M100 Band3 Combine 4.2.2

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Overview

Combine and Image the 7m+12m

Split off CO spws

# In CASA
os.system('m100_*m.ms.listobs')
listobs('M100_Band3_12m_CalibratedData.ms',listfile='m100_12m.ms.listobs')
listobs('M100_Band3_7m_CalibratedData.ms',listfile='m100_7m.ms.listobs')

Investigation shows that the CO is spw=0 for the 12m data and in spws 1,3 for the 7m data. There are two for the 7m data because some of the data was taken with a slightly different correlator setup.

Also note that the integration time per visibility is different: 10.1s for the 7m and 6.05s for the 12m data as this will be important to correctly weighting the data.

# In CASA
os.system('rm -rf m100_12m_CO.ms')
split(vis='M100_Band3_12m_CalibratedData.ms',
      outputvis='m100_12m_CO.ms',spw='0',field='M100',
      datacolumn='data',keepflags=False)
os.system('rm -rf m100_7m_CO.ms')
split(vis='M100_Band3_7m_CalibratedData.ms',
      outputvis='m100_7m_CO.ms',spw='1,3',field='M100',
      datacolumn='data',keepflags=False)

Because the continuum is too weak to contribute to a 5km/s channel we will forgo the the continuum subtraction step.

Concat with 1/sigma2 scaling of Weights

When combining data with disparate properties it is very important that the relative weights of each visibility be in the correct proportion to the other data according to the radiometer equation. Formally, the visibility weights should be proportional to 1/sigma**2 where sigma is the variance or rms noise of a given visibility.

<figure id="12m_WT.png">

12m weights.

</figure>

<figure id="7m_WT.png">

7m weights.

</figure>


CASA currently scales the weights by 1/[(Tsys(i) * Tsys(j)] if calwt=True for the Tsys table applycal. To verify, we plot the weights of the 7m and 12m data. No averaging can be turned on when plotting the weights.

# In CASA
os.system('rm -rf 7m_WT.png 12m_WT.png')
plotms(vis='m100_12m_CO.ms',yaxis='wt',xaxis='uvdist',spw='0~2:200',
       coloraxis='spw',plotfile='12m_WT.png')

plotms(vis='m100_7m_CO.ms',yaxis='wt',xaxis='uvdist',spw='0~2:200',
       coloraxis='spw',plotfile='7m_WT.png')

As you can see from these plots, the weights are quite similar at this stage because the data were taken under similar weather conditions and hence Tsys.

Assuming that the 7m and 12m antennas have similar apperture and quantization efficiencies (a reasonable assumption since they were designed this way)


rms noise in a single channel for a single visibility is:

[math]\displaystyle{ \sigma_{ij}=\frac{2k}{A_{eff}} }[/math] [math]\displaystyle{ \sqrt{\frac{T_{sys,i} T_{sys,j}}{\Delta\nu_{ch} t_{ij}}} }[/math]


Where k is Boltzmann's constant, Aeff is the effective antenna area, Tsys,i is the system temperature for antenna i, Δνch is the channel width, and tij is the integration time per visibility.

The two key things that are different between the 7m and 12m-array data are that the effective dish Areas are different by (7/12)2 and the integration times are different by sqrt(10.1/6.05). Since dish area is in the numerator of the radiometer equation and integration time per visibility is in the denominator, and assuming WT propto 1/sigma2, the 7m weight should be scaled by: (7./12.)4 x (10.1/6.05) = 0.193

to account for the difference in telescope size and integration time per visibility.

<figure id="Intcombo_0.193_WT.png">

7m and 12m weights after scaling by relative sensitivity.

</figure>

  1. Concat and scale weights
# In CASA
os.system('rm -rf M100_Intcombo_0.193.ms')
concat(vis=['m100_12m_CO.ms','m100_7m_CO.ms'],
       concatvis='M100_Intcombo_0.193.ms',
       visweightscale=[1,0.193])

Now plot the concatenated weights to verify they are as expected.

# In CASA
os.system('rm -rf Intcombo_0.193_WT.png')
plotms(vis='M100_Intcombo_0.193.ms',yaxis='wt',xaxis='uvdist',spw='0~2:200',
       coloraxis='spw',plotfile='Intcombo_0.193_WT.png')

Some additinal useful plots to show the uv-distribution of amplitudes, and the spectral line as a function of velocity and channel.

# In CASA
os.system('rm -rfM100_Intcombo_0.193 _uvdist.png')
plotms(vis='M100_Intcombo_0.193.ms',yaxis='amp',xaxis='uvdist',spw='',
       avgchannel='5000',
       coloraxis='spw',plotfile='M100_Intcombo_0.193_uvdist.png') 

os.system('rm -rfM100_Intcombo_0.193 _vel.png')
plotms(vis='M100_Intcombo_0.193.ms',yaxis='amp',xaxis='velocity',spw='',
       avgtime='1e8',coloraxis='spw',
       transform=True,freqframe='LSRK',restfreq='115.271201800GHz',
       plotfile='M100_Intcombo_0.193_vel.png')

os.system('rm -rfM100_Intcombo_0.193 _chan.png')
plotms(vis='M100_Intcombo_0.193.ms',yaxis='amp',xaxis='channel',spw='',
       avgtime='1e8',coloraxis='spw',plotfile='M100_Intcombo_0.193_chan.png')