Improving piano music signal recognition through enhanced frequency domain analysis

Journal of Measurements in Engineering Pub Date : 2024-02-23 DOI:10.21595/jme.2024.23774

Hongjiao Gao

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Abstract

Feature extraction is a crucial component in the analysis of piano music signals. This article introduced three methods for feature extraction based on frequency domain analysis, namely short-time Fourier transform (STFT), linear predictive cepstral coefficient (LPCC), and Mel-frequency cepstral coefficient (MFCC). An improvement was then made to the MFCC. The inverse MFCC (IMFCC) was combined with mid-frequency MFCC (MidMFCC). The Fisher criterion was used to select the 12-order parameters with the maximum Fisher ratio, which were combined into the F-MFCC feature for recognizing 88 single piano notes through a support vector machine. The results indicated that when compared with the STFT and LPCC, the MFCC exhibited superior performance in recognizing piano music signals, with an accuracy rate of 78.03 % and an F1 value of 85.92 %. Nevertheless, the proposed F-MFCC achieved a remarkable accuracy rate of 90.91 %, representing a substantial improvement by 12.88 % over the MFCC alone. These findings provide evidence for the effectiveness of the designed F-MFCC feature for piano music signal recognition as well as its potential application in practical music signal analysis.

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通过增强频域分析提高钢琴音乐信号识别能力

特征提取是钢琴音乐信号分析的重要组成部分。本文介绍了三种基于频域分析的特征提取方法，即短时傅立叶变换 (STFT)、线性预测前谱系数 (LPCC) 和梅尔-频率前谱系数 (MFCC)。随后对 MFCC 进行了改进。反 MFCC（IMFCC）与中频 MFCC（MidMFCC）相结合。利用 Fisher 准则选出 Fisher 比值最大的 12 阶参数，并将其组合成 F-MFCC 特征，通过支持向量机识别 88 个单个钢琴音符。结果表明，与 STFT 和 LPCC 相比，MFCC 在识别钢琴音乐信号方面表现更优，准确率为 78.03%，F1 值为 85.92%。然而，拟议的 F-MFCC 的准确率达到了 90.91%，比单独使用 MFCC 提高了 12.88%。这些结果证明了所设计的 F-MFCC 特征在钢琴音乐信号识别中的有效性，以及在实际音乐信号分析中的应用潜力。

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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Journal of Measurements in Engineering

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