Litcius/Paper detail

SAMoSA

Vimal Mollyn, Karan Ahuja, Dhruv Verma, Chris Harrison, Mayank Goel

2022Proceedings of the ACM on Interactive Mobile Wearable and Ubiquitous Technologies49 citationsDOIOpen Access PDF

Abstract

Despite advances in audio- and motion-based human activity recognition (HAR) systems, a practical, power-efficient, and privacy-sensitive activity recognition system has remained elusive. State-of-the-art activity recognition systems often require power-hungry and privacy-invasive audio data. This is especially challenging for resource-constrained wearables, such as smartwatches. To counter the need for an always-on audio-based activity classification system, we first make use of power and compute-optimized IMUs sampled at 50 Hz to act as a trigger for detecting activity events. Once detected, we use a multimodal deep learning model that augments the motion data with audio data captured on a smartwatch. We subsample this audio to rates ≤ 1 kHz, rendering spoken content unintelligible, while also reducing power consumption on mobile devices. Our multimodal deep learning model achieves a recognition accuracy of 92.2% across 26 daily activities in four indoor environments. Our findings show that subsampling audio from 16 kHz down to 1 kHz, in concert with motion data, does not result in a significant drop in inference accuracy. We also analyze the speech content intelligibility and power requirements of audio sampled at less than 1 kHz and demonstrate that our proposed approach can improve the practicality of human activity recognition systems.

Topics & Concepts

SmartwatchComputer scienceActivity recognitionWearable computerRendering (computer graphics)InferenceMobile deviceSpeech recognitionWearable technologyDeep learningArtificial intelligencePower consumptionPower (physics)Embedded systemOperating systemQuantum mechanicsPhysicsMusic and Audio ProcessingContext-Aware Activity Recognition SystemsSpeech and Audio Processing