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Liu Dezi
csst_msc_sim
Commits
885d85b2
Commit
885d85b2
authored
Apr 28, 2024
by
JX
😵
Browse files
Merge remote-tracking branch 'origin/develop'
parents
c48d8742
228262c4
Changes
5
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.gitignore
View file @
885d85b2
...
@@ -7,4 +7,6 @@ dist/*
...
@@ -7,4 +7,6 @@ dist/*
*interp.c
*interp.c
!*libshao.so
!*libshao.so
*.out
*.out
pnodes
pnodes
\ No newline at end of file
.coverage
coverage
\ No newline at end of file
ObservationSim/Instrument/Chip/Chip.py
View file @
885d85b2
...
@@ -280,774 +280,774 @@ class Chip(FocalPlane):
...
@@ -280,774 +280,774 @@ class Chip(FocalPlane):
noise
=
self
.
dark_noise
*
exptime
+
self
.
read_noise
**
2
noise
=
self
.
dark_noise
*
exptime
+
self
.
read_noise
**
2
return
noise
return
noise
def
addEffects
(
self
,
config
,
img
,
chip_output
,
filt
,
ra_cen
,
dec_cen
,
img_rot
,
exptime
=
150.
,
pointing_ID
=
0
,
timestamp_obs
=
1621915200
,
pointing_type
=
'SCI'
,
sky_map
=
None
,
post_flash_map
=
None
,
tel
=
None
,
logger
=
None
):
#
def addEffects(self, config, img, chip_output, filt, ra_cen, dec_cen, img_rot, exptime=150., pointing_ID=0, timestamp_obs=1621915200, pointing_type='SCI', sky_map=None, post_flash_map=None, tel=None, logger=None):
# Set random seeds
#
# Set random seeds
SeedGainNonuni
=
int
(
config
[
"random_seeds"
][
"seed_gainNonUniform"
])
#
SeedGainNonuni = int(config["random_seeds"]["seed_gainNonUniform"])
SeedBiasNonuni
=
int
(
config
[
"random_seeds"
][
"seed_biasNonUniform"
])
#
SeedBiasNonuni = int(config["random_seeds"]["seed_biasNonUniform"])
SeedRnNonuni
=
int
(
config
[
"random_seeds"
][
"seed_rnNonUniform"
])
#
SeedRnNonuni = int(config["random_seeds"]["seed_rnNonUniform"])
SeedBadColumns
=
int
(
config
[
"random_seeds"
][
"seed_badcolumns"
])
#
SeedBadColumns = int(config["random_seeds"]["seed_badcolumns"])
SeedDefective
=
int
(
config
[
"random_seeds"
][
"seed_defective"
])
#
SeedDefective = int(config["random_seeds"]["seed_defective"])
SeedCosmicRay
=
int
(
config
[
"random_seeds"
][
"seed_CR"
])
#
SeedCosmicRay = int(config["random_seeds"]["seed_CR"])
fullwell
=
int
(
self
.
full_well
)
#
fullwell = int(self.full_well)
if
config
[
"ins_effects"
][
"add_hotpixels"
]
==
True
:
#
if config["ins_effects"]["add_hotpixels"] == True:
BoolHotPix
=
True
#
BoolHotPix = True
else
:
#
else:
BoolHotPix
=
False
#
BoolHotPix = False
if
config
[
"ins_effects"
][
"add_deadpixels"
]
==
True
:
#
if config["ins_effects"]["add_deadpixels"] == True:
BoolDeadPix
=
True
#
BoolDeadPix = True
else
:
#
else:
BoolDeadPix
=
False
#
BoolDeadPix = False
self
.
logger
=
logger
#
self.logger = logger
# Get Poisson noise generator
#
# Get Poisson noise generator
rng_poisson
,
poisson_noise
=
chip_utils
.
get_poisson
(
#
rng_poisson, poisson_noise = chip_utils.get_poisson(
seed
=
int
(
config
[
"random_seeds"
][
"seed_poisson"
])
+
pointing_ID
*
30
+
self
.
chipID
,
sky_level
=
0.
)
#
seed=int(config["random_seeds"]["seed_poisson"]) + pointing_ID*30 + self.chipID, sky_level=0.)
# Add sky background
#
# Add sky background
if
config
[
"ins_effects"
][
"add_back"
]
==
True
:
#
if config["ins_effects"]["add_back"] == True:
img
,
sky_map
=
chip_utils
.
add_sky_background
(
#
img, sky_map = chip_utils.add_sky_background(
img
=
img
,
filt
=
filt
,
exptime
=
exptime
,
sky_map
=
sky_map
,
tel
=
tel
)
#
img=img, filt=filt, exptime=exptime, sky_map=sky_map, tel=tel)
del
sky_map
#
del sky_map
# Apply flat-field large scale structure for one chip
#
# Apply flat-field large scale structure for one chip
if
config
[
"ins_effects"
][
"flat_fielding"
]
==
True
:
#
if config["ins_effects"]["flat_fielding"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Creating and applying Flat-Fielding"
,
logger
=
self
.
logger
)
#
msg=" Creating and applying Flat-Fielding", logger=self.logger)
chip_utils
.
log_info
(
msg
=
str
(
img
.
bounds
),
logger
=
self
.
logger
)
#
chip_utils.log_info(msg=str(img.bounds), logger=self.logger)
flat_img
,
flat_normal
=
chip_utils
.
get_flat
(
#
flat_img, flat_normal = chip_utils.get_flat(
img
=
img
,
seed
=
int
(
config
[
"random_seeds"
][
"seed_flat"
]))
#
img=img, seed=int(config["random_seeds"]["seed_flat"]))
if
self
.
survey_type
==
"photometric"
:
#
if self.survey_type == "photometric":
img
*=
flat_normal
#
img *= flat_normal
del
flat_normal
#
del flat_normal
if
config
[
"output_setting"
][
"flat_output"
]
==
False
:
#
if config["output_setting"]["flat_output"] == False:
del
flat_img
#
del flat_img
if
post_flash_map
is
not
None
:
#
if post_flash_map is not None:
img
=
img
+
post_flash_map
#
img = img + post_flash_map
# Apply Shutter-effect for one chip
#
# Apply Shutter-effect for one chip
if
config
[
"ins_effects"
][
"shutter_effect"
]
==
True
:
#
if config["ins_effects"]["shutter_effect"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Apply shutter effect"
,
logger
=
self
.
logger
)
#
msg=" Apply shutter effect", logger=self.logger)
# shutter effect normalized image for this chip
#
# shutter effect normalized image for this chip
shuttimg
=
effects
.
ShutterEffectArr
(
#
shuttimg = effects.ShutterEffectArr(
img
,
t_shutter
=
1.3
,
dist_bearing
=
735
,
dt
=
1E-3
)
#
img, t_shutter=1.3, dist_bearing=735, dt=1E-3)
if
self
.
survey_type
==
"photometric"
:
#
if self.survey_type == "photometric":
img
*=
shuttimg
#
img *= shuttimg
# output 16-bit shutter effect image with pixel value <=65535
#
# output 16-bit shutter effect image with pixel value <=65535
if
config
[
"output_setting"
][
"shutter_output"
]
==
True
:
#
if config["output_setting"]["shutter_output"] == True:
shutt_gsimg
=
galsim
.
ImageUS
(
shuttimg
*
6E4
)
#
shutt_gsimg = galsim.ImageUS(shuttimg*6E4)
shutt_gsimg
.
write
(
"%s/ShutterEffect_%s_1.fits"
%
#
shutt_gsimg.write("%s/ShutterEffect_%s_1.fits" %
(
chip_output
.
subdir
,
self
.
chipID
))
#
(chip_output.subdir, self.chipID))
del
shutt_gsimg
#
del shutt_gsimg
del
shuttimg
#
del shuttimg
# # Add Poisson noise to the resulting images
#
# # Add Poisson noise to the resulting images
# # (NOTE): this can only applied to the slitless image
#
# # (NOTE): this can only applied to the slitless image
# # since it dose not use photon shooting to draw stamps
#
# # since it dose not use photon shooting to draw stamps
# if self.survey_type == "spectroscopic":
#
# if self.survey_type == "spectroscopic":
# img.addNoise(poisson_noise)
#
# img.addNoise(poisson_noise)
# Add cosmic-rays
#
# Add cosmic-rays
if
config
[
"ins_effects"
][
"cosmic_ray"
]
==
True
and
pointing_type
==
'SCI'
:
#
if config["ins_effects"]["cosmic_ray"] == True and pointing_type == 'SCI':
chip_utils
.
log_info
(
msg
=
" Adding Cosmic-Ray"
,
logger
=
self
.
logger
)
#
chip_utils.log_info(msg=" Adding Cosmic-Ray", logger=self.logger)
img
,
crmap_gsimg
,
cr_event_num
=
chip_utils
.
add_cosmic_rays
(
img
=
img
,
chip
=
self
,
exptime
=
exptime
,
#
img, crmap_gsimg, cr_event_num = chip_utils.add_cosmic_rays(img=img, chip=self, exptime=exptime,
seed
=
SeedCosmicRay
+
pointing_ID
*
30
+
self
.
chipID
)
#
seed=SeedCosmicRay+pointing_ID*30+self.chipID)
chip_utils
.
outputCal
(
#
chip_utils.outputCal(
chip
=
self
,
#
chip=self,
img
=
crmap_gsimg
,
#
img=crmap_gsimg,
ra_cen
=
ra_cen
,
#
ra_cen=ra_cen,
dec_cen
=
dec_cen
,
#
dec_cen=dec_cen,
img_rot
=
img_rot
,
#
img_rot=img_rot,
im_type
=
'CRS'
,
#
im_type='CRS',
pointing_ID
=
pointing_ID
,
#
pointing_ID=pointing_ID,
output_dir
=
chip_output
.
subdir
,
#
output_dir=chip_output.subdir,
exptime
=
exptime
,
#
exptime=exptime,
project_cycle
=
config
[
"project_cycle"
],
#
project_cycle=config["project_cycle"],
run_counter
=
config
[
"run_counter"
],
#
run_counter=config["run_counter"],
timestamp
=
timestamp_obs
)
#
timestamp=timestamp_obs)
del
crmap_gsimg
#
del crmap_gsimg
# Apply PRNU effect and output PRNU flat file:
#
# Apply PRNU effect and output PRNU flat file:
if
config
[
"ins_effects"
][
"prnu_effect"
]
==
True
:
#
if config["ins_effects"]["prnu_effect"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Applying PRNU effect"
,
logger
=
self
.
logger
)
#
msg=" Applying PRNU effect", logger=self.logger)
img
,
prnu_img
=
chip_utils
.
add_PRNU
(
img
=
img
,
chip
=
self
,
#
img, prnu_img = chip_utils.add_PRNU(img=img, chip=self,
seed
=
int
(
config
[
"random_seeds"
][
"seed_prnu"
]
+
self
.
chipID
))
#
seed=int(config["random_seeds"]["seed_prnu"]+self.chipID))
if
config
[
"output_setting"
][
"prnu_output"
]
==
True
:
#
if config["output_setting"]["prnu_output"] == True:
prnu_img
.
write
(
"%s/FlatImg_PRNU_%s.fits"
%
#
prnu_img.write("%s/FlatImg_PRNU_%s.fits" %
(
chip_output
.
subdir
,
self
.
chipID
))
#
(chip_output.subdir, self.chipID))
if
config
[
"output_setting"
][
"flat_output"
]
==
False
:
#
if config["output_setting"]["flat_output"] == False:
del
prnu_img
#
del prnu_img
# # Add dark current
#
# # Add dark current
# if config["ins_effects"]["add_dark"] == True:
#
# if config["ins_effects"]["add_dark"] == True:
# dark_noise = galsim.DeviateNoise(galsim.PoissonDeviate(rng_poisson, self.dark_noise*(exptime+0.5*self.readout_time)))
#
# dark_noise = galsim.DeviateNoise(galsim.PoissonDeviate(rng_poisson, self.dark_noise*(exptime+0.5*self.readout_time)))
# img.addNoise(dark_noise)
#
# img.addNoise(dark_noise)
# Add dark current & Poisson noise
#
# Add dark current & Poisson noise
InputDark
=
False
#
InputDark = False
if
config
[
"ins_effects"
][
"add_dark"
]
==
True
:
#
if config["ins_effects"]["add_dark"] == True:
if
InputDark
:
#
if InputDark:
img
=
chip_utils
.
add_inputdark
(
#
img = chip_utils.add_inputdark(
img
=
img
,
chip
=
self
,
exptime
=
exptime
)
#
img=img, chip=self, exptime=exptime)
else
:
#
else:
img
,
_
=
chip_utils
.
add_poisson
(
#
img, _ = chip_utils.add_poisson(
img
=
img
,
chip
=
self
,
exptime
=
exptime
,
poisson_noise
=
poisson_noise
)
#
img=img, chip=self, exptime=exptime, poisson_noise=poisson_noise)
else
:
#
else:
img
,
_
=
chip_utils
.
add_poisson
(
#
img, _ = chip_utils.add_poisson(
img
=
img
,
chip
=
self
,
exptime
=
exptime
,
poisson_noise
=
poisson_noise
,
dark_noise
=
0.
)
#
img=img, chip=self, exptime=exptime, poisson_noise=poisson_noise, dark_noise=0.)
# Add diffusion & brighter-fatter effects
#
# Add diffusion & brighter-fatter effects
if
config
[
"ins_effects"
][
"bright_fatter"
]
==
True
:
#
if config["ins_effects"]["bright_fatter"] == True:
img
=
chip_utils
.
add_brighter_fatter
(
img
=
img
)
#
img = chip_utils.add_brighter_fatter(img=img)
# Add Hot Pixels or/and Dead Pixels
#
# Add Hot Pixels or/and Dead Pixels
rgbadpix
=
Generator
(
PCG64
(
int
(
SeedDefective
+
self
.
chipID
)))
#
rgbadpix = Generator(PCG64(int(SeedDefective+self.chipID)))
badfraction
=
5E-5
*
(
rgbadpix
.
random
()
*
0.5
+
0.7
)
#
badfraction = 5E-5*(rgbadpix.random()*0.5+0.7)
img
=
effects
.
DefectivePixels
(
img
,
IfHotPix
=
BoolHotPix
,
IfDeadPix
=
BoolDeadPix
,
#
img = effects.DefectivePixels(img, IfHotPix=BoolHotPix, IfDeadPix=BoolDeadPix,
fraction
=
badfraction
,
seed
=
SeedDefective
+
self
.
chipID
,
biaslevel
=
0
)
#
fraction=badfraction, seed=SeedDefective+self.chipID, biaslevel=0)
# Apply Bad lines
#
# Apply Bad lines
if
config
[
"ins_effects"
][
"add_badcolumns"
]
==
True
:
#
if config["ins_effects"]["add_badcolumns"] == True:
img
=
effects
.
BadColumns
(
#
img = effects.BadColumns(
img
,
seed
=
SeedBadColumns
,
chipid
=
self
.
chipID
,
logger
=
self
.
logger
)
#
img, seed=SeedBadColumns, chipid=self.chipID, logger=self.logger)
# Apply Nonlinearity on the chip image
#
# Apply Nonlinearity on the chip image
if
config
[
"ins_effects"
][
"non_linear"
]
==
True
:
#
if config["ins_effects"]["non_linear"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Applying Non-Linearity on the chip image"
,
logger
=
self
.
logger
)
#
msg=" Applying Non-Linearity on the chip image", logger=self.logger)
img
=
effects
.
NonLinearity
(
GSImage
=
img
,
beta1
=
5.e-7
,
beta2
=
0
)
#
img = effects.NonLinearity(GSImage=img, beta1=5.e-7, beta2=0)
# Apply CCD Saturation & Blooming
#
# Apply CCD Saturation & Blooming
if
config
[
"ins_effects"
][
"saturbloom"
]
==
True
:
#
if config["ins_effects"]["saturbloom"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Applying CCD Saturation & Blooming"
,
logger
=
self
.
logger
)
#
msg=" Applying CCD Saturation & Blooming", logger=self.logger)
img
=
effects
.
SaturBloom
(
#
img = effects.SaturBloom(
GSImage
=
img
,
nsect_x
=
1
,
nsect_y
=
1
,
fullwell
=
fullwell
)
#
GSImage=img, nsect_x=1, nsect_y=1, fullwell=fullwell)
# Apply CTE Effect
#
# Apply CTE Effect
# if config["ins_effects"]["cte_trail"] == True:
#
# if config["ins_effects"]["cte_trail"] == True:
# chip_utils.log_info(msg=" Apply CTE Effect", logger=self.logger)
#
# chip_utils.log_info(msg=" Apply CTE Effect", logger=self.logger)
# img = effects.CTE_Effect(GSImage=img, threshold=27)
#
# img = effects.CTE_Effect(GSImage=img, threshold=27)
pre1
=
self
.
prescan_x
# 27
#
pre1 = self.prescan_x # 27
over1
=
self
.
overscan_x
# 71
#
over1 = self.overscan_x # 71
pre2
=
self
.
prescan_y
# 0 #4
#
pre2 = self.prescan_y # 0 #4
over2
=
self
.
overscan_y
# 84 #80
#
over2 = self.overscan_y # 84 #80
if
config
[
"ins_effects"
][
"cte_trail"
]
==
True
:
#
if config["ins_effects"]["cte_trail"] == True:
chip_utils
.
log_info
(
msg
=
" Apply CTE Effect"
,
logger
=
self
.
logger
)
#
chip_utils.log_info(msg=" Apply CTE Effect", logger=self.logger)
# img = effects.CTE_Effect(GSImage=img, threshold=27)
#
# img = effects.CTE_Effect(GSImage=img, threshold=27)
# CTI_modeling
#
# CTI_modeling
# 2*8 -> 1*16 img-layout
#
# 2*8 -> 1*16 img-layout
img
=
chip_utils
.
formatOutput
(
GSImage
=
img
)
#
img = chip_utils.formatOutput(GSImage=img)
self
.
nsecy
=
1
#
self.nsecy = 1
self
.
nsecx
=
16
#
self.nsecx = 16
img_arr
=
img
.
array
#
img_arr = img.array
ny
,
nx
=
img_arr
.
shape
#
ny, nx = img_arr.shape
dx
=
int
(
nx
/
self
.
nsecx
)
#
dx = int(nx/self.nsecx)
dy
=
int
(
ny
/
self
.
nsecy
)
#
dy = int(ny/self.nsecy)
newimg
=
galsim
.
Image
(
nx
,
int
(
ny
+
over2
),
init_value
=
0
)
#
newimg = galsim.Image(nx, int(ny+over2), init_value=0)
for
ichannel
in
range
(
16
):
#
for ichannel in range(16):
print
(
'
\n
***add CTI effects: pointing-{:} chip-{:} channel-{:}***'
.
format
(
#
print('\n***add CTI effects: pointing-{:} chip-{:} channel-{:}***'.format(
pointing_ID
,
self
.
chipID
,
ichannel
+
1
))
#
pointing_ID, self.chipID, ichannel+1))
# nx,ny,noverscan,nsp,nmax = 4608,4616,84,3,10
#
# nx,ny,noverscan,nsp,nmax = 4608,4616,84,3,10
noverscan
,
nsp
,
nmax
=
over2
,
3
,
10
#
noverscan, nsp, nmax = over2, 3, 10
beta
,
w
,
c
=
0.478
,
84700
,
0
#
beta, w, c = 0.478, 84700, 0
t
=
np
.
array
([
0.74
,
7.7
,
37
],
dtype
=
np
.
float32
)
#
t = np.array([0.74, 7.7, 37], dtype=np.float32)
rho_trap
=
np
.
array
([
0.6
,
1.6
,
1.4
],
dtype
=
np
.
float32
)
#
rho_trap = np.array([0.6, 1.6, 1.4], dtype=np.float32)
trap_seeds
=
np
.
array
(
#
trap_seeds = np.array(
[
0
,
1000
,
10000
],
dtype
=
np
.
int32
)
+
ichannel
+
self
.
chipID
*
16
#
[0, 1000, 10000], dtype=np.int32) + ichannel + self.chipID*16
release_seed
=
50
+
ichannel
+
pointing_ID
*
30
+
self
.
chipID
*
16
#
release_seed = 50 + ichannel + pointing_ID*30 + self.chipID*16
newimg
.
array
[:,
0
+
ichannel
*
dx
:
dx
+
ichannel
*
dx
]
=
CTI_sim
(
#
newimg.array[:, 0+ichannel*dx:dx+ichannel*dx] = CTI_sim(
img_arr
[:,
0
+
ichannel
*
dx
:
dx
+
ichannel
*
dx
],
dx
,
dy
,
noverscan
,
nsp
,
nmax
,
beta
,
w
,
c
,
t
,
rho_trap
,
trap_seeds
,
release_seed
)
#
img_arr[:, 0+ichannel*dx:dx+ichannel*dx], dx, dy, noverscan, nsp, nmax, beta, w, c, t, rho_trap, trap_seeds, release_seed)
newimg
.
wcs
=
img
.
wcs
#
newimg.wcs = img.wcs
del
img
#
del img
img
=
newimg
#
img = newimg
# 1*16 -> 2*8 img-layout
#
# 1*16 -> 2*8 img-layout
img
=
chip_utils
.
formatRevert
(
GSImage
=
img
)
#
img = chip_utils.formatRevert(GSImage=img)
self
.
nsecy
=
2
#
self.nsecy = 2
self
.
nsecx
=
8
#
self.nsecx = 8
# prescan & overscan
#
# prescan & overscan
if
config
[
"ins_effects"
][
"add_prescan"
]
==
True
:
#
if config["ins_effects"]["add_prescan"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Apply pre/over-scan"
,
logger
=
self
.
logger
)
#
msg=" Apply pre/over-scan", logger=self.logger)
if
config
[
"ins_effects"
][
"cte_trail"
]
==
False
:
#
if config["ins_effects"]["cte_trail"] == False:
img
=
chip_utils
.
AddPreScan
(
#
img = chip_utils.AddPreScan(
GSImage
=
img
,
pre1
=
pre1
,
pre2
=
pre2
,
over1
=
over1
,
over2
=
over2
)
#
GSImage=img, pre1=pre1, pre2=pre2, over1=over1, over2=over2)
if
config
[
"ins_effects"
][
"cte_trail"
]
==
True
:
#
if config["ins_effects"]["cte_trail"] == True:
img
=
chip_utils
.
AddPreScan
(
#
img = chip_utils.AddPreScan(
GSImage
=
img
,
pre1
=
pre1
,
pre2
=
pre2
,
over1
=
over1
,
over2
=
0
)
#
GSImage=img, pre1=pre1, pre2=pre2, over1=over1, over2=0)
# 1*16 output
#
# 1*16 output
if
config
[
"ins_effects"
][
"format_output"
]
==
True
:
#
if config["ins_effects"]["format_output"] == True:
chip_utils
.
log_info
(
msg
=
" Apply 1*16 format"
,
logger
=
self
.
logger
)
#
chip_utils.log_info(msg=" Apply 1*16 format", logger=self.logger)
img
=
chip_utils
.
formatOutput
(
GSImage
=
img
)
#
img = chip_utils.formatOutput(GSImage=img)
self
.
nsecy
=
1
#
self.nsecy = 1
self
.
nsecx
=
16
#
self.nsecx = 16
# Add Bias level
#
# Add Bias level
if
config
[
"ins_effects"
][
"add_bias"
]
==
True
:
#
if config["ins_effects"]["add_bias"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Adding Bias level and 16-channel non-uniformity"
,
logger
=
self
.
logger
)
#
msg=" Adding Bias level and 16-channel non-uniformity", logger=self.logger)
if
config
[
"ins_effects"
][
"bias_16channel"
]
==
True
:
#
if config["ins_effects"]["bias_16channel"] == True:
img
=
effects
.
AddBiasNonUniform16
(
img
,
#
img = effects.AddBiasNonUniform16(img,
bias_level
=
float
(
#
bias_level=float(
self
.
bias_level
),
#
self.bias_level),
nsecy
=
self
.
nsecy
,
nsecx
=
self
.
nsecx
,
#
nsecy=self.nsecy, nsecx=self.nsecx,
seed
=
SeedBiasNonuni
+
self
.
chipID
,
#
seed=SeedBiasNonuni+self.chipID,
logger
=
self
.
logger
)
#
logger=self.logger)
elif
config
[
"ins_effects"
][
"bias_16channel"
]
==
False
:
#
elif config["ins_effects"]["bias_16channel"] == False:
img
+=
self
.
bias_level
#
img += self.bias_level
# Add Read-out Noise
#
# Add Read-out Noise
if
config
[
"ins_effects"
][
"add_readout"
]
==
True
:
#
if config["ins_effects"]["add_readout"] == True:
seed
=
int
(
config
[
"random_seeds"
][
"seed_readout"
]
#
seed = int(config["random_seeds"]["seed_readout"]
)
+
pointing_ID
*
30
+
self
.
chipID
#
) + pointing_ID*30 + self.chipID
rng_readout
=
galsim
.
BaseDeviate
(
seed
)
#
rng_readout = galsim.BaseDeviate(seed)
readout_noise
=
galsim
.
GaussianNoise
(
#
readout_noise = galsim.GaussianNoise(
rng
=
rng_readout
,
sigma
=
self
.
read_noise
)
#
rng=rng_readout, sigma=self.read_noise)
img
.
addNoise
(
readout_noise
)
#
img.addNoise(readout_noise)
# Apply Gain & Quantization
#
# Apply Gain & Quantization
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Applying Gain (and 16 channel non-uniformity) & Quantization"
,
logger
=
self
.
logger
)
#
msg=" Applying Gain (and 16 channel non-uniformity) & Quantization", logger=self.logger)
if
config
[
"ins_effects"
][
"gain_16channel"
]
==
True
:
#
if config["ins_effects"]["gain_16channel"] == True:
img
,
self
.
gain_channel
=
effects
.
ApplyGainNonUniform16
(
#
img, self.gain_channel = effects.ApplyGainNonUniform16(
img
,
gain
=
self
.
gain
,
#
img, gain=self.gain,
nsecy
=
self
.
nsecy
,
nsecx
=
self
.
nsecx
,
#
nsecy=self.nsecy, nsecx=self.nsecx,
seed
=
SeedGainNonuni
+
self
.
chipID
,
#
seed=SeedGainNonuni+self.chipID,
logger
=
self
.
logger
)
#
logger=self.logger)
elif
config
[
"ins_effects"
][
"gain_16channel"
]
==
False
:
#
elif config["ins_effects"]["gain_16channel"] == False:
img
/=
self
.
gain
#
img /= self.gain
img
.
array
[
img
.
array
>
65535
]
=
65535
#
img.array[img.array > 65535] = 65535
img
.
replaceNegative
(
replace_value
=
0
)
#
img.replaceNegative(replace_value=0)
img
.
quantize
()
#
img.quantize()
######################################################################################
#
######################################################################################
# Output images for calibration pointing
#
# Output images for calibration pointing
######################################################################################
#
######################################################################################
# Bias output
#
# Bias output
if
config
[
"ins_effects"
][
"add_bias"
]
==
True
and
config
[
"output_setting"
][
"bias_output"
]
==
True
and
pointing_type
==
'CAL'
:
#
if config["ins_effects"]["add_bias"] == True and config["output_setting"]["bias_output"] == True and pointing_type == 'CAL':
if
self
.
logger
is
not
None
:
#
if self.logger is not None:
self
.
logger
.
info
(
" Output N frame Bias files"
)
#
self.logger.info(" Output N frame Bias files")
else
:
#
else:
print
(
" Output N frame Bias files"
,
flush
=
True
)
#
print(" Output N frame Bias files", flush=True)
NBias
=
int
(
config
[
"output_setting"
][
"NBias"
])
#
NBias = int(config["output_setting"]["NBias"])
for
i
in
range
(
NBias
):
#
for i in range(NBias):
# BiasCombImg, BiasTag = effects.MakeBiasNcomb(
#
# BiasCombImg, BiasTag = effects.MakeBiasNcomb(
# self.npix_x, self.npix_y,
#
# self.npix_x, self.npix_y,
# bias_level=float(self.bias_level),
#
# bias_level=float(self.bias_level),
# ncombine=1, read_noise=self.read_noise, gain=1,
#
# ncombine=1, read_noise=self.read_noise, gain=1,
# seed=SeedBiasNonuni+self.chipID,
#
# seed=SeedBiasNonuni+self.chipID,
# logger=self.logger)
#
# logger=self.logger)
BiasCombImg
=
galsim
.
Image
(
#
BiasCombImg = galsim.Image(
self
.
npix_x
,
self
.
npix_y
,
init_value
=
0
)
#
self.npix_x, self.npix_y, init_value=0)
if
config
[
"ins_effects"
][
"add_bias"
]
==
True
:
#
if config["ins_effects"]["add_bias"] == True:
biaslevel
=
self
.
bias_level
#
biaslevel = self.bias_level
overscan
=
biaslevel
-
2
#
overscan = biaslevel-2
elif
config
[
"ins_effects"
][
"add_bias"
]
==
False
:
#
elif config["ins_effects"]["add_bias"] == False:
biaslevel
=
0
#
biaslevel = 0
overscan
=
0
#
overscan = 0
# Readout noise for Biases is not generated with random seeds. So readout noise for bias images can't be reproduced.
#
# Readout noise for Biases is not generated with random seeds. So readout noise for bias images can't be reproduced.
if
config
[
"ins_effects"
][
"cosmic_ray"
]
==
True
:
#
if config["ins_effects"]["cosmic_ray"] == True:
if
config
[
"ins_effects"
][
"cray_differ"
]
==
True
:
#
if config["ins_effects"]["cray_differ"] == True:
cr_map
,
cr_event_num
=
effects
.
produceCR_Map
(
#
cr_map, cr_event_num = effects.produceCR_Map(
xLen
=
self
.
npix_x
,
yLen
=
self
.
npix_y
,
#
xLen=self.npix_x, yLen=self.npix_y,
exTime
=
0.01
,
#
exTime=0.01,
cr_pixelRatio
=
0.003
*
#
cr_pixelRatio=0.003 *
(
0.01
+
0.5
*
self
.
readout_time
)
/
150.
,
#
(0.01+0.5*self.readout_time)/150.,
gain
=
self
.
gain
,
#
gain=self.gain,
attachedSizes
=
self
.
attachedSizes
,
#
attachedSizes=self.attachedSizes,
seed
=
SeedCosmicRay
+
pointing_ID
*
30
+
self
.
chipID
+
1
)
#
seed=SeedCosmicRay+pointing_ID*30+self.chipID+1)
# seed: obj-imaging:+0; bias:+1; dark:+2; flat:+3;
#
# seed: obj-imaging:+0; bias:+1; dark:+2; flat:+3;
BiasCombImg
+=
cr_map
#
BiasCombImg += cr_map
del
cr_map
#
del cr_map
# Apply Bad lines
#
# Apply Bad lines
if
config
[
"ins_effects"
][
"add_badcolumns"
]
==
True
:
#
if config["ins_effects"]["add_badcolumns"] == True:
BiasCombImg
=
effects
.
BadColumns
(
#
BiasCombImg = effects.BadColumns(
BiasCombImg
-
float
(
self
.
bias_level
)
+
5
,
seed
=
SeedBadColumns
,
chipid
=
self
.
chipID
,
logger
=
self
.
logger
)
+
float
(
self
.
bias_level
)
-
5
#
BiasCombImg-float(self.bias_level)+5, seed=SeedBadColumns, chipid=self.chipID, logger=self.logger) + float(self.bias_level)-5
# Non-Linearity for Bias
#
# Non-Linearity for Bias
if
config
[
"ins_effects"
][
"non_linear"
]
==
True
:
#
if config["ins_effects"]["non_linear"] == True:
if
self
.
logger
is
not
None
:
#
if self.logger is not None:
self
.
logger
.
info
(
#
self.logger.info(
" Applying Non-Linearity on the Bias image"
)
#
" Applying Non-Linearity on the Bias image")
else
:
#
else:
print
(
#
print(
" Applying Non-Linearity on the Bias image"
,
flush
=
True
)
#
" Applying Non-Linearity on the Bias image", flush=True)
BiasCombImg
=
effects
.
NonLinearity
(
#
BiasCombImg = effects.NonLinearity(
GSImage
=
BiasCombImg
,
beta1
=
5.e-7
,
beta2
=
0
)
#
GSImage=BiasCombImg, beta1=5.e-7, beta2=0)
# START
#
# START
pre1
=
self
.
prescan_x
# 27
#
pre1 = self.prescan_x # 27
over1
=
self
.
overscan_x
# 71
#
over1 = self.overscan_x # 71
pre2
=
self
.
prescan_y
# 0 #4
#
pre2 = self.prescan_y # 0 #4
over2
=
self
.
overscan_y
# 84 #80
#
over2 = self.overscan_y # 84 #80
# prescan & overscan
#
# prescan & overscan
if
config
[
"ins_effects"
][
"add_prescan"
]
==
True
:
#
if config["ins_effects"]["add_prescan"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Apply pre/over-scan"
,
logger
=
self
.
logger
)
#
msg=" Apply pre/over-scan", logger=self.logger)
BiasCombImg
=
chip_utils
.
AddPreScan
(
#
BiasCombImg = chip_utils.AddPreScan(
GSImage
=
BiasCombImg
,
pre1
=
pre1
,
pre2
=
pre2
,
over1
=
over1
,
over2
=
over2
)
#
GSImage=BiasCombImg, pre1=pre1, pre2=pre2, over1=over1, over2=over2)
# 1*16 output
#
# 1*16 output
if
config
[
"ins_effects"
][
"format_output"
]
==
True
:
#
if config["ins_effects"]["format_output"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Apply 1*16 format"
,
logger
=
self
.
logger
)
#
msg=" Apply 1*16 format", logger=self.logger)
BiasCombImg
=
chip_utils
.
formatOutput
(
GSImage
=
BiasCombImg
)
#
BiasCombImg = chip_utils.formatOutput(GSImage=BiasCombImg)
self
.
nsecy
=
1
#
self.nsecy = 1
self
.
nsecx
=
16
#
self.nsecx = 16
# END
#
# END
# Add Bias level
#
# Add Bias level
if
config
[
"ins_effects"
][
"add_bias"
]
==
True
:
#
if config["ins_effects"]["add_bias"] == True:
if
self
.
logger
is
not
None
:
#
if self.logger is not None:
self
.
logger
.
info
(
#
self.logger.info(
" Adding Bias level and 16-channel non-uniformity"
)
#
" Adding Bias level and 16-channel non-uniformity")
else
:
#
else:
print
(
" Adding Bias level and 16-channel non-uniformity"
)
#
print(" Adding Bias level and 16-channel non-uniformity")
BiasCombImg
=
effects
.
AddBiasNonUniform16
(
BiasCombImg
,
#
BiasCombImg = effects.AddBiasNonUniform16(BiasCombImg,
bias_level
=
biaslevel
,
#
bias_level=biaslevel,
nsecy
=
self
.
nsecy
,
nsecx
=
self
.
nsecx
,
#
nsecy=self.nsecy, nsecx=self.nsecx,
seed
=
SeedBiasNonuni
+
self
.
chipID
,
#
seed=SeedBiasNonuni+self.chipID,
logger
=
self
.
logger
)
#
logger=self.logger)
rng
=
galsim
.
UniformDeviate
()
#
rng = galsim.UniformDeviate()
ncombine
=
1
#
ncombine = 1
NoiseBias
=
galsim
.
GaussianNoise
(
#
NoiseBias = galsim.GaussianNoise(
rng
=
rng
,
sigma
=
self
.
read_noise
*
ncombine
**
0.5
)
#
rng=rng, sigma=self.read_noise*ncombine**0.5)
BiasCombImg
.
addNoise
(
NoiseBias
)
#
BiasCombImg.addNoise(NoiseBias)
BiasCombImg
,
self
.
gain_channel
=
effects
.
ApplyGainNonUniform16
(
BiasCombImg
,
gain
=
self
.
gain
,
#
BiasCombImg, self.gain_channel = effects.ApplyGainNonUniform16(BiasCombImg, gain=self.gain,
nsecy
=
self
.
nsecy
,
nsecx
=
self
.
nsecx
,
#
nsecy=self.nsecy, nsecx=self.nsecx,
seed
=
SeedGainNonuni
+
self
.
chipID
,
#
seed=SeedGainNonuni+self.chipID,
logger
=
self
.
logger
)
#
logger=self.logger)
# BiasCombImg = effects.AddOverscan(
#
# BiasCombImg = effects.AddOverscan(
# BiasCombImg,
#
# BiasCombImg,
# overscan=float(config["ins_effects"]["bias_level"])-2, gain=self.gain,
#
# overscan=float(config["ins_effects"]["bias_level"])-2, gain=self.gain,
# widthl=27, widthr=27, widtht=8, widthb=8)
#
# widthl=27, widthr=27, widtht=8, widthb=8)
BiasCombImg
.
replaceNegative
(
replace_value
=
0
)
#
BiasCombImg.replaceNegative(replace_value=0)
BiasCombImg
.
quantize
()
#
BiasCombImg.quantize()
BiasCombImg
=
galsim
.
ImageUS
(
BiasCombImg
)
#
BiasCombImg = galsim.ImageUS(BiasCombImg)
timestamp_obs
+=
10
*
60
#
timestamp_obs += 10 * 60
chip_utils
.
outputCal
(
#
chip_utils.outputCal(
chip
=
self
,
#
chip=self,
img
=
BiasCombImg
,
#
img=BiasCombImg,
ra_cen
=
ra_cen
,
#
ra_cen=ra_cen,
dec_cen
=
dec_cen
,
#
dec_cen=dec_cen,
img_rot
=
img_rot
,
#
img_rot=img_rot,
im_type
=
'BIAS'
,
#
im_type='BIAS',
pointing_ID
=
pointing_ID
,
#
pointing_ID=pointing_ID,
output_dir
=
chip_output
.
subdir
,
#
output_dir=chip_output.subdir,
exptime
=
0.0
,
#
exptime=0.0,
project_cycle
=
config
[
"project_cycle"
],
#
project_cycle=config["project_cycle"],
run_counter
=
config
[
"run_counter"
],
#
run_counter=config["run_counter"],
timestamp
=
timestamp_obs
)
#
timestamp=timestamp_obs)
del
BiasCombImg
#
del BiasCombImg
# Export combined (ncombine, Vignetting + PRNU) & single vignetting flat-field file
#
# Export combined (ncombine, Vignetting + PRNU) & single vignetting flat-field file
if
config
[
"ins_effects"
][
"flat_fielding"
]
==
True
and
config
[
"output_setting"
][
"flat_output"
]
==
True
and
pointing_type
==
'CAL'
:
#
if config["ins_effects"]["flat_fielding"] == True and config["output_setting"]["flat_output"] == True and pointing_type == 'CAL':
if
self
.
logger
is
not
None
:
#
if self.logger is not None:
self
.
logger
.
info
(
" Output N frame Flat-Field files"
)
#
self.logger.info(" Output N frame Flat-Field files")
else
:
#
else:
print
(
" Output N frame Flat-Field files"
,
flush
=
True
)
#
print(" Output N frame Flat-Field files", flush=True)
NFlat
=
int
(
config
[
"output_setting"
][
"NFlat"
])
#
NFlat = int(config["output_setting"]["NFlat"])
if
config
[
"ins_effects"
][
"add_bias"
]
==
True
:
#
if config["ins_effects"]["add_bias"] == True:
biaslevel
=
self
.
bias_level
#
biaslevel = self.bias_level
overscan
=
biaslevel
-
2
#
overscan = biaslevel-2
elif
config
[
"ins_effects"
][
"add_bias"
]
==
False
:
#
elif config["ins_effects"]["add_bias"] == False:
biaslevel
=
0
#
biaslevel = 0
overscan
=
0
#
overscan = 0
darklevel
=
self
.
dark_noise
*
\
#
darklevel = self.dark_noise * \
(
self
.
flat_exptime
+
0.5
*
self
.
readout_time
)
#
(self.flat_exptime+0.5*self.readout_time)
for
i
in
range
(
NFlat
):
#
for i in range(NFlat):
FlatSingle
=
flat_img
*
prnu_img
+
darklevel
#
FlatSingle = flat_img * prnu_img + darklevel
FlatCombImg
,
FlatTag
=
effects
.
MakeFlatNcomb
(
#
FlatCombImg, FlatTag = effects.MakeFlatNcomb(
flat_single_image
=
FlatSingle
,
#
flat_single_image=FlatSingle,
ncombine
=
1
,
#
ncombine=1,
read_noise
=
self
.
read_noise
,
#
read_noise=self.read_noise,
gain
=
1
,
#
gain=1,
overscan
=
overscan
,
#
overscan=overscan,
biaslevel
=
0
,
#
biaslevel=0,
seed_bias
=
SeedDefective
+
self
.
chipID
,
#
seed_bias=SeedDefective+self.chipID,
logger
=
self
.
logger
#
logger=self.logger
)
#
)
if
config
[
"ins_effects"
][
"cosmic_ray"
]
==
True
:
#
if config["ins_effects"]["cosmic_ray"] == True:
if
config
[
"ins_effects"
][
"cray_differ"
]
==
True
:
#
if config["ins_effects"]["cray_differ"] == True:
cr_map
,
cr_event_num
=
effects
.
produceCR_Map
(
#
cr_map, cr_event_num = effects.produceCR_Map(
xLen
=
self
.
npix_x
,
yLen
=
self
.
npix_y
,
#
xLen=self.npix_x, yLen=self.npix_y,
exTime
=
self
.
flat_exptime
+
0.5
*
self
.
readout_time
,
#
exTime=self.flat_exptime+0.5*self.readout_time,
cr_pixelRatio
=
0.003
*
#
cr_pixelRatio=0.003 *
(
self
.
flat_exptime
+
0.5
*
self
.
readout_time
)
/
150.
,
#
(self.flat_exptime+0.5*self.readout_time)/150.,
gain
=
self
.
gain
,
#
gain=self.gain,
attachedSizes
=
self
.
attachedSizes
,
#
attachedSizes=self.attachedSizes,
seed
=
SeedCosmicRay
+
pointing_ID
*
30
+
self
.
chipID
+
3
)
#
seed=SeedCosmicRay+pointing_ID*30+self.chipID+3)
# seed: obj-imaging:+0; bias:+1; dark:+2; flat:+3;
#
# seed: obj-imaging:+0; bias:+1; dark:+2; flat:+3;
FlatCombImg
+=
cr_map
#
FlatCombImg += cr_map
del
cr_map
#
del cr_map
# Add Hot Pixels or/and Dead Pixels
#
# Add Hot Pixels or/and Dead Pixels
rgbadpix
=
Generator
(
PCG64
(
int
(
SeedDefective
+
self
.
chipID
)))
#
rgbadpix = Generator(PCG64(int(SeedDefective+self.chipID)))
badfraction
=
5E-5
*
(
rgbadpix
.
random
()
*
0.5
+
0.7
)
#
badfraction = 5E-5*(rgbadpix.random()*0.5+0.7)
FlatCombImg
=
effects
.
DefectivePixels
(
#
FlatCombImg = effects.DefectivePixels(
FlatCombImg
,
IfHotPix
=
BoolHotPix
,
IfDeadPix
=
BoolDeadPix
,
fraction
=
badfraction
,
seed
=
SeedDefective
+
self
.
chipID
,
biaslevel
=
0
)
#
FlatCombImg, IfHotPix=BoolHotPix, IfDeadPix=BoolDeadPix, fraction=badfraction, seed=SeedDefective+self.chipID, biaslevel=0)
# Apply Bad lines
#
# Apply Bad lines
if
config
[
"ins_effects"
][
"add_badcolumns"
]
==
True
:
#
if config["ins_effects"]["add_badcolumns"] == True:
FlatCombImg
=
effects
.
BadColumns
(
#
FlatCombImg = effects.BadColumns(
FlatCombImg
,
seed
=
SeedBadColumns
,
chipid
=
self
.
chipID
,
logger
=
self
.
logger
)
#
FlatCombImg, seed=SeedBadColumns, chipid=self.chipID, logger=self.logger)
if
config
[
"ins_effects"
][
"non_linear"
]
==
True
:
#
if config["ins_effects"]["non_linear"] == True:
if
self
.
logger
is
not
None
:
#
if self.logger is not None:
self
.
logger
.
info
(
#
self.logger.info(
" Applying Non-Linearity on the Flat image"
)
#
" Applying Non-Linearity on the Flat image")
else
:
#
else:
print
(
#
print(
" Applying Non-Linearity on the Flat image"
,
flush
=
True
)
#
" Applying Non-Linearity on the Flat image", flush=True)
FlatCombImg
=
effects
.
NonLinearity
(
#
FlatCombImg = effects.NonLinearity(
GSImage
=
FlatCombImg
,
beta1
=
5.e-7
,
beta2
=
0
)
#
GSImage=FlatCombImg, beta1=5.e-7, beta2=0)
# if config["ins_effects"]["cte_trail"] == True:
#
# if config["ins_effects"]["cte_trail"] == True:
# FlatCombImg = effects.CTE_Effect(GSImage=FlatCombImg, threshold=3)
#
# FlatCombImg = effects.CTE_Effect(GSImage=FlatCombImg, threshold=3)
# START
#
# START
pre1
=
self
.
prescan_x
# 27
#
pre1 = self.prescan_x # 27
over1
=
self
.
overscan_x
# 71
#
over1 = self.overscan_x # 71
pre2
=
self
.
prescan_y
# 0 #4
#
pre2 = self.prescan_y # 0 #4
over2
=
self
.
overscan_y
# 84 #80
#
over2 = self.overscan_y # 84 #80
if
config
[
"ins_effects"
][
"cte_trail"
]
==
True
:
#
if config["ins_effects"]["cte_trail"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Apply CTE Effect"
,
logger
=
self
.
logger
)
#
msg=" Apply CTE Effect", logger=self.logger)
# img = effects.CTE_Effect(GSImage=img, threshold=27)
#
# img = effects.CTE_Effect(GSImage=img, threshold=27)
# CTI_modeling
#
# CTI_modeling
# 2*8 -> 1*16 img-layout
#
# 2*8 -> 1*16 img-layout
FlatCombImg
=
chip_utils
.
formatOutput
(
GSImage
=
FlatCombImg
)
#
FlatCombImg = chip_utils.formatOutput(GSImage=FlatCombImg)
self
.
nsecy
=
1
#
self.nsecy = 1
self
.
nsecx
=
16
#
self.nsecx = 16
img_arr
=
FlatCombImg
.
array
#
img_arr = FlatCombImg.array
ny
,
nx
=
img_arr
.
shape
#
ny, nx = img_arr.shape
dx
=
int
(
nx
/
self
.
nsecx
)
#
dx = int(nx/self.nsecx)
dy
=
int
(
ny
/
self
.
nsecy
)
#
dy = int(ny/self.nsecy)
newimg
=
galsim
.
Image
(
nx
,
int
(
ny
+
over2
),
init_value
=
0
)
#
newimg = galsim.Image(nx, int(ny+over2), init_value=0)
for
ichannel
in
range
(
16
):
#
for ichannel in range(16):
print
(
'
\n
***add CTI effects: pointing-{:} chip-{:} channel-{:}***'
.
format
(
#
print('\n***add CTI effects: pointing-{:} chip-{:} channel-{:}***'.format(
pointing_ID
,
self
.
chipID
,
ichannel
+
1
))
#
pointing_ID, self.chipID, ichannel+1))
# nx,ny,noverscan,nsp,nmax = 4608,4616,84,3,10
#
# nx,ny,noverscan,nsp,nmax = 4608,4616,84,3,10
noverscan
,
nsp
,
nmax
=
over2
,
3
,
10
#
noverscan, nsp, nmax = over2, 3, 10
beta
,
w
,
c
=
0.478
,
84700
,
0
#
beta, w, c = 0.478, 84700, 0
t
=
np
.
array
([
0.74
,
7.7
,
37
],
dtype
=
np
.
float32
)
#
t = np.array([0.74, 7.7, 37], dtype=np.float32)
rho_trap
=
np
.
array
([
0.6
,
1.6
,
1.4
],
dtype
=
np
.
float32
)
#
rho_trap = np.array([0.6, 1.6, 1.4], dtype=np.float32)
trap_seeds
=
np
.
array
(
#
trap_seeds = np.array(
[
0
,
1000
,
10000
],
dtype
=
np
.
int32
)
+
ichannel
+
self
.
chipID
*
16
#
[0, 1000, 10000], dtype=np.int32) + ichannel + self.chipID*16
release_seed
=
50
+
ichannel
+
pointing_ID
*
30
+
self
.
chipID
*
16
#
release_seed = 50 + ichannel + pointing_ID*30 + self.chipID*16
newimg
.
array
[:,
0
+
ichannel
*
dx
:
dx
+
ichannel
*
dx
]
=
CTI_sim
(
#
newimg.array[:, 0+ichannel*dx:dx+ichannel*dx] = CTI_sim(
img_arr
[:,
0
+
ichannel
*
dx
:
dx
+
ichannel
*
dx
],
dx
,
dy
,
noverscan
,
nsp
,
nmax
,
beta
,
w
,
c
,
t
,
rho_trap
,
trap_seeds
,
release_seed
)
#
img_arr[:, 0+ichannel*dx:dx+ichannel*dx], dx, dy, noverscan, nsp, nmax, beta, w, c, t, rho_trap, trap_seeds, release_seed)
newimg
.
wcs
=
FlatCombImg
.
wcs
#
newimg.wcs = FlatCombImg.wcs
del
FlatCombImg
#
del FlatCombImg
FlatCombImg
=
newimg
#
FlatCombImg = newimg
# 1*16 -> 2*8 img-layout
#
# 1*16 -> 2*8 img-layout
FlatCombImg
=
chip_utils
.
formatRevert
(
GSImage
=
FlatCombImg
)
#
FlatCombImg = chip_utils.formatRevert(GSImage=FlatCombImg)
self
.
nsecy
=
2
#
self.nsecy = 2
self
.
nsecx
=
8
#
self.nsecx = 8
# prescan & overscan
#
# prescan & overscan
if
config
[
"ins_effects"
][
"add_prescan"
]
==
True
:
#
if config["ins_effects"]["add_prescan"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Apply pre/over-scan"
,
logger
=
self
.
logger
)
#
msg=" Apply pre/over-scan", logger=self.logger)
if
config
[
"ins_effects"
][
"cte_trail"
]
==
False
:
#
if config["ins_effects"]["cte_trail"] == False:
FlatCombImg
=
chip_utils
.
AddPreScan
(
#
FlatCombImg = chip_utils.AddPreScan(
GSImage
=
FlatCombImg
,
pre1
=
pre1
,
pre2
=
pre2
,
over1
=
over1
,
over2
=
over2
)
#
GSImage=FlatCombImg, pre1=pre1, pre2=pre2, over1=over1, over2=over2)
if
config
[
"ins_effects"
][
"cte_trail"
]
==
True
:
#
if config["ins_effects"]["cte_trail"] == True:
FlatCombImg
=
chip_utils
.
AddPreScan
(
#
FlatCombImg = chip_utils.AddPreScan(
GSImage
=
FlatCombImg
,
pre1
=
pre1
,
pre2
=
pre2
,
over1
=
over1
,
over2
=
0
)
#
GSImage=FlatCombImg, pre1=pre1, pre2=pre2, over1=over1, over2=0)
# 1*16 output
#
# 1*16 output
if
config
[
"ins_effects"
][
"format_output"
]
==
True
:
#
if config["ins_effects"]["format_output"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Apply 1*16 format"
,
logger
=
self
.
logger
)
#
msg=" Apply 1*16 format", logger=self.logger)
FlatCombImg
=
chip_utils
.
formatOutput
(
GSImage
=
FlatCombImg
)
#
FlatCombImg = chip_utils.formatOutput(GSImage=FlatCombImg)
self
.
nsecy
=
1
#
self.nsecy = 1
self
.
nsecx
=
16
#
self.nsecx = 16
# END
#
# END
# Add Bias level
#
# Add Bias level
if
config
[
"ins_effects"
][
"add_bias"
]
==
True
:
#
if config["ins_effects"]["add_bias"] == True:
if
self
.
logger
is
not
None
:
#
if self.logger is not None:
self
.
logger
.
info
(
#
self.logger.info(
" Adding Bias level and 16-channel non-uniformity"
)
#
" Adding Bias level and 16-channel non-uniformity")
else
:
#
else:
print
(
" Adding Bias level and 16-channel non-uniformity"
)
#
print(" Adding Bias level and 16-channel non-uniformity")
# img += float(config["ins_effects"]["bias_level"])
#
# img += float(config["ins_effects"]["bias_level"])
FlatCombImg
=
effects
.
AddBiasNonUniform16
(
FlatCombImg
,
#
FlatCombImg = effects.AddBiasNonUniform16(FlatCombImg,
bias_level
=
biaslevel
,
#
bias_level=biaslevel,
nsecy
=
self
.
nsecy
,
nsecx
=
self
.
nsecx
,
#
nsecy=self.nsecy, nsecx=self.nsecx,
seed
=
SeedBiasNonuni
+
self
.
chipID
,
#
seed=SeedBiasNonuni+self.chipID,
logger
=
self
.
logger
)
#
logger=self.logger)
# Add Read-out Noise
#
# Add Read-out Noise
if
config
[
"ins_effects"
][
"add_readout"
]
==
True
:
#
if config["ins_effects"]["add_readout"] == True:
seed
=
int
(
config
[
"random_seeds"
][
"seed_readout"
]
#
seed = int(config["random_seeds"]["seed_readout"]
)
+
pointing_ID
*
30
+
self
.
chipID
+
3
#
) + pointing_ID*30 + self.chipID + 3
rng_readout
=
galsim
.
BaseDeviate
(
seed
)
#
rng_readout = galsim.BaseDeviate(seed)
readout_noise
=
galsim
.
GaussianNoise
(
#
readout_noise = galsim.GaussianNoise(
rng
=
rng_readout
,
sigma
=
self
.
read_noise
)
#
rng=rng_readout, sigma=self.read_noise)
FlatCombImg
.
addNoise
(
readout_noise
)
#
FlatCombImg.addNoise(readout_noise)
FlatCombImg
,
self
.
gain_channel
=
effects
.
ApplyGainNonUniform16
(
FlatCombImg
,
gain
=
self
.
gain
,
#
FlatCombImg, self.gain_channel = effects.ApplyGainNonUniform16(FlatCombImg, gain=self.gain,
nsecy
=
self
.
nsecy
,
nsecx
=
self
.
nsecx
,
#
nsecy=self.nsecy, nsecx=self.nsecx,
seed
=
SeedGainNonuni
+
self
.
chipID
,
#
seed=SeedGainNonuni+self.chipID,
logger
=
self
.
logger
)
#
logger=self.logger)
# FlatCombImg = effects.AddOverscan(FlatCombImg, overscan=overscan, gain=self.gain, widthl=27, widthr=27, widtht=8, widthb=8)
#
# FlatCombImg = effects.AddOverscan(FlatCombImg, overscan=overscan, gain=self.gain, widthl=27, widthr=27, widtht=8, widthb=8)
FlatCombImg
.
replaceNegative
(
replace_value
=
0
)
#
FlatCombImg.replaceNegative(replace_value=0)
FlatCombImg
.
quantize
()
#
FlatCombImg.quantize()
FlatCombImg
=
galsim
.
ImageUS
(
FlatCombImg
)
#
FlatCombImg = galsim.ImageUS(FlatCombImg)
timestamp_obs
+=
10
*
60
#
timestamp_obs += 10 * 60
chip_utils
.
outputCal
(
#
chip_utils.outputCal(
chip
=
self
,
#
chip=self,
img
=
FlatCombImg
,
#
img=FlatCombImg,
ra_cen
=
ra_cen
,
#
ra_cen=ra_cen,
dec_cen
=
dec_cen
,
#
dec_cen=dec_cen,
img_rot
=
img_rot
,
#
img_rot=img_rot,
im_type
=
'FLAT'
,
#
im_type='FLAT',
pointing_ID
=
pointing_ID
,
#
pointing_ID=pointing_ID,
output_dir
=
chip_output
.
subdir
,
#
output_dir=chip_output.subdir,
exptime
=
self
.
flat_exptime
,
#
exptime=self.flat_exptime,
project_cycle
=
config
[
"project_cycle"
],
#
project_cycle=config["project_cycle"],
run_counter
=
config
[
"run_counter"
],
#
run_counter=config["run_counter"],
timestamp
=
timestamp_obs
)
#
timestamp=timestamp_obs)
del
FlatCombImg
,
FlatSingle
,
prnu_img
#
del FlatCombImg, FlatSingle, prnu_img
# flat_img.replaceNegative(replace_value=0)
#
# flat_img.replaceNegative(replace_value=0)
# flat_img.quantize()
#
# flat_img.quantize()
# galsim.ImageUS(flat_img).write("%s/FlatImg_Vignette_%s.fits" % (chip_output.subdir, self.chipID))
#
# galsim.ImageUS(flat_img).write("%s/FlatImg_Vignette_%s.fits" % (chip_output.subdir, self.chipID))
del
flat_img
#
del flat_img
# Export Dark current images
#
# Export Dark current images
if
config
[
"ins_effects"
][
"add_dark"
]
==
True
and
config
[
"output_setting"
][
"dark_output"
]
==
True
and
pointing_type
==
'CAL'
:
#
if config["ins_effects"]["add_dark"] == True and config["output_setting"]["dark_output"] == True and pointing_type == 'CAL':
if
self
.
logger
is
not
None
:
#
if self.logger is not None:
self
.
logger
.
info
(
" Output N frame Dark Current files"
)
#
self.logger.info(" Output N frame Dark Current files")
else
:
#
else:
print
(
" Output N frame Dark Current files"
,
flush
=
True
)
#
print(" Output N frame Dark Current files", flush=True)
NDark
=
int
(
config
[
"output_setting"
][
"NDark"
])
#
NDark = int(config["output_setting"]["NDark"])
if
config
[
"ins_effects"
][
"add_bias"
]
==
True
:
#
if config["ins_effects"]["add_bias"] == True:
biaslevel
=
self
.
bias_level
#
biaslevel = self.bias_level
overscan
=
biaslevel
-
2
#
overscan = biaslevel-2
elif
config
[
"ins_effects"
][
"add_bias"
]
==
False
:
#
elif config["ins_effects"]["add_bias"] == False:
biaslevel
=
0
#
biaslevel = 0
overscan
=
0
#
overscan = 0
for
i
in
range
(
NDark
):
#
for i in range(NDark):
DarkCombImg
,
DarkTag
=
effects
.
MakeDarkNcomb
(
#
DarkCombImg, DarkTag = effects.MakeDarkNcomb(
self
.
npix_x
,
self
.
npix_y
,
#
self.npix_x, self.npix_y,
overscan
=
overscan
,
bias_level
=
0
,
darkpsec
=
0.02
,
exptime
=
self
.
dark_exptime
+
0.5
*
self
.
readout_time
,
#
overscan=overscan, bias_level=0, darkpsec=0.02, exptime=self.dark_exptime+0.5*self.readout_time,
ncombine
=
1
,
read_noise
=
self
.
read_noise
,
#
ncombine=1, read_noise=self.read_noise,
gain
=
1
,
seed_bias
=
SeedBiasNonuni
+
self
.
chipID
,
#
gain=1, seed_bias=SeedBiasNonuni+self.chipID,
logger
=
self
.
logger
)
#
logger=self.logger)
if
config
[
"ins_effects"
][
"cosmic_ray"
]
==
True
:
#
if config["ins_effects"]["cosmic_ray"] == True:
if
config
[
"ins_effects"
][
"cray_differ"
]
==
True
:
#
if config["ins_effects"]["cray_differ"] == True:
cr_map
,
cr_event_num
=
effects
.
produceCR_Map
(
#
cr_map, cr_event_num = effects.produceCR_Map(
xLen
=
self
.
npix_x
,
yLen
=
self
.
npix_y
,
#
xLen=self.npix_x, yLen=self.npix_y,
exTime
=
self
.
dark_exptime
+
0.5
*
self
.
readout_time
,
#
exTime=self.dark_exptime+0.5*self.readout_time,
cr_pixelRatio
=
0.003
*
#
cr_pixelRatio=0.003 *
(
self
.
dark_exptime
+
0.5
*
self
.
readout_time
)
/
150.
,
#
(self.dark_exptime+0.5*self.readout_time)/150.,
gain
=
self
.
gain
,
#
gain=self.gain,
attachedSizes
=
self
.
attachedSizes
,
#
attachedSizes=self.attachedSizes,
seed
=
SeedCosmicRay
+
pointing_ID
*
30
+
self
.
chipID
+
2
)
#
seed=SeedCosmicRay+pointing_ID*30+self.chipID+2)
# seed: obj-imaging:+0; bias:+1; dark:+2; flat:+3;
#
# seed: obj-imaging:+0; bias:+1; dark:+2; flat:+3;
DarkCombImg
+=
cr_map
#
DarkCombImg += cr_map
cr_map
[
cr_map
>
65535
]
=
65535
#
cr_map[cr_map > 65535] = 65535
cr_map
[
cr_map
<
0
]
=
0
#
cr_map[cr_map < 0] = 0
crmap_gsimg
=
galsim
.
Image
(
cr_map
,
dtype
=
np
.
uint16
)
#
crmap_gsimg = galsim.Image(cr_map, dtype=np.uint16)
del
cr_map
#
del cr_map
# START
#
# START
# prescan & overscan
#
# prescan & overscan
if
config
[
"ins_effects"
][
"add_prescan"
]
==
True
:
#
if config["ins_effects"]["add_prescan"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Apply pre/over-scan"
,
logger
=
self
.
logger
)
#
msg=" Apply pre/over-scan", logger=self.logger)
crmap_gsimg
=
chip_utils
.
AddPreScan
(
#
crmap_gsimg = chip_utils.AddPreScan(
GSImage
=
crmap_gsimg
,
pre1
=
pre1
,
pre2
=
pre2
,
over1
=
over1
,
over2
=
over2
)
#
GSImage=crmap_gsimg, pre1=pre1, pre2=pre2, over1=over1, over2=over2)
# 1*16 output
#
# 1*16 output
if
config
[
"ins_effects"
][
"format_output"
]
==
True
:
#
if config["ins_effects"]["format_output"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Apply 1*16 format"
,
logger
=
self
.
logger
)
#
msg=" Apply 1*16 format", logger=self.logger)
crmap_gsimg
=
chip_utils
.
formatOutput
(
#
crmap_gsimg = chip_utils.formatOutput(
GSImage
=
crmap_gsimg
)
#
GSImage=crmap_gsimg)
self
.
nsecy
=
1
#
self.nsecy = 1
self
.
nsecx
=
16
#
self.nsecx = 16
# END
#
# END
chip_utils
.
outputCal
(
#
chip_utils.outputCal(
chip
=
self
,
#
chip=self,
img
=
crmap_gsimg
,
#
img=crmap_gsimg,
ra_cen
=
ra_cen
,
#
ra_cen=ra_cen,
dec_cen
=
dec_cen
,
#
dec_cen=dec_cen,
img_rot
=
img_rot
,
#
img_rot=img_rot,
im_type
=
'CRD'
,
#
im_type='CRD',
pointing_ID
=
pointing_ID
,
#
pointing_ID=pointing_ID,
output_dir
=
chip_output
.
subdir
,
#
output_dir=chip_output.subdir,
exptime
=
self
.
dark_exptime
,
#
exptime=self.dark_exptime,
project_cycle
=
config
[
"project_cycle"
],
#
project_cycle=config["project_cycle"],
run_counter
=
config
[
"run_counter"
],
#
run_counter=config["run_counter"],
timestamp
=
timestamp_obs
)
#
timestamp=timestamp_obs)
del
crmap_gsimg
#
del crmap_gsimg
# Add Hot Pixels or/and Dead Pixels
#
# Add Hot Pixels or/and Dead Pixels
rgbadpix
=
Generator
(
PCG64
(
int
(
SeedDefective
+
self
.
chipID
)))
#
rgbadpix = Generator(PCG64(int(SeedDefective+self.chipID)))
badfraction
=
5E-5
*
(
rgbadpix
.
random
()
*
0.5
+
0.7
)
#
badfraction = 5E-5*(rgbadpix.random()*0.5+0.7)
DarkCombImg
=
effects
.
DefectivePixels
(
#
DarkCombImg = effects.DefectivePixels(
DarkCombImg
,
IfHotPix
=
BoolHotPix
,
IfDeadPix
=
BoolDeadPix
,
fraction
=
badfraction
,
seed
=
SeedDefective
+
self
.
chipID
,
biaslevel
=
0
)
#
DarkCombImg, IfHotPix=BoolHotPix, IfDeadPix=BoolDeadPix, fraction=badfraction, seed=SeedDefective+self.chipID, biaslevel=0)
# Apply Bad lines
#
# Apply Bad lines
if
config
[
"ins_effects"
][
"add_badcolumns"
]
==
True
:
#
if config["ins_effects"]["add_badcolumns"] == True:
DarkCombImg
=
effects
.
BadColumns
(
#
DarkCombImg = effects.BadColumns(
DarkCombImg
,
seed
=
SeedBadColumns
,
chipid
=
self
.
chipID
,
logger
=
self
.
logger
)
#
DarkCombImg, seed=SeedBadColumns, chipid=self.chipID, logger=self.logger)
# Non-Linearity for Dark
#
# Non-Linearity for Dark
if
config
[
"ins_effects"
][
"non_linear"
]
==
True
:
#
if config["ins_effects"]["non_linear"] == True:
if
self
.
logger
is
not
None
:
#
if self.logger is not None:
self
.
logger
.
info
(
#
self.logger.info(
" Applying Non-Linearity on the Dark image"
)
#
" Applying Non-Linearity on the Dark image")
else
:
#
else:
print
(
#
print(
" Applying Non-Linearity on the Dark image"
,
flush
=
True
)
#
" Applying Non-Linearity on the Dark image", flush=True)
DarkCombImg
=
effects
.
NonLinearity
(
#
DarkCombImg = effects.NonLinearity(
GSImage
=
DarkCombImg
,
beta1
=
5.e-7
,
beta2
=
0
)
#
GSImage=DarkCombImg, beta1=5.e-7, beta2=0)
# if config["ins_effects"]["cte_trail"] == True:
#
# if config["ins_effects"]["cte_trail"] == True:
# DarkCombImg = effects.CTE_Effect(GSImage=DarkCombImg, threshold=3)
#
# DarkCombImg = effects.CTE_Effect(GSImage=DarkCombImg, threshold=3)
# START
#
# START
pre1
=
self
.
prescan_x
# 27
#
pre1 = self.prescan_x # 27
over1
=
self
.
overscan_x
# 71
#
over1 = self.overscan_x # 71
pre2
=
self
.
prescan_y
# 0 #4
#
pre2 = self.prescan_y # 0 #4
over2
=
self
.
overscan_y
# 84 #80
#
over2 = self.overscan_y # 84 #80
if
config
[
"ins_effects"
][
"cte_trail"
]
==
True
:
#
if config["ins_effects"]["cte_trail"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Apply CTE Effect"
,
logger
=
self
.
logger
)
#
msg=" Apply CTE Effect", logger=self.logger)
# img = effects.CTE_Effect(GSImage=img, threshold=27)
#
# img = effects.CTE_Effect(GSImage=img, threshold=27)
# CTI_modeling
#
# CTI_modeling
# 2*8 -> 1*16 img-layout
#
# 2*8 -> 1*16 img-layout
DarkCombImg
=
chip_utils
.
formatOutput
(
GSImage
=
DarkCombImg
)
#
DarkCombImg = chip_utils.formatOutput(GSImage=DarkCombImg)
self
.
nsecy
=
1
#
self.nsecy = 1
self
.
nsecx
=
16
#
self.nsecx = 16
img_arr
=
DarkCombImg
.
array
#
img_arr = DarkCombImg.array
ny
,
nx
=
img_arr
.
shape
#
ny, nx = img_arr.shape
dx
=
int
(
nx
/
self
.
nsecx
)
#
dx = int(nx/self.nsecx)
dy
=
int
(
ny
/
self
.
nsecy
)
#
dy = int(ny/self.nsecy)
newimg
=
galsim
.
Image
(
nx
,
int
(
ny
+
over2
),
init_value
=
0
)
#
newimg = galsim.Image(nx, int(ny+over2), init_value=0)
for
ichannel
in
range
(
16
):
#
for ichannel in range(16):
print
(
'
\n
***add CTI effects: pointing-{:} chip-{:} channel-{:}***'
.
format
(
#
print('\n***add CTI effects: pointing-{:} chip-{:} channel-{:}***'.format(
pointing_ID
,
self
.
chipID
,
ichannel
+
1
))
#
pointing_ID, self.chipID, ichannel+1))
# nx,ny,noverscan,nsp,nmax = 4608,4616,84,3,10
#
# nx,ny,noverscan,nsp,nmax = 4608,4616,84,3,10
noverscan
,
nsp
,
nmax
=
over2
,
3
,
10
#
noverscan, nsp, nmax = over2, 3, 10
beta
,
w
,
c
=
0.478
,
84700
,
0
#
beta, w, c = 0.478, 84700, 0
t
=
np
.
array
([
0.74
,
7.7
,
37
],
dtype
=
np
.
float32
)
#
t = np.array([0.74, 7.7, 37], dtype=np.float32)
rho_trap
=
np
.
array
([
0.6
,
1.6
,
1.4
],
dtype
=
np
.
float32
)
#
rho_trap = np.array([0.6, 1.6, 1.4], dtype=np.float32)
trap_seeds
=
np
.
array
(
#
trap_seeds = np.array(
[
0
,
1000
,
10000
],
dtype
=
np
.
int32
)
+
ichannel
+
self
.
chipID
*
16
#
[0, 1000, 10000], dtype=np.int32) + ichannel + self.chipID*16
release_seed
=
50
+
ichannel
+
pointing_ID
*
30
+
self
.
chipID
*
16
#
release_seed = 50 + ichannel + pointing_ID*30 + self.chipID*16
newimg
.
array
[:,
0
+
ichannel
*
dx
:
dx
+
ichannel
*
dx
]
=
CTI_sim
(
#
newimg.array[:, 0+ichannel*dx:dx+ichannel*dx] = CTI_sim(
img_arr
[:,
0
+
ichannel
*
dx
:
dx
+
ichannel
*
dx
],
dx
,
dy
,
noverscan
,
nsp
,
nmax
,
beta
,
w
,
c
,
t
,
rho_trap
,
trap_seeds
,
release_seed
)
#
img_arr[:, 0+ichannel*dx:dx+ichannel*dx], dx, dy, noverscan, nsp, nmax, beta, w, c, t, rho_trap, trap_seeds, release_seed)
newimg
.
wcs
=
DarkCombImg
.
wcs
#
newimg.wcs = DarkCombImg.wcs
del
DarkCombImg
#
del DarkCombImg
DarkCombImg
=
newimg
#
DarkCombImg = newimg
# 1*16 -> 2*8 img-layout
#
# 1*16 -> 2*8 img-layout
DarkCombImg
=
chip_utils
.
formatRevert
(
GSImage
=
DarkCombImg
)
#
DarkCombImg = chip_utils.formatRevert(GSImage=DarkCombImg)
self
.
nsecy
=
2
#
self.nsecy = 2
self
.
nsecx
=
8
#
self.nsecx = 8
# prescan & overscan
#
# prescan & overscan
if
config
[
"ins_effects"
][
"add_prescan"
]
==
True
:
#
if config["ins_effects"]["add_prescan"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Apply pre/over-scan"
,
logger
=
self
.
logger
)
#
msg=" Apply pre/over-scan", logger=self.logger)
if
config
[
"ins_effects"
][
"cte_trail"
]
==
False
:
#
if config["ins_effects"]["cte_trail"] == False:
DarkCombImg
=
chip_utils
.
AddPreScan
(
#
DarkCombImg = chip_utils.AddPreScan(
GSImage
=
DarkCombImg
,
pre1
=
pre1
,
pre2
=
pre2
,
over1
=
over1
,
over2
=
over2
)
#
GSImage=DarkCombImg, pre1=pre1, pre2=pre2, over1=over1, over2=over2)
if
config
[
"ins_effects"
][
"cte_trail"
]
==
True
:
#
if config["ins_effects"]["cte_trail"] == True:
DarkCombImg
=
chip_utils
.
AddPreScan
(
#
DarkCombImg = chip_utils.AddPreScan(
GSImage
=
DarkCombImg
,
pre1
=
pre1
,
pre2
=
pre2
,
over1
=
over1
,
over2
=
0
)
#
GSImage=DarkCombImg, pre1=pre1, pre2=pre2, over1=over1, over2=0)
# 1*16 output
#
# 1*16 output
if
config
[
"ins_effects"
][
"format_output"
]
==
True
:
#
if config["ins_effects"]["format_output"] == True:
chip_utils
.
log_info
(
#
chip_utils.log_info(
msg
=
" Apply 1*16 format"
,
logger
=
self
.
logger
)
#
msg=" Apply 1*16 format", logger=self.logger)
DarkCombImg
=
chip_utils
.
formatOutput
(
GSImage
=
DarkCombImg
)
#
DarkCombImg = chip_utils.formatOutput(GSImage=DarkCombImg)
self
.
nsecy
=
1
#
self.nsecy = 1
self
.
nsecx
=
16
#
self.nsecx = 16
# END
#
# END
# Add Bias level
#
# Add Bias level
if
config
[
"ins_effects"
][
"add_bias"
]
==
True
:
#
if config["ins_effects"]["add_bias"] == True:
if
self
.
logger
is
not
None
:
#
if self.logger is not None:
self
.
logger
.
info
(
#
self.logger.info(
" Adding Bias level and 16-channel non-uniformity"
)
#
" Adding Bias level and 16-channel non-uniformity")
else
:
#
else:
print
(
" Adding Bias level and 16-channel non-uniformity"
)
#
print(" Adding Bias level and 16-channel non-uniformity")
# img += float(config["ins_effects"]["bias_level"])
#
# img += float(config["ins_effects"]["bias_level"])
DarkCombImg
=
effects
.
AddBiasNonUniform16
(
DarkCombImg
,
#
DarkCombImg = effects.AddBiasNonUniform16(DarkCombImg,
bias_level
=
biaslevel
,
#
bias_level=biaslevel,
nsecy
=
self
.
nsecy
,
nsecx
=
self
.
nsecx
,
#
nsecy=self.nsecy, nsecx=self.nsecx,
seed
=
SeedBiasNonuni
+
self
.
chipID
,
#
seed=SeedBiasNonuni+self.chipID,
logger
=
self
.
logger
)
#
logger=self.logger)
# Add Read-out Noise
#
# Add Read-out Noise
if
config
[
"ins_effects"
][
"add_readout"
]
==
True
:
#
if config["ins_effects"]["add_readout"] == True:
seed
=
int
(
config
[
"random_seeds"
][
"seed_readout"
]
#
seed = int(config["random_seeds"]["seed_readout"]
)
+
pointing_ID
*
30
+
self
.
chipID
+
2
#
) + pointing_ID*30 + self.chipID + 2
rng_readout
=
galsim
.
BaseDeviate
(
seed
)
#
rng_readout = galsim.BaseDeviate(seed)
readout_noise
=
galsim
.
GaussianNoise
(
#
readout_noise = galsim.GaussianNoise(
rng
=
rng_readout
,
sigma
=
self
.
read_noise
)
#
rng=rng_readout, sigma=self.read_noise)
DarkCombImg
.
addNoise
(
readout_noise
)
#
DarkCombImg.addNoise(readout_noise)
DarkCombImg
,
self
.
gain_channel
=
effects
.
ApplyGainNonUniform16
(
#
DarkCombImg, self.gain_channel = effects.ApplyGainNonUniform16(
DarkCombImg
,
gain
=
self
.
gain
,
#
DarkCombImg, gain=self.gain,
nsecy
=
self
.
nsecy
,
nsecx
=
self
.
nsecx
,
#
nsecy=self.nsecy, nsecx=self.nsecx,
seed
=
SeedGainNonuni
+
self
.
chipID
,
#
seed=SeedGainNonuni+self.chipID,
logger
=
self
.
logger
)
#
logger=self.logger)
# DarkCombImg = effects.AddOverscan(
#
# DarkCombImg = effects.AddOverscan(
# DarkCombImg,
#
# DarkCombImg,
# overscan=overscan, gain=self.gain,
#
# overscan=overscan, gain=self.gain,
# widthl=27, widthr=27, widtht=8, widthb=8)
#
# widthl=27, widthr=27, widtht=8, widthb=8)
DarkCombImg
.
replaceNegative
(
replace_value
=
0
)
#
DarkCombImg.replaceNegative(replace_value=0)
DarkCombImg
.
quantize
()
#
DarkCombImg.quantize()
DarkCombImg
=
galsim
.
ImageUS
(
DarkCombImg
)
#
DarkCombImg = galsim.ImageUS(DarkCombImg)
timestamp_obs
+=
10
*
60
#
timestamp_obs += 10 * 60
chip_utils
.
outputCal
(
#
chip_utils.outputCal(
chip
=
self
,
#
chip=self,
img
=
DarkCombImg
,
#
img=DarkCombImg,
ra_cen
=
ra_cen
,
#
ra_cen=ra_cen,
dec_cen
=
dec_cen
,
#
dec_cen=dec_cen,
img_rot
=
img_rot
,
#
img_rot=img_rot,
im_type
=
'DARK'
,
#
im_type='DARK',
pointing_ID
=
pointing_ID
,
#
pointing_ID=pointing_ID,
output_dir
=
chip_output
.
subdir
,
#
output_dir=chip_output.subdir,
exptime
=
self
.
dark_exptime
,
#
exptime=self.dark_exptime,
project_cycle
=
config
[
"project_cycle"
],
#
project_cycle=config["project_cycle"],
run_counter
=
config
[
"run_counter"
],
#
run_counter=config["run_counter"],
timestamp
=
timestamp_obs
)
#
timestamp=timestamp_obs)
del
DarkCombImg
#
del DarkCombImg
# img = galsim.ImageUS(img)
#
# img = galsim.ImageUS(img)
# # 16 output channel, with each a single image file
#
# # 16 output channel, with each a single image file
# if config["ins_effects"]["readout16"] == True:
#
# if config["ins_effects"]["readout16"] == True:
# print(" 16 Output Channel simulation")
#
# print(" 16 Output Channel simulation")
# for coli in [0, 1]:
#
# for coli in [0, 1]:
# for rowi in range(8):
#
# for rowi in range(8):
# sub_img = effects.readout16(
#
# sub_img = effects.readout16(
# GSImage=img,
#
# GSImage=img,
# rowi=rowi,
#
# rowi=rowi,
# coli=coli,
#
# coli=coli,
# overscan_value=self.overscan)
#
# overscan_value=self.overscan)
# rowcoltag = str(rowi) + str(coli)
#
# rowcoltag = str(rowi) + str(coli)
# img_name_root = chip_output.img_name.split(".")[0]
#
# img_name_root = chip_output.img_name.split(".")[0]
# sub_img.write("%s/%s_%s.fits" % (chip_output.subdir, img_name_root, rowcoltag))
#
# sub_img.write("%s/%s_%s.fits" % (chip_output.subdir, img_name_root, rowcoltag))
# del sub_img
#
# del sub_img
return
img
#
return img
ObservationSim/Instrument/FocalPlane.py
View file @
885d85b2
import
galsim
import
galsim
import
numpy
as
np
import
numpy
as
np
class
FocalPlane
(
object
):
class
FocalPlane
(
object
):
def
__init__
(
self
,
config
=
None
,
chip_list
=
None
,
survey_type
=
'Photometric'
,
bad_chips
=
None
):
def
__init__
(
self
,
chip_list
=
None
,
survey_type
=
'Photometric'
,
bad_chips
=
None
):
"""Get the focal plane layout
"""Get the focal plane layout
"""
"""
self
.
nchips
=
42
self
.
nchips
=
42
...
@@ -14,7 +15,7 @@ class FocalPlane(object):
...
@@ -14,7 +15,7 @@ class FocalPlane(object):
self
.
bad_chips
=
bad_chips
self
.
bad_chips
=
bad_chips
for
chip_id
in
bad_chips
:
for
chip_id
in
bad_chips
:
self
.
ignore_chips
.
append
(
chip_id
)
self
.
ignore_chips
.
append
(
chip_id
)
if
chip_list
is
not
None
:
if
chip_list
is
not
None
:
for
i
in
range
(
42
):
for
i
in
range
(
42
):
if
not
(
i
+
1
in
chip_list
):
if
not
(
i
+
1
in
chip_list
):
...
@@ -39,25 +40,25 @@ class FocalPlane(object):
...
@@ -39,25 +40,25 @@ class FocalPlane(object):
for
i
in
range
(
1
,
31
):
for
i
in
range
(
1
,
31
):
self
.
ignore_chips
.
append
(
i
)
self
.
ignore_chips
.
append
(
i
)
if
config
is
not
None
:
#
if config is not None:
self
.
nchip_x
=
config
[
"nchip_x"
]
#
self.nchip_x = config["nchip_x"]
self
.
nchip_y
=
config
[
"nchip_y"
]
#
self.nchip_y = config["nchip_y"]
self
.
npix_tot_x
=
config
[
"npix_tot_x"
]
#
self.npix_tot_x = config["npix_tot_x"]
self
.
npix_tot_y
=
config
[
"npix_tot_y"
]
#
self.npix_tot_y = config["npix_tot_y"]
self
.
npix_gap_x
=
config
[
"npix_gap_x"
]
#
self.npix_gap_x = config["npix_gap_x"]
self
.
npix_gap_y
=
config
[
"npix_gap_y"
]
#
self.npix_gap_y = config["npix_gap_y"]
if
"chipLabelIDs"
in
config
:
#
if "chipLabelIDs" in config:
self
.
chipLabelIDs
=
config
[
"chipLabelIDs"
]
#
self.chipLabelIDs = config["chipLabelIDs"]
if
"bad_chips"
in
config
:
#
if "bad_chips" in config:
self
.
bad_chips
=
config
[
"bad_chips"
]
#
self.bad_chips = config["bad_chips"]
else
:
#
else:
self
.
nchip_x
=
6
self
.
nchip_x
=
6
self
.
nchip_y
=
5
self
.
nchip_y
=
5
self
.
npix_tot_x
=
59516
self
.
npix_tot_x
=
59516
self
.
npix_tot_y
=
49752
self
.
npix_tot_y
=
49752
self
.
npix_gap_x
=
(
534
,
1309
)
self
.
npix_gap_x
=
(
534
,
1309
)
self
.
npix_gap_y
=
898
self
.
npix_gap_y
=
898
self
.
_getCenter
()
self
.
_getCenter
()
def
_getCenter
(
self
):
def
_getCenter
(
self
):
...
@@ -65,7 +66,7 @@ class FocalPlane(object):
...
@@ -65,7 +66,7 @@ class FocalPlane(object):
self
.
cen_pix_y
=
0
self
.
cen_pix_y
=
0
def
getChipLabel
(
self
,
chipID
):
def
getChipLabel
(
self
,
chipID
):
return
str
(
"0%d"
%
chipID
)[
-
2
:]
return
str
(
"0%d"
%
chipID
)[
-
2
:]
def
isBadChip
(
self
,
chipID
):
def
isBadChip
(
self
,
chipID
):
"""Check if chip #(chipID) on the focal plane is bad or not
"""Check if chip #(chipID) on the focal plane is bad or not
...
@@ -89,7 +90,8 @@ class FocalPlane(object):
...
@@ -89,7 +90,8 @@ class FocalPlane(object):
WCS of the focal plane
WCS of the focal plane
"""
"""
if
logger
is
not
None
:
if
logger
is
not
None
:
logger
.
info
(
" Construct the wcs of the entire image mosaic using Gnomonic/TAN projection"
)
logger
.
info
(
" Construct the wcs of the entire image mosaic using Gnomonic/TAN projection"
)
if
(
xcen
==
None
)
or
(
ycen
==
None
):
if
(
xcen
==
None
)
or
(
ycen
==
None
):
xcen
=
self
.
cen_pix_x
xcen
=
self
.
cen_pix_x
ycen
=
self
.
cen_pix_y
ycen
=
self
.
cen_pix_y
...
@@ -98,13 +100,14 @@ class FocalPlane(object):
...
@@ -98,13 +100,14 @@ class FocalPlane(object):
# dvdx = -np.sin(img_rot.rad) * pix_scale
# dvdx = -np.sin(img_rot.rad) * pix_scale
# dvdy = +np.cos(img_rot.rad) * pix_scale
# dvdy = +np.cos(img_rot.rad) * pix_scale
dudx
=
-
np
.
cos
(
img_rot
.
rad
)
*
pix_scale
dudx
=
-
np
.
cos
(
img_rot
.
rad
)
*
pix_scale
dudy
=
+
np
.
sin
(
img_rot
.
rad
)
*
pix_scale
dudy
=
+
np
.
sin
(
img_rot
.
rad
)
*
pix_scale
dvdx
=
-
np
.
sin
(
img_rot
.
rad
)
*
pix_scale
dvdx
=
-
np
.
sin
(
img_rot
.
rad
)
*
pix_scale
dvdy
=
-
np
.
cos
(
img_rot
.
rad
)
*
pix_scale
dvdy
=
-
np
.
cos
(
img_rot
.
rad
)
*
pix_scale
moscen
=
galsim
.
PositionD
(
x
=
xcen
,
y
=
ycen
)
moscen
=
galsim
.
PositionD
(
x
=
xcen
,
y
=
ycen
)
sky_center
=
galsim
.
CelestialCoord
(
ra
=
ra
*
galsim
.
degrees
,
dec
=
dec
*
galsim
.
degrees
)
sky_center
=
galsim
.
CelestialCoord
(
ra
=
ra
*
galsim
.
degrees
,
dec
=
dec
*
galsim
.
degrees
)
affine
=
galsim
.
AffineTransform
(
dudx
,
dudy
,
dvdx
,
dvdy
,
origin
=
moscen
)
affine
=
galsim
.
AffineTransform
(
dudx
,
dudy
,
dvdx
,
dvdy
,
origin
=
moscen
)
WCS
=
galsim
.
TanWCS
(
affine
,
sky_center
,
units
=
galsim
.
arcsec
)
WCS
=
galsim
.
TanWCS
(
affine
,
sky_center
,
units
=
galsim
.
arcsec
)
...
@@ -115,10 +118,10 @@ class FocalPlane(object):
...
@@ -115,10 +118,10 @@ class FocalPlane(object):
The sky coverage of an area
The sky coverage of an area
"""
"""
r2d
=
180.0
/
np
.
pi
r2d
=
180.0
/
np
.
pi
s1
=
wcs
.
toWorld
(
galsim
.
PositionD
(
x0
,
y0
))
s1
=
wcs
.
toWorld
(
galsim
.
PositionD
(
x0
,
y0
))
s2
=
wcs
.
toWorld
(
galsim
.
PositionD
(
x0
,
y1
))
s2
=
wcs
.
toWorld
(
galsim
.
PositionD
(
x0
,
y1
))
s3
=
wcs
.
toWorld
(
galsim
.
PositionD
(
x1
,
y0
))
s3
=
wcs
.
toWorld
(
galsim
.
PositionD
(
x1
,
y0
))
s4
=
wcs
.
toWorld
(
galsim
.
PositionD
(
x1
,
y1
))
s4
=
wcs
.
toWorld
(
galsim
.
PositionD
(
x1
,
y1
))
ra
=
[
s1
.
ra
.
rad
*
r2d
,
s2
.
ra
.
rad
*
r2d
,
s3
.
ra
.
rad
*
r2d
,
s4
.
ra
.
rad
*
r2d
]
ra
=
[
s1
.
ra
.
rad
*
r2d
,
s2
.
ra
.
rad
*
r2d
,
s3
.
ra
.
rad
*
r2d
,
s4
.
ra
.
rad
*
r2d
]
dec
=
[
s1
.
dec
.
rad
*
r2d
,
s2
.
dec
.
rad
*
r2d
,
s3
.
dec
.
rad
*
r2d
,
s4
.
dec
.
rad
*
r2d
]
dec
=
[
s1
.
dec
.
rad
*
r2d
,
s2
.
dec
.
rad
*
r2d
,
s3
.
dec
.
rad
*
r2d
,
s4
.
dec
.
rad
*
r2d
]
...
...
tests/.coverage
deleted
100644 → 0
View file @
c48d8742
}q(U collectorqUcoverage v3.6b3qUlinesq}u.
\ No newline at end of file
tests/test_focalplane.py
0 → 100644
View file @
885d85b2
import
unittest
import
os
import
galsim
from
ObservationSim.Instrument
import
FocalPlane
,
Chip
class
TestFocalPlane
(
unittest
.
TestCase
):
def
__init__
(
self
,
methodName
=
'runTest'
):
super
(
TestFocalPlane
,
self
).
__init__
(
methodName
)
self
.
dataPath
=
os
.
path
.
join
(
os
.
getenv
(
'UNIT_TEST_DATA_ROOT'
),
'csst_msc_sim/csst_fz_msc'
)
self
.
focal_plane
=
FocalPlane
(
chip_list
=
[
'8'
])
self
.
assertTrue
(
self
.
focal_plane
.
cen_pix_x
==
0
)
self
.
assertTrue
(
self
.
focal_plane
.
cen_pix_y
==
0
)
test_focal_plane_phot
=
FocalPlane
(
survey_type
=
'Photometric'
)
test_focal_plane_spec
=
FocalPlane
(
survey_type
=
'Spectroscopic'
)
test_focal_plane_FGS
=
FocalPlane
(
survey_type
=
'FGS'
)
test_focal_plane_bad_chips
=
FocalPlane
(
bad_chips
=
[
"1"
])
def
test_fp_method
(
self
):
wcs
=
self
.
focal_plane
.
getTanWCS
(
192.8595
,
0.
,
0.
*
galsim
.
degrees
,
0.0074
)
sky_coverage
=
self
.
focal_plane
.
getSkyCoverage
(
wcs
,
x0
=-
1
,
x1
=
0
,
y0
=-
1
,
y1
=
0
)
print
(
sky_coverage
.
area
())
self
.
assertTrue
(
abs
(
sky_coverage
.
area
()
-
0.0074
**
2
/
(
3600.
**
2
))
<
1e13
)
if
__name__
==
'__main_'
:
unittest
.
main
()
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