Cross-Body UWB Radar Sensing of Arterial Pulse Propagation and Ventricular Dynamics

2018 IEEE Biomedical Circuits and Systems Conference (BioCAS) Pub Date : 2018-10-01 DOI:10.1109/BIOCAS.2018.8584690

T. Lauteslager, Mathias Tømmer, T. Lande, T. Constandinou

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引用次数: 3

Abstract

Single-chip UWB radar systems have enormous potential for the development of portable, low-cost and easy-to-use devices for monitoring the cardiovascular system. Using body coupled antennas, electromagnetic energy can be directed into the body to measure arterial pulsation and cardiac motion, and estimate arterial stiffness as well as blood pressure. In the current study we validate that heart rate signals, obtained using multiple UWB radar-on-chip modules and body coupled antennas, do indeed originate from arterial pulsation. Through ECG-aligned averaging, pulse arrival time at a number of locations in the body could be measured with high precision, and arterial pulse propagation through the femoral and carotid artery was demonstrated. In addition, cardiac dynamics were measured from the chest. Onset and offset of ventricular systole were clearly distinguishable, as well as onset of atrial systole. Although further validation is required, these results show that UWB radar-on-chip is highly suitable for monitoring of vascular health as well as the heart's mechanical functioning.

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跨体超宽带雷达感知动脉脉冲传播和心室动力学

单芯片超宽带雷达系统在开发便携式、低成本和易于使用的心血管系统监测设备方面具有巨大的潜力。利用人体耦合天线，电磁能量可以直接进入人体，测量动脉搏动和心脏运动，并估计动脉硬度和血压。在目前的研究中，我们验证了使用多个超宽带雷达芯片模块和身体耦合天线获得的心率信号确实来自动脉搏动。通过心电图对准平均，可以高精度地测量体内多个位置的脉冲到达时间，并显示动脉脉冲通过股动脉和颈动脉的传播。此外，从胸部测量心脏动力学。心室收缩期的起止和偏移明显，心房收缩期的起止也明显。虽然还需要进一步的验证，但这些结果表明，超宽带芯片雷达非常适合监测血管健康和心脏的机械功能。

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2018 IEEE Biomedical Circuits and Systems Conference (BioCAS)

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