DARF: A data-reduced FADE version for simulations of speech recognition thresholds with real hearing aids

•Automatic-speech-recogniton-inspired model (FADE) simulates hearing aid benefits.•Speech recognition thresholds can be predicted for any signal processing algorithm.•A modified FADE predicts speech recognition with ≈ 30 min of (processed) signals.•The modified FADE may aid hearing aid development a...

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Veröffentlicht in:Hearing research 2021-05, Vol.404, p.108217-108217, Article 108217
Hauptverfasser: Hülsmeier, David, Schädler, Marc René, Kollmeier, Birger
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Sprache:eng
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Zusammenfassung:•Automatic-speech-recogniton-inspired model (FADE) simulates hearing aid benefits.•Speech recognition thresholds can be predicted for any signal processing algorithm.•A modified FADE predicts speech recognition with ≈ 30 min of (processed) signals.•The modified FADE may aid hearing aid development and hearing aid fitting. Developing and selecting hearing aids is a time consuming process which is simplified by using objective models. Previously, the framework for auditory discrimination experiments (FADE) accurately simulated benefits of hearing aid algorithms with root mean squared prediction errors below 3 dB. One FADE simulation requires several hours of (un)processed signals, which is obstructive when the signals have to be recorded. We propose and evaluate a data-reduced FADE version (DARF) which facilitates simulations with signals that cannot be processed digitally, but that can only be recorded in real-time. DARF simulates one speech recognition threshold (SRT) with about 30 min of recorded and processed signals of the (German) matrix sentence test. Benchmark experiments were carried out to compare DARF and standard FADE exhibiting small differences for stationary maskers (1 dB), but larger differences with strongly fluctuating maskers (5 dB). Hearing impairment and hearing aid algorithms seemed to reduce the differences. Hearing aid benefits were simulated in terms of speech recognition with three pairs of real hearing aids in silence (≥8 dB), in stationary and fluctuating maskers in co-located (stat. 2 dB; fluct. 6 dB), and spatially separated speech and noise signals (stat. ≥8 dB; fluct. 8 dB). The simulations were plausible in comparison to data from literature, but a comparison with empirical data is still open. DARF facilitates objective SRT simulations with real devices with unknown signal processing in real environments. Yet, a validation of DARF for devices with unknown signal processing is still pending since it was only tested with three similar devices. Nonetheless, DARF could be used for improving as well as for developing or model-based fitting of hearing aids.
ISSN:0378-5955
1878-5891
DOI:10.1016/j.heares.2021.108217