English

Optimizing tiny colorless feedback delay networks

Audio and Speech Processing 2025-12-19 v4 Sound

Abstract

A common bane of artificial reverberation algorithms is spectral coloration in the synthesized sound, typically manifesting as metallic ringing, leading to a degradation in the perceived sound quality. In delay network methods, coloration is more pronounced when fewer delay lines are used. This paper presents an optimization framework in which a tiny differentiable feedback delay network, with as few as four delay lines, is used to learn a set of parameters to iteratively reduce coloration. The parameters under optimization include the feedback matrix, as well as the input and output gains. The optimization objective is twofold: to maximize spectral flatness through a spectral loss while maintaining temporal density by penalizing sparseness in the parameter values. A favorable narrow distribution of modal excitation is achieved while maintaining the desired impulse response density. In a subjective assessment, the new method proves effective in reducing perceptual coloration of late reverberation. Compared to the author's previous work, which serves as the baseline and utilizes a sparsity loss in the time domain, the proposed method achieves computational savings while maintaining performance. The effectiveness of this work is demonstrated through two application scenarios where smooth-sounding synthetic room impulse responses are obtained via the introduction of attenuation filters and an optimizable scattering feedback matrix.

Keywords

Cite

@article{arxiv.2402.11216,
  title  = {Optimizing tiny colorless feedback delay networks},
  author = {Gloria Dal Santo and Karolina Prawda and Sebastian J. Schlecht and Vesa Välimäki},
  journal= {arXiv preprint arXiv:2402.11216},
  year   = {2025}
}
R2 v1 2026-06-28T14:51:41.436Z