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This guide continues from '''[[Image_Continuum | Image the Continuum Template]]''' and '''[[Self_Calibration_Template | Self-Calibration Template]]''' (optional). Imaging parameters and calibration tables (if applicable) should already be set prior to continuing.
Commands for this guide can be found in scriptForImaging_template.py available on [https://github.com/aakepley/ALMAImagingScript github].
== Continuum Subtraction for Line Emission ==
== Continuum Subtraction for Line Emission ==


If you have observations that include both line and strong continuum emission (>3 sigma above the noise), you need to subtract the continuum from the line data. You should not subtract the continuum from the line data if the line of interest is an absorption line. You will need to insert any continuum spws that weren’t included in flagchannels. For example, if your continuum spws are '0,1,2' and flagchannels='1:260~500', au.invertChannelRanges will return '1:0~259,1:501~3839'. The fitspw parameter should be '0,1:0~259,1:501~3839,2'.
If you have observations that include both line and strong continuum emission (>3 sigma per channel), you should subtract the continuum from the spectral windows before imaging the line. You do not need to continuum subtract if the line of interest is an absorption line.  


Contsub is done for each field in turn; however, if the fields have different line free channels then the contsub will need to be done separately for each field.  
To subtract the continuum, you need to select channel ranges which only contain continuum. You can use {{plotms}} to make sure that the appropriate data is in the appropriate column of your ms. Note that this behavior is different in the pipeline implementation of continuum subtraction '''hif_uvcontsub'''. The continuum subtraction routine will then do a linear fit to each integration to determine the continuum and then subtract that linear fit from the data. The range used to fit the continuum is just the opposite of the channels you flagged when creating the continuum (see [[Image Continuum#Create an Averaged Continuum MS | Create an Averaged Continuum MS]] section of the [[Image Continuum]] guide. You can either manually invert the channels or use the Analysis Utilities routine [https://safe.nrao.edu/wiki/bin/view/ALMA/InvertChannelRanges au.invertChannelRanges] to determine the channel ranges. Note that if you use [https://safe.nrao.edu/wiki/bin/view/ALMA/InvertChannelRanges au.invertChannelRanges], you will need to include any continuum spws that weren't in flagchannels. For example, if your continuum spws are '0,1,2' and flagchannels='1:260~500', [https://safe.nrao.edu/wiki/bin/view/ALMA/InvertChannelRanges au.invertChannelRanges] will return '1:0~259,1:501~3839'. The fitspw parameter should be '0,1:0~259,1:501~3839,2'. If you haven't installed Analysis Utilities, see [https://casaguides.nrao.edu/index.php?title=Analysis_Utilities Obtaining Analysis Utilities] for instructions.
 
Continuum subtraction is done per field. If all your fields have the same line-free channels, you only have to run {{uvcontsub}} once.  However, if different fields have different line-free channels, then you will need to run {{uvcontsub}} multiple times. (And probably get a cup of coffee or two.)
 
The output file for {{uvcontsub}} will be vis + ".contsub". It will read from the corrected data column if it is present and the data column if the corrected data column is not present. 
 
Note that want_cont=True produces a model of the emission and not the actual continuum subtracted ms.  The results of want_cont=True should not be used to produce an image of the continuum for a source.


<source lang="python">
<source lang="python">
# in CASA
# in CASA
fitspw = '2:1201~2199,3:1201~2199' # line free channels. Use au.invertChannelRanges
fitspw = '2:0~1200;1500~3839,3:0~1200;1500~3839' # line free channels. Use au.invertChannelRanges
linespw = '2,3' # line spectral windows. You can subtract the continuum from multiple spectral line windows at once.
linespw = '2,3' # line spectral windows. You can subtract the continuum from multiple spectral line windows at once.


Line 14: Line 23:
uvcontsub(vis=finalvis,
uvcontsub(vis=finalvis,
           spw=linespw, # spw to do continuum subtraction on
           spw=linespw, # spw to do continuum subtraction on
           fitspw=fitspw, # regions with lines. can be set equal to flagchannels
           fitspw=fitspw, # regions without lines.
           excludechans=False,
           excludechans=False, # fit the regions in fitspw
           combine='spw',
           #combine='spw', uncomment if there are no line-free channels in the line spectral window. 
           solint='int',
           solint='int',
           fitorder=1,
           fitorder=1,
Line 24: Line 33:
== Apply continuum self-calibration to line data (optional) ==
== Apply continuum self-calibration to line data (optional) ==


If you find self calibration does help with lowering the rms in your continuum images it is a good idea to apply the continuum self-calibration to the line data. Depending on if you performed continuum subtraction, select the definition of linevis accordingly. Once this has been done, it is recommended that you save the flags before you apply the self-calibration solution to the individual line spectral windows, in case you do not like results or they do not improve the image. If self calibration of the continuum does improve the quality of those data, apply the derived gaintable to the spectral line channels using the applycal task. This will improve the image quality of the stronger spectral line channels, but will not help (or harm) the weaker line channels. Then save the results of self-cal in a new ms and reset the image name. You also need to reset the corrected data column in the ms to the original calibration. The clearcal(linevis) task can also be used to return your ms to its original pre-self-cal state if you are dissatisfied with the self-calibration results.  
This section depends on solutions derived with '''[[Self_Calibration_Template | Self-Calibration Template]]'''. Skip to [[Image_Line#Image_line_emission_.28repeat_as_necessary.29 | Image Line Emission]] if you do not wish to apply self-calibration solutions to the line data.
 
If you find self-calibration does help with lowering the rms in your continuum images, it is a good idea to apply the continuum self-calibration to the line data. Depending on if you performed continuum subtraction, select the definition of linevis accordingly. Once this has been done, it is recommended that you save the flags before you apply the self-calibration solution to the individual line spectral windows, in case you do not like the results or they do not improve the image. If self-calibration of the continuum does improve the quality of the data, apply the derived gaintable to the spectral line channels using the {{applycal}} task. This will improve the image quality of the stronger spectral line channels, but will not help (or harm) the weaker line channels. Then save the results of self-cal in a new ms and reset the image name. You also need to reset the corrected data column in the ms to the original calibration. The clearcal(linevis) task can also be used to return your ms to its original pre-self-cal state, if you are dissatisfied with the self-calibration results.  
<source lang="python">
<source lang="python">
# in CASA
# in CASA
Line 40: Line 51:
         gainfield='',
         gainfield='',
         calwt=False,
         calwt=False,
         flagbackup=False)
         flagbackup=False,
        interp=['linearperobs','linearperobs'])


# Save results of self-cal in a new ms and reset the image name.
# Save results of self-cal in a new ms and reset the image name.
Line 50: Line 62:
== Image line emission (repeat as necessary) ==
== Image line emission (repeat as necessary) ==


You should now have a measurement set that is ready to image in velocity mode to create line cubes. Depending on the observation, the measurement set may have a variety of names. Make sure to select the correct option below.
You should now have a measurement set that is ready to create cubes of the line emission.
 
If you are new to line imaging, look at [[First Look at Line Imaging]] for an introduction to creating line cubes.
 
You may also find the [https://casaguides.nrao.edu/index.php/Automasking_Guide Automasking Guide] useful if you would like {{tclean}} to produce the mask for you.
 
If you expect more complex emission and do not want to create the mask by hand, you can use the directions at [[Create a Clean Mask from Continuum Image or Moment Cube]] to create a mask from the dirty cube.
 
Depending on the observation and the steps you have applied previously, the measurement set may have a variety of names. Make sure to select the correct option below.


<source lang="python">
<source lang="python">
Line 59: Line 79:
# linevis = finalvis
# linevis = finalvis
# uncomment if you have continuum subtracted your data
# uncomment if you have continuum subtracted your data
# linevis = finalvis + .contsub’
# linevis = finalvis + '.contsub'
# uncomment if you have both continuum subtracted and self-calibrated your data
# uncomment if you have both continuum subtracted and self-calibrated your data
# linevis = finalvis + '.contsub.selfcal'
# linevis = finalvis + '.contsub.selfcal'
Line 66: Line 86:
</source>
</source>


Now the linevis variable will be used for the rest of the cleaning. Spectral windows and field numbers may have been re-numbered. Check for these changes.
The measurement set indicated in the linevis variable will be used for the rest of the cleaning. Before starting to clean your line cube, run a {{vishead}} or {{listobs}} to check on the spectral window and field numbers, which may have been re-numbered during the previous steps in the imaging process.


<source lang="python">
<source lang="python">
Line 73: Line 93:
</source>
</source>


Set the necessary parameters for {{clean}}. The name of the image will be formated as sourcename_linetransition.
Now you need to set the necessary parameters for {{tclean}}. If you haven't already, follow the procedure in the [[Image Continuum#Imaging Parameters | Image Continuum]] section to set the imsize, cellsize, field, phasecenter,etc.  Here we focus on the additional parameters needed to image line data.
 
First, we set the imagename. Here we name the image for the source and line observed, but you could give it any name you'd like.


<source lang="python">
<source lang="python">
Line 82: Line 104:
</source>
</source>


The restfreq is typically set at the rest frequency of the line of interest. We do not recommend imaging multiple spectral windows tuned to different frequencies. If the source is significantly redshifted (z>0.2), use the observed sky frequency (nu_rest/1+z) instead. If {{cvel}} or {{mstransform was used to regrid spectral windows, make sure to use the same values below.
Next select the spws you would like to image. You should only image spws associated with a single rest frequency in the same image. If you have multiple executions and did not regrid the frequency axis using cvel, you will have to select multiple spws (one for each execution). The restfreq is typically set at the rest frequency of the line of interest. If the source is significantly redshifted (z>0.2), common practice is to set the rest frequency to the observed sky frequency (nu_rest/1+z) instead. Then the velocity axis shows offsets from the expected sky frequency.


Finally, if {{cvel}} or {{mstransform}} was used to regrid spectral windows, make sure to use the same values below as you used with those tasks. In other words, avoid regridding your frequency axis twice: once in {{cvel}} and once in {{tclean}}.
[[File:TWHydra_CO3_2_plotms.png|thumb|<caption>The CO window is plotted in plotms. Use this to determine the start and nchan parameters.</caption>]]
<source lang="python">
<source lang="python">
# in CASA
# in CASA
spw = '0' # update to the spw you would like to image
restfreq='115.27120GHz’
restfreq='115.27120GHz’
</source>
</source>


Select the spw you would like to image. If you have multiple executions, you will need to select the spws at the same rest frequency.
<source lang="python">
# in CASA
spw = ‘0’ # update to the spw you would like to image
</source>


The start, width, and nchan parameters will determine the size of the cube you create. Setting the values at their defaults will image the entire spectral window at the native resolution.  
The start, width, and nchan parameters will determine the size of the cube you create. Setting the values at their defaults will image the entire spectral window at the native resolution.  


<source lang="python">
<source lang="python">
# in CASA
# in CASA
start = ‘’
start = ''
width = ‘’
width = ''
nchan = -1
nchan = -1
</source>
</source>


You can also image a subset of the cube. For example, you may wish to image the inner 100 channels at a spectral resolution of 2 km/s
You can also image a subset of the cube. By only imaging a subsection of the spectral window you can speed up the time it takes {tclean} to produce a cube and reduces the final size of the cube.
start='-100km/s'
width='2km/s'
nchan = 100 
You can use plotms to find the line if it is apparent in the visibilities.  


<source lang="python">
<source lang="python">
# in CASA
# in CASA
plotms(vis=linevis,xaxis=’velocity’,yaxis=’amp’,avgtime=’1e8’,avgscan=True,avgantenna=True,spw=spw,coloraxis=’spw’,transform=True,freqframe=outframe.upper(),restfreq=restfreq)
start='-100km/s'
width='2km/s'
nchan = 100
</source>
</source>


The following commands can be run to re-start the cleaning process from scratch if you have already created a cube.
Remember that you have already set two specific velocity parameters called outframe and veltype. Outframe is the coordinate system used for the observation. If you have access to the original proposal, this can be found in the Observing Tool (OT) under field setup. A list of acceptable outframes that can be used in CASA can be found at https://help.almascience.org/kb/articles/what-are-the-frequency-reference-frames-in-casa. Note: heliocentric(hel) is deprecated in CASA. Use barycentric(bary) in this case. The most common choices are 'bary' and 'lsrk'. Usually 'bary' is used for 'extragalactic' sources and 'lsrk is used for 'galactic' sources. For ephemeris objects, the outframe should be set to a blank string, for example outframe =  <nowiki>''</nowiki>, as the you have likely already regridded to the source velocity.
 
Generally, if you set outframe = 'bary' and restfreq = observed frequency, the line center should be at around 0 km/s. If you set outframe = 'lsrk' and restfreq = lab frequency, you will need to know the source radial velocity in order to predict the line position. If you are unsure, you can use the {{plotms}} command below to plot the visibilities to explore the effects of outframe and restfreq.


You will also have to set the veltype for the {{tclean}} command. This variable has only two options available, radio and optical. It is standard to leave this set to ‘radio’ in all projects regardless of the velocity frame used in the project.
<source lang="python">
<source lang="python">
# in CASA
# in CASA
clearcal(vis=linevis)
outframe='lsrk' # velocity reference frame. See science goals.
delmod(vis=linevis)
veltype='radio' # velocity type.
for ext in ['.flux','.image','.mask','.model','.pbcor','.psf','.residual','.flux.pbcoverage','.pb','.wtsum']:
    rmtables(lineimagename + ext)
</source>
</source>


[https://casaguides.nrao.edu/index.php/First_Look_at_Line_Imaging The First Look at Spectral Line Imaging] guide can be used for first time imagers. Check out the tips and tricks for imaging in the continuum imaging section of this guide.
You can use {{plotms}} to find the line if it is bright enough to show up in the averaged visibilities. This is similar to the procedure you used to identify the line when creating the averaged continuum ms in [[Image Continuum#Create an Averaged | Continuum MS]].  


[[File:CO_initial_image.png|thumb|<caption>Channel 54 of the CO line cube is shown. Create a mask for each channel or all channels and proceed with cleaning.</caption>]]
<source lang="python">
<source lang="python">
# in CASA
# in CASA
clean(vis=linevis,
plotms(vis=linevis,xaxis='velocity',yaxis='amp',avgtime='1e8',avgscan=True,avgantenna=True,
      imagename=lineimagename,
    spw=spw,coloraxis='spw',transform=True,freqframe=outframe.upper(),restfreq=restfreq)
      field=field,
      spw=spw,
#      phasecenter=phasecenter, # uncomment if mosaic.     
      mode='velocity',
      start=start,
      width=width,
      nchan=nchan,  
      outframe=outframe,  
      veltype=veltype,  
      restfreq=restfreq,  
      niter=niter, 
      threshold=threshold,
      interactive=True,
      cell=cell,
      imsize=imsize,
      weighting=weighting,
      robust=robust,
      imagermode=imagermode)
</source>
</source>


You can use this template to image all targeted lines in your observation.
The {{tclean}} command for generating your line cube is shown below. You can use this template to image all targeted lines in your observation. For more information about the tclean GUI, see [[Image_Continuum#Imaging_the_Continuum | Imaging the Continuum]] section of the guide.


== Apply a primary beam correction ==
If you are creating your mask manually, notice that the default is to apply the mask to the current channel you are viewing. The mask can also be applied to all channels. This is indicated with the "This Channel" or "All Channels" toggle.


Once all imaging is finished, diagnostic images will be made. The first of these is a primary beam correction image of the data. Each telescope's primary beam is, for the most part, approximately a gaussian with small side lobes that can be approximated to zero. Because of this, the center of the beam has much more sensitivity than the edges. To correct for this, flux is added to the edges of the image in order for all pixels across the beam to have the same relative brightness based on the beam pattern.
In CASA 5.4 and later, {{tclean}} calls with gridder = 'mosaic' have an additional parameter mosweight with a default of True. When mosweight = True, the gridder weights each field in the mosaic independently. The mosweight parameter is particularly important for mosaics with non-uniform sensitivity, with rectangular shapes, or when using more uniform values of robust Briggs weighting. For more information on mosweight, please see the {{tclean}} documentation.
 
Impbcor is used to produce the primary beam corrected images . You will need the *.flux and *.pbcor files.  


<source lang="python">
<source lang="python">
# in CASA
# in CASA
import glob
tclean(vis=linevis,
      imagename=lineimagename,
      field=field,
      spw=spw,
      # phasecenter=phasecenter, # uncomment if mosaic or imaging an ephemeris object 
      # mosweight=True, # uncomment if mosaic     
      specmode='cube', # comment this if observing an ephemeris source
      # specmode='cubesource', #uncomment this line if observing an ephemeris source
      # perchanweightdensity=False # uncomment if you are running in CASA >=5.5.0
      start=start,
      width=width,
      nchan=nchan,
      outframe=outframe,
      veltype=veltype,
      restfreq=restfreq,
      niter=niter, 
      threshold=threshold,
      interactive=True,
      cell=cell,
      imsize=imsize,
      weighting=weighting,
      robust=robust,
      gridder=gridder,
      pbcor=True,
      restoringbeam='common',
      chanchunks=-1, # break up large cubes automatically so that you don't run out of memory.
      usepointing=False)
</source>


myimages = glob.glob("*.image")
As you may recall from the continuum imaging section, {{tclean}} generates several images with the name imagename+extension every time it cleans an image. If you re-run tclean with the same imagename, {{tclean}} will use the existing files as a starting point, continuing the tclean where you left off. To start completely from scratch, either change the imagename or delete all the files from the previous {{tclean}} run. Note that CASA retains some image information in memory, so to truly delete the images from open version of CASA, you need to run the {{rmtables}} command. See below for an example.


rmtables('*.pbcor')
<source lang="python">
for image in myimages:
# in CASA
pbimage = image.rsplit('.',1)[0]+'.flux'
clearcal(vis=linevis)
outfile = image.rsplit('.',1)[0]+'.pbcor'
delmod(vis=linevis)
impbcor(imagename=image, pbimage=pbimage, outfile = outfile)
for ext in ['.image','.mask','.model','.image.pbcor','.psf','.residual','.pb','.sumwt']:
    rmtables(lineimagename + ext)
</source>
</source>


== Export the images ==
== Export the images ==


Use exportfits to create fits files of the *.flux and *.pbcor files.  
Use {{exportfits}} to create fits files of the *.flux and *.pbcor files.  


<source lang="python">
<source lang="python">
Line 185: Line 212:
     exportfits(imagename=image, fitsimage=image+'.fits',overwrite=True)
     exportfits(imagename=image, fitsimage=image+'.fits',overwrite=True)


myimages = glob.glob("*.flux")
myimages = glob.glob("*.pb")
for image in myimages:
for image in myimages:
     exportfits(imagename=image, fitsimage=image+'.fits',overwrite=True)
     exportfits(imagename=image, fitsimage=image+'.fits',overwrite=True)  
</source>
</source>


== Create Diagnostic PNGs ==
== Create Diagnostic PNGs ==
 
[[File:TWHydra_CO_3_2.image.mom8.png|thumb|<caption>The moment 8 map is shown for the CO (3-2) line cube created above.</caption>]]
[https://casaguides.nrao.edu/index.php/First_Look_at_Image_Analysis The First Look at Image Analysis] guide gives an introduction to a variety of options to begin image analysis, including using {{immoments}} to create moment maps.
[https://casaguides.nrao.edu/index.php/First_Look_at_Image_Analysis The First Look at Image Analysis] guide gives an introduction to a variety of options to begin image analysis, including using {{immoments}} to create moment maps.
The commands create png files of the continuum image and moment 8 maps.  
The commands create png files of the continuum image and moment 8 maps.  
Line 199: Line 225:
# in CASA
# in CASA
os.system("rm -rf *.png")
os.system("rm -rf *.png")
mycontimages = glob.glob("calibrated*.image")
for cimage in mycontimages:
    max=imstat(cimage)['max'][0]
    min=-0.1*max
    outimage = cimage+'.png'
    os.system('rm -rf '+outimage)
    imview(raster={'file':cimage,'range':[min,max]},out=outimage)


# this will have to be run for each sourcename
mylineimages = glob.glob("*cube*manual.image")
sourcename='' # insert source here, if it isn't already set
mylineimages = glob.glob(sourcename+"*.image")
for limage in mylineimages:
for limage in mylineimages:
    rms=imstat(limage,chans='1')['rms'][0]
     mom8=limage+'.mom8'
     mom8=limage+'.mom8'
     os.system("rm -rf "+mom8)
     os.system("rm -rf "+mom8)
     immoments(limage,moments=[8],outfile=mom8)
     immoments(limage,moments=[8],outfile=mom8)
     max=imstat(mom8)['max'][0]
     mymax=imstat(mom8)['max'][0]
     min=-0.1*max
     mymin=-0.1*mymax
     os.system("rm "+mom8+".png")
     os.system("rm -rf "+mom8+".png")
     imview(raster={'file':mom8,'range':[min,max]},out=mom8+'.png')
     imview(raster={'file':mom8,'range':[mymin,mymax]},out=mom8+'.png')
</source>
</source>
'''[[Guide_NA_ImagingTemplate | Return to the Main Page]]'''

Latest revision as of 20:36, 28 February 2024

This guide continues from Image the Continuum Template and Self-Calibration Template (optional). Imaging parameters and calibration tables (if applicable) should already be set prior to continuing. Commands for this guide can be found in scriptForImaging_template.py available on github.

Continuum Subtraction for Line Emission

If you have observations that include both line and strong continuum emission (>3 sigma per channel), you should subtract the continuum from the spectral windows before imaging the line. You do not need to continuum subtract if the line of interest is an absorption line.

To subtract the continuum, you need to select channel ranges which only contain continuum. You can use plotms to make sure that the appropriate data is in the appropriate column of your ms. Note that this behavior is different in the pipeline implementation of continuum subtraction hif_uvcontsub. The continuum subtraction routine will then do a linear fit to each integration to determine the continuum and then subtract that linear fit from the data. The range used to fit the continuum is just the opposite of the channels you flagged when creating the continuum (see Create an Averaged Continuum MS section of the Image Continuum guide. You can either manually invert the channels or use the Analysis Utilities routine au.invertChannelRanges to determine the channel ranges. Note that if you use au.invertChannelRanges, you will need to include any continuum spws that weren't in flagchannels. For example, if your continuum spws are '0,1,2' and flagchannels='1:260~500', au.invertChannelRanges will return '1:0~259,1:501~3839'. The fitspw parameter should be '0,1:0~259,1:501~3839,2'. If you haven't installed Analysis Utilities, see Obtaining Analysis Utilities for instructions.

Continuum subtraction is done per field. If all your fields have the same line-free channels, you only have to run uvcontsub once. However, if different fields have different line-free channels, then you will need to run uvcontsub multiple times. (And probably get a cup of coffee or two.)

The output file for uvcontsub will be vis + ".contsub". It will read from the corrected data column if it is present and the data column if the corrected data column is not present.

Note that want_cont=True produces a model of the emission and not the actual continuum subtracted ms. The results of want_cont=True should not be used to produce an image of the continuum for a source.

# in CASA
fitspw = '2:0~1200;1500~3839,3:0~1200;1500~3839' # line free channels. Use au.invertChannelRanges
linespw = '2,3' # line spectral windows. You can subtract the continuum from multiple spectral line windows at once.

finalvis='calibrated_final.ms'

uvcontsub(vis=finalvis,
          spw=linespw, # spw to do continuum subtraction on
          fitspw=fitspw, # regions without lines.
          excludechans=False, # fit the regions in fitspw
          #combine='spw', uncomment if there are no line-free channels in the line spectral window.  
          solint='int',
          fitorder=1,
          want_cont=False) # This value should not be changed.

Apply continuum self-calibration to line data (optional)

This section depends on solutions derived with Self-Calibration Template. Skip to Image Line Emission if you do not wish to apply self-calibration solutions to the line data.

If you find self-calibration does help with lowering the rms in your continuum images, it is a good idea to apply the continuum self-calibration to the line data. Depending on if you performed continuum subtraction, select the definition of linevis accordingly. Once this has been done, it is recommended that you save the flags before you apply the self-calibration solution to the individual line spectral windows, in case you do not like the results or they do not improve the image. If self-calibration of the continuum does improve the quality of the data, apply the derived gaintable to the spectral line channels using the applycal task. This will improve the image quality of the stronger spectral line channels, but will not help (or harm) the weaker line channels. Then save the results of self-cal in a new ms and reset the image name. You also need to reset the corrected data column in the ms to the original calibration. The clearcal(linevis) task can also be used to return your ms to its original pre-self-cal state, if you are dissatisfied with the self-calibration results.

# in CASA
# Uncomment one of the following: 
# linevis = finalvis+'.contsub' # if continuum subtracted
# linevis = finalvis  #  if not continuum subtracted
# save original flags in case you don't like the self-cal
flagmanager(vis=linevis,mode='save',versionname='before_selfcal',merge='replace')

spwmap_line = [0] # Mapping self-calibration solution to the individual line spectral windows.
applycal(vis=linevis,
         spwmap=[spwmap_line, spwmap_line], # entering the appropriate spwmap_line value for each spw in the input dataset
         field=field,
         gaintable=['pcal3','apcal'],
         gainfield='',
         calwt=False,
         flagbackup=False,
         interp=['linearperobs','linearperobs'])

# Save results of self-cal in a new ms and reset the image name.
split(vis=linevis,
      outputvis=linevis+'.selfcal',
      datacolumn='corrected')

Image line emission (repeat as necessary)

You should now have a measurement set that is ready to create cubes of the line emission.

If you are new to line imaging, look at First Look at Line Imaging for an introduction to creating line cubes.

You may also find the Automasking Guide useful if you would like tclean to produce the mask for you.

If you expect more complex emission and do not want to create the mask by hand, you can use the directions at Create a Clean Mask from Continuum Image or Moment Cube to create a mask from the dirty cube.

Depending on the observation and the steps you have applied previously, the measurement set may have a variety of names. Make sure to select the correct option below.

# in CASA
finalvis = 'calibrated_final.ms'

# uncomment if you have neither continuum subtracted nor self-calibrated your data
# linevis = finalvis
# uncomment if you have continuum subtracted your data
# linevis = finalvis + '.contsub'
# uncomment if you have both continuum subtracted and self-calibrated your data
# linevis = finalvis + '.contsub.selfcal'
# uncomment if you have only self-calibrated your data
# linevis = finalvis + '.selfcal'

The measurement set indicated in the linevis variable will be used for the rest of the cleaning. Before starting to clean your line cube, run a vishead or listobs to check on the spectral window and field numbers, which may have been re-numbered during the previous steps in the imaging process.

# in CASA
vishead(linevis)

Now you need to set the necessary parameters for tclean. If you haven't already, follow the procedure in the Image Continuum section to set the imsize, cellsize, field, phasecenter,etc. Here we focus on the additional parameters needed to image line data.

First, we set the imagename. Here we name the image for the source and line observed, but you could give it any name you'd like.

# in CASA
sourcename ='n253' # name of source
linename = 'CO10' # name of transition 
lineimagename = sourcename+'_'+linename # name of line image

Next select the spws you would like to image. You should only image spws associated with a single rest frequency in the same image. If you have multiple executions and did not regrid the frequency axis using cvel, you will have to select multiple spws (one for each execution). The restfreq is typically set at the rest frequency of the line of interest. If the source is significantly redshifted (z>0.2), common practice is to set the rest frequency to the observed sky frequency (nu_rest/1+z) instead. Then the velocity axis shows offsets from the expected sky frequency.

Finally, if cvel or mstransform was used to regrid spectral windows, make sure to use the same values below as you used with those tasks. In other words, avoid regridding your frequency axis twice: once in cvel and once in tclean.

The CO window is plotted in plotms. Use this to determine the start and nchan parameters.
# in CASA
spw = '0' # update to the spw you would like to image
restfreq='115.27120GHz’


The start, width, and nchan parameters will determine the size of the cube you create. Setting the values at their defaults will image the entire spectral window at the native resolution.

# in CASA
start = ''
width = ''
nchan = -1

You can also image a subset of the cube. By only imaging a subsection of the spectral window you can speed up the time it takes {tclean} to produce a cube and reduces the final size of the cube.

# in CASA
start='-100km/s' 
width='2km/s'
nchan = 100

Remember that you have already set two specific velocity parameters called outframe and veltype. Outframe is the coordinate system used for the observation. If you have access to the original proposal, this can be found in the Observing Tool (OT) under field setup. A list of acceptable outframes that can be used in CASA can be found at https://help.almascience.org/kb/articles/what-are-the-frequency-reference-frames-in-casa. Note: heliocentric(hel) is deprecated in CASA. Use barycentric(bary) in this case. The most common choices are 'bary' and 'lsrk'. Usually 'bary' is used for 'extragalactic' sources and 'lsrk is used for 'galactic' sources. For ephemeris objects, the outframe should be set to a blank string, for example outframe = '', as the you have likely already regridded to the source velocity.

Generally, if you set outframe = 'bary' and restfreq = observed frequency, the line center should be at around 0 km/s. If you set outframe = 'lsrk' and restfreq = lab frequency, you will need to know the source radial velocity in order to predict the line position. If you are unsure, you can use the plotms command below to plot the visibilities to explore the effects of outframe and restfreq.

You will also have to set the veltype for the tclean command. This variable has only two options available, radio and optical. It is standard to leave this set to ‘radio’ in all projects regardless of the velocity frame used in the project.

# in CASA
outframe='lsrk' # velocity reference frame. See science goals.
veltype='radio' # velocity type.

You can use plotms to find the line if it is bright enough to show up in the averaged visibilities. This is similar to the procedure you used to identify the line when creating the averaged continuum ms in Continuum MS.

Channel 54 of the CO line cube is shown. Create a mask for each channel or all channels and proceed with cleaning.
# in CASA
plotms(vis=linevis,xaxis='velocity',yaxis='amp',avgtime='1e8',avgscan=True,avgantenna=True,
    spw=spw,coloraxis='spw',transform=True,freqframe=outframe.upper(),restfreq=restfreq)

The tclean command for generating your line cube is shown below. You can use this template to image all targeted lines in your observation. For more information about the tclean GUI, see Imaging the Continuum section of the guide.

If you are creating your mask manually, notice that the default is to apply the mask to the current channel you are viewing. The mask can also be applied to all channels. This is indicated with the "This Channel" or "All Channels" toggle.

In CASA 5.4 and later, tclean calls with gridder = 'mosaic' have an additional parameter mosweight with a default of True. When mosweight = True, the gridder weights each field in the mosaic independently. The mosweight parameter is particularly important for mosaics with non-uniform sensitivity, with rectangular shapes, or when using more uniform values of robust Briggs weighting. For more information on mosweight, please see the tclean documentation.

# in CASA
tclean(vis=linevis,
       imagename=lineimagename, 
       field=field,
       spw=spw,
       # phasecenter=phasecenter, # uncomment if mosaic or imaging an ephemeris object   
       # mosweight=True, # uncomment if mosaic      
       specmode='cube', # comment this if observing an ephemeris source
       # specmode='cubesource', #uncomment this line if observing an ephemeris source
       # perchanweightdensity=False # uncomment if you are running in CASA >=5.5.0
       start=start,
       width=width,
       nchan=nchan, 
       outframe=outframe,
       veltype=veltype, 
       restfreq=restfreq, 
       niter=niter,  
       threshold=threshold, 
       interactive=True,
       cell=cell,
       imsize=imsize, 
       weighting=weighting,
       robust=robust,
       gridder=gridder,
       pbcor=True,
       restoringbeam='common',
       chanchunks=-1, # break up large cubes automatically so that you don't run out of memory.
       usepointing=False)

As you may recall from the continuum imaging section, tclean generates several images with the name imagename+extension every time it cleans an image. If you re-run tclean with the same imagename, tclean will use the existing files as a starting point, continuing the tclean where you left off. To start completely from scratch, either change the imagename or delete all the files from the previous tclean run. Note that CASA retains some image information in memory, so to truly delete the images from open version of CASA, you need to run the rmtables command. See below for an example.

# in CASA
clearcal(vis=linevis)
delmod(vis=linevis)
for ext in ['.image','.mask','.model','.image.pbcor','.psf','.residual','.pb','.sumwt']:
    rmtables(lineimagename + ext)

Export the images

Use exportfits to create fits files of the *.flux and *.pbcor files.

# in CASA
import glob

myimages = glob.glob("*.pbcor")
for image in myimages:
    exportfits(imagename=image, fitsimage=image+'.fits',overwrite=True)

myimages = glob.glob("*.pb")
for image in myimages:
    exportfits(imagename=image, fitsimage=image+'.fits',overwrite=True)

Create Diagnostic PNGs

The moment 8 map is shown for the CO (3-2) line cube created above.

The First Look at Image Analysis guide gives an introduction to a variety of options to begin image analysis, including using immoments to create moment maps. The commands create png files of the continuum image and moment 8 maps.

# in CASA
os.system("rm -rf *.png")

mylineimages = glob.glob("*cube*manual.image")
for limage in mylineimages:
    mom8=limage+'.mom8'
    os.system("rm -rf "+mom8)
    immoments(limage,moments=[8],outfile=mom8)
    mymax=imstat(mom8)['max'][0]
    mymin=-0.1*mymax
    os.system("rm -rf "+mom8+".png")
    imview(raster={'file':mom8,'range':[mymin,mymax]},out=mom8+'.png')

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