Litcius/Paper detail

Differentiable Artificial Reverberation

Sungho Lee, Hyeong-Seok Choi, Kyogu Lee

2022IEEE/ACM Transactions on Audio Speech and Language Processing33 citationsDOI

Abstract

Artificial reverberation (AR) models play a central role in various audio applications. Therefore, estimating the AR model parameters (ARPs) of a reference reverberation is a crucial task. Although a few recent deep-learning-based approaches have shown promising performance, their non-end-to-end training scheme prevents them from fully exploiting the potential of deep neural networks. This motivates the introduction of differentiable artificial reverberation (DAR) models, allowing loss gradients to be back-propagated end-to-end. However, implementing the AR models with their difference equations “as is” in the deep learning framework severely bottlenecks the training speed when executed with a parallel processor like GPU due to their infinite impulse response (IIR) components. We tackle this problem by replacing the IIR filters with finite impulse response (FIR) approximations with the frequency-sampling method. Using this technique, we implement three DAR models—differentiable Filtered Velvet Noise (FVN), Advanced Filtered Velvet Noise (AFVN), and Delay Network (DN). For each AR model, we train its ARP estimation networks for analysis-synthesis (RIR-to-ARP) and blind estimation (reverberant-speech-to-ARP) task in an end-to-end manner with its DAR model counterpart. Experiment results show that the proposed method achieves consistent performance improvement over the non-end-to-end approaches in both objective metrics and subjective listening test results.

Topics & Concepts

ReverberationComputer scienceInfinite impulse responseDifferentiable functionDeep learningArtificial neural networkNoise (video)End-to-end principleDeep neural networksFinite impulse responseSpeech recognitionArtificial intelligenceAlgorithmAcousticsMathematicsDigital filterComputer visionFilter (signal processing)Mathematical analysisPhysicsImage (mathematics)Speech and Audio ProcessingHearing Loss and RehabilitationAcoustic Wave Phenomena Research
Differentiable Artificial Reverberation | Litcius