用于语音和音乐分离的显式记忆多分辨率自适应框架。

IF 1.7 3区 计算机科学 Q2 ACOUSTICS Eurasip Journal on Audio Speech and Music Processing Pub Date : 2023-01-01 Epub Date: 2023-05-09 DOI:10.1186/s13636-023-00286-7
Ashwin Bellur, Karan Thakkar, Mounya Elhilali
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引用次数: 0

摘要

人类听觉系统采用了许多原理来促进从复杂的声音混合物中选择在感知上分离的流。大脑利用输入的多尺度冗余表示,并使用记忆(或先验)来指导从输入混合物中选择目标声音。此外,反馈机制细化了记忆结构,从而进一步提高了特定声音对象在动态背景中的选择性。本研究提出了一个统一的端到端计算框架,该框架模拟了应用于语音和音乐混合物的声源分离的这些原理。虽然由于每个信号域的限制和特殊性,语音增强和音乐分离的问题通常被单独解决,但当前的工作认为声源分离的通用原则是域不可知的。在所提出的方案中,并行和分层卷积路径将输入混合物映射到冗余但分布的高维子空间上,并利用时间相干性的概念来选择属于在存储器中抽象的目标流的嵌入。这些显式记忆通过来自输入观测的自反馈进一步细化,以提高系统在面对未知背景时的选择性。该模型为语音和音乐混合产生了稳定的源分离结果,并证明了显式记忆作为先验的强大表示的好处,先验指导从复杂输入中选择信息。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Explicit-memory multiresolution adaptive framework for speech and music separation.

The human auditory system employs a number of principles to facilitate the selection of perceptually separated streams from a complex sound mixture. The brain leverages multi-scale redundant representations of the input and uses memory (or priors) to guide the selection of a target sound from the input mixture. Moreover, feedback mechanisms refine the memory constructs resulting in further improvement of selectivity of a particular sound object amidst dynamic backgrounds. The present study proposes a unified end-to-end computational framework that mimics these principles for sound source separation applied to both speech and music mixtures. While the problems of speech enhancement and music separation have often been tackled separately due to constraints and specificities of each signal domain, the current work posits that common principles for sound source separation are domain-agnostic. In the proposed scheme, parallel and hierarchical convolutional paths map input mixtures onto redundant but distributed higher-dimensional subspaces and utilize the concept of temporal coherence to gate the selection of embeddings belonging to a target stream abstracted in memory. These explicit memories are further refined through self-feedback from incoming observations in order to improve the system's selectivity when faced with unknown backgrounds. The model yields stable outcomes of source separation for both speech and music mixtures and demonstrates benefits of explicit memory as a powerful representation of priors that guide information selection from complex inputs.

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来源期刊
Eurasip Journal on Audio Speech and Music Processing
Eurasip Journal on Audio Speech and Music Processing ACOUSTICS-ENGINEERING, ELECTRICAL & ELECTRONIC
CiteScore
4.10
自引率
4.20%
发文量
0
审稿时长
12 months
期刊介绍: The aim of “EURASIP Journal on Audio, Speech, and Music Processing” is to bring together researchers, scientists and engineers working on the theory and applications of the processing of various audio signals, with a specific focus on speech and music. EURASIP Journal on Audio, Speech, and Music Processing will be an interdisciplinary journal for the dissemination of all basic and applied aspects of speech communication and audio processes.
期刊最新文献
Compression of room impulse responses for compact storage and fast low-latency convolution Guest editorial: AI for computational audition—sound and music processing Physics-constrained adaptive kernel interpolation for region-to-region acoustic transfer function: a Bayesian approach Physics-informed neural network for volumetric sound field reconstruction of speech signals Optimal sensor placement for the spatial reconstruction of sound fields
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