English

Revisiting the Approximate Carath\'eodory Problem via the Frank-Wolfe Algorithm

Optimization and Control 2021-12-07 v5 Data Structures and Algorithms Machine Learning

Abstract

The approximate Carath\'eodory theorem states that given a compact convex set CRn\mathcal{C}\subset\mathbb{R}^n and p[2,+[p\in\left[2,+\infty\right[, each point xCx^*\in\mathcal{C} can be approximated to ϵ\epsilon-accuracy in the p\ell_p-norm as the convex combination of O(pDp2/ϵ2)\mathcal{O}(pD_p^2/\epsilon^2) vertices of C\mathcal{C}, where DpD_p is the diameter of C\mathcal{C} in the p\ell_p-norm. A solution satisfying these properties can be built using probabilistic arguments or by applying mirror descent to the dual problem. We revisit the approximate Carath\'eodory problem by solving the primal problem via the Frank-Wolfe algorithm, providing a simplified analysis and leading to an efficient practical method. Furthermore, improved cardinality bounds are derived naturally using existing convergence rates of the Frank-Wolfe algorithm in different scenarios, when xx^* is in the interior of C\mathcal{C}, when xx^* is the convex combination of a subset of vertices with small diameter, or when C\mathcal{C} is uniformly convex. We also propose cardinality bounds when p[1,2[{+}p\in\left[1,2\right[\cup\{+\infty\} via a nonsmooth variant of the algorithm. Lastly, we address the problem of finding sparse approximate projections onto C\mathcal{C} in the p\ell_p-norm, p[1,+]p\in\left[1,+\infty\right].

Keywords

Cite

@article{arxiv.1911.04415,
  title  = {Revisiting the Approximate Carath\'eodory Problem via the Frank-Wolfe Algorithm},
  author = {Cyrille W. Combettes and Sebastian Pokutta},
  journal= {arXiv preprint arXiv:1911.04415},
  year   = {2021}
}

Comments

Final version MAPR

R2 v1 2026-06-23T12:11:59.036Z