用物理模型和人工吹风机研究单簧管的发音

Q1 Arts and Humanities

Acta Acustica united with Acustica Pub Date : 2019-07-01 DOI:10.3813/AAA.919348

V. Chatziioannou, Sebastian Schmutzhard, Montserrat Pàmies-Vilà, A. Hofmann

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引用次数: 10

摘要

提出了一种时域物理模型，该模型能够模拟单簧木管乐器的各种发音技术，并适用于实时声音合成。由于激励机制的非线性性质，为了保证算法的稳定性，采用基于能量的方法构建数值格式。为了验证模型，使用人工吹风机进行了测量。详细描述了该机器的结构，包括配备传感器的簧片和口以及自动人工舌和唇。通过调节舌的运动，吹箫机可以产生与连音和断音发音相对应的音频信号。这些信号在基于所提出的物理模型的逆建模方法下重新合成，在此期间估计模型参数。所有估计的参数都在物理上可行的范围内，可用于声音合成和声音分析应用。

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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Investigating Clarinet Articulation Using a Physical Model and an Artificial Blowing Machine

A time-domain physical model is presented that is capable of simulating a variety of articulation techniques in single-reed woodwind instruments and suitable for real-time sound synthesis. Due to the nonlinear nature of the excitation mechanism, an energy-based approach is adopted for the construction of the numerical scheme in order to ensure algorithm stability. To validate the model, measurements are carried out using an artificial blowing machine. The construction of the machine, including a sensor-equipped reed and mouthpiece as well as an automated artificial tongue and lip, is described in detail. By adjusting the motion of the tongue, the blowing machine can generate audio signals corresponding to portato and staccato articulation. These signals are resynthesised following an inverse modelling approach based on the presented physical model, during which model parameters are estimated. All estimated parameters lie in a physically feasible range and may be used for sound synthesis and sound analysis applications.

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来源期刊

Acta Acustica united with Acustica 物理-声学

CiteScore

2.60

自引率

0.00%

发文量

审稿时长

6.8 months

期刊介绍： Cessation. Acta Acustica united with Acustica (Acta Acust united Ac), was published together with the European Acoustics Association (EAA). It was an international, peer-reviewed journal on acoustics. It published original articles on all subjects in the field of acoustics, such as • General Linear Acoustics, • Nonlinear Acoustics, Macrosonics, • Aeroacoustics, • Atmospheric Sound, • Underwater Sound, • Ultrasonics, • Physical Acoustics, • Structural Acoustics, • Noise Control, • Active Control, • Environmental Noise, • Building Acoustics, • Room Acoustics, • Acoustic Materials and Metamaterials, • Audio Signal Processing and Transducers, • Computational and Numerical Acoustics, • Hearing, Audiology and Psychoacoustics, • Speech, • Musical Acoustics, • Virtual Acoustics, • Auditory Quality of Systems, • Animal Bioacoustics, • History of Acoustics.