基于频谱稀疏度量的音乐音符起音检测。

IF 1.7 3区 计算机科学 Q2 ACOUSTICS
Mina Mounir, Peter Karsmakers, Toon van Waterschoot
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引用次数: 0

摘要

如果说音乐是宇宙的语言,那么音符的节拍可能就是这种语言的音节。音符的起音不仅定义了乐曲的时间模式,而且其时间频率特性还包含了有关产生音符的乐器身份的丰富信息。音符起音检测(NOD)是许多音乐信息检索任务的基本组成部分,在音频信号处理研究中引起了极大的兴趣。在本文中,我们提出了一种基于 "基于频谱稀疏性的音符起音归一化识别(NINOS2)"这一新颖特征的 NOD 方法。NINOS2 特征可视为一种频谱稀疏度量,旨在利用音符不同部分之间的频谱稀疏度差异。在计算音符起音特征时,传统上会过滤掉低幅度的频谱成分,而这种频谱结构在关注低幅度频谱成分时就会显现出来。我们展示了大量的 NOD 模拟结果,涵盖了各种乐器、演奏风格和混合选项。对于最难处理的一组乐器,即持续弦乐器,所提出的算法始终优于基准对数频谱通量(LSF)特征。在复调音乐和颤音演奏等具有挑战性的情况下,它也表现出了更好的性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Musical note onset detection based on a spectral sparsity measure.

Musical note onset detection based on a spectral sparsity measure.

Musical note onset detection based on a spectral sparsity measure.

Musical note onset detection based on a spectral sparsity measure.

If music is the language of the universe, musical note onsets may be the syllables for this language. Not only do note onsets define the temporal pattern of a musical piece, but their time-frequency characteristics also contain rich information about the identity of the musical instrument producing the notes. Note onset detection (NOD) is the basic component for many music information retrieval tasks and has attracted significant interest in audio signal processing research. In this paper, we propose an NOD method based on a novel feature coined as Normalized Identification of Note Onset based on Spectral Sparsity (NINOS2). The NINOS2 feature can be thought of as a spectral sparsity measure, aiming to exploit the difference in spectral sparsity between the different parts of a musical note. This spectral structure is revealed when focusing on low-magnitude spectral components that are traditionally filtered out when computing note onset features. We present an extensive set of NOD simulation results covering a wide range of instruments, playing styles, and mixing options. The proposed algorithm consistently outperforms the baseline Logarithmic Spectral Flux (LSF) feature for the most difficult group of instruments which are the sustained-strings instruments. It also shows better performance for challenging scenarios including polyphonic music and vibrato performances.

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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.
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