Constructing a New Wavelength Template
Overview
This doc describes how to create a wavelength template used to perform wavelength calibration with the Automated Algorithms.
See Wavelength Calibration for a discussion of various algorithms and see WaveCalib for a discussion of the main outputs and good/bad examples.
Finding Data
To build a new template, the requirements are wavelength calibrations for the arc spectra over the full wavelength range needed. This may take multiple exposures of arc lamps to cover the full range.
Using the Holy Grail Algorithm
Once you have a set of different arc lamp exposures that cover the desired range, run through the data using the option of the Holy Grail algorithm to generate a wavelength calibration and select the slits where the technique is successful. See WaveCalib for an example QA plot that illustrates a good wavelength solution.
With a complete set of correctly calibrated arc line data, identify wavelength regions, with no gaps, that cover the full range in wavelength desired.
In situations where the Holy Grail fails, one may resort to pypeit_identify.
If a calibrated arc line spectrum that covers the desired wavelength range is
already available, an ascii file with 2 columns, wavelength and flux,
can be used instead of running the reduction with the Holy Grail
algorithm.
Creating the Template
Once all of the slits and wavelength calibration files are selected, use
build_template() to turn the
list of slits, wavelength ranges, and WaveCalib files into a final
template.
For longevity, it is a good idea to install the PypeIt Development Suite (see
here) and combine your solution with all PypeIt wavelength
solutions using the same instrument and grating. If you used the
pypeit_identify utility, it will output a file called wvcalib.fits.
You should put this file in the appropriate instrument folder in the PypeIt
Development Suite templates directory:
$PYPEIT_DEV/dev_algorithms/wavelengths/template_files/
you should also rename this file to match the current formatting:
mv wvcalib.fits ${TELESCOPE}_${INSTRUMENT}_${GRATING}_${WAVECEN}.fits
Now, open the
pypeit/core/wavecal/spectrographs/templ_TELESCOPE_INSTRUMENT.py file, and
either (1) add a new setup if yours doesn’t already exist or (2) edit a setup if
you want to add your solution to a pre-existing setup. The latter is only
usually warranted if you are extending the wavelength coverage of a previous
setup. The key information you will need is the spectral binning and the slit
spatid. Both of these numbers are printed on the command line when you
complete the fitting with the pypeit_identify utility. Once this is
setup, simply execute python templates.py from the directory that contains
templ_TELESCOPE_INSTRUMENT.py.
This will automatically put your solution into the reid_arxiv directory.
Add all of these files to git, and submit a PR for both PypeIt and the PypeIt
Development Suite.
Alternatively, if you want to construct a template file yourself (with the possible disadvantage that your solution cannot be stitched together with solutions from the same spectrograph+grating in the future), you can write a script where the input looks like the following:
from pypeit.core.wavecal import templates
templates.build_template(wfiles, slits, wv_cuts, binspec, outroot, ifiles=ifiles,
det_cut=det_cut, chk=True, normalize=False, lowredux=False,
subtract_conti=True, overwrite=overwrite, shift_wave=True)
See build_template() for a description of
all the parameters, and pypeit/core/wavecal/spectrographs for examples of
the use of this function.
This produces a file called outroot that contains the template. The templates are saved in
pypeit/data/arc_lines/reid_arxiv. It also produces a plot of the final product.