English

Scalable Random Wavelet Features: Efficient Non-Stationary Kernel Approximation with Convergence Guarantees

Machine Learning 2026-02-03 v1

Abstract

Modeling non-stationary processes, where statistical properties vary across the input domain, is a critical challenge in machine learning; yet most scalable methods rely on a simplifying assumption of stationarity. This forces a difficult trade-off: use expressive but computationally demanding models like Deep Gaussian Processes, or scalable but limited methods like Random Fourier Features (RFF). We close this gap by introducing Random Wavelet Features (RWF), a framework that constructs scalable, non-stationary kernel approximations by sampling from wavelet families. By harnessing the inherent localization and multi-resolution structure of wavelets, RWF generates an explicit feature map that captures complex, input-dependent patterns. Our framework provides a principled way to generalize RFF to the non-stationary setting and comes with a comprehensive theoretical analysis, including positive definiteness, unbiasedness, and uniform convergence guarantees. We demonstrate empirically on a range of challenging synthetic and real-world datasets that RWF outperforms stationary random features and offers a compelling accuracy-efficiency trade-off against more complex models, unlocking scalable and expressive kernel methods for a broad class of real-world non-stationary problems.

Keywords

Cite

@article{arxiv.2602.00987,
  title  = {Scalable Random Wavelet Features: Efficient Non-Stationary Kernel Approximation with Convergence Guarantees},
  author = {Sawan Kumar and Souvik Chakraborty},
  journal= {arXiv preprint arXiv:2602.00987},
  year   = {2026}
}

Comments

Accepted at ICLR 2026

R2 v1 2026-07-01T09:29:50.216Z