English

Sample-Efficient Learning of Mixtures

Machine Learning 2018-06-05 v3

Abstract

We consider PAC learning of probability distributions (a.k.a. density estimation), where we are given an i.i.d. sample generated from an unknown target distribution, and want to output a distribution that is close to the target in total variation distance. Let F\mathcal F be an arbitrary class of probability distributions, and let Fk\mathcal{F}^k denote the class of kk-mixtures of elements of F\mathcal F. Assuming the existence of a method for learning F\mathcal F with sample complexity mF(ϵ)m_{\mathcal{F}}(\epsilon), we provide a method for learning Fk\mathcal F^k with sample complexity O(klogkmF(ϵ)/ϵ2)O({k\log k \cdot m_{\mathcal F}(\epsilon) }/{\epsilon^{2}}). Our mixture learning algorithm has the property that, if the F\mathcal F-learner is proper/agnostic, then the Fk\mathcal F^k-learner would be proper/agnostic as well. This general result enables us to improve the best known sample complexity upper bounds for a variety of important mixture classes. First, we show that the class of mixtures of kk axis-aligned Gaussians in Rd\mathbb{R}^d is PAC-learnable in the agnostic setting with O~(kd/ϵ4)\widetilde{O}({kd}/{\epsilon ^ 4}) samples, which is tight in kk and dd up to logarithmic factors. Second, we show that the class of mixtures of kk Gaussians in Rd\mathbb{R}^d is PAC-learnable in the agnostic setting with sample complexity O~(kd2/ϵ4)\widetilde{O}({kd^2}/{\epsilon ^ 4}), which improves the previous known bounds of O~(k3d2/ϵ4)\widetilde{O}({k^3d^2}/{\epsilon ^ 4}) and O~(k4d4/ϵ2)\widetilde{O}(k^4d^4/\epsilon ^ 2) in its dependence on kk and dd. Finally, we show that the class of mixtures of kk log-concave distributions over Rd\mathbb{R}^d is PAC-learnable using O~(d(d+5)/2ϵ(d+9)/2k)\widetilde{O}(d^{(d+5)/2}\epsilon^{-(d+9)/2}k) samples.

Keywords

Cite

@article{arxiv.1706.01596,
  title  = {Sample-Efficient Learning of Mixtures},
  author = {Hassan Ashtiani and Shai Ben-David and Abbas Mehrabian},
  journal= {arXiv preprint arXiv:1706.01596},
  year   = {2018}
}

Comments

A bug from the previous version, which appeared in AAAI 2018 proceedings, is fixed. 18 pages

R2 v1 2026-06-22T20:10:03.568Z