VLA 5 GHz continuum survey of Seyfert galaxies 5.7.2

From CASA Guides
Revision as of 22:35, 22 June 2017 by Jsalcido (talk | contribs)
Jump to navigationJump to search


VLA Tutorials

This particular tutorial demonstrates how to calibrate a VLA continuum survey, consisting of a flux calibrator, target sources, and their respective phase calibrators. What distinguishes this example is that it includes multiple sources and multiple phase calibrators.


Importing VLA Archive Data

Download your data from the VLA Archive; in this example we'll use the publicly available survey AG733, which consists of VLA C-array, C-band (5 GHz) continuum observations of a handful of Seyfert galaxies.

With some sensible fiddling of the web interface, you should be able to download two archive formatted files, one from 06-Dec-09 and one from 06-Dec-13, with names like AG733_A061209.xp1 and AG733_B061213.xp1 or 2006-12/vla2006-12-09.dat and 2006-12/vla2006-12-13.dat.

Example snippet of listobs output for program AG733.

It's helpful to make a subdirectory to store the VLA archive data and the CASA measurement sets before starting CASA. Linux-level commands are given assuming you are using bash as your default shell.

# In bash
mkdir ~/AG733
mv AG733_* ~/AG733
cd ~/AG733
casapy

To load the data in CASA, we employ the importvla command.

Graphics window produced by plotants. Shown are the antennas of the VLA for the program AG733.
# In CASA
# Before importing, get rid of any original version of the measurement set
if os.path.exists('ag733.ms'): rmtables('ag733.ms')
# let glob find the archive files, store in a python global "myFiles"
from glob import glob as filesearch 
myFiles = filesearch("AG733*.xp?")
importvla(archivefiles=myFiles,vis='ag733.ms')
listobs('ag733.ms')
vishead('ag733.ms')

The output measurement set, i.e., the data to be worked on, is ag733.ms. Note that the (interesting) output of listobs and vishead go to the CASA message log window.

listobs is similar to LISTR in AIPS and provides a list of scans, sources and their respective indices, and antennas. You can also get a more useful plot of antennas, akin to the output of the AIPS task PRTAN, using plotants. The antennas plot aids the selection of a reference antenna; the antenna VA05 looks like a reasonable choice.

# In CASA
vis = 'ag733.ms'
plotants()


Editing the Measurement Set

This technique is detailed in the tutorial Data flagging with plotms. Here's a shorter version.

# In CASA
plotms()

Plotms brings up the following graphical display.

The plotms GUI.

In this example, the measurement set was selected by navigating to and highlighting the measurement set ag733.ms (which will look like a directory to your file browser, because measurement sets are actually directory structures). A specific subset of data (the flux calibrator 3C48 = 0137+331 on the first observing day) was selected by specifying in the appropriate "Data -> Selection" boxes,

  • field = 0137+331, and
  • timerange = 2006/12/09/0:0:0~23:0:0.

For this specific field, we see no obvious bad data. Note that the low points are actually cross-polarization data; if you want to only look at the right and left polarizations, enter

  • corr = RR, LL.

For the sake of this example, we'll clip out the early part of the observations:

Firstly, box the region to be flagged by using the "Mark Regions" button . Next, go the the "Flag" tab at top, and select "Extend flags" and "Correlation", so that we will delete the RL and LR data as well (despite the fact that we're not plotting it). Then, press the "Go" button, or "Flag" button to zap those data.

The viewer tool provides utilities to flag data in a manner similar to the AIPS task TVFLG; see the tutorial Data flagging with viewer.

If we leave the field and timerange filter boxes blank and plot again, we see a number of visibilities with extremely large amplitudes. By highlighting and locating the bad points (described in detail in the data flagging with plotms tutorial), we find most of the bad data can be attributed to one antenna, 'VA15', at specific times, and one time range where all antennas contribute. In the text below we flag these points using flagdata; you can also flag data interactively in the plotms display (though this is generally not encouraged since it does not save backup versions of the flags, and it can be easy to flag data by mistake or miss data that's not plotted).

# In CASA
flagdata(vis='ag733.ms', antenna='VA15', timerange='2006/12/09/04:45:10.0~04:45:20.0')
flagdata(vis='ag733.ms', antenna='VA15', timerange='2006/12/09/06:12:30.0~06:14:10.0')
flagdata(vis='ag733.ms', antenna='VA15', timerange='2006/12/13/04:32:40.0~04:35:30.0')
flagdata(vis='ag733.ms', antenna='VA15', timerange='2006/12/09/06:12:30.0~06:12:40.0')
flagdata(vis='ag733.ms', antenna='VA15', timerange='2006/12/09/06:13:00.0~06:13:40.0')
flagdata(vis='ag733.ms', antenna='VA15', timerange='2006/12/09/06:13:50.0~06:14:00.0')
flagdata(vis='ag733.ms', antenna='VA15', timerange='2006/12/09/06:14:00.0~06:14:10.0')
flagdata(vis='ag733.ms', timerange='2006/12/09/06:24:50.0~06:25:00.0')

Notice that you can flag in one line multiple time ranges for a given antenna. Plot the data again to make sure the amplitudes look reasonable (if plotms is already open, just hit Shift+Plot to reload with the current flags):

# In CASA
plotms()

Careful with Cross-Pols

By default, plotms plots all of the data, including cross-polarization. All those low-amplitude points in your data are probably not junk. They are real cross-polarization data. Flagging those data will cause grief later on. Take a look at the tutorial data flagging with plotms.

Tread lightly! And, whenever possible, flag with tflagdata and keep careful track of what you flag in a separate file.

A Python Interlude

CASA uses python as an interactive wrapper and scripting language. Python offers the ability to define global variables on the fly, and it's worth using such variables to take care of bookkeeping. First we'll define some list variables that store calibrator and source information.

ampcallist = ['0137+331']
phasecallist = ['2250+143', '0119+321', '0237+288', '0239-025',
                '0323+055', '0339-017', '0423-013'] 
sourcelist = ['NGC7469', 'MRK0993', 'MRK1040', 'NGC1056', 'NGC1068',
              'NGC1194', 'NGC1241', 'NGC1320', 'F04385-0828',
              'NGC1667'] 
allcals = ampcallist + phasecallist
print allcals

It will also be helpful later to have a way of referencing which phase calibrator should be assigned to which source. We can define the matching explicitly by using a dictionary variable.

calDict = {'NGC7469':'2250+143',
           'MRK0993':'0119+321', 
           'MRK1040':'0237+288', 
           'NGC1056':'0237+288',
           'NGC1068':'0239-025',
           'NGC1194':'0323+055',
           'NGC1241':'0323+055',
           'NGC1320':'0339-017',
           'F04385-0828':'0423-013',
           'NGC1667':'0423-013'}

Those variables being defined, we can proceed with the calibration (and not have to type source and calibrator names over and over).

Calibration

Set the Flux Scale

As in AIPS, CASA sets the flux scale using an observation of a flux calibrator (here, 0137+331) and the task setjy. For this example, we'll determine the calibration in reference to a model image of the calibrator source. Look at the inputs of setjy and get it ready to go!

 
# in CASA
# perhaps restore setjy back to its defaults
default setjy
inp
vis = 'ag733.ms'
field = '0137+331'
# For the model image, need to specify the correct directory, something like the following
#
# load the CASA path from environment variable
import os
casapath = os.environ.get('CASAPATH').split()[0]
# generate full path to the image
modimage = casapath + '/data/nrao/VLA/CalModels/3C48_C.im'
go

That example was set up to demonstrate some AIPS heritage. You could equally well run setjy the following way.

 
# in CASA
setjy('ag733.ms', field = '0137+331', modimage = casapath + '/data/nrao/VLA/CalModels/3C48_C.im')

Determine calibration solutions

At this stage the data have an overall flux scaling determined, but full gain solutions aren't there yet. The relevant task is gaincal (analogous to the AIPS task CALIB).

Rather than generate solution tables (SN tables in AIPS) that are attached to the measurement set, gaincal will produce a separate table, which we'll call cal.G.

rmtables('cal.G') # get rid of any old, unmeritorious versions of the calibration
#
# Some caution on the following step. The solution interval is set to 'inf,' meaning to average over entire
# scans of each calibrator in turn. If a given scan is however longer than the coherence time (esp. on long baselines), 
# some decorrelation will occur and the flux calibration will be thrown off. Suggest, e.g., solint='1min' or solint='2min' 
# as reasonable alternatives to solint='inf'. Trial and error may be your friend here.
#
gaincal(vis='ag733.ms',caltable='cal.G', field=','.join(allcals), solint='inf',
        refant='VA05', gaintable=['gc.cal'], append=False)
plotcal('cal.G',yaxis='amp',timerange='2006/12/09/04:0:0~06:30:0')

There's some python trickery buried in this example. If you are unfamiliar with the string method join, try the following example. Recall that we had defined the variable allcals above in A Python Interlude.

print allcals 
print ','.join(allcals)

It's worth playing with the timerange, etc. in plotcal to explore the solutions. You may notice that the antenna 'EA26' looks a little junky on the second day. Here's how to flag it manually and then repeat the calibration (be sure to close the plotcal window displaying the previous solutions first).

tflagdata(vis='ag733.ms',antenna='EA26', timerange='2006/12/13/0:0:0~24:0:0')
rmtables('cal.G') 
gaincal(vis='ag733.ms',caltable='cal.G', field=','.join(allcals), solint='inf',
        refant='VA05', append=False, gaincurve=False)

Go back and re-plot the calibration; this example shows even more AIPS heritage.

tget plotcal
plotcal()

Finally, bootstrap the flux scale of the flux calibrator onto the phase calibrators. AIPS called it GETJY, but CASA calls it fluxscale.

rmtables('cal.Gflx') # remove any old versions of the calibration table, if necessary
myFluxes = fluxscale(vis='ag733.ms', caltable='cal.G', reference=','.join(ampcallist), 
                     transfer=','.join(phasecallist), fluxtable='cal.Gflx', append=False)

Here, the calibration table cal.G is modified and stored as 'cal.Gflx.' The Python dictionary "myFluxes" will also contain information about the flux scaling and other useful tidbits (type "myFluxes" to see its contents). So far, solutions have been generated only for the calibrators, and they have not yet been transfered to the sources.

We could equally well have used reference='0137+337', but use of the join method allows for the more general possibility of multiple flux calibrators.

Apply the Calibrations

In AIPS, the task CLCAL applies calibration solutions to a calibration table. In CASA the equivalent task is applycal. We loop over sources and calibrators to properly match them:

for source, calibrator in calDict.iteritems():
    applycal(vis='ag733.ms', field=source,
             gaintable='cal.Gflx', gainfield=calibrator,
             gaincurve=False)

Baseline-based corrections

Initial clean image of NGC1068 without blcal.
Initial clean image of NGC1068 with blcal applied.

Although it makes only modest improvements for the present example, observations including a mix of EVLA and VLA telescopes may benefit from performing baseline-based corrections on a strong calibrator. Now that we have initial antenna-based solutions, we can use blcal.

default('blcal')
vis = 'ag733.ms'
# output baseline-based calibration solutions
caltable = 'cal.BL' 
# use the strong flux calibrator to determine baseline-based solutions
field = '0137+331' 
# generate a solution for each calibrator scan
solint = 'inf' 
gaintable = 'cal.Gflx'
# calibration table with the best antenna-based solutions, so far
gainfield = '0137+331' 
# calibrator for the BL calibrator; in this example, gain cal and bl cal are the same
interp = 'nearest'
gaincurve = False
# do the first day's data
timerange = '2006/12/09/0:0:0~24:0:0'
blcal()
# now the second day
timerange = '2006/12/13/0:0:0~24:0:0'
blcal()

This operation generates the calibration table cal.BL. Solutions can be inspected with plotcal. Now we have to use applycal again to apply both the antenna-based and baseline-based calibration solutions to the data.

for source, calibrator in calDict.iteritems():
    applycal(vis='ag733.ms', field=source,
             gaintable=['cal.Gflx','cal.BL'], gainfield=calibrator,
             gaincurve=False)

Did the blcal operation make a difference here? Getting ahead of ourselves a little, the plots at right show the initial clean images of NGC1068, one with blcal applied, and one without, and both images are displayed with the same stretch. There does appear a slight reduction of artifacts with blcal applied, but of course your mileage will vary.

Splitting the calibrated source data from the multisource measurement set

To split the calibrated source data out of the measurement set, use the CASA task split.

splitfile = 'NGC1667.split.ms'
rmtables(splitfile) # get rid of any old versions before splitting
split(vis='ag733.ms',outputvis=splitfile, datacolumn='corrected', field='NGC1667')

Alternatively, you can take advantage of scripting to loop over the sources.

for source in sourcelist:
    splitfile = source + '.split.ms'
    rmtables(splitfile)
    split(vis='ag733.ms',outputvis=splitfile, 
          datacolumn='corrected', field=source)

Imaging

An example desktop display of viewer, showing the image display panel, the data display options window, and the data loader.

Use clean for imaging and clean deconvolution. Like IMAGR in AIPS, it's worth some time mulling over all of the options. A complete list of keywords is given in the example, below. Most of the options should be relatively familiar to the AIPS user.

For this snapshot survey, the example chooses a fairly conservative, slow clean to accommodate the less-than-ideal beam. You could probably get away with more efficient cleaning, but it's better to play it safe in scripted self-calibration.

default(clean)
mode                =      'mfs'        
niter               =       2000      
gain                =        0.1       
threshold           = '4.5e-5Jy'      
psfmode             =    'clark'       
imagermode          =  'csclean'     
cyclefactor    =          3       
cyclespeedup   =         -1       
multiscale          =         []       
interactive         =      False      
mask                =         []       
imsize              = [1024, 1024]      
cell                = ['0.75arcsec', '0.75arcsec']
stokes              =        'I'        
weighting           =  'natural'        
uvtaper             =      False      
pbcor               =      False      
minpb               =        0.1      
usescratch          =      False       
async               =      False      
for source in sourcelist:
    splitfile = source + '.split.ms'
    vis = splitfile
    imagename = source + '_img'
    rmtables(imagename + '*') # get rid of earlier versions of the image
    clean()

Take a look at the image using viewer.

viewer()

From the GUI, select the .image file you want to view, select Raster Image, and then dismiss and close your way through to the display.

Self-calibration

At this point we have a set of calibrated visibilities (the "splits") and a set of images. There's not much more that can be done for the fainter sources, but the brighter sources will almost certainly show some residual calibration artifacts that can be cleaned up with self-calibration. The strategy is to repeat using the primary calibration application gaincal, only this time we use the source itself as a calibrator.

NGC 1068 is a good example of a difficult source. Firstly, it's very bright, so residual phase calibration errors should be obvious. Secondly, like the larger fraction of the sky, it's located painfully close to the celestial equator, meaning that the (u,v) coverage is particularly poor.

To view the calibration artifacts, use viewer to display the image of NGC 1068, but adjust the display levels so that the displayed image saturates at 10 mJy. To do this, select the leftmost button bearing a wrench icon. The "Data Display Options" GUI opens, and you can enter the desired display stretch in the Data Range text box. To cutoff the stretch at 30 mJy,

  • Data Range: [-0.005,0.03]

You can see some residual systematics in the background and sidelobe artifacts that suggest the phase calibration isn't as good as it might be.

The process of self-calibration will involve iterating between (i) improved clean models of the source and (i+1) improved calibrations generated by gaincal. For simplicity, in this example we will repeatedly generate new calibration tables so that we can avoid using accum.

Step i

In principle, we could start with the initial clean model that we generated above. For this example, we'll take a more cautious approach and re-run clean interactively.

source = 'NGC1068' # set up a global variable to store the source we're working on
tget clean
vis = source + '.split.ms'
imagename = source + '_img0'
interactive = True
npercycle = 10
go

The trick to interactive cleaning is to draw clean boxes around the sources as they appear in the residual image. By default, clean boxes are set by right-clicking on the image and dragging. The box can be edited until you double right-click inside the box, which then sets that box for cleaning. Press the green icon to continue cleaning the image; on the next major cycle, a new residual map will be displayed, affording the option to add clean boxes as new sources appear where they were once swamped by sidelobes.

Of course, for self-calibration, it pays to stop the cleaning early when artifacts start to appear in the residuals!

Step i + 1

To start, we should already have a clean model for NGC 1068 stored in the visibility database. Now we can set up gaincal.

default('gaincal') # reset inputs for gaincal (akin to RESTORE in AIPS)
vis = source + '.split.ms'
caltable = source + '.gcal0'
gaintype = 'G'
calmode = 'p' # phase-only self-calibration at this stage
solint = '10 min' # set up a fairly coarse correction interval in this early stage
minsnr = 3.0
gaintable = ''
field = source
gainfield = source # are these necessary?
gaincurve = False
gaincal() # or go!

Pause for Reflection and Troubleshooting

Self-calibration is a method to fine-tune your original calibration, and, as such, should produce relatively small phase corrections assuming the primary calibration was applied correctly. Now is a good time to run plotcal on your new calibration table (NGC1068.gcal0) to make sure the phase corrections range from a few to perhaps 10 or 20 degrees. If you see phase corrections greatly exceeding 20 degrees, then there's a chance of either

  • the primary calibration wasn't applied to the split database correctly, and should be checked, or
plotcal(caltable, iteration='antenna', xaxis='time', yaxis='phase', plotrange=[-1,-1,-180,180])

Step i + 2

Assuming plotcal gave reasonable results, next apply the calibration.

default('applycal')
vis = source + '.split.ms'
gaintable = source + '.gcal0'
gainfield = source
go

And now we can generate a new clean model.

tget clean
imagename=source + '_img1' # choose an image root name that matches the future cal table to facilitate bookkeeping
go

Further Steps

Assuming things are going well, we can now continue to repeat the process until we are satisfied with the image.

Final, self-calibrated image of NGC1068.
tget gaincal
caltable = source +'.gcal1'
solint = "5 min" # halve the solution interval. 
go

# good idea to plotcal() again here!

tget applycal
gaintable = source + '.gcal1'
go

tget clean
imagename = source + '_img2'
go

And so on, decreasing the solution interval as much as the S/N and sampling allow.

Note that gaincal always uses the 'data' column (not the recently self-calibrated 'corrected' column) to find gain solutions. Therefore, these iterations simply serve to improve the data model, and gain solutions at each iteration are independent (e.g., the solution from the second self calibration iteration does not accumulate on top of the solution from the first interval. Use the CASA task accum if you wish to accumulate gain solutions).

One Last Iteration: Amplitude & Phase Self Calibration

After you have improved the phase calibration as much as possible, one last iteration where both phase and amplitude are calibrated can be beneficial. A&P self calibration should be performed with long solution intervals---typically the length of a scan.

default('gaincal') # reset inputs for gaincal (akin to RESTORE in AIPS)
vis = source + '.split.ms'
caltable = source + '.gcalap'
gaintype = 'G'
calmode = 'ap' # it's finally time to calibrate amplitudes, too
solint = 'inf' # one solution interval per scan (in conjunction with combine='') 
combine = ''
minsnr = 3.0
gaintable = source + '.gcal1' # apply your best phase calibration on the fly. 
gaincal() # or go!

Here, we are applying the best phase calibration solution on the fly by setting the gaintable parameter, so that this A&P self calibration iteration will only make small tweaks on top of the phase solutions we just worked so hard to find. Check your solutions in plotcal---amplitudes should not vary much and should be close to unity. Phase tweaks should be minimal and close to zero. If the solutions look reasonable, go ahead and apply the calibration:

default('applycal')
vis = source + '.split.ms'
gaintable = [source + '.gcal1', source + '.gcalap']
gainfield = source
go

The critical difference here from phase-only self calibration iterations is that we are applying two gain tables---the best phase solutions (source + '.gcal1') and the A&P solutions (source + '.gcalap'). Now you should be ready for one final imaging run with clean! For consistency, we will run it with the same command we used the first time:

default(clean)
mode                =      'mfs'        
niter               =       2000      
gain                =        0.1       
threshold           = '4.5e-5Jy'      
psfmode             =    'clark'       
imagermode          =  'csclean'     
cyclefactor    =          3       
cyclespeedup   =         -1       
multiscale          =         []       
interactive         =      False      
mask                =         []       
imsize              = [1024, 1024]      
cell                = ['0.75arcsec', '0.75arcsec']
stokes              =        'I'        
weighting           =  'natural'        
uvtaper             =      False      
pbcor               =      False      
minpb               =        0.1      
async               =      False  
usescratch          =      False    
vis = 'NGC1068.split.ms'
imagename = 'NGC1068_img4'
rmtables(imagename + '*') # get rid of earlier versions of the image
clean()


Last checked on CASA Version 3.4.0.

VLA Tutorials

Updated: Miriam Krauss, 15 June 2012