Egocentric Deep Multi-Channel Audio-Visual Active Speaker Localization
This addresses the challenge of understanding social interactions for augmented reality device users, though it is incremental by building on existing audio-visual methods.
The paper tackles the problem of detecting and localizing active speakers in egocentric conversational environments, proposing a novel deep learning approach that achieves robust voice activity detection and localization, including outside the camera's field of view, with real-time performance and noise robustness.
Augmented reality devices have the potential to enhance human perception and enable other assistive functionalities in complex conversational environments. Effectively capturing the audio-visual context necessary for understanding these social interactions first requires detecting and localizing the voice activities of the device wearer and the surrounding people. These tasks are challenging due to their egocentric nature: the wearer's head motion may cause motion blur, surrounding people may appear in difficult viewing angles, and there may be occlusions, visual clutter, audio noise, and bad lighting. Under these conditions, previous state-of-the-art active speaker detection methods do not give satisfactory results. Instead, we tackle the problem from a new setting using both video and multi-channel microphone array audio. We propose a novel end-to-end deep learning approach that is able to give robust voice activity detection and localization results. In contrast to previous methods, our method localizes active speakers from all possible directions on the sphere, even outside the camera's field of view, while simultaneously detecting the device wearer's own voice activity. Our experiments show that the proposed method gives superior results, can run in real time, and is robust against noise and clutter.