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Physics-Informed Data Denoising for Real-Life Sensing Systems

Machine Learning 2023-11-14 v1 Artificial Intelligence Signal Processing Machine Learning

Abstract

Sensors measuring real-life physical processes are ubiquitous in today's interconnected world. These sensors inherently bear noise that often adversely affects performance and reliability of the systems they support. Classic filtering-based approaches introduce strong assumptions on the time or frequency characteristics of sensory measurements, while learning-based denoising approaches typically rely on using ground truth clean data to train a denoising model, which is often challenging or prohibitive to obtain for many real-world applications. We observe that in many scenarios, the relationships between different sensor measurements (e.g., location and acceleration) are analytically described by laws of physics (e.g., second-order differential equation). By incorporating such physics constraints, we can guide the denoising process to improve even in the absence of ground truth data. In light of this, we design a physics-informed denoising model that leverages the inherent algebraic relationships between different measurements governed by the underlying physics. By obviating the need for ground truth clean data, our method offers a practical denoising solution for real-world applications. We conducted experiments in various domains, including inertial navigation, CO2 monitoring, and HVAC control, and achieved state-of-the-art performance compared with existing denoising methods. Our method can denoise data in real time (4ms for a sequence of 1s) for low-cost noisy sensors and produces results that closely align with those from high-precision, high-cost alternatives, leading to an efficient, cost-effective approach for more accurate sensor-based systems.

Keywords

Cite

@article{arxiv.2311.06968,
  title  = {Physics-Informed Data Denoising for Real-Life Sensing Systems},
  author = {Xiyuan Zhang and Xiaohan Fu and Diyan Teng and Chengyu Dong and Keerthivasan Vijayakumar and Jiayun Zhang and Ranak Roy Chowdhury and Junsheng Han and Dezhi Hong and Rashmi Kulkarni and Jingbo Shang and Rajesh Gupta},
  journal= {arXiv preprint arXiv:2311.06968},
  year   = {2023}
}

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