超低功耗射频能量收集整流电路的分析与设计方法

IF 2.4 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Ziyue Xu;Adam Khalifa;Ankit Mittal;Mehdi Nasrollahpourmotlaghzanjani;Ralph Etienne-Cummings;Nian Xiang Sun;Sydney S. Cash;Aatmesh Shrivastava
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引用次数: 5

摘要

本文回顾和分析了流行的射频能量采集系统的设计,并提出了一种使用新的方波近似方法对其电路结构进行定性和定量分析的方法。这种方法有助于简化设计分析。利用这种分析,我们可以建立整流器的空载输出电压特性、整流器效率上限和最大功率特性。本文将有助于指导射频识别(RFID)、物联网(IoT)、可穿戴和植入式医疗设备应用的射频能量采集整流电路的设计。在设计挑战的背景下解释了不同的应用场景,并讨论了相应的设计注意事项,以评估其性能。还研究了不同整流器拓扑结构的优缺点。除了介绍流行的整流器拓扑结构外,还介绍了用65nm、130nm和180nm CMOS技术制造的这些能量采集器拓扑结构的新测量结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Analysis and Design Methodology of RF Energy Harvesting Rectifier Circuit for Ultra-Low Power Applications
This paper reviews and analyses the design of popular radio frequency energy harvesting systems and proposes a method to qualitatively and quantitatively analyze their circuit architectures using new square-wave approximation method. This approach helps in simplifying design analysis. Using this analysis, we can establish no load output voltage characteristics, upper limit on rectifier efficiency, and maximum power characteristics of a rectifier. This paper will help guide the design of RF energy harvesting rectifier circuits for radio frequency identification (RFIDs), the Internet of Things (IoTs), wearable, and implantable medical device applications. Different application scenarios are explained in the context of design challenges, and corresponding design considerations are discussed in order to evaluate their performance. The pros and cons of different rectifier topologies are also investigated. In addition to presenting the popular rectifier topologies, new measurement results of these energy harvester topologies, fabricated in 65nm, 130nm and 180nm CMOS technologies are also presented.
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