End-to-End Multi-Task Learning for Adjustable Joint Noise Reduction and Hearing Loss Compensation

TL;DR

This paper introduces a novel end-to-end multi-task deep learning framework that jointly performs noise reduction and hearing loss compensation, allowing for listener-specific customization and adjustable processing levels.

Contribution

It presents the first differentiable auditory model integrated into a DNN for simultaneous noise reduction and hearing loss compensation, enabling personalized and adjustable hearing aid processing.

Findings

Improves objective metrics over single-task models

Outperforms cascaded DNN approaches

Achieves competitive hearing-aid prescription results

Abstract

A multi-task learning framework is proposed for optimizing a single deep neural network (DNN) for joint noise reduction (NR) and hearing loss compensation (HLC). A distinct training objective is defined for each task, and the DNN predicts two time-frequency masks. During inference, the amounts of NR and HLC can be adjusted independently by exponentiating each mask before combining them. In contrast to recent approaches that rely on training an auditory-model emulator to define a differentiable training objective, we propose an auditory model that is inherently differentiable, thus allowing end-to-end optimization. The audiogram is provided as an input to the DNN, thereby enabling listener-specific personalization without the need for retraining. Results show that the proposed approach not only allows adjusting the amounts of NR and HLC individually, but also improves objective metrics compared to optimizing a single training objective. It also outperforms a cascade of two DNNs that were separately trained for NR and HLC, and shows competitive HLC performance compared to a traditional hearing-aid prescription. To the best of our knowledge, this is the first study that uses an auditory model to train a single DNN for both NR and HLC across a wide range of listener profiles.