Estimating Pitch Information From Simulated Cochlear Implant Signals With Deep Neural Networks.

IF 2.6 2区医学 Q1 AUDIOLOGY & SPEECH-LANGUAGE PATHOLOGY

Trends in Hearing Pub Date : 2024-01-01 DOI:10.1177/23312165241298606

Takanori Ashihara, Shigeto Furukawa, Makio Kashino

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引用次数: 0

Abstract

Cochlear implant (CI) users, even with substantial speech comprehension, generally have poor sensitivity to pitch information (or fundamental frequency, F0). This insensitivity is often attributed to limited spectral and temporal resolution in the CI signals. However, the pitch sensitivity markedly varies among individuals, and some users exhibit fairly good sensitivity. This indicates that the CI signal contains sufficient information about F0, and users' sensitivity is predominantly limited by other physiological conditions such as neuroplasticity or neural health. We estimated the upper limit of F0 information that a CI signal can convey by decoding F0 from simulated CI signals (multi-channel pulsatile signals) with a deep neural network model (referred to as the CI model). We varied the number of electrode channels and the pulse rate, which should respectively affect spectral and temporal resolutions of stimulus representations. The F0-estimation performance generally improved with increasing number of channels and pulse rate. For the sounds presented under quiet conditions, the model performance was at best comparable to that of a control waveform model, which received raw-waveform inputs. Under conditions in which background noise was imposed, the performance of the CI model generally degraded by a greater degree than that of the waveform model. The pulse rate had a particularly large effect on predicted performance. These observations indicate that the CI signal contains some information for predicting F0, which is particularly sufficient for targets under quiet conditions. The temporal resolution (represented as pulse rate) plays a critical role in pitch representation under noisy conditions.

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利用深度神经网络从模拟人工耳蜗信号中估计音高信息

人工耳蜗 (CI) 用户即使有很强的语音理解能力，一般对音高信息（或基频，F0）的敏感度也很低。这种不敏感通常归因于 CI 信号的频谱和时间分辨率有限。然而，不同个体的音调灵敏度存在明显差异，有些用户的灵敏度相当高。这表明 CI 信号包含足够的 F0 信息，而用户的灵敏度主要受到神经可塑性或神经健康等其他生理条件的限制。我们通过使用深度神经网络模型（简称 CI 模型）对模拟 CI 信号（多通道脉动信号）进行 F0 解码，从而估算出 CI 信号所能传达的 F0 信息上限。我们改变了电极通道的数量和脉冲频率，这将分别影响刺激表征的频谱和时间分辨率。随着通道数和脉冲频率的增加，F0 估算性能普遍提高。对于在安静条件下呈现的声音，模型性能最多只能与接收原始波形输入的对照波形模型相媲美。在有背景噪音的条件下，CI 模型的性能通常比波形模型的性能下降得更多。脉搏率对预测性能的影响尤其大。这些观察结果表明，CI 信号包含一些预测 F0 的信息，尤其是对安静条件下的目标而言，这些信息是足够的。时间分辨率（以脉搏率表示）在噪声条件下的音高表示中起着至关重要的作用。

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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来源期刊

Trends in Hearing AUDIOLOGY & SPEECH-LANGUAGE PATHOLOGYOTORH-OTORHINOLARYNGOLOGY

CiteScore

4.50

自引率

11.10%

发文量

审稿时长

12 weeks

期刊介绍： Trends in Hearing is an open access journal completely dedicated to publishing original research and reviews focusing on human hearing, hearing loss, hearing aids, auditory implants, and aural rehabilitation. Under its former name, Trends in Amplification, the journal established itself as a forum for concise explorations of all areas of translational hearing research by leaders in the field. Trends in Hearing has now expanded its focus to include original research articles, with the goal of becoming the premier venue for research related to human hearing and hearing loss.