Simple MAP Inference via Low-Rank Relaxations
Abstract
We focus on the problem of maximum a posteriori (MAP) inference in Markov random fields with binary variables and pairwise interactions. For this common subclass of inference tasks, we consider low-rank relaxations that interpolate between the discrete problem and its full-rank semidefinite relaxation, followed by randomized rounding. We develop new theoretical bounds studying the effect of rank, showing that as the rank grows, the relaxed objective increases but saturates, and that the fraction in objective value retained by the rounded discrete solution decreases. In practice, we show two algorithms for optimizing the low-rank objectives which are simple to implement, enjoy ties to the underlying theory, and outperform existing approaches on benchmark MAP inference tasks.
Cite
Text
Frostig et al. "Simple MAP Inference via Low-Rank Relaxations." Neural Information Processing Systems, 2014.Markdown
[Frostig et al. "Simple MAP Inference via Low-Rank Relaxations." Neural Information Processing Systems, 2014.](https://mlanthology.org/neurips/2014/frostig2014neurips-simple/)BibTeX
@inproceedings{frostig2014neurips-simple,
title = {{Simple MAP Inference via Low-Rank Relaxations}},
author = {Frostig, Roy and Wang, Sida and Liang, Percy and Manning, Christopher D.},
booktitle = {Neural Information Processing Systems},
year = {2014},
pages = {3077-3085},
url = {https://mlanthology.org/neurips/2014/frostig2014neurips-simple/}
}