Perceptually Relevant Preservation of Interaural Time Differences in Binaural Hearing Aids

TL;DR

This paper introduces a noise reduction method for binaural hearing aids that preserves interaural time differences (ITD), maintaining spatial cues and lateralization of noise sources, validated through objective and psychoacoustic tests.

Contribution

It applies the interaural coherence concept to the Multichannel Wiener Filter to enhance ITD preservation and noise reduction in binaural hearing aids, especially below 1.5 kHz.

Findings

Effective noise reduction while preserving ITD cues.

Maintains natural lateralization of directional noise.

Validated by objective and psychoacoustic experiments.

Abstract

This work presents a noise reduction method with perceptually relevant preservation of the interaural time difference (ITD) of the residual noise in binaural hearing aids. The interaural coherence (IC) concept, previously applied to the Multichannel Wiener Filter (MWF) for preservation of the spatial subjective sensation of diffuse noise fields, is proposed here to both preserve and emphasize the ITD binaural cues of a directional acoustic noise source. It is demonstrated that the previously developed MWF-ITD technique may decrease the original IC magnitude of the processed noise, consequently increasing the variance of the interaural phase difference (IPD) of the output signals. It is shown that the MWF-IC technique concomitantly minimizes a nonlinear function of the difference between input and output IPD, which is strictly related to ITD, and preserves the natural coherence of the directional noise captured by the reference microphones. Objective measures and psychoacoustic experiments corroborate the theoretical findings, showing the MWF-IC technique provides relevant noise reduction, while preserving the original ITD subjective perception and original lateralization for a directional noise source. These results are especially relevant for hearing aid designers, since they indicate the MWF-IC as a noise reduction technique that provides resid-ual noise spatial preservation for both diffuse and directional noise sources in frequencies below 1.5 kHz.