M51 at z = 0.1: Difference between revisions

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=== Cosmology Calculations ===
=== Cosmology Calculations ===
Next we'll set up some python globals to handle the scaling of the model coordinates and flux densities appropriate for new redshift. We'll primarily need the angular size and luminosity distances for a given cosmology. To keep things simple, we'll use [http://www.astro.ucla.edu/~wright/CosmoCalc.html Ned Wright's CosmoCalc] with the default cosmology; redshifts are obtained from [http://nedwww.ipac.caltech.edu/cgi-bin/nph-objsearch?objname=M51&extend=no&hconst=73&omegam=0.27&omegav=0.73&corr_z=1&out_csys=Equatorial&out_equinox=J2000.0&obj_sort=RA+or+Longitude&of=pre_text&zv_breaker=30000.0&list_limit=5&img_stamp=YES NED].
<source lang="python">
#z's
z_old_cmb = 0.002122 # CMB-referenced z for cosmological distances
z_old_lsrk = 0.001544 # z_obs from BIMA header
z_new = 0.1
# angular size distances from CosmoCalc
da_old = 9.0
da_new = 375.9
# luminosity distances from CosmoCalc
dl_old = 8.937
dl_new = 454.8
</source>


=== Preparing the Model ===
=== Preparing the Model ===

Revision as of 15:00, 29 April 2010


This article is under construction. Watch this space!

Overview

This tutorial presents a simulation of ALMA observations of a well-known galaxy, M51, as it would be observed at redshift z = 0.1.

The goal of this tutorial is to provide a complete run-through of a relatively simple simulation. Included in this simulation are the effects of (u, v) sampling of a 50-antenna ALMA, the primary beam of the ALMA antennas, and thermal noise levels appropriate for the ALMA site. Calibration overheads are not included, nor is phase noise owing to a varying troposphere. As such, this simulation should be viewed as somewhat optimistic.

For this tutorial, we'll use the BIMA SONG observations of M51 as the basis for the model. Grab the file NGC5194.bima12m.cm.fits.gz and uncompress it in a working directory.

# in bash (or other unix shell)
gunzip NGC5194.bima.12m.cm.fits

Load these data into CASA. For later convenience, we'll store the name of the resulting measurement set into the python global cubeName.

cubeName = 'm51-song'
importfits(fitsimage='NGC5194.bima12m.cm.fits', imagename=cubeName)

Cosmology Calculations

Next we'll set up some python globals to handle the scaling of the model coordinates and flux densities appropriate for new redshift. We'll primarily need the angular size and luminosity distances for a given cosmology. To keep things simple, we'll use Ned Wright's CosmoCalc with the default cosmology; redshifts are obtained from NED.

#z's 
z_old_cmb = 0.002122 # CMB-referenced z for cosmological distances
z_old_lsrk = 0.001544 # z_obs from BIMA header
z_new = 0.1

# angular size distances from CosmoCalc
da_old = 9.0
da_new = 375.9

# luminosity distances from CosmoCalc
dl_old = 8.937
dl_new = 454.8

Preparing the Model

Simdata

Results