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正常听力受试者中300Hz以下畸变产物耳声发射的测量

Distortion-Product Otoacoustic Emission Measured Below 300 Hz in Normal-Hearing Human Subjects.

作者信息

Christensen Anders T, Ordoñez Rodrigo, Hammershøi Dorte

机构信息

Section for Signal and Information Processing, Department of Electronic Systems, Fredrik Bajers Vej 7B5, 9220, Aalborg, Denmark.

出版信息

J Assoc Res Otolaryngol. 2017 Apr;18(2):197-208. doi: 10.1007/s10162-016-0600-x. Epub 2016 Nov 21.

Abstract

Physiological noise levels in the human ear canal often exceed naturally low levels of otoacoustic emissions (OAEs) near the threshold of hearing. Low-frequency noise, and electronic filtering to cope with it, has effectively limited the study of OAE to frequencies above about 500 Hz. Presently, a custom-built low-frequency acoustic probe was put to use in 21 normal-hearing human subjects (of 34 recruited). Distortion-product otoacoustic emission (DPOAE) was measured in the enclosed ear canal volume as the response to two simultaneously presented tones with frequencies f and f . The stimulus-frequency ratio f /f was varied systematically to find the "optimal" ratio evoking the largest level at 2 f -f frequencies 87.9, 176, and 264 Hz. No reference data exist in this frequency region. Results show that DPOAE exists down to at least 87.9 Hz, maintaining the bell-shaped dependence on the f /f ratio known from higher frequencies. Toward low frequencies, however, the bell broadens and the optimal ratio increases proportionally to the bandwidth of an auditory filter as defined by the equivalent rectangular bandwidth. The DPOAE phase rotates monotonously as a function of the stimulus ratio, and its slope trend supports the notion of a lack of scaling symmetry in the apex of the cochlea.

摘要

人耳道内的生理噪声水平常常超过听力阈值附近自然产生的低水平耳声发射(OAE)。低频噪声以及应对它的电子滤波有效地将OAE的研究限制在了约500Hz以上的频率。目前,一种定制的低频声学探头被应用于21名听力正常的人类受试者(招募的34名受试者中的)。在封闭的耳道容积中测量畸变产物耳声发射(DPOAE),作为对两个同时呈现的频率为f和f的纯音的响应。系统地改变刺激频率比f/f,以找到在2f - f频率87.9、176和264Hz时引发最大水平的“最佳”比率。在该频率区域不存在参考数据。结果表明,DPOAE至少存在至87.9Hz,保持了与高频时已知的对f/f比率的钟形依赖关系。然而,向低频方向,钟形变宽,并且最佳比率与由等效矩形带宽定义的听觉滤波器的带宽成比例增加。DPOAE相位作为刺激比率的函数单调旋转,并且其斜率趋势支持耳蜗顶部缺乏比例对称性的观点。

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Frequency selectivity for frequencies below 100 Hz: comparisons with mid-frequencies.
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