English

Progressive Power Homotopy for Non-convex Optimization

Optimization and Control 2026-01-23 v1 Artificial Intelligence Machine Learning

Abstract

We propose a novel first-order method for non-convex optimization of the form maxwRdExD[fw(x)]\max_{\bm{w}\in\mathbb{R}^d}\mathbb{E}_{\bm{x}\sim\mathcal{D}}[f_{\bm{w}}(\bm{x})], termed Progressive Power Homotopy (Prog-PowerHP). The method applies stochastic gradient ascent to a surrogate objective obtained by first performing a power transformation and then Gaussian smoothing, FN,σ(μ):=EwN(μ,σ2Id),xD[eNfw(x)]F_{N,\sigma}(\bm{\mu}):=\mathbb{E}_{\bm{w}\sim\mathcal{N}(\bm{\mu},\sigma^2I_d),\bm{x}\sim\mathcal{D}}[e^{Nf_w(\bm{x})}], while progressively increasing the power parameter NN and decreasing the smoothing scale σ\sigma along the optimization trajectory. We prove that, under mild regularity conditions, Prog-PowerHP converges to a small neighborhood of the global optimum with an iteration complexity scaling nearly as O(d2ε2)O(d^2\varepsilon^{-2}). Empirically, Prog-PowerHP demonstrates clear advantages in phase retrieval when the samples-to-dimension ratio approaches the information-theoretic limit, and in training two-layer neural networks in under-parameterized regimes. These results suggest that Prog-PowerHP is particularly effective for navigating cluttered non-convex landscapes where standard first-order methods struggle.

Keywords

Cite

@article{arxiv.2601.15915,
  title  = {Progressive Power Homotopy for Non-convex Optimization},
  author = {Chen Xu},
  journal= {arXiv preprint arXiv:2601.15915},
  year   = {2026}
}
R2 v1 2026-07-01T09:15:43.494Z