Litcius/Paper detail

Push the Limit of Highly Accurate Ranging on Commercial UWB Devices

Junqi Ma, Fusang Zhang, Beihong Jin, Su Chang, Siheng Li, Zhi Wang, Jiazhi Ni

2024Proceedings of the ACM on Interactive Mobile Wearable and Ubiquitous Technologies16 citationsDOIOpen Access PDF

Abstract

Ranging plays a crucial role in many wireless sensing applications. Among the wireless techniques employed for ranging, Ultra-Wideband (UWB) has received much attention due to its excellent performance and widespread integration into consumer-level electronics. However, the ranging accuracy of the current UWB systems is limited to the centimeter level due to bandwidth limitation, hindering their use for applications that require a very high resolution. This paper proposes a novel system that achieves sub-millimeter-level ranging accuracy on commercial UWB devices for the first time. Our approach leverages the fine-grained phase information of commercial UWB devices. To eliminate the phase drift, we design a fine-grained phase recovery method by utilizing the bi-directional messages in UWB two-way ranging. We further present a dual-frequency switching method to resolve phase ambiguity. Building upon this, we design and implement the ranging system on commercial UWB modules. Extensive experiments demonstrate that our system achieves a median ranging error of just 0.77 mm, reducing the error by 96.54% compared to the state-of-the-art method. We also present three real-life applications to showcase the fine-grained sensing capabilities of our system, including i) smart speaker control, ii) free-style user handwriting, and iii) 3D tracking for virtual-reality (VR) controllers.

Topics & Concepts

RangingLimit (mathematics)Computer scienceTelecommunicationsMathematicsMathematical analysisIndoor and Outdoor Localization TechnologiesUltra-Wideband Communications TechnologyMicrowave Imaging and Scattering Analysis