English

The Ball-Proximal (="Broximal") Point Method: a New Algorithm, Convergence Theory, and Applications

Optimization and Control 2025-07-31 v2 Machine Learning Machine Learning

Abstract

Non-smooth and non-convex global optimization poses significant challenges across various applications, where standard gradient-based methods often struggle. We propose the Ball-Proximal Point Method, Broximal Point Method, or Ball Point Method (BPM) for short - a novel algorithmic framework inspired by the classical Proximal Point Method (PPM) (Rockafellar, 1976), which, as we show, sheds new light on several foundational optimization paradigms and phenomena, including non-convex and non-smooth optimization, acceleration, smoothing, adaptive stepsize selection, and trust-region methods. At the core of BPM lies the ball-proximal ("broximal") operator, which arises from the classical proximal operator by replacing the quadratic distance penalty by a ball constraint. Surprisingly, and in sharp contrast with the sublinear rate of PPM in the nonsmooth convex regime, we prove that BPM converges linearly and in a finite number of steps in the same regime. Furthermore, by introducing the concept of ball-convexity, we prove that BPM retains the same global convergence guarantees under weaker assumptions, making it a powerful tool for a broader class of potentially non-convex optimization problems. Just like PPM plays the role of a conceptual method inspiring the development of practically efficient algorithms and algorithmic elements, e.g., gradient descent, adaptive step sizes, acceleration (Ahn & Sra, 2020), and "W" in AdamW (Zhuang et al., 2022), we believe that BPM should be understood in the same manner: as a blueprint and inspiration for further development.

Keywords

Cite

@article{arxiv.2502.02002,
  title  = {The Ball-Proximal (="Broximal") Point Method: a New Algorithm, Convergence Theory, and Applications},
  author = {Kaja Gruntkowska and Hanmin Li and Aadi Rane and Peter Richtárik},
  journal= {arXiv preprint arXiv:2502.02002},
  year   = {2025}
}

Comments

47 pages, 3 figures

R2 v1 2026-06-28T21:31:37.668Z