$\mathbb{R}^{2k}$ is Theoretically Large Enough for Embedding-based Top-$k$ Retrieval
Abstract
This paper studies the minimal dimension required to embed subset memberships ( elements and subsets of at most elements) into vector spaces, denoted as Minimal Embeddable Dimension (MED). The tight bounds of MED are derived theoretically and supported empirically for various notions of "distances" or "similarities," including the metric, inner product, and cosine similarity. In addition, we conduct numerical simulation in a more achievable setting, where the subset embeddings are chosen as the centroid of the embeddings of the contained elements. Our simulation easily realizes a logarithmic dependency between the MED and the number of elements to embed. These findings imply that embedding-based retrieval limitations stem primarily from learnability challenges, not geometric constraints, guiding future algorithm design.
Cite
@article{arxiv.2601.20844,
title = {$\mathbb{R}^{2k}$ is Theoretically Large Enough for Embedding-based Top-$k$ Retrieval},
author = {Zihao Wang and Hang Yin and Lihui Liu and Hanghang Tong and Yangqiu Song and Ginny Wong and Simon See},
journal= {arXiv preprint arXiv:2601.20844},
year = {2026}
}
Comments
v2: fix broken citation