PPdisk simdata (CASA 3.1): Difference between revisions
No edit summary |
|||
| Line 6: | Line 6: | ||
*Simdata2 version of script: [[File:Ppdisk.simdata2.txt]] | *Simdata2 version of script: [[File:Ppdisk.simdata2.txt]] | ||
--------------- | |||
<br> | |||
*Explanation of the script: | |||
<br> | |||
Set simdata2 as current task and reset all parameters | |||
default("simdata2") | |||
Specify sky model image | |||
modelimage = "input50pc_672GHz.fits" | |||
Image coordinate system can be verified | |||
imhead("input50pc_672GHz.fits") | |||
Image center can be identified | |||
# ia.open("input50pc_672GHz.fits") | |||
# ia.shape() | |||
# [257L, 257L, 1L, 1L] | |||
# ia.toworld([128.5,128.5]) | |||
# {'numeric': array([ 4.71239120e+00, -4.01423802e-01, 1.00000000e+00, 6.72000001e+11])} | |||
# qa.formxxx("4.71239120rad",format='hms',prec=5) | |||
# '18:00:00.03052' | |||
# qa.formxxx("-0.401423802rad",format='dms',prec=5) | |||
# '-022.59.59.602743' | |||
# ia.done() | |||
Brightness scale can be viewed with 'imstat' task | |||
# imstat("input50pc_672GHz.fits") | |||
# ... | |||
# 'max': array([ 6.52469971e-05]), | |||
# ... | |||
# that's 0.0652 mJy/pixel. | |||
Let's leave the brightness of the image as it is. | |||
inbright = "unchanged" | |||
Let's call our project psim2 | |||
project = "psim2" | |||
We'll leave the sky model the way it is -- simdata2 will create psim2.skymodel CASA image since this | |||
model is a fits file, and most but not all of CASA routines can operate directly on fits | |||
modifymodel = False | |||
skymodel = "input50pc_672GHz.fits" | |||
We need to decide where to point the telescope. The image is 2/3 arcsec in size, so we only need | |||
one pointing. We could put that in a text file ourself, or let simdata2 create the ascii | |||
pointing file for us. | |||
setpointings = True | |||
direction = "J2000 18h00m00.031s -22d59m59.6s" | |||
mapsize = "0.76arcsec" | |||
The default pointingspacing is fine - we'll only fit one pointing in the small mapsize | |||
the default calculation maptype hexagonal is ok too since only one will fit anyway. | |||
We do want to calculate visibilities in a measurement set: | |||
let's do a 20 min snapshot observation using out20 configuration: | |||
predict = True | |||
totaltime = "1200s" | |||
Use appropriate antenna configurations based on desired angular resolution | |||
repodir=os.getenv("CASAPATH").split(' ')[0] | |||
antennalist = repodir+"/data/alma/simmos/alma.out20.cfg" | |||
Deconvolve the visibilities back into an image | |||
image = True | |||
vis = "$project.ms" | |||
imsize = [192, 192] | |||
Specify number of iteration of cleaning task with proper threshold and weighting | |||
niter = 10000 | |||
threshold = "1e-7Jy" | |||
weighting = "natural" | |||
We'd like to calculate a difference and fidelity image, and see some diagnostics: | |||
analyze = True | |||
And see the array but not the UV coverage: | |||
showarray = True | |||
showuv = False | |||
Plot both to the screen and the png files, and giving us lots of messages: | |||
graphics = "both" | |||
verbose = True | |||
overwrite = True | |||
*To run the script, type | *To run the script, type | ||
| Line 14: | Line 84: | ||
-------- | |||
-------- | |||
*Output results: | *Output results: | ||
Revision as of 22:16, 8 June 2010
↵ Simulating Observations in CASA
Protoplanetary disk
- This fits file is a model of a protoplanetary disk from S. Wolf (If you use it for anything more than learning CASA, please cite Wolf & D'Angelo 2005).
- Simdata2 version of script: File:Ppdisk.simdata2.txt
- Explanation of the script:
Set simdata2 as current task and reset all parameters
default("simdata2")
Specify sky model image
modelimage = "input50pc_672GHz.fits"
Image coordinate system can be verified
imhead("input50pc_672GHz.fits")
Image center can be identified
# ia.open("input50pc_672GHz.fits")
# ia.shape()
# [257L, 257L, 1L, 1L]
# ia.toworld([128.5,128.5])
# {'numeric': array([ 4.71239120e+00, -4.01423802e-01, 1.00000000e+00, 6.72000001e+11])}
# qa.formxxx("4.71239120rad",format='hms',prec=5)
# '18:00:00.03052'
# qa.formxxx("-0.401423802rad",format='dms',prec=5)
# '-022.59.59.602743'
# ia.done()
Brightness scale can be viewed with 'imstat' task
# imstat("input50pc_672GHz.fits")
# ...
# 'max': array([ 6.52469971e-05]),
# ...
# that's 0.0652 mJy/pixel.
Let's leave the brightness of the image as it is.
inbright = "unchanged"
Let's call our project psim2
project = "psim2"
We'll leave the sky model the way it is -- simdata2 will create psim2.skymodel CASA image since this
model is a fits file, and most but not all of CASA routines can operate directly on fits modifymodel = False skymodel = "input50pc_672GHz.fits"
We need to decide where to point the telescope. The image is 2/3 arcsec in size, so we only need
one pointing. We could put that in a text file ourself, or let simdata2 create the ascii pointing file for us. setpointings = True direction = "J2000 18h00m00.031s -22d59m59.6s" mapsize = "0.76arcsec"
The default pointingspacing is fine - we'll only fit one pointing in the small mapsize the default calculation maptype hexagonal is ok too since only one will fit anyway.
We do want to calculate visibilities in a measurement set: let's do a 20 min snapshot observation using out20 configuration:
predict = True totaltime = "1200s"
Use appropriate antenna configurations based on desired angular resolution
repodir=os.getenv("CASAPATH").split(' ')[0]
antennalist = repodir+"/data/alma/simmos/alma.out20.cfg"
Deconvolve the visibilities back into an image
image = True vis = "$project.ms" imsize = [192, 192]
Specify number of iteration of cleaning task with proper threshold and weighting
niter = 10000 threshold = "1e-7Jy" weighting = "natural"
We'd like to calculate a difference and fidelity image, and see some diagnostics:
analyze = True
And see the array but not the UV coverage:
showarray = True showuv = False
Plot both to the screen and the png files, and giving us lots of messages:
graphics = "both" verbose = True overwrite = True
- To run the script, type
CASA<> execfile("Ppdisk.simdata2.txt")
CASA<> go simdata2
- Output results:
Input:
|
Predict:
|
Image:
|
Analyze:
|
