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STATCONT - A statistical continuum level determination method for line-rich sources

STATCONT is a python-based tool designed to determine the continuum emission level in line-rich spectral data. The tool inspects the intensity distribution of a given spectrum and automatically determines the continuum level by using differeng statistical approaches. The different methods included in STATCONT have been tested against synthetic data. We conclude that the sigma-clipping algorithm provides the most accurate continuum level determination, together with information on the uncertainty in its determination. This uncertainty is used to correct the final continuum emission level, resulting in the here-called 'corrected sigma-clipping method' or cSCM. The cSCM has been tested against synthetic data cubes reproducing typical conditions found in astronomical line-rich sources. In general, we obtain accuracies of < 10 % in the continuum determination, and < 5 % in most cases. The main products of STATCONT are the continuum emission level, together with its uncertainty, and data cubes containing only spectral line emission, i.e. continuum-subtracted data cubes. STATCONT also includes the option to estimate the spectral index or variation of the continuum emission with frequency.

If you find STATCONT useful, please cite/refer to: Sanchez-Monge, Schilke, Ginsburg, Cesaroni and Schmiedeke 2018, A&A, 609, A101 Access to the article in PDF format.

More information about STATCONT can be found in http://www.astro.uni-koeln.de/~sanchez/statcont

This README document is intented to help you install and use STATCONT. In the following you will find:


Installation instructions

STATCONT uses the ASTROPY package-template and is fully compatible with the ASTROPY ecosystem. It is freely available for download at the GitHub repository Radio Astro Tools, as well as in this webpage. The only required software to use STATCONT is Python and Astropy, together with some basic Python packages that you can find listed here.

Installation method 1
You can clone STATCONT in your computer from the GitHub repository. For this, create a directory and move there. Then type:

   git init
   git clone https://github.com/radio-astro-tools/statcont
   cd statcont
   python setup.py install

Installation method 2
You can also directly install STATCONT by typing in a terminal session in your computer (you may need sudo permissions depending on the configuration of your system):

   pip install https://github.com/radio-astro-tools/statcont/archive/master.zip

Installation method 3
Alternatively, STATCONT can also be downloaded locally as a zip file from: master.zip. In order to install it, download the file to a directory in your computer:

   unzip master.zip
   cd statcont
   python setup.py install

How to solve permission errors
If you get a permission error, this means that you do not have the required administrative access to install STATCONT to your Python installation. In this case you can use the option --user when installing the setup.py script. You can follow these instructions:

   python setup.py install --user --install-scripts="~/bin/"
   export PATH=~/bin/:$PATH

Check your installation
Following the installation, you have immediate access to STATCONT in your computer by typing "statcont" in a terminal session. For example, inspect the help by doing:

   statcont --help

At the beginning of the help message you will see the version of STATCONT. The current stable release is version 1.5.


Required Python packages

STATCONT uses the following Python packages:

The versions indicated above have been recently tested, older versions worked fine in previous tests and are expected to continue working.


Main STATCONT commands and options

The following table contains the main commands and options of STATCONT. They can be explored and executed by typing

   statcont --help
Command Necessary? Description
--help Show the help message and all the STATCONT commands
-i / --iname NECESSARY
(unless -f, -s or -l are used)
Name of the FITS file to be processed (without extension, which should be .fits)
Example: -i SYNTHETIC_cube
The file SYNTHETIC_cube.fits has to be stored in the data directory
-f / --ifile NECESSARY
(unless -i, -s or -l are used)
Text file containing a list of FITS files to be processed (files to be processed have to be listed without extension, which should be .fits)
Example: -f file.txt
The file file.txt has to be stored in the running directory
-s / --ispec NECESSARY
(unless -i, -f or -l are used)
Name of the ASCII file to be processed (without extension, which should be .dat)
Example: -s my_emission
The file my_emission.dat has to be stored in the data directory
-l / --ilist NECESSARY
(unless -i, -f or -s are used)
Text file containing a list of ASCII files to be processed (files to be processed have to be listed without extension, which should be .dat)
Example: -l file.txt
The file file.txt has to be stored in the running directory
-p / --ipath OPTIONAL Specify the path/directory there the files to be processed are stored.
This path/directory has to inside the data directory
-n / --noise NECESSARY Typical RMS noise level of the observations
A value of 1 can be used in most of the cases
--continuum OPTIONAL Determination of the continuum level and create of line-only cube or spectrum
--plots OPTIONAL Create plots on a pixel-by-pixel basis
--cutout OPTIONAL Create a cutout image of the original FITS cube
Three parameters have to be specified (xcen, ycen and size) in pixels
--spindex OPTIONAL Determine the spectral index (ALPHA) defined as flux = FACTOR * frequency^(ALPHA)

Examples and test cases

In the following we explain how to execute the main tasks of STATCONT. A set of test cases is provided in this test_cases.tar.gz file. Download the file to your computer and follow these instructions:

   gunzip test_cases.tar.gz
   tar -xvf test_cases.tar

This creates a directory called statcont-tests. Inside, you will find a directory called data that contains three other subdirectories MAP_TESTS, SPEC_TESTS, and SPINDEX

STATCONT requires of a directory data where the files to be processed are stored. By executing STATCONT, another directory called products will be generated. The files to be processed, can be directly saved in the data directory or in subdirectories within data. In the examples provided here, we have a set of single-spectrum files (in ASCII format) saved in the subdirectories SPEC_TESTS and SPINDEX, and a FITS cube in the subdirectory MAP_TESTS.

Determining the continuum in single spectrum files (ASCII files)

   statcont -p SPEC_TESTS -s my_emission -n 1
  • The option -p indicates the subdirectory in data that contains the file to be analyzed
  • The option -s indicates the name of the ASCII file to be analyzed, without the extension [.dat]
  • The option -n indicates the rms noise level (in the units of the data) of the data to be analyzed. In this case, it is 1 K

If you want to determine the continuum level:

   statcont -p SPEC_TESTS -s my_emission -n 1 --continuum
  • The option --continuum makes use of the 'corrected sigma-clipping algorithm' described in Sanchez-Monge et al (2018), to determine the continuum level, the error in the continuum level, and to produce a file that contains only the line emission, i.e. a continuum-subtracted file

Using different methods to determine the continuum level. STATCONT contains a set of different statistical methods that can be used by the user at his/her convenience. You can select all them like this:

   statcont -p SPEC_TESTS -s my_emission -n 1 --call

Or you can select individual methods like:

   statcont -p SPEC_TESTS -s my_emission -n 1 --cmax
   statcont -p SPEC_TESTS -s my_emission -n 1 --cmean
   statcont -p SPEC_TESTS -s my_emission -n 1 --cmedian
   statcont -p SPEC_TESTS -s my_emission -n 1 --cpercent
   statcont -p SPEC_TESTS -s my_emission -n 1 --cGaussian
   statcont -p SPEC_TESTS -s my_emission -n 1 --cKDEmax
   statcont -p SPEC_TESTS -s my_emission -n 1 --csigmaclip

You can call several methods at once:

   statcont -p SPEC_TESTS -s my_emission -n 1 --cmax --cGaussian --csigmaclip

The different methods are explained in Sanchez-Monge et al (2018)

If you want to remove the continuum from the original spectrum, in order to produce a line-only data file, you can use:

   statcont -p SPEC_TESTS - s my_emission -n 1 --csigmaclip --cfree
  • The option --cfree uses the 'corrected sigma-clipping algorithm' to determine the continuum, and removes it from the original datafile.

You can use other example files, like for example:

   statcont -p SPEC_TESTS -s my_absorption -n 1 --continuum

And you can select multiple files simultaneously, as long as they are saved in the same subdirectory, and they are considered to have the same rms noise level (option -n ):

   statcont -p SPEC_TESTS -s my_emission my_absorption my_broad-lines -n 1 --continuum

The products can be found in products/SPEC_TESTS You can produce plots of the spectrum analyzed with the continuum levels by using the option --plots. As an example:

   statcont -p SPEC_TESTS -s my_emission -n 1 --continuum --plots

In this case the plot is saved in products/SPEC_TESTS/plots/my_emission_1_1.png You can use all the continuum methods and plot them all together, like:

   statcont -p SPEC_TESTS -s my_emission -n 1 --call --plots

Have a look now at the plot products/SPEC_TESTS/plots/my_emission_1_1.png (see image below)

STATCONT all methods

Determining the continuum in a 3D cube file (FITS files)

   statcont -p MAP_TESTS -i SYNTHETIC_cube -n 1
  • The option -p indicates the subdirectory in data that contains the file to be analyzed
  • The option -i indicates the name of the FITS file to be analyzed, without the extension [.fits]
  • The option -n indicates the rms noise level (in the units of the data) of the data to be analyzed. In this case, it is 1 K

If you want to determine the continuum level:

   statcont -p MAP_TESTS -i SYNTHETIC_cube -n 1 --continuum

This process analyzes each individual pixel, determining the continuum level, and then combines all the pixels to produce a continuum FITS image with the label "_continuum". Simultaneously, the --csigmaclip method provides information on the error in the determination of the continuum that is saved as a FITS image with the label "_noise". Finally, a line-only FITS datacube is also produced. All these files are saved in the directory products/MAP_TESTS

All the other options applicable to the single-spectrum ASCII files are also available for the FITS images (e.g. different continuum methods, creation of plots).

If your original FITS file is too large and you just want to determine the continuum level of a small portion you can indicate it like this:

   statcont -p MAP_TESTS -i SYNTHETIC_cube -n 1 --continuum --cutout 25 25 6
  • The --cutout option allows to select a central pixel (in this case 25, 25) and the number of pixels in each direction of the final image (in this case 6). With this option, the products are saved with the label "_cutout"

Determining the spectral index from multiple input files

If you have multiple ASCII or FITS files at different frequencies, you can use the option --spindex to determine, first, the continuum level of every single file, and then the spectral index, i.e. the variation of the continuum emission with frequency.

The spectral index (ALPHA) is defined as flux = FACTOR * frequency^(ALPHA)

   statcont -p SPINDEX -l list.txt -n 1 --continuum
   statcont -p SPINDEX -l list.txt -n 1 --spindex

The first command determines the continuum level for all the files contained in the list.txt file, while the second command determines the spectral index.


Real data examples

If you have multiple ASCII or FITS files at different frequencies, you can use

SgrB2 G29.96-0.02
Example case SgrB2(N) (see Sanchez-Monge et al 2017) Example case G29.96-0.02 (see Cesaroni et al 2017)

In both examples: (Top-left) Continuum emission map as determined with STATCONT. (Top-right) Continuum emission map determined with the classical approach (search for line-free channels). (Middle-left) Noise map obtained with STATCONT. (Middle-right) Ratio of the STATCONT to classical-approach continuum maps. (Bottom panels) Continuum-subtracted spectra using STATCONT towards two selected positions A and B, shown in the top-left panel.


Publications citing STATCONT

The following is a list with more than 30 publications using STATCONT in their analysis. The publications cover topics of low and high-mass star formation, extragalactic sources and astrochemical studies.

  • Is There Any Linkage between Interstellar Aldehyde and Alcohol?
    by Mondal et al. 2021, ApJ, 922, 194 (link)

  • A cold accretion flow onto one component of a multiple protostellar system
    by Murillo et al. 2021, accepted for publication in A&A (link)

  • Starburst Energy Feedback Seen Through HCO + /HOC + Emission in NGC 253 from ALCHEMI
    by Harada et al. 2021, accepted for publication in ApJ (link)

  • The GUAPOS project. II. A comprehensive study of peptide-like bond molecules
    by Colzi et al. 2021, A&A, 653, A129 (link)

  • ALCHEMI: an ALMA Comprehensive High-resolution Extragalactic Molecular Inventory. Survey presentation and first results from the ACA array
    by Martin et al. 2021, accepted for publication in A&A (link)

  • ALMA observations of doubly deuterated water: inheritance of water from the prestellar environment
    by Jensen et al. 2021, A&A, 650, A172 (link)

  • The ionized heart of a molecular disk. ALMA observations of the hyper-compact HII region G24.78+0.08 A1
    by Moscadelli et al. 2021, A&A, 650, A142 (link)

  • Star formation in 'the Brick': ALMA reveals an active protocluster in the Galactic centre cloud G0.253+0.016
    by Walker et al. 2021, MNRAS, 503, 77 (link)

  • Fragmentation in the massive G31.41+0.31 protocluster
    by Beltran et al. 2021, A&A, 648, A100 (link)

  • Digging into the Interior of Hot Cores with ALMA (DIHCA). I. Dissecting the High-mass Star-forming Core G335.579-0.292 MM1
    by Olguin et al. 2021, ApJ, 909, 199 (link)

  • The prebiotic molecular inventory of Serpens SMM1. I. An investigation of the isomers CH3NCO and HOCH2CN
    by Ligterink et al. 2021, A&A, 647, A87 (link)

  • Subarcsecond Imaging of the Complex Organic Chemistry in Massive Star-forming Region G10.6-0.4
    by Law et al. 2021, ApJ, 909, 214 (link)

  • The GUAPOS project: G31.41+0.31 Unbiased ALMA sPectral Observational Survey. I. Isomers of C2H4O2
    by Mininni et al. 2020, A&A, 644, A84 (link)

  • Multidirectional Mass Accretion and Collimated Outflows on Scales of 100-2000 au in Early Stages of High-mass Protostars
    by Goddi et al. 2020, ApJ, 905, 25 (link)

  • Evidence for Dense Gas Heated by the Explosion in Orion KL
    by Li et al. 2020, ApJ, 901, 62 (link)

  • Detection of hydroxyacetone in protostar IRAS 16293-2422 B
    by Zhou et al. 2020, RAA, 20, 125 (link)

  • Constraints of the Formation and Abundances of Methyl Carbamate, a Glycine Isomer, in Hot Corinos
    by Sahu et al. 2020, ApJ, 899, 65 (link)

  • Astrochemistry During the Formation of Stars
    by Jorgensen et al. 2020, ARA&A, 58, 727 (link)

  • Exploring the formation pathways of formamide. Near young O-type stars
    by Allen et al. 2020, A&A, 636, A67 (link)

  • The HI/OH/Recombination line survey of the inner Milky Way (THOR): data release 2 and H I overview
    by Wang et al. 2020, A&A, 634, A83 (link)

  • Survey Observation of CH 3 NH 2 and Its Formation Process
    by Suzuki et al. 2019, submitted to ApJ (link)

  • Molecular analysis of a high-mass prestellar core candidate in W43-MM1
    by Molet et al. 2019, A&A, 626, A132 (link)

  • The CARMA-NRO Orion Survey. Filamentary structure as seen in C18O emission
    by Suri et al. 2019, A&A, 623, A142 (link)

  • A 10-M⊙ YSO with a Keplerian disk and a nonthermal radio jet
    by Moscadelli et al. 2019, A&A, 622, A206 (link)

  • Evidence for the First Extragalactic Hydrogen Recombination Line Maser in NGC 253
    by Baez-Rubio et al. 2018, ApJL, 867, L6 (link)

  • Chasing discs around O-type (proto)stars. ALMA evidence for an SiO disc and disc wind from G17.64+0.16
    by Maud et al. 2018, A&A, 620, A31 (link)

  • The Extraordinary Outburst in the Massive Protostellar System NGC 6334I-MM1: Flaring of the Water Masers in a North-South Bipolar Outflow Driven by MM1B
    by Brogan et al. 2018, ApJ, 866, 87 (link)

  • The feedback of an HC HII region on its parental molecular core. The case of core A1 in the star-forming region G24.78+0.08
    by Moscadelli et al. 2018, A&A, 616, A66 (link)

  • Accelerating infall and rotational spin-up in the hot molecular core G31.41+0.31
    by Beltran et al. 2018, A&A, 615, A141 (link)

  • The physical and chemical structure of Sagittarius B2 - III. Radiative transfer simulations of the hot core Sgr B2(M) for methyl cyanide
    by Pols et al. 2018, A&A, 614, A123 (link)

  • Radio outburst from a massive (proto)star. When accretion turns into ejection
    by Cesaroni et al. 2018, A&A, 612, A103 (link)

  • Distributed Star Formation throughout the Galactic Center Cloud Sgr B2
    by Ginsburg et al. 2018, ApJ, 853, 171 (link)

  • The physical and chemical structure of Sagittarius B2 - II. Continuum millimeter emission of SgrB2(M) and SgrB2(N) with ALMA
    by Sanchez-Monge et al. 2017, A&A, 604, A6 (link)

  • Chasing disks around O-type (proto)stars: Evidence from ALMA observations
    by Cesaroni et al. 2017, A&A, 602, A59 (link)

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