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Agnostic Sample Compression Schemes for Regression

Machine Learning 2024-02-06 v2 Information Theory math.IT Statistics Theory Machine Learning Statistics Theory

Abstract

We obtain the first positive results for bounded sample compression in the agnostic regression setting with the p\ell_p loss, where p[1,]p\in [1,\infty]. We construct a generic approximate sample compression scheme for real-valued function classes exhibiting exponential size in the fat-shattering dimension but independent of the sample size. Notably, for linear regression, an approximate compression of size linear in the dimension is constructed. Moreover, for 1\ell_1 and \ell_\infty losses, we can even exhibit an efficient exact sample compression scheme of size linear in the dimension. We further show that for every other p\ell_p loss, p(1,)p\in (1,\infty), there does not exist an exact agnostic compression scheme of bounded size. This refines and generalizes a negative result of David, Moran, and Yehudayoff for the 2\ell_2 loss. We close by posing general open questions: for agnostic regression with 1\ell_1 loss, does every function class admits an exact compression scheme of size equal to its pseudo-dimension? For the 2\ell_2 loss, does every function class admit an approximate compression scheme of polynomial size in the fat-shattering dimension? These questions generalize Warmuth's classic sample compression conjecture for realizable-case classification.

Cite

@article{arxiv.1810.01864,
  title  = {Agnostic Sample Compression Schemes for Regression},
  author = {Idan Attias and Steve Hanneke and Aryeh Kontorovich and Menachem Sadigurschi},
  journal= {arXiv preprint arXiv:1810.01864},
  year   = {2024}
}

Comments

New results in this version: (1) Approximate agnostic sample compression scheme for function classes with finite fat-shattering dimension and the $\ell_p$ loss (section 3), (2) Near-optimal approximate compression for linear functions and the $\ell_p$ loss (section 4.1) The results in sections 4.2 and 4.3 appear in the previous version

R2 v1 2026-06-23T04:27:35.035Z