一种带有片上天线的1.6mm3无线供电可重构FDD无线电，可实现4.7 pJ/b TX和1 pJ/b RX能量效率，用于医疗植入物

2020 IEEE Custom Integrated Circuits Conference (CICC) Pub Date : 2020-03-01 DOI:10.1109/CICC48029.2020.9075935

Hamed Rahmani, A. Babakhani

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引用次数: 9

摘要

本文介绍了一种集成的无线供电无线电，具有两个片上天线，总体积为2.4×2.2×0.3 mm3，比最先进的无线供电收发器的占地面积×7小。该系统采用台积电180nm工艺制造，可在严格的医疗植入物功耗预算下运行。电源和下行链路数据通过aks调制的射频链路传输到系统，能量效率为1 pJ/b。该设计可以在各种功率预算下运行，并利用电源管理技术来调整有效数据速率和功耗。TX模块基于功率振荡器结构，并在负载处使用片上偶极子天线。可重构TX块可以通过OOK和UWB调制方案传输上行数据，支持150mbps的最大数据速率，在15cm距离内实现4.65 pJ/b的能效。在UWB模式下，TX块以高达40mbps的数据速率连续运行。

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A 1.6mm3 Wirelessly Powered Reconfigurable FDD Radio with On-Chip Antennas Achieving 4.7 pJ/b TX and 1 pJ/b RX Energy Efficiencies for Medical Implants

This paper presents an integrated wirelessly powered radio with two on-chip antennas and a total volume of 2.4×2.2×0.3 mm3 achieving ×7 smaller footprint than state-of-the-art wirelessly powered transceivers. The system is fabricated in TSMC 180nm process and is designed to operate under stringent power budgets of medical implants. Power and downlink data are carried to the system via an AKS-modulated RF link with an energy efficiency of 1 pJ/b. This design can operate under various power budgets and utilizes a power management technique to adjust the effective data rate and power consumption. TX block is based on a power oscillator structure and utilizes an on-chip dipole antenna at the load. Reconfigurable TX block can transmit uplink data with OOK and UWB modulation schemes and supports a maximum data rate of 150 Mbps achieving an energy efficiency of 4.65 pJ/b at a 15cm distance. In UWB modes, the TX block operates continuously for data rates of up to 40 Mbps.

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2020 IEEE Custom Integrated Circuits Conference (CICC)

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