English

Quantitative Bounds for Sorting-Based Permutation-Invariant Embeddings

Machine Learning 2026-05-26 v2 Information Theory Functional Analysis math.IT Metric Geometry

Abstract

We study permutation-invariant embeddings of dd-dimensional point sets, which are defined by sorting DD independent one-dimensional projections of the input. Such embeddings arise in graph deep learning where outputs should be invariant to permutations of graph nodes. Previous work showed that for large enough DD and projections in general position, this mapping is injective, and moreover satisfies a bi-Lipschitz condition. However, two gaps remain: firstly, the optimal size DD required for injectivity is not yet known, and secondly, no estimates of the bi-Lipschitz constants of the mapping are known. In this paper, we make substantial progress in addressing both of these gaps. Regarding the first gap, we improve upon the best known upper bounds for the embedding dimension DD necessary for injectivity, and also provide a lower bound on the minimal injectivity dimension. Regarding the second gap, we construct matrices of projection vectors, so that the bi-Lipschitz distortion of the mapping depends quadratically on the number of points nn, and is completely independent of the dimension dd. We also show that for any choice of projection vectors, the distortion of the mapping will never be better than a bound proportional to the square root of nn. Finally, we show that similar guarantees can be provided even when linear projections are applied to the mapping to reduce its dimension.

Keywords

Cite

@article{arxiv.2510.22186,
  title  = {Quantitative Bounds for Sorting-Based Permutation-Invariant Embeddings},
  author = {Nadav Dym and Matthias Wellershoff and Efstratios Tsoukanis and Daniel Levy and Radu Balan},
  journal= {arXiv preprint arXiv:2510.22186},
  year   = {2026}
}

Comments

Minor revision; 37 pages, 1 figure, 2 tables

R2 v1 2026-07-01T07:05:21.308Z