Dual VC Dimension Obstructs Sample Compression by Embeddings
Abstract
This work studies embedding of arbitrary VC classes in well-behaved VC classes, focusing particularly on extremal classes. Our main result expresses an impossibility: such embeddings necessarily require a significant increase in dimension. In particular, we prove that for every there is a class with VC dimension that cannot be embedded in any extremal class of VC dimension smaller than exponential in . In addition to its independent interest, this result has an important implication in learning theory, as it reveals a fundamental limitation of one of the most extensively studied approaches to tackling the long-standing sample compression conjecture. Concretely, the approach proposed by Floyd and Warmuth entails embedding any given VC class into an extremal class of a comparable dimension, and then applying an optimal sample compression scheme for extremal classes. However, our results imply that this strategy would in some cases result in a sample compression scheme at least exponentially larger than what is predicted by the sample compression conjecture. The above implications follow from a general result we prove: any extremal class with VC dimension has dual VC dimension at most . This bound is exponentially smaller than the classical bound of Assouad, which applies to general concept classes (and is known to be unimprovable for some classes). We in fact prove a stronger result, establishing that upper bounds the dual Radon number of extremal classes. This theorem represents an abstraction of the classical Radon theorem for convex sets, extending its applicability to a wider combinatorial framework, without relying on the specifics of Euclidean convexity. The proof utilizes the topological method and is primarily based on variants of the Topological Radon Theorem.
Keywords
Cite
@article{arxiv.2405.17120,
title = {Dual VC Dimension Obstructs Sample Compression by Embeddings},
author = {Zachary Chase and Bogdan Chornomaz and Steve Hanneke and Shay Moran and Amir Yehudayoff},
journal= {arXiv preprint arXiv:2405.17120},
year = {2024}
}