BLISS is a Bayesian method for deblending and cataloging light sources. BLISS provides
- Accurate estimation of parameters in blended field.
- Calibrated uncertainties through fitting an approximate Bayesian posterior.
- Scalability of Bayesian inference to entire astronomical surveys.
BLISS uses state-of-the-art variational inference techniques including
- Amortized inference, in which a neural network maps telescope images to an approximate Bayesian posterior on parameters of interest.
- Variational auto-encoders (VAEs) to fit a flexible model for galaxy morphology and deblend galaxies.
- Wake-sleep algorithm to jointly fit the approximate posterior and model parameters such as the PSF and the galaxy VAE.
BLISS is pip installable with the following command:
pip install bliss-toolkit
and the required dependencies are listed in the [tool.poetry.dependencies]
block of the pyproject.toml
file.
-
To use and install
bliss
you first need to install poetry. -
Then, install the fftw library (which is used by
galsim
). With Ubuntu you can install it by running
sudo apt-get install libfftw3-dev
- Install git-lfs if you haven't already installed it for another project:
git-lfs install
- Now download the bliss repo and fetch some pre-trained models and test data from git-lfs:
git clone [email protected]:prob-ml/bliss.git
- To create a poetry environment with the
bliss
dependencies satisified, run
cd bliss
export POETRY_VIRTUALENVS_IN_PROJECT=1
poetry install
poetry shell
- Verify that bliss is installed correctly by running the tests both on your CPU (default) and on your GPU:
pytest
pytest --gpu
- Finally, if you are planning to contribute code to this repository, consider installing our pre-commit hooks so that your code commits will be checked locally for compliance with our coding conventions:
pre-commit install
- BLISS now includes a galaxy model based on a VAE that was trained on Galsim galaxies.
- BLISS now includes an algorithm for detecting, measuring, and deblending galaxies.
- BLISS already includes the StarNet functionality from its predecessor repo: DeblendingStarFields.
Runjing Liu, Jon D. McAuliffe, Jeffrey Regier, and The LSST Dark Energy Science Collaboration. Variational inference for deblending crowded starfields, Journal of Machine Learning Research. 2023
Mallory Wang, Ismael Mendoza, Cheng Wang, Camille Avestruz, and Jeffrey Regier. Statistical inference for coadded astronomical images.. NeurIPS Workshop on Machine Learning and the Physical Sciences. 2022.
Yash Patel and Jeffrey Regier. Scalable Bayesian inference for detecting strong gravitational lensing systems.. NeurIPS Workshop on Machine Learning and the Physical Sciences. 2022.
Derek Hansen, Ismael Mendoza, Runjing Liu, Ziteng Pang, Zhe Zhao, Camille Avestruz, and Jeffrey Regier. Scalable Bayesian inference for detection and deblending in astronomical images. ICML Workshop on Machine Learning for Astrophysics. 2022.