English

Scaling Wearable Foundation Models

Machine Learning 2024-10-18 v1 Artificial Intelligence Human-Computer Interaction

Abstract

Wearable sensors have become ubiquitous thanks to a variety of health tracking features. The resulting continuous and longitudinal measurements from everyday life generate large volumes of data; however, making sense of these observations for scientific and actionable insights is non-trivial. Inspired by the empirical success of generative modeling, where large neural networks learn powerful representations from vast amounts of text, image, video, or audio data, we investigate the scaling properties of sensor foundation models across compute, data, and model size. Using a dataset of up to 40 million hours of in-situ heart rate, heart rate variability, electrodermal activity, accelerometer, skin temperature, and altimeter per-minute data from over 165,000 people, we create LSM, a multimodal foundation model built on the largest wearable-signals dataset with the most extensive range of sensor modalities to date. Our results establish the scaling laws of LSM for tasks such as imputation, interpolation and extrapolation, both across time and sensor modalities. Moreover, we highlight how LSM enables sample-efficient downstream learning for tasks like exercise and activity recognition.

Keywords

Cite

@article{arxiv.2410.13638,
  title  = {Scaling Wearable Foundation Models},
  author = {Girish Narayanswamy and Xin Liu and Kumar Ayush and Yuzhe Yang and Xuhai Xu and Shun Liao and Jake Garrison and Shyam Tailor and Jake Sunshine and Yun Liu and Tim Althoff and Shrikanth Narayanan and Pushmeet Kohli and Jiening Zhan and Mark Malhotra and Shwetak Patel and Samy Abdel-Ghaffar and Daniel McDuff},
  journal= {arXiv preprint arXiv:2410.13638},
  year   = {2024}
}
R2 v1 2026-06-28T19:26:00.196Z