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Autori principali: Roden, Reinhild, Sankowsky-Rothe, Tobias, Wulbusch, Nick, Chernov, Alexey, Blau, Matthias
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2511.12552
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author Roden, Reinhild
Sankowsky-Rothe, Tobias
Wulbusch, Nick
Chernov, Alexey
Blau, Matthias
author_facet Roden, Reinhild
Sankowsky-Rothe, Tobias
Wulbusch, Nick
Chernov, Alexey
Blau, Matthias
contents To derive ear canal transfer functions for individualized equalization algorithms of in-ear hearing systems, individual ear canal models are needed. In a one-dimensional approach, this requires the estimation of the individual area function of the ear canal. The area function can be effectively and reproducibly calculated as the inverse solution of Webster's horn equation by finite difference approximation of the time domain reflectance. Building upon previous research, the present study further investigates the termination of the approximation at an optimal spatial resolution, addressing the absence of higher frequencies in typical ear canal measurements and enhancing the accuracy of the inverse solution. Compared to the geometric reference, more precise area functions were achieved by extrapolating simulated input impedances of ear canal geometries up to a frequency of 3.5 MHz, corresponding to 0.1 mm spatial resolution. The low pass of the previous work was adopted but adjusted for its cut-off frequency depending on the highest frequency of the band-limited input impedance. Robust criteria for terminating the area function at the approximated ear canal length were found. Finally, three-dimensional simulated and measured ear canal transfer impedances were replicated well employing the previously introduced and herein validated one-dimensional electro-acoustic model fed by the area functions.
format Preprint
id arxiv_https___arxiv_org_abs_2511_12552
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Eardrum sound pressure prediction from ear canal reflectance based on the inverse solution of Webster's horn equation
Roden, Reinhild
Sankowsky-Rothe, Tobias
Wulbusch, Nick
Chernov, Alexey
Blau, Matthias
Audio and Speech Processing
Applied Physics
To derive ear canal transfer functions for individualized equalization algorithms of in-ear hearing systems, individual ear canal models are needed. In a one-dimensional approach, this requires the estimation of the individual area function of the ear canal. The area function can be effectively and reproducibly calculated as the inverse solution of Webster's horn equation by finite difference approximation of the time domain reflectance. Building upon previous research, the present study further investigates the termination of the approximation at an optimal spatial resolution, addressing the absence of higher frequencies in typical ear canal measurements and enhancing the accuracy of the inverse solution. Compared to the geometric reference, more precise area functions were achieved by extrapolating simulated input impedances of ear canal geometries up to a frequency of 3.5 MHz, corresponding to 0.1 mm spatial resolution. The low pass of the previous work was adopted but adjusted for its cut-off frequency depending on the highest frequency of the band-limited input impedance. Robust criteria for terminating the area function at the approximated ear canal length were found. Finally, three-dimensional simulated and measured ear canal transfer impedances were replicated well employing the previously introduced and herein validated one-dimensional electro-acoustic model fed by the area functions.
title Eardrum sound pressure prediction from ear canal reflectance based on the inverse solution of Webster's horn equation
topic Audio and Speech Processing
Applied Physics
url https://arxiv.org/abs/2511.12552