Python Limb Darkening Toolkit - a Python toolkit for calculating stellar limb darkening profiles and model-specific coefficients for arbitrary passbands using the stellar spectrum model library by Husser et al (2013).
from ldtk import LDPSetCreator, BoxcarFilter
filters = [BoxcarFilter('a', 450, 550), # Define your passbands
BoxcarFilter('b', 650, 750), # - Boxcar filters useful in
BoxcarFilter('c', 850, 950)] # transmission spectroscopy
sc = LDPSetCreator(teff=(6400, 50), # Define your star, and the code
logg=(4.50, 0.20), # downloads the uncached stellar
z=(0.25, 0.05), # spectra from the Husser et al.
filters=filters) # FTP server automatically.
ps = sc.create_profiles() # Create the limb darkening profiles
cq,eq = ps.coeffs_qd(do_mc=True) # Estimate quadratic law coefficients
lnlike = ps.lnlike_qd([[0.45,0.15], # Calculate the quadratic law log
[0.35,0.10], # likelihood for a set of coefficients
[0.25,0.05]]) # (returns the joint likelihood)
lnlike = ps.lnlike_qd([0.25,0.05],flt=0) # Quad. law log L for the first filter
...and the same, but for 19 narrow passbands...
PyLDTk automates the calculation of custom stellar limb darkening (LD) profiles and model-specific limb darkening coefficients (LDC) using the library of PHOENIX-generated specific intensity spectra by Husser et al. (2013).
The aim of the package is to facilitate exoplanet transit light curve modeling, especially transmission spectroscopy where the modeling is carried out for custom narrow passbands. The package can be
- used to construct model-specific priors on the limb darkening coefficients prior to the transit light curve modeling
- directly integrated into the log posterior computation of any pre-existing transit modeling code with minimal modifications.
The second approach can be used to constrain the LD model parameter space directly by the LD profile, allowing for the marginalization over the whole parameter space that can explain the profile without the need to approximate this constraint by a prior distribution. This is useful when using a high-order limb darkening model where the coefficients are often correlated, and the priors estimated from the tabulated values usually fail to include these correlations.
-
Version 1.6 (4.5.2021)
- Added
ldtk.SVOFilter
filter class that creates a filter using the Spanish Virtual Observatory (SVO) Filter Profile Service (FPS). The FPS contains over 10000 named filters, and creating a filter based on the FPS data is now as simple as giving theSVOFilter
the SVO filter name.
- Added
-
Version 1.5 (3.3.2021)
-
LDTk can now use four different sets of the modelled stellar spectra:
vis
,vis-lowres
,visir
, andvisir-lowres
. The first,vis
, is the original one by Husser et al (2013) spanning from 50 nm to 2600 nm;vis-lowres
is a lower resolution version of the original dataset, binned to a 5 nm resolution;visir
is a new version of the original model set extended to span from 50 nm to 5500 nm; andvisir-lowres
is a lower resolution version of the new model set binned to 5 nm resolution. -
The model set can be chosen in the
LDPSetCreator
initialisation by setting thedataset
argument. LDTk usesvis-lowres
as a default, butvisir-lowres
can be used when dealing with IR observations, and the original versions (vis
andvisir
) can be used if a spectral resolution higher than 5 nm is required.
-
-
Version 1.4
- Added automatic detection and re-download of corrupted fits files (a highly welcome contribution by T. Fatahi).
-
Version 1.3
- Changed to calculate the limb darkening models using numba. This should give a significant performance boost.
-
Version 1.2
- Added an option to use low resolution version of the original specific intensity spectra. These spectra are binned to 5 nm resolution in wavelength and are kindly hosted by T. Husser at the same FTP server as the original spectra.
- The behavior can be toggled with a new
LDPSetCreator
initialisation argument,lowres
. - LDTk uses now low resolution spectra by default. This is because the wavelength resolution should be good enough for most broadband photometry analyses, and the this decreases the download times and file storage sizes significantly.
- Python 2.7 or Python 3
- NumPy => 1.7
- SciPy => 0.16
- tqdm
- astropy
- IPython => 3.0
Use pip
pip install [--user] [--upgrade] ldtk
or clone the source from github and follow the basic Python package installation routine
git clone https://github.com/hpparvi/ldtk.git
cd ldtk
python setup.py build install [--user]
Examples for basic and more advanced usage can be found from the notebooks
directory.
The LDPSet
class offers methods to calculate log likelihoods for a set of limb darkening models.
lnlike_ln
: Linear modellnlike_qd
: Quadratic modellnlike_tq
: Quadratic model with triangular parametrization (Kipping 2013)lnlike_nl
: Nonlinear modellnlike_gn
: General modellnlike_p2
: Power-2 model
The limb darkening profiles can be resampled to a desired sampling in mu
using the resampling methods in the LDPSet
.
resample_linear_z(nz=100)
: Resample the profiles to be linear in zresample_linear_mu(nmu=100)
: Resample the profiles to be linear in mureset_sampling()
: Reset back to native sampling in muresample()
:
- LDPSetCreator : Generates a set of limb darkening profiles given a set of filters and stellar TEff, logg, and z.
- LDPSet : Encapsulates the limb darkening profiles and offers methods for model coefficient estimation and log likelihood evaluation.
If you use PyLDTk in your research, please cite the PyLDTk paper
Parviainen, H. & Aigrain, S. MNRAS 453, 3821–3826 (2015) (DOI:10.1093/mnras/stv1857).
and the paper describing the spectrum library without which PyLDTk would be rather useless
Husser, T.-O. et al. A&A 553, A6 (2013) (DOI:10.1051/0004-6361/201219058).
or use these ready made BibTeX entries
@article{Parviainen2015,
author = {Parviainen, Hannu and Aigrain, Suzanne},
doi = {10.1093/mnras/stv1857},
journal = {MNRAS},
month = nov,
number = {4},
pages = {3821--3826},
title = {{ldtk: Limb Darkening Toolkit}},
url = {http://mnras.oxfordjournals.org/lookup/doi/10.1093/mnras/stv1857},
volume = {453},
year = {2015}
}
@article{Husser2013,
author = {Husser, T.-O. and {Wende-von Berg}, S and Dreizler, S and Homeier, D and
Reiners, A and Barman, T. and Hauschildt, Peter H},
doi = {10.1051/0004-6361/201219058},
journal = {A{\&}A},
pages = {A6},
title = {{Astrophysics A new extensive library of PHOENIX stellar atmospheres}},
volume = {553},
year = {2013}
}
Hannu Parviainen, University of Oxford
- Rainer Wichmann, Hamburger Sternwarte, Universität Hamburg
- Tom Louden, University of Warwick
- Ian Crossfield, University of Arizona
--
Copyright © 2016 Hannu Parviainen [email protected]