On a Gradient Approach to Chebyshev Center Problems with Applications to Function Learning
Abstract
We introduce , the first gradient-based optimization framework for solving Chebyshev center problems, a fundamental challenge in optimal function learning and geometric optimization. hinges on reformulating the semi-infinite problem as a finitary max-min optimization, making it amenable to gradient-based techniques. By leveraging automatic differentiation for precise numerical gradient computation, ensures numerical stability and scalability, making it suitable for large-scale settings. Under strong convexity of the ambient norm, provably recovers optimal Chebyshev centers while directly computing the associated radius. This addresses a key bottleneck in constructing stable optimal interpolants. Empirically, achieves significant improvements in accuracy and efficiency on 34 benchmark Chebyshev center problems from a benchmark library. Moreover, we extend to general convex semi-infinite programming (CSIP), attaining up to speedups over the state-of-the-art solver tested on the indicated library containing 67 benchmark problems. Furthermore, we provide the first theoretical foundation for applying gradient-based methods to Chebyshev center problems, bridging rigorous analysis with practical algorithms. thus offers a unified solution framework for Chebyshev centers and broader CSIPs.
Cite
@article{arxiv.2601.06434,
title = {On a Gradient Approach to Chebyshev Center Problems with Applications to Function Learning},
author = {Abhinav Raghuvanshi and Mayank Baranwal and Debasish Chatterjee},
journal= {arXiv preprint arXiv:2601.06434},
year = {2026}
}
Comments
Accepted to TMLR