Provable Accuracy Collapse in Embedding-Based Representations under Dimensionality Mismatch
Abstract
Embedding-based representations in Euclidean space are a cornerstone of modern machine learning, where a major goal is to use the \emph{smallest dimension} that faithfully captures data relations. In this work, we prove sharp dimension--accuracy tradeoffs and identify a fundamental information-theoretic limitation: unless the embedding dimension is chosen close to the ground-truth dimension , accuracy undergoes a sudden collapse. Our main result shows that this phenomenon arises even in standard contrastive learning settings, where supervision is limited to a set of anchor--positive--negative triplets encoding distance comparisons . Specifically, given triplets realizable by an unknown ground-truth embedding in dimensions, we prove that there exists constant , such that \emph{every embedding of dimension at most violates half of the triplets}, yielding accuracy as low as a trivial one-dimensional solution that ignores the input. We complement our information-theoretic bounds with strong computational hardness results: under the Unique Games Conjecture, even if the given triplets are nearly realizable in dimension, no polynomial-time algorithm -- \textit{regardless of its dimension} -- can achieve accuracy above the trivial baseline.
Cite
@article{arxiv.2605.03346,
title = {Provable Accuracy Collapse in Embedding-Based Representations under Dimensionality Mismatch},
author = {Dionysis Arvanitakis and Vaggos Chatziafratis and Yiyuan Luo},
journal= {arXiv preprint arXiv:2605.03346},
year = {2026}
}
Comments
Preliminary version, accepted to ICML 2026 as spotlight presentation