Causal Diffusion Models for Generalized Speech Enhancement

IF 2.9 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE open journal of signal processing Pub Date : 2024-03-19 DOI:10.1109/OJSP.2024.3379070
Julius Richter;Simon Welker;Jean-Marie Lemercier;Bunlong Lay;Tal Peer;Timo Gerkmann
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Abstract

In this work, we present a causal speech enhancement system that is designed to handle different types of corruptions. This paper is an extended version of our contribution to the “ICASSP 2023 Speech Signal Improvement Challenge”. The method is based on a generative diffusion model which has been shown to work well in scenarios beyond speech-in-noise, such as missing data and non-additive corruptions. We guarantee causal processing with an algorithmic latency of 20 ms by modifying the network architecture and removing non-causal normalization techniques. To train and test our model, we generate a new corrupted speech dataset which includes additive background noise, reverberation, clipping, packet loss, bandwidth reduction, and codec artifacts. We compare the causal and non-causal versions of our method to investigate the impact of causal processing and we assess the gap between specialized models trained on a particular corruption type and the generalized model trained on all corruptions. Although specialized models and non-causal models have a small advantage, we show that the generalized causal approach does not suffer from a significant performance penalty, while it can be flexibly employed for real-world applications where different types of distortions may occur.
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用于广义语音增强的因果扩散模型
在这项工作中,我们提出了一种因果语音增强系统,旨在处理不同类型的损坏。本文是我们为 "ICASSP 2023 语音信号改进挑战赛 "所做贡献的扩展版本。该方法基于生成扩散模型,该模型已被证明能在噪声语音以外的场景中良好工作,例如缺失数据和非加性损坏。我们通过修改网络架构和去除非因果归一化技术,确保因果处理的算法延迟为 20 毫秒。为了训练和测试我们的模型,我们生成了一个新的损坏语音数据集,其中包括加性背景噪声、混响、削波、数据包丢失、带宽降低和编解码器假象。我们比较了我们方法的因果和非因果版本,以研究因果处理的影响,并评估了针对特定损坏类型训练的专用模型与针对所有损坏类型训练的通用模型之间的差距。虽然专业化模型和非因果模型的优势较小,但我们表明,广义因果方法不会受到明显的性能损失,同时可以灵活地应用于可能出现不同类型畸变的实际应用中。
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CiteScore
5.30
自引率
0.00%
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0
审稿时长
22 weeks
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