Adaptive Per-Channel Energy Normalization Front-end for Robust Audio Signal Processing
Abstract
In audio signal processing, learnable front-ends have shown strong performance across diverse tasks by optimizing task-specific representation. However, their parameters remain fixed once trained, lacking flexibility during inference and limiting robustness under dynamic complex acoustic environments. In this paper, we introduce a novel adaptive paradigm for audio front-ends that replaces static parameterization with a closed-loop neural controller. Specifically, we simplify the learnable front-end LEAF architecture and integrate a neural controller for adaptive representation via dynamically tuning Per-Channel Energy Normalization. The neural controller leverages both the current and the buffered past subband energies to enable input-dependent adaptation during inference. Experimental results on multiple audio classification tasks demonstrate that the proposed adaptive front-end consistently outperforms prior fixed and learnable front-ends under both clean and complex acoustic conditions. These results highlight neural adaptability as a promising direction for the next generation of audio front-ends.
Cite
@article{arxiv.2510.18206,
title = {Adaptive Per-Channel Energy Normalization Front-end for Robust Audio Signal Processing},
author = {Hanyu Meng and Vidhyasaharan Sethu and Eliathamby Ambikairajah and Qiquan Zhang and Haizhou Li},
journal= {arXiv preprint arXiv:2510.18206},
year = {2026}
}
Comments
Accepted by ICASSP2026