Abstract
Physiological and psychophysical methods allow for an extended investigation of ascending (afferent) neural pathways from the ear to the brain in mammals, and their role in enhancing signals in noise. However, there is increased interest in descending (efferent) neural fibers in the mammalian auditory pathway. This efferent pathway operates via the olivocochlear system, modifying auditory processing by cochlear innervation and enhancing human ability to detect sounds in noisy backgrounds. Effective speech intelligibility may depend on a complex interaction between efferent time-constants and types of background noise. In this study, an auditory model with efferent-inspired processing provided the front-end to an automatic-speech-recognition system (ASR), used as a tool to evaluate speech recognition with changes in time-constants (50 to 2000 ms) and background noise type (unmodulated and modulated noise). With efferent activation, maximal speech recognition improvement (for both noise types) occurred for signal-to-noise ratios around 10 dB, characteristic of real-world speech-listening situations. Net speech improvement due to efferent activation (NSIEA) was smaller in modulated noise than in unmodulated noise. For unmodulated noise, NSIEA increased with increasing time-constant. For modulated noise, NSIEA increased for time-constants up to 200 ms but remained similar for longer time-constants, consistent with speech-envelope modulation times important to speech recognition in modulated noise. The model improves our understanding of the complex interactions involved in speech recognition in noise, and could be used to simulate the difficulties of speech perception in noise as a consequence of different types of hearing loss.
Highlights
Much is known of the role of ascending neural fibers in the mammalian auditory pathway in conveying information about sound processing from peripheral auditory structures to higher brain centers
Reference [17] used an auditory model with a gain-control based on an ensemble interval histogram representation and showed that speech representation could be improved with efferent-inspired feedback; [17] did not measure speech recognition performance with specific efferent time constants derived from humans
Maximal speech improvement for either UM or AM noise with efferent activation is at an SNR of around 10 dB
Summary
Much is known of the role of ascending (afferent) neural fibers in the mammalian auditory pathway in conveying information about sound processing from peripheral auditory structures to higher brain centers. Recently there has been renewed interest in the descending (efferent) neural pathways which convey information from higher brain centers back to peripheral auditory structures, and may play. A role in humans in enhancing speech in background noise One such efferent pathway, originating in the brainstem with connections in the Medial OlivoCochlear (MOC) system, innervates the cochlea of the inner ear [1], [2]. One of the main roles of MOC feedback in humans is suggested to be the improvement of speech perception in noisy environments [4], [5] This is demonstrated by assessing the performance of individuals with lesions in the auditory
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