Self-Adaptive Motion Tracking Against On-Body Displacement of Flexible Sensors
Abstract
Flexible sensors are promising for ubiquitous sensing of human status due to their flexibility and easy integration as wearable systems. However, on-body displacement of sensors is inevitable since the device cannot be firmly worn at a fixed position across different sessions. This displacement issue causes complicated patterns and significant challenges to subsequent machine learning algorithms. Our work proposes a novel self-adaptive motion tracking network to address this challenge. Our network consists of three novel components: i) a light-weight learnable Affine Transformation layer whose parameters can be tuned to efficiently adapt to unknown displacements; ii) a Fourier-encoded LSTM network for better pattern identification; iii) a novel sequence discrepancy loss equipped with auxiliary regressors for unsupervised tuning of Affine Transformation parameters.
Cite
Text
Zuo et al. "Self-Adaptive Motion Tracking Against On-Body Displacement of Flexible Sensors." Neural Information Processing Systems, 2023.Markdown
[Zuo et al. "Self-Adaptive Motion Tracking Against On-Body Displacement of Flexible Sensors." Neural Information Processing Systems, 2023.](https://mlanthology.org/neurips/2023/zuo2023neurips-selfadaptive/)BibTeX
@inproceedings{zuo2023neurips-selfadaptive,
title = {{Self-Adaptive Motion Tracking Against On-Body Displacement of Flexible Sensors}},
author = {Zuo, Chengxu and Jiawei, Fang and Guo, Shihui and Qin, Yipeng},
booktitle = {Neural Information Processing Systems},
year = {2023},
url = {https://mlanthology.org/neurips/2023/zuo2023neurips-selfadaptive/}
}