Computing Low-Entropy Couplings for Large-Support Distributions
Abstract
Minimum-entropy coupling (MEC)—the process of finding a joint distribution with minimum entropy for given marginals—has applications in areas such as causality and steganography. However, existing algorithms are either computationally intractable for large-support distributions or limited to specific distribution types and sensitive to hyperparameter choices. This work addresses these limitations by unifying a prior family of iterative MEC (IMEC) approaches into a generalized partition-based formalism. From this framework, we derive a novel IMEC algorithm called ARIMEC, capable of handling arbitrary discrete distributions, and introduce a method to make IMEC robust to suboptimal hyperparameter settings. These innovations facilitate the application of IMEC to high-throughput steganography with language models, among other settings.
Cite
Text
Sokota et al. "Computing Low-Entropy Couplings for Large-Support Distributions." Uncertainty in Artificial Intelligence, 2024.Markdown
[Sokota et al. "Computing Low-Entropy Couplings for Large-Support Distributions." Uncertainty in Artificial Intelligence, 2024.](https://mlanthology.org/uai/2024/sokota2024uai-computing/)BibTeX
@inproceedings{sokota2024uai-computing,
title = {{Computing Low-Entropy Couplings for Large-Support Distributions}},
author = {Sokota, Samuel and Sam, Dylan and Witt, Christian and Compton, Spencer and Foerster, Jakob and Kolter, J. Zico},
booktitle = {Uncertainty in Artificial Intelligence},
year = {2024},
pages = {3279-3298},
volume = {244},
url = {https://mlanthology.org/uai/2024/sokota2024uai-computing/}
}