(
psfFrac
>
fraction
)[
0
][
0
]
wgt
=
np
.
ones_like
(
dis
)
wgt
[
np
.
where
(
dis
>
dis
[
np
.
where
(
img
==
imgY
[
ind
])])]
=
0
REE80
=
np
.
rad2deg
(
dis
[
np
.
where
(
img
==
imgY
[
ind
])]
*
psfSampleSizeInMicrons
*
1e-6
/
focalLengthInMeters
)
*
3600
return
img
*
wgt
,
REE80
###图像能量百分比查找###
def
imSigRange
(
img
,
fraction
=
0.80
):
"""
extract the image within x-percent (DISCARD)
Parameters:
img (numpy.array-float): image
fraction (float-optional): a percentage
Returns:
im1 (numpy.array-float): image
"""
im1
=
img
.
copy
()
im1size
=
im1
.
shape
im2
=
np
.
sort
(
im1
.
reshape
(
im1size
[
0
]
*
im1size
[
1
]))
im2
=
im2
[::
-
1
]
im3
=
np
.
cumsum
(
im2
)
/
np
.
sum
(
im2
)
loc
=
np
.
where
(
im3
>
fraction
)
#print(im3[loc[0][0]], im2[loc[0][0]])
im1
[
np
.
where
(
im1
<=
im2
[
loc
[
0
][
0
]])]
=
0
return
im1
###孔径内图像裁剪###
def
psfTailor
(
img
,
apSizeInArcsec
=
0.5
,
psfSampleSizeInMicrons
=
5
,
focalLengthInMeters
=
28
):
"""
psf tailor within a given aperture size
Parameters:
img (numpy.array-float): image
apSizeInArcsec (float-optional): aperture size in arcseconds.
psfSampleSizeInMicrons (float-optional): psf pixel size in microns.
focalLengthInMeters (float-optional): csst focal length im meters.
Returns:
imgT (numpy.array-float): image
"""
#imgMaxPix_x, imgMaxPix_y = findMaxPix(img)
y
,
x
=
ndimage
.
center_of_mass
(
img
)
#y-rows, x-cols
imgMaxPix_x
=
int
(
x
)
imgMaxPix_y
=
int
(
y
)
apSizeInMicrons
=
np
.
deg2rad
(
apSizeInArcsec
/
3600.
)
*
focalLengthInMeters
*
1e6
apSizeInPix
=
apSizeInMicrons
/
psfSampleSizeInMicrons
apSizeInPix
=
np
.
int
(
np
.
ceil
(
apSizeInPix
))
imgT
=
np
.
zeros_like
(
img
)
imgT
[
imgMaxPix_y
-
apSizeInPix
:
imgMaxPix_y
+
apSizeInPix
+
1
,
imgMaxPix_x
-
apSizeInPix
:
imgMaxPix_x
+
apSizeInPix
+
1
]
=
\
img
[
imgMaxPix_y
-
apSizeInPix
:
imgMaxPix_y
+
apSizeInPix
+
1
,
imgMaxPix_x
-
apSizeInPix
:
imgMaxPix_x
+
apSizeInPix
+
1
]
return
imgT
###centroid with a window###
def
centroidWgt
(
img
,
nt
=
160
):
#libCentroid = ctypes.CDLL('/public/home/weichengliang/lnData/CSST_new_framwork/csstPSF/libCentroid/libCentroid.so') # CDLL加载库
libCentroid
=
ctypes
.
CDLL
(
'./libCentroid/libCentroid.so'
)
# CDLL加载库
libCentroid
.
centroidWgt
.
argtypes
=
[
ctypes
.
POINTER
(
ctypes
.
c_float
),
ctypes
.
c_int
,
ctypes
.
c_int
,
ctypes
.
POINTER
(
ctypes
.
c_double
)]
libCentroid
.
imSplint
.
argtypes
=
[
ctypes
.
POINTER
(
ctypes
.
c_float
),
ctypes
.
c_int
,
ctypes
.
c_int
,
ctypes
.
POINTER
(
ctypes
.
c_double
),
ctypes
.
c_int
,
ctypes
.
c_int
,
ctypes
.
POINTER
(
ctypes
.
c_float
)]
imx
=
img
/
np
.
sum
(
img
)
ny
,
nx
=
imx
.
shape
#imx centroid
nn
=
nx
*
ny
arr
=
(
ctypes
.
c_float
*
nn
)()
arr
[:]
=
imx
.
reshape
(
nn
)
para
=
(
ctypes
.
c_double
*
10
)()
libCentroid
.
centroidWgt
(
arr
,
ny
,
nx
,
para
)
imx_cy
=
para
[
3
]
#irow
imx_cx
=
para
[
4
]
#icol
#imx -> imy
nxt
=
nyt
=
nt
nn
=
nxt
*
nyt
yat
=
(
ctypes
.
c_float
*
nn
)()
libCentroid
.
imSplint
(
arr
,
ny
,
nx
,
para
,
nxt
,
nyt
,
yat
)
imy
=
np
.
array
(
yat
[:]).
reshape
([
nxt
,
nyt
])
return
imy
,
imx_cx
,
imx_cy
'''
def psfCentering_wgt(ipsfMat, psf_image_x, psf_image_y, psfSampleSizeInMicrons=5.0):
img, cx, cy = centroidWgt(ipsfMat, nt=160)
nrows, ncols = ipsfMat.shape
cyt = (cy + nrows/2)*psfSampleSizeInMicrons*1e-3 +psf_image_y
cxt = (cx + ncols/2)*psfSampleSizeInMicrons*1e-3 +psf_image_x
return img, cxt, cyt
'''
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp_v2/__init__.py
deleted
100644 → 0
View file @
e82a5dcc
from
.PSFInterp
import
PSFInterp
\ No newline at end of file
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp_v2/__pycache__/PSFConfig.cpython-37.pyc
deleted
100644 → 0
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e82a5dcc
File deleted
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp_v2/__pycache__/PSFConfig.cpython-38.pyc
deleted
100644 → 0
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e82a5dcc
File deleted
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp_v2/__pycache__/PSFInterp.cpython-38.pyc
deleted
100644 → 0
View file @
e82a5dcc
File deleted
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp_v2/__pycache__/PSFUtil.cpython-37.pyc
deleted
100644 → 0
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e82a5dcc
File deleted
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp_v2/__pycache__/PSFUtil.cpython-38.pyc
deleted
100644 → 0
View file @
e82a5dcc
File deleted
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp_v2/__pycache__/__init__.cpython-38.pyc
deleted
100644 → 0
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e82a5dcc
File deleted
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp_v2/libCentroid/.DS_Store
deleted
100644 → 0
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e82a5dcc
File deleted
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp_v2/libCentroid/Makefile
deleted
100644 → 0
View file @
e82a5dcc
#OPTS += -D
CC
=
gcc
OPTIMIZE
=
-fPIC
-g
-O3
#-Wall -wd981 #-wd1419 -wd810
#GSLI = -I/home/alex/opt/gsl/include
#GSLL = -L/home/alex/opt/gsl/lib -lgsl -lgslcblas
#FFTWI = -I/home/alex/opt/fftw/include
#FFTWL = -L/home/alex/opt/fftw/lib -lfftw3 -lfftw3f
#HDF5I = -I/home/alex/opt/hdf5/include
#HDF5L = -L/home/alex/opt/hdf5/lib -lhdf5_hl -lhdf5
#FITSI = -I/home/alex/opt/cfitsio/include
#FITSL = -L/home/alex/opt/cfitsio/lib -lcfitsio
#EXTRACFLAGS =
#EXTRACLIB =
CLINK
=
$(CC)
CFLAGS
=
$(OPTIMIZE)
#
$(EXTRACFLAGS)
$(OPTS)
CLIB
=
-shared
-lm
#
$(EXTRACLIB)
OBJS
=
centroidWgt.o nrutil.o
EXEC
=
libCentroid.so
all
:
$(EXEC)
$(EXEC)
:
$(OBJS)
$(CLINK)
$(CFLAGS)
-o
$@
$(OBJS)
$(CLIB)
$(OBJS)
:
nrutil.h Makefile
.PHONY
:
clean
clean
:
rm
-f
*
.o
$(EXEC)
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp_v2/libCentroid/centroidWgt.c
deleted
100644 → 0
View file @
e82a5dcc
#include
<math.h>
#include
<stdio.h>
#include
<stdlib.h>
#include
"nrutil.h"
//y is the input image, nx and ny are the pixels along x and y axis;
//yt and residu are the required matrix for the function
//para contains the needed parameters: centx=para[3], centy=para[4]
void
star_gaus
(
float
**
y
,
int
nx
,
int
ny
,
double
*
para
);
void
Interp_bicubic
(
int
nx
,
int
ny
,
float
**
a0
,
int
nbound
,
int
nxt
,
int
nyt
,
float
**
at
,
double
*
xcen
);
void
splie2
(
float
**
ya
,
int
m
,
int
n
,
float
**
y2a
);
void
spline
(
float
y
[],
int
n
,
float
yp1
,
float
ypn
,
float
y2
[]);
void
splint
(
float
ya
[],
float
y2a
[],
int
n
,
float
x
,
float
*
y
);
void
centroidWgt
(
float
*
y
,
int
nx
,
int
ny
,
double
*
para
)
{
int
i
,
j
,
k
;
float
**
yy
;
double
**
basef
;
double
**
coff
;
double
ccol
,
crow
;
yy
=
matrix
(
0
,
nx
-
1
,
0
,
ny
-
1
);
for
(
i
=
0
;
i
<
nx
;
i
++
)
for
(
j
=
0
;
j
<
ny
;
j
++
)
{
k
=
j
+
i
*
nx
;
yy
[
i
][
j
]
=
y
[
k
];
}
star_gaus
(
yy
,
nx
,
ny
,
para
);
//ccol = para[4];
//crow = para[3];
}
void
imSplint
(
float
*
y
,
int
nx
,
int
ny
,
double
*
para
,
int
nxt
,
int
nyt
,
float
*
yat
)
{
int
i
,
j
,
k
;
float
**
yy
;
double
**
basef
;
double
**
coff
;
double
ccol
,
crow
;
yy
=
matrix
(
0
,
nx
-
1
,
0
,
ny
-
1
);
for
(
i
=
0
;
i
<
nx
;
i
++
)
for
(
j
=
0
;
j
<
ny
;
j
++
)
{
k
=
j
+
i
*
nx
;
yy
[
i
][
j
]
=
y
[
k
];
}
crow
=
para
[
3
];
ccol
=
para
[
4
];
int
nbound
;
float
**
at
;
double
xcen
[
2
];
at
=
matrix
(
0
,
nxt
-
1
,
0
,
nyt
-
1
);
nbound
=
(
int
)((
nx
-
nxt
)
/
2
);
xcen
[
0
]
=
crow
;
xcen
[
1
]
=
ccol
;
Interp_bicubic
(
nx
,
ny
,
yy
,
nbound
,
nxt
,
nyt
,
at
,
xcen
);
for
(
i
=
0
;
i
<
nxt
;
i
++
)
for
(
j
=
0
;
j
<
nyt
;
j
++
)
{
k
=
j
+
i
*
nxt
;
yat
[
k
]
=
at
[
i
][
j
];
}
}
//void star_gaus(float **y,int nx,int ny,float **yt,float **residu,double *para)
void
star_gaus
(
float
**
y
,
int
nx
,
int
ny
,
double
*
para
)
{
void
gasfit_2D
(
double
**
x
,
double
*
y
,
int
np
,
double
*
para
,
double
bg0
,
int
fbg
);
double
**
xs
,
*
ys
,
ymax
;
int
i
,
j
,
np
,
npt
,
im
,
jm
,
**
xi
,
k
;
double
kc
,
bgc
,
sigmac
,
xc
,
yc
,
sigma2v
,
det
;
double
bg0
=
0
;
int
fbg
=
0
;
np
=
nx
*
ny
;
xs
=
dmatrix
(
0
,
np
-
1
,
0
,
1
);
ys
=
dvector
(
0
,
np
-
1
);
xi
=
imatrix
(
0
,
np
-
1
,
0
,
1
);
ymax
=
y
[
0
][
0
];
for
(
i
=
0
;
i
<
nx
;
i
++
)
for
(
j
=
0
;
j
<
ny
;
j
++
){
if
(
ymax
<
y
[
i
][
j
]){
ymax
=
y
[
i
][
j
];
im
=
i
;
jm
=
j
;}
}
int
cutPix
;
cutPix
=
23
;
npt
=
0
;
for
(
i
=-
cutPix
;
i
<=
cutPix
;
i
++
){
for
(
j
=-
cutPix
;
j
<=
cutPix
;
j
++
){
xs
[
npt
][
0
]
=
xi
[
npt
][
0
]
=
i
+
im
;
xs
[
npt
][
1
]
=
xi
[
npt
][
1
]
=
j
+
jm
;
ys
[
npt
]
=
y
[
im
+
i
][
jm
+
j
];
npt
++
;
}
}
gasfit_2D
(
xs
,
ys
,
npt
,
para
,
bg0
,
fbg
);
kc
=
para
[
0
];
sigmac
=
para
[
1
];
bgc
=
para
[
2
];
xc
=
para
[
3
];
yc
=
para
[
4
];
// printf("%e %e %e %e %e\n",kc,sigmac,bgc,xc,yc);
/*
sigma2v=-1./(2.*sigmac*sigmac);
for(i=0;i<nx;i++){
for(j=0;j<ny;j++){
det=DSQR(i-xc)+DSQR(j-yc);
yt[i][j]=kc*exp(det*sigma2v)+bgc;
residu[i][j]=y[i][j]-yt[i][j];
}
}
*/
free_dmatrix
(
xs
,
0
,
np
-
1
,
0
,
1
);
free_imatrix
(
xi
,
0
,
np
-
1
,
0
,
1
);
free_dvector
(
ys
,
0
,
np
-
1
);
}
void
gasfit_2D
(
double
**
x
,
double
*
y
,
int
np
,
double
*
para
,
double
bg0
,
int
fbg
)
{
void
search_2D
(
double
**
x
,
double
*
y
,
int
np
,
double
kc
,
double
kd
,
double
sigmac
,
double
sigmad
,
double
bgc
,
double
bgd
,
double
xc
,
double
xd
,
double
yc
,
double
yd
,
double
*
para
,
double
bg0
,
int
fbg
);
int
i
,
j
,
k
,
imax
=
0
,
isigma
;
double
ymax
,
ymin
,
kc
,
kd
,
sigmac
,
sigmad
,
bgc
,
bgd
,
ysigma
,
xc
,
yc
,
xd
,
yd
;
double
det
,
dett
;
ymin
=
ymax
=
y
[
imax
];
for
(
i
=
1
;
i
<
np
;
i
++
){
if
(
ymax
<
y
[
i
]){
imax
=
i
;
ymax
=
y
[
i
];}
if
(
ymin
>
y
[
i
])
ymin
=
y
[
i
];
}
kc
=
ymax
;
kd
=
ymax
/
12
.;
det
=
ysigma
=
kc
*
exp
(
-
0
.
5
);
for
(
i
=
0
;
i
<
np
;
i
++
){
dett
=
fabs
(
ysigma
-
y
[
i
]);
if
(
dett
<
det
&&
y
[
i
]
!=
kc
){
det
=
dett
;
isigma
=
i
;}
//if(dett<det){det=dett;isigma=i;}
}
xc
=
x
[
imax
][
0
];
yc
=
x
[
imax
][
1
];
sigmac
=
sqrt
(
DSQR
(
xc
-
x
[
isigma
][
0
])
+
DSQR
(
yc
-
x
[
isigma
][
1
]))
*
1
.;
xd
=
yd
=
sigmac
*
0
.
25
;
sigmad
=
0
.
25
*
sigmac
;
bgc
=
0
.;
bgd
=
fabs
(
ymin
);
for
(
i
=
0
;
i
<
4
;
i
++
){
search_2D
(
x
,
y
,
np
,
kc
,
kd
,
sigmac
,
sigmad
,
bgc
,
bgd
,
xc
,
xd
,
yc
,
yd
,
para
,
bg0
,
fbg
);
kd
*=
0
.
33
;
sigmad
*=
0
.
33
;
bgd
*=
0
.
33
;
xd
*=
0
.
33
;
yd
*=
0
.
33
;
kc
=
para
[
0
];
sigmac
=
para
[
1
];
bgc
=
para
[
2
];
xc
=
para
[
3
];
yc
=
para
[
4
];
}
if
(
fbg
==
0
)
para
[
2
]
=
bg0
;
}
void
search_2D
(
double
**
x
,
double
*
y
,
int
np
,
double
kc
,
double
kd
,
double
sigmac
,
double
sigmad
,
double
bgc
,
double
bgd
,
double
xc
,
double
xd
,
double
yc
,
double
yd
,
double
*
para
,
double
bg0
,
int
fbg
)
{
double
k
,
sigma
,
bg
,
k2
,
k20
,
sigma2v
,
det
,
xt
,
yt
;
int
i
,
j
,
l
,
m
,
p
,
q
;
sigma2v
=-
1
.
/
(
2
.
*
sigmac
*
sigmac
);
bg
=
bgc
;
k20
=
0
;
for
(
m
=
0
;
m
<
np
;
m
++
){
det
=
DSQR
(
x
[
m
][
0
]
-
xc
)
+
DSQR
(
x
[
m
][
1
]
-
yc
);
det
=
kc
*
exp
(
det
*
sigma2v
)
+
bgc
-
y
[
m
];
k20
+=
det
*
det
;
}
for
(
i
=-
4
;
i
<=
4
;
i
++
){
k
=
kc
+
i
*
kd
;
if
(
k
>
0
){
for
(
j
=-
4
;
j
<=
4
;
j
++
){
sigma
=
sigmac
+
j
*
sigmad
;
if
(
sigma
>
0
){
sigma2v
=-
1
.
/
(
2
.
*
sigma
*
sigma
);
for
(
p
=-
4
;
p
<=
4
;
p
++
){
xt
=
xc
+
p
*
xd
;
for
(
q
=-
4
;
q
<=
4
;
q
++
){
yt
=
yc
+
q
*
yd
;
k2
=
0
;
if
(
fbg
==
0
){
bg
=
bg0
;
for
(
m
=
0
;
m
<
np
;
m
++
){
det
=
DSQR
(
x
[
m
][
0
]
-
xt
)
+
DSQR
(
x
[
m
][
1
]
-
yt
);
det
=
k
*
exp
(
det
*
sigma2v
)
+
bg
-
y
[
m
];
k2
+=
det
*
det
;
}
}
else
{
for
(
l
=-
4
;
l
<=
4
;
l
++
){
bg
=
bgc
+
l
*
bgd
;
for
(
m
=
0
;
m
<
np
;
m
++
){
det
=
DSQR
(
x
[
m
][
0
]
-
xt
)
+
DSQR
(
x
[
m
][
1
]
-
yt
);
det
=
k
*
exp
(
det
*
sigma2v
)
+
bg
-
y
[
m
];
k2
+=
det
*
det
;
}
}
}
//printf("k20=%e k2=%e\n",k20,k2);
if
(
k2
<=
k20
){
k20
=
k2
;
para
[
5
]
=
k2
;
para
[
0
]
=
k
;
para
[
1
]
=
sigma
;
para
[
2
]
=
bg
;
para
[
3
]
=
xt
;
para
[
4
]
=
yt
;}
}
}
}
}
}
}
}
/////////////////////////////
//#include <math.h>
//#include <stdio.h>
//#include <stdlib.h>
//#include "nrutil.h"
//nx,ny is the pixels of x and y direction
//a0 is the input image in nx*ny
//nbound is the boundary limit
//nxt,nyt is out put image dimentions
//at is the output image and cen represent the required center
void
Interp_bicubic
(
int
nx
,
int
ny
,
float
**
a0
,
int
nbound
,
int
nxt
,
int
nyt
,
float
**
at
,
double
*
xcen
)
{
void
splie2
(
float
**
ya
,
int
m
,
int
n
,
float
**
y2a
);
void
spline
(
float
y
[],
int
n
,
float
yp1
,
float
ypn
,
float
y2
[]);
void
splint
(
float
ya
[],
float
y2a
[],
int
n
,
float
x
,
float
*
y
);
int
i
,
j
,
m
,
n
,
ic
,
jc
;
float
*
ytmp
,
*
yytmp
,
**
y2a
,
x1
,
x2
,
shift1
,
shift2
;
y2a
=
matrix
(
0
,
nx
,
0
,
ny
);
ytmp
=
vector
(
0
,
ny
);
yytmp
=
vector
(
0
,
ny
);
splie2
(
a0
,
nx
,
ny
,
y2a
);
ic
=
nx
*
0
.
5
;
jc
=
ny
*
0
.
5
;
shift1
=
xcen
[
0
]
-
ic
;
//-0.5;
shift2
=
xcen
[
1
]
-
jc
;
//-0.5;
if
(
fabs
(
shift1
)
>
nbound
||
fabs
(
shift2
)
>
nbound
){
printf
(
"bicubic shifts too much %e %e
\n
"
,
shift1
,
shift2
);
getchar
();
}
for
(
n
=
0
;
n
<
nyt
;
n
++
){
x2
=
n
+
nbound
+
shift2
;
for
(
i
=
0
;
i
<
nx
;
i
++
){
splint
(
a0
[
i
],
y2a
[
i
],
ny
,
x2
,
&
yytmp
[
i
]);
spline
(
yytmp
,
ny
,
1.0e30
,
1.0e30
,
ytmp
);
}
for
(
m
=
0
;
m
<
nxt
;
m
++
){
x1
=
m
+
nbound
+
shift1
;
splint
(
yytmp
,
ytmp
,
ny
,
x1
,
&
at
[
m
][
n
]);
}
}
free_vector
(
yytmp
,
0
,
ny
);
free_vector
(
ytmp
,
0
,
ny
);
free_matrix
(
y2a
,
0
,
nx
,
0
,
ny
);
}
void
splie2
(
float
**
ya
,
int
m
,
int
n
,
float
**
y2a
)
{
void
spline
(
float
y
[],
int
n
,
float
yp1
,
float
ypn
,
float
y2
[]);
int
j
;
for
(
j
=
0
;
j
<
m
;
j
++
)
spline
(
ya
[
j
],
n
,
1.0e30
,
1.0e30
,
y2a
[
j
]);
}
void
spline
(
float
y
[],
int
n
,
float
yp1
,
float
ypn
,
float
y2
[])
{
int
i
,
k
;
float
p
,
qn
,
sig
,
un
,
*
u
;
u
=
vector
(
0
,
n
-
1
);
if
(
yp1
>
0.99e30
)
y2
[
0
]
=
u
[
0
]
=
0
.
0
;
else
{
y2
[
0
]
=
-
0
.
5
;
u
[
0
]
=
3
.
0
*
(
y
[
1
]
-
y
[
0
]
-
yp1
);
}
sig
=
0
.
5
;
for
(
i
=
1
;
i
<=
n
-
2
;
i
++
)
{
p
=
sig
*
y2
[
i
-
1
]
+
2
.
0
;
y2
[
i
]
=
(
sig
-
1
.
0
)
/
p
;
u
[
i
]
=
(
y
[
i
+
1
]
-
2
.
*
y
[
i
]
+
y
[
i
-
1
]);
u
[
i
]
=
(
3
.
0
*
u
[
i
]
-
sig
*
u
[
i
-
1
])
/
p
;
}
if
(
ypn
>
0.99e30
)
qn
=
un
=
0
.
0
;
else
{
qn
=
0
.
5
;
un
=
3
.
0
*
(
ypn
-
y
[
n
-
1
]
+
y
[
n
-
2
]);
}
y2
[
n
-
1
]
=
(
un
-
qn
*
u
[
n
-
2
])
/
(
qn
*
y2
[
n
-
2
]
+
1
.
0
);
for
(
k
=
n
-
2
;
k
>=
0
;
k
--
)
y2
[
k
]
=
y2
[
k
]
*
y2
[
k
+
1
]
+
u
[
k
];
free_vector
(
u
,
0
,
n
-
1
);
}
void
splint
(
float
ya
[],
float
y2a
[],
int
n
,
float
x
,
float
*
y
)
{
void
nrerror
(
char
error_text
[]);
int
klo
,
khi
,
k
;
float
h
,
b
,
a
;
klo
=
x
;
if
(
klo
<
0
)
klo
=
0
;
if
(
klo
==
n
-
1
)
klo
=
n
-
2
;
khi
=
klo
+
1
;
if
(
klo
<
0
||
khi
>=
n
)
printf
(
"error:klo, khi, n: %d %d %d
\n
"
,
klo
,
khi
,
n
);
if
(
klo
<
0
||
khi
>=
n
)
nrerror
(
"Bad xa input to routine splint"
);
a
=
(
khi
-
x
);
b
=
(
x
-
klo
);
*
y
=
a
*
ya
[
klo
]
+
b
*
ya
[
khi
]
+
((
a
*
a
*
a
-
a
)
*
y2a
[
klo
]
+
(
b
*
b
*
b
-
b
)
*
y2a
[
khi
])
/
6
.
0
;
}
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp_v2/libCentroid/centroidWgt.o
deleted
100644 → 0
View file @
e82a5dcc
File deleted
ObservationSim/PSF/PSFInterp_deprecated/PSFInterp_v2/libCentroid/libCentroid.so
deleted
100755 → 0
View file @
e82a5dcc
File deleted
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