研究音频分类中频谱形状的有效动态信息

IF 8.4 1区计算机科学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS

IEEE Transactions on Multimedia Pub Date : 2024-12-24 DOI:10.1109/TMM.2024.3521837

Liangwei Chen;Xiren Zhou;Qiuju Chen;Fang Xiong;Huanhuan Chen

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引用次数: 0

摘要

频谱形状包含音频分类（AC）的关键信息，包括频谱的包络线、细节和随时间的动态变化。传统方法利用倒谱系数进行光谱形状描述，但忽略了其变化细节。深度学习方法捕获了一些动态，但需要大量的培训或微调资源。即使在计算资源和数据有限的情况下，模型空间学习（LMS）框架也能通过模型拟合精确地捕获时间数据的动态信息。然而，将LMS应用到音频中面临着以下挑战：1)音频的高采样率阻碍了有效的数据拟合和动态信息的捕获。2)局部光谱形状的动态信息（DIPSS）可以增强分类能力，因为只有特定的光谱形状与AC相关。本文扩展了一个称为有效动态信息捕获（EDIC）的AC框架来解决上述问题。EDIC构建了不同维间隔内的Mel-Frequency Cepstral Coefficients （MFCC）序列作为拟合数据，不仅减少了序列采样点的数量，而且可以描述不同部分的频谱形状随时间的变化。EDIC使我们能够在模型空间中实现基于拓扑的选择算法，为当前交流任务选择有效的DIPSS。在三个任务上的表现证实了EDIC的有效性。

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Investigating the Effective Dynamic Information of Spectral Shapes for Audio Classification

The spectral shape holds crucial information for Audio Classification (AC), encompassing the spectrum's envelope, details, and dynamic changes over time. Conventional methods utilize cepstral coefficients for spectral shape description but overlook its variation details. Deep-learning approaches capture some dynamics but demand substantial training or fine-tuning resources. The Learning in the Model Space (LMS) framework precisely captures the dynamic information of temporal data by utilizing model fitting, even when computational resources and data are limited. However, applying LMS to audio faces challenges: 1) The high sampling rate of audio hinders efficient data fitting and capturing of dynamic information. 2) The Dynamic Information of Partial Spectral Shapes (DIPSS) may enhance classification, as only specific spectral shapes are relevant for AC. This paper extends an AC framework called Effective Dynamic Information Capture (EDIC) to tackle the above issues. EDIC constructs Mel-Frequency Cepstral Coefficients (MFCC) sequences within different dimensional intervals as the fitted data, which not only reduces the number of sequence sampling points but can also describe the change of the spectral shape in different parts over time. EDIC enables us to implement a topology-based selection algorithm in the model space, selecting effective DIPSS for the current AC task. The performance on three tasks confirms the effectiveness of EDIC.

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来源期刊

IEEE Transactions on Multimedia 工程技术-电信学

CiteScore

11.70

自引率

11.00%

发文量

576

审稿时长

5.5 months

期刊介绍： The IEEE Transactions on Multimedia delves into diverse aspects of multimedia technology and applications, covering circuits, networking, signal processing, systems, software, and systems integration. The scope aligns with the Fields of Interest of the sponsors, ensuring a comprehensive exploration of research in multimedia.