Biomechanical simulation of the human ear

2015 IEEE 4th Portuguese Meeting on Bioengineering (ENBENG) Pub Date : 2015-04-20 DOI:10.1109/ENBENG.2015.7088813

B. Areias, M. Parente, F. Gentil, R. N. Natal Jorge, A. Fernandes

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Abstract

Summary form only given. In this study, the biomechanical behaviour of the human hearing was studied. An accurate finite element model can be used to evaluate the influence of certain hearing diseases and aid in their treatment, as well as help to comprehend the phenomenon of sound transmission. This research was based on the project "The Visible Ear" developed by a group of Danish students in order to obtain a set of high quality images of the temporal bone, using a "cryosectioning" procedure [1]. This project allowed the development of the computational models used. CAD software was used to treat each of the parts that compose the human ear. The first tested model (simple model) was composed of the tympanic membrane, ossicles, cochlea, two muscles, six ligaments, two joints, and the temporal bone. The full model was based on the simple model adding air to the external auditory canal and middle ear, the skin, the jaw and the ear cartilage. Comparing the results obtained by both models, it was possible to understand the importance of the ear canal in the transmission of the sound to the eardrum. The models were simulated numerically with the Abaqus software. The natural frequencies, displacements of the umbo and stapes footplate were obtained for both models, for different sound pressure levels. The frequency band used in this study was between 100 Hz and 10 kHz.

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人耳的生物力学模拟

只提供摘要形式。本研究对人类听觉的生物力学行为进行了研究。一个精确的有限元模型可以用来评估某些听力疾病的影响和帮助治疗，也有助于理解声音传播的现象。本研究基于一组丹麦学生开发的“看得见的耳朵”项目，目的是通过“冷冻切片”程序获得一组高质量的颞骨图像[1]。这个项目允许开发所使用的计算模型。使用CAD软件对组成人耳的每个部分进行处理。第一个实验模型(简单模型)由鼓膜、听骨、耳蜗、2块肌肉、6条韧带、2个关节和颞骨组成。完整模型是在简单模型的基础上，在外耳道、中耳、皮肤、下颚和耳软骨中加入空气。比较两种模型得到的结果，可以理解耳道在声音传输到鼓膜中的重要性。利用Abaqus软件对模型进行了数值模拟。得到了两种模型在不同声压级下的固有频率、双脚底板和镫骨底板的位移。这项研究中使用的频带在100赫兹到10千赫之间。

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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2015 IEEE 4th Portuguese Meeting on Bioengineering (ENBENG)

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