MagSound: Magnetic Field Assisted Wireless Earphone Tracking

Lihao Wang, Wei Wang, Haipeng Dai, Shizhe Liu
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Abstract

Wireless earphones are pervasive acoustic sensing platforms that can be used for many applications such as motion tracking and handwriting input. However, wireless earphones suffer clock offset between the connected smart devices, which would accumulate error rapidly over time. Moreover, compared with smartphone and voice assistants, the acoustic signal transmitted by wireless earphone is much weaker due to the poor frequency response. In this paper, we propose MagSound, which uses the built-in magnets to improve the tracking and acoustic sensing performance of Commercial-Off-The-Shelf (COTS) earphones. Leveraging magnetic field strength, MagSound can predict the position of wireless earphones free from clock offset, which can be used to re-calibrate the acoustic tracking. Further, the fusion of the two modalities mitigates the accumulated clock offset and multipath effect. Besides, to increase the robustness to noise, MagSound employs finely designed Orthogonal Frequency-Division Multiplexing (OFDM) ranging signals. We implement a prototype of MagSound on COTS and perform experiments for tracking and handwriting input. Results demonstrate that MagSound maintains millimeter-level error in 2D tracking, and improves the handwriting recognition accuracy by 49.81%. We believe that MagSound can contribute to practical applications of wireless earphones-based sensing.
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MagSound:磁场辅助无线耳机跟踪
无线耳机是一种普遍的声学传感平台,可用于许多应用,如运动跟踪和手写输入。然而,无线耳机在连接的智能设备之间存在时钟偏移,这将随着时间的推移迅速积累误差。此外,与智能手机和语音助手相比,无线耳机由于频率响应差,传输的声信号要弱得多。在本文中,我们提出了MagSound,它使用内置磁铁来提高商用现货(COTS)耳机的跟踪和声传感性能。利用磁场强度,MagSound可以预测无线耳机的位置,不受时钟偏移的影响,可以用来重新校准声音跟踪。此外,两种模式的融合减轻了累积时钟偏移和多径效应。此外,MagSound采用了精心设计的正交频分复用(OFDM)测距信号,增强了对噪声的鲁棒性。我们在COTS上实现了MagSound的原型,并进行了跟踪和手写输入的实验。结果表明,MagSound在二维跟踪中保持了毫米级的误差,将手写识别准确率提高了49.81%。我们相信MagSound可以为无线耳机传感的实际应用做出贡献。
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