A 3.9mW 25-electrode reconfigured thoracic impedance/ECG SoC with body-channel transponder

Long Yan, Joonsung Bae, Seulki Lee, Binhee Kim, Taehwan Roh, Kiseok Song, H. Yoo
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引用次数: 25

Abstract

Recently, wearable heart monitoring systems have been developed for cardiovascular-related disease [1] with wearable body sensor network (WBSN) [2–3]. The WBSN introduced in [3] monitored ECG at maximum 48 points, and transferred data using arrayed inductive link for cm-range wireless inter-connectivity. However, most of the previous attempts were limited to sense only ECG signals at limited points [2] on the body with limited network coverage [3]. Thoracic impedance variance (TIV) from the change of aortic blood volume and velocity at each cardiac cycle provides important hemodynamic information (stroke volume, cardiac output). Combined with ECG signals from more than 6 points, it enables the early detection of abnormal symptoms of pandemic diseases like hypertension and heart failure so that the patients can take prophylactic measures [6]. In spite of its importance, the TIV detection was not realized in WBSN due to its requirement of high impedance (≪0.2Ω) detection sensitivity which needs to detect AM signal with modulation depth as low as less than 3%. A pure single tone sinusoidal current signal at 1kHz–100kHz [6] is required to realize such a high sensitivity, and only a bulky implementation was reported so far [7]. In this paper, we report a 3.9mW low power SoC with body-channel-transceiver (BCT), which can detect TIV (0.1Ω) and ECG (up to 8 points) concurrently. The chip is integrated on a 4-layer fabric circuit board with thin flexible battery as a poultice-like plaster. In addition, it can reconfigure the 25-electrode array and optimize them in-situ to automatically consider the user dependency of the TIV/ECG signals. The recorded data is transmitted at 1Mbps through body-channel-communication (BCC) [8] with duty cycle modification to extend battery life time and enlarge the network coverage.
3.9mW 25电极重新配置胸廓阻抗/ECG SoC与身体通道应答器
近年来,基于可穿戴身体传感器网络(WBSN)的可穿戴式心脏监测系统被开发用于心血管相关疾病[1][2-3]。[3]中引入的WBSN最多监测48个心电点,并使用阵列感应链路传输数据,实现厘米范围的无线互联。然而,之前的大多数尝试仅限于在有限的网络覆盖范围[3]下,仅在身体上有限的点[2]感知心电信号。每个心动周期主动脉血容量和速度变化的胸阻抗方差(TIV)提供了重要的血流动力学信息(搏量、心输出量)。结合6点以上的心电信号,可早期发现高血压、心力衰竭等大流行疾病的异常症状,及时采取预防措施[6]。尽管TIV探测很重要,但由于其要求高阻抗(0.2Ω)探测灵敏度,需要探测调制深度低于3%的调幅信号,因此未能在WBSN中实现TIV探测。要实现如此高的灵敏度,需要1kHz-100kHz的纯单音正弦电流信号[6],到目前为止只报道了一个庞大的实现[7]。在本文中,我们报告了一种3.9mW低功耗SoC,具有体通道收发器(BCT),可以同时检测TIV (0.1Ω)和ECG(最多8个点)。该芯片集成在一个4层织物电路板上,薄的柔性电池就像膏药一样。此外,它还可以重新配置25个电极阵列并对其进行原位优化,以自动考虑用户对TIV/ECG信号的依赖性。记录的数据通过体通道通信(BCC)以1Mbps的速度传输[8],并修改占空比以延长电池寿命,扩大网络覆盖范围。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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