A Reconfigurable Bidirectional Wireless Power and Full-Duplex Data Transceiver IC for Wearable Biomedical Applications.

IEEE transactions on biomedical circuits and systems Pub Date : 2024-10-21 DOI:10.1109/TBCAS.2024.3483950

Junhyuck Lee, Yemin Kim, Dongil Kang, Ickhyun Song, Byunghun Lee

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Abstract

This paper presents a reconfigurable bidirectional wireless power and data transceiver (RB-WPDT) integrated circuit (IC) for wearable biomedical applications. The proposed transceiver can be reconfigured as a differential class-D power amplifier or a full-wave rectifier depending on the mode signal to facilitate power transfer between devices. Additionally, the RBWPDT system supports full-duplex (FD) data transmission via a single inductive link, enabling real-time control and monitoring between devices. The proposed FD method utilizes frequency shift-keying pulse-width modulation (FSK-PWM) for downlink and load shift-keying (LSK) for uplink, achieving simultaneous bidirectional data transmission by ensuring that the FSK-PWM downlink and LSK uplink data channels operate independently with minimal interference. The measured downlink and uplink data rates are 250 kb/s and 67 kb/s, respectively. The measured overall DC-to-DC efficiency is 49%, while the power delivered to the load (PDL) is 120 mW at a 5 mm distance. The proposed chip is fabricated using a 180-nm BCD CMOS process.

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用于可穿戴生物医学应用的可重构双向无线电源和全双工数据收发器集成电路。

本文介绍了一种用于可穿戴生物医学应用的可重新配置双向无线功率和数据收发器（RB-WPDT）集成电路（IC）。所提出的收发器可根据模式信号重新配置为差分 D 类功率放大器或全波整流器，以促进设备之间的功率传输。此外，RBWPDT 系统还支持通过单一感应链路进行全双工（FD）数据传输，从而实现设备之间的实时控制和监测。所提出的全双工方法利用频移键控脉宽调制（FSK-PWM）进行下行链路调制，利用负载移位键控（LSK）进行上行链路调制，通过确保 FSK-PWM 下行链路和 LSK 上行链路数据通道独立运行且干扰最小，实现了同步双向数据传输。测得的下行和上行数据传输速率分别为 250 kb/s 和 67 kb/s。测得的整体直流对直流效率为 49%，而在 5 毫米距离内输送到负载（PDL）的功率为 120 毫瓦。该芯片采用 180 纳米 BCD CMOS 工艺制造。

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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IEEE transactions on biomedical circuits and systems

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