Optimal Scale-Invariant Wavelet Representation and Filtering of Human Otoacoustic Emissions.

IF 2.4 3区 医学 Q3 NEUROSCIENCES Jaro-Journal of the Association for Research in Otolaryngology Pub Date : 2024-08-01 Epub Date: 2024-05-24 DOI:10.1007/s10162-024-00943-4
Arturo Moleti
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Abstract

Otoacoustic emissions (OAEs) are generated in the cochlea and recorded in the ear canal either as a time domain waveform or as a collection of complex responses to tones in the frequency domain (Probst et al. J Account Soc Am 89:2027-2067, 1991). They are typically represented either in their original acquisition domain or in its Fourier-conjugated domain. Round-trip excursions to the conjugated domain are often used to perform filtering operations in the computationally simplest way, exploiting the convolution theorem. OAE signals consist of the superposition of backward waves generated in different cochlear regions by different generation mechanisms, over a wide frequency range. The cochlear scaling symmetry (cochlear physics is the same at all frequency scales), which approximately holds in the human cochlea, leaves its fingerprints in the mathematical properties of OAE signals. According to a generally accepted taxonomy (Sher and Guinan Jr, J Acoust Soc Am 105:782-798, 1999), OAEs are generated either by wave-fixed sources, moving with frequency according with the cochlear scaling (as in nonlinear distortion) or by place-fixed sources (as in coherent reflection by roughness). If scaling symmetry holds, the two generation mechanisms yield OAEs with different phase gradient delay: almost null for wave-fixed sources, and long (and scaling as 1/f) for place-fixed sources. Thus, the most effective representation of OAE signals is often that respecting the cochlear scale-invariance, such as the time-frequency domain representation provided by the wavelet transform. In the time-frequency domain, the elaborate spectra or waveforms yielded by the superposition of OAE components from different generation mechanisms assume a much clearer 2-D pattern, with each component localized in a specific and predictable region. The wavelet representation of OAE signals is optimal both for visualization purposes and for designing filters that effectively separate different OAE components, improving both the specificity and the sensitivity of OAE-based applications. Indeed, different OAE components have different physiological meanings, and filtering dramatically improves the signal-to-noise ratio.

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人体声发射的最佳尺度不变小波表示和滤波。
耳声发射 (OAE) 在耳蜗中产生,并在耳道中记录为时域波形或频域中对音调的复杂响应集合(Probst et al. J Account Soc Am 89:2027-2067, 1991)。它们通常以原始采集域或傅立叶共轭域表示。共轭域的往返偏移通常用于利用卷积定理,以最简单的计算方式执行滤波操作。OAE 信号由不同耳蜗区域通过不同产生机制产生的后向波在宽频率范围内的叠加组成。耳蜗的比例对称性(耳蜗物理学在所有频率范围内都是相同的)在人类耳蜗中大致成立,它在 OAE 信号的数学特性中留下了自己的痕迹。根据普遍接受的分类法(Sher 和 Guinan Jr,J Acoust Soc Am 105:782-798,1999),OAE 要么由固定波源产生,随耳蜗缩放频率移动(如非线性失真),要么由固定位置源产生(如粗糙度的相干反射)。如果缩放对称性成立,这两种产生机制会产生具有不同相位梯度延迟的 OAE:波固定源几乎为空,而位置固定源则较长(且缩放为 1/f)。因此,OAE 信号最有效的表示方法通常是尊重耳蜗尺度不变性的表示方法,如小波变换提供的时频域表示方法。在时频域中,来自不同产生机制的 OAE 分量叠加产生的复杂频谱或波形呈现出更清晰的二维模式,每个分量都定位在特定的可预测区域。OAE 信号的小波表示法是可视化和设计滤波器的最佳选择,可有效分离不同的 OAE 成分,提高基于 OAE 的应用的特异性和灵敏度。事实上,不同的 OAE 成分具有不同的生理意义,而滤波可显著提高信噪比。
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来源期刊
CiteScore
4.10
自引率
12.50%
发文量
57
审稿时长
6-12 weeks
期刊介绍: JARO is a peer-reviewed journal that publishes research findings from disciplines related to otolaryngology and communications sciences, including hearing, balance, speech and voice. JARO welcomes submissions describing experimental research that investigates the mechanisms underlying problems of basic and/or clinical significance. Authors are encouraged to familiarize themselves with the kinds of papers carried by JARO by looking at past issues. Clinical case studies and pharmaceutical screens are not likely to be considered unless they reveal underlying mechanisms. Methods papers are not encouraged unless they include significant new findings as well. Reviews will be published at the discretion of the editorial board; consult the editor-in-chief before submitting.
期刊最新文献
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