Protoplanetary Disk Simulation (CASA 3.4): Difference between revisions

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[[Category: Simulations]]
[[Category: Simulations]]


'''This guide is applicable to CASA version 3.4.  For older versions of CASA see [[PPdisk_simdata_(CASA_3.3)]].'''
* '''This guide is applicable to CASA version 3.4.  For older versions of CASA see [[PPdisk_simdata_(CASA_3.3)]].'''
* '''To create a script of the Python code on this page see [[Extracting scripts from these tutorials]].'''
* '''To create a script of the Python code on this page see [[Extracting scripts from these tutorials]].'''


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== Data ==
== Data ==
For this CASA Guide we will use [ftp://ftp.cv.nrao.edu/NRAO-staff/rindebet/input50pc_672GHz.fits a protoplanetary disk model] from S. Wolf.  ''If you use this FITS data for anything more than learning CASA, please cite [http://adsabs.harvard.edu/abs/2005ApJ...619.1114W Wolf & D'Angelo 2005].''
For this CASA Guide we will use [ftp://ftp.cv.nrao.edu/NRAO-staff/rindebet/input50pc_672GHz.fits a protoplanetary disk model] from S. Wolf.  ''If you use this FITS data for anything more than learning CASA, please cite [http://adsabs.harvard.edu/abs/2005ApJ...619.1114W Wolf & D'Angelo 2005].''


==Explanation of the script==
== Script with Explanation ==
 
Set '''simobserve''' as the current task and reset all parameters.


=====Set sim_observe as current task and reset all parameters=====
<source lang="python">
<source lang="python">
# Setting everything in simobserve to original defaults
# In CASA
default("simobserve")
default("simobserve")
</source>  
</source>
=====Image coordinate system can be verified=====
 
Review the image coordinate system using task {{imhead}}.
 
<source lang="python">
<source lang="python">
# This reports image header parameters in the Log Messages window
# This reports image header parameters in the Log Messages window
imhead("input50pc_672GHz.fits")
imhead("input50pc_672GHz.fits")
</source>   
</source>   
=====Image center can be identified=====
 
We now us the '''ia''' (image analysis) and '''qa''' (units and quantities) tools from the CASA Toolkit to find the image center.  In comparison to tasks, tools are a more advanced way of manipulating data in CASA.  You can learn more about tools using the [http://casa.nrao.edu/docs/CasaRef/CasaRef.html tool reference manual].
 
When data are being manipulated with tools the data file must be explicitly opened and closed.
 
<source lang="python">
<source lang="python">
# These are tools found in the CASA toolkit
# In CASA
# They are very useful, but the interface is not as straightforward as the tasks
# You can find the tool reference manual here: http://casa.nrao.edu/docs/CasaRef/CasaRef.html
# The following command is used to open an image (this is part of the image analysis toolkit)
# Whenever data are being viewed/manipulated by tools, what is being operated on needs to be explicitly opened
# and closed (i.e. an image, a table, etc.)
ia.open("input50pc_672GHz.fits")
ia.open("input50pc_672GHz.fits")
#  Out[9]: True
</source>
#
 
# Reports the length of each axis in the opened image
Next, get the right ascension and declination of the image center.  We get the number of pixels along each axis using '''ia.shape'''. Then, we get the RA and Dec values for the center pixel using '''ia.toworld'''.
ia.shape()
 
# Out[11]: [257L, 257L, 1L, 1L]
<source lang="python">
#
# In CASA
# This command converts from pixel (our source file) to world coordinates (something usable by simdata)
axesLength = ia.shape()
ia.toworld([128.5,128.5])
# Divide the first two elements of axesLength by 2.
#  Out[12]:
center_pixel = [ x / 2.0 for x in axesLength[:2] ]
#{'numeric': array([  4.71239120e+00,  -4.01423802e-01,  1.00000000e+00,
# Feed center_pixel to ia.toworld and and save the RA and Dec to ra_radians and dec_radians
#        6.72000001e+11])}
(ra_radians, dec_radians) = ia.toworld( center_pixel )['numeric'][:2]
#
# Formats the coordinate just converted into hms
qa.formxxx("4.71239120rad",format='hms',prec=5)
# Out[13]: '18:00:00.03052'
#
# Formats one of the other coordinates into dms
qa.formxxx("-0.401423802rad",format='dms',prec=5)
#  Out[14]: '-022.59.59.602743'
#
# Final housekeeping by closing the image tool
# The image tool will now be detached from the image
ia.close()
ia.close()
</source>
Use the '''qa''' tool to convert the image center from radians to sexagesimal coordinates.
<source lang="python">
ra_hms  = qa.formxxx(str(ra_radians)+"rad",format='hms',prec=5)
dec_dms = qa.formxxx(str(dec_radians)+"rad",format='dms',prec=5)
</source>
</source>



Revision as of 20:14, 8 June 2012

Simulating Observations in CASA


Data

For this CASA Guide we will use a protoplanetary disk model from S. Wolf. If you use this FITS data for anything more than learning CASA, please cite Wolf & D'Angelo 2005.

Script with Explanation

Set simobserve as the current task and reset all parameters.

# In CASA
default("simobserve")

Review the image coordinate system using task imhead.

# This reports image header parameters in the Log Messages window
imhead("input50pc_672GHz.fits")

We now us the ia (image analysis) and qa (units and quantities) tools from the CASA Toolkit to find the image center. In comparison to tasks, tools are a more advanced way of manipulating data in CASA. You can learn more about tools using the tool reference manual.

When data are being manipulated with tools the data file must be explicitly opened and closed.

# In CASA
ia.open("input50pc_672GHz.fits")

Next, get the right ascension and declination of the image center. We get the number of pixels along each axis using ia.shape. Then, we get the RA and Dec values for the center pixel using ia.toworld.

# In CASA
axesLength = ia.shape()
# Divide the first two elements of axesLength by 2.
center_pixel = [ x / 2.0 for x in axesLength[:2] ]
# Feed center_pixel to ia.toworld and and save the RA and Dec to ra_radians and dec_radians
(ra_radians, dec_radians) = ia.toworld( center_pixel )['numeric'][:2]
ia.close()

Use the qa tool to convert the image center from radians to sexagesimal coordinates.

ra_hms  = qa.formxxx(str(ra_radians)+"rad",format='hms',prec=5)
dec_dms = qa.formxxx(str(dec_radians)+"rad",format='dms',prec=5)
Brightness scale can be viewed with 'imstat' task
# Default parameters are adequate for this
imstat("input50pc_672GHz.fits")
# ...
#  'max': array([  6.52469971e-05]),
# ...
# that's 0.0652 mJy/pixel.
Let's call our project psim2
default("simobserve")
# This defines the root prefix for any output files from simobserve
project            =  "psim2"
We'll leave the sky model the way it is: simobserve 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
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 simobserve 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 the "out20" ALMA antenna configuration:
obsmode            =  "int"
totaltime          =  "1200s"
Use appropriate antenna configurations based on desired angular resolution (configuration 20 - alma.out20.cfg in this case - is the largest "compact" configuration)
antennalist        =  "alma.out20.cfg"
simobserve()
Deconvolve the visibilities back into an image
default ("simanalyze")
project            =  "psim2"
image              =  True
# Prior image to use in clean
modelimage         =  "input50pc_672GHz.fits"
vis                =  project+".alma.out20.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:
showuv             =  False
showresidual       =  True  
showconvolved      =  True
Plot both to the screen and the png files with lots of messages:
graphics           =  "both"
verbose            =  True
overwrite = True

Run simdata

# This commands CASA to execute simanalyze
simanalyze()


  • Output results:


Input:
Predict:
Image:
Analyze:

Simulating Observations in CASA

Last checked on CASA Version 3.4.0.