A Unified Frequency Principle for Quantum and Classical Machine Learning
Abstract
Quantum neural networks constitute a key class of near-term quantum learning models, yet their training dynamics remain not fully understood. Here, we present a unified theoretical framework for the frequency principle (F-principle) that characterizes the training dynamics of both classical and quantum neural networks. Within this framework, we prove that quantum neural networks exhibit a spectral bias toward learning low-frequency components of target functions, mirroring the behavior observed in classical deep networks. We further analyze the impact of noise and show that, when single-qubit noise is applied after encoding-layer rotations and modeled as a Pauli channel aligned with the rotation axis, the Fourier component labeled by is suppressed by a factor . This leads to exponential attenuation of high-frequency terms while preserving the learnability of low-frequency structure. In the same setting, we establish that the resulting noisy circuits admit efficient classical simulation up to average-case error. Numerical experiments corroborate our theoretical predictions: Quantum neural networks primarily learn low-frequency features during early optimization and maintain robustness against dephasing and depolarizing noise acting on the encoding layer. Our results provide a frequency-domain lens that unifies classical and quantum learning dynamics, clarifies the role of noise in shaping trainability, and guides the design of noise-resilient quantum neural networks.
Cite
@article{arxiv.2601.03169,
title = {A Unified Frequency Principle for Quantum and Classical Machine Learning},
author = {Rundi Lu and Ruiqi Zhang and Weikang Li and Zhaohui Wei and Dong-Ling Deng and Zhengwei Liu},
journal= {arXiv preprint arXiv:2601.03169},
year = {2026}
}
Comments
26 pages, 6 figures. Comments are welcome