Set Representation Learning with Generalized Sliced-Wasserstein Embeddings
Abstract
An increasing number of machine learning tasks deal with learning representations from set-structured data. Solutions to these problems involve the composition of permutation-equivariant modules (e.g., self-attention, or individual processing via feed-forward neural networks) and permutation-invariant modules (e.g., global average pooling, or pooling by multi-head attention). In this paper, we propose a geometrically-interpretable framework for learning representations from set-structured data, which is rooted in the optimal mass transportation problem. In particular, we treat elements of a set as samples from a probability measure and propose an exact Euclidean embedding for Generalized Sliced Wasserstein (GSW) distances to learn from set-structured data effectively. We evaluate our proposed framework on multiple supervised and unsupervised set learning tasks and demonstrate its superiority over state-of-the-art set representation learning approaches.
Cite
@article{arxiv.2103.03892,
title = {Set Representation Learning with Generalized Sliced-Wasserstein Embeddings},
author = {Navid Naderializadeh and Soheil Kolouri and Joseph F. Comer and Reed W. Andrews and Heiko Hoffmann},
journal= {arXiv preprint arXiv:2103.03892},
year = {2021}
}