CNFET-based voltage rectifier circuit for biomedical implantable applications

CNFET-based voltage rectifier circuit for biomedical implantable applications

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摘要 Carbon nanotube field effect transistor（CNFET） shows lower threshold voltage and smaller leakage current in comparison to its CMOS counterpart. In this paper, two kinds of CNFET-based rectifiers, full-wave rectifiers and voltage doubler rectifiers are presented for biomedical implantable applications. Based on the standard 32 nm CNFET model, the electrical performance of CNFET rectifiers is analyzed and compared. Simulation results show the voltage conversion efficiency（VCE） and power conversion efficiency（PCE） achieve 70.82% and 72.49% for CNFET full-wave rectifiers and 56.60% and 61.17% for CNFET voltage double rectifiers at typical 1.0 V input voltage excitation, which are higher than that of CMOS design. Moreover, considering the controllable property of CNFET threshold voltage, the effect of various design parameters on the electrical performance is investigated.It is observed that the VCE and PCE of CNFET rectifier increase with increasing CNT diameter and number of tubes. The proposed results would provide some guidelines for design and optimization of CNFET-based rectifier circuits. Carbon nanotube field effect transistor（CNFET） shows lower threshold voltage and smaller leakage current in comparison to its CMOS counterpart. In this paper, two kinds of CNFET-based rectifiers, full-wave rectifiers and voltage doubler rectifiers are presented for biomedical implantable applications. Based on the standard 32 nm CNFET model, the electrical performance of CNFET rectifiers is analyzed and compared. Simulation results show the voltage conversion efficiency（VCE） and power conversion efficiency（PCE） achieve 70.82% and 72.49% for CNFET full-wave rectifiers and 56.60% and 61.17% for CNFET voltage double rectifiers at typical 1.0 V input voltage excitation, which are higher than that of CMOS design. Moreover, considering the controllable property of CNFET threshold voltage, the effect of various design parameters on the electrical performance is investigated.It is observed that the VCE and PCE of CNFET rectifier increase with increasing CNT diameter and number of tubes. The proposed results would provide some guidelines for design and optimization of CNFET-based rectifier circuits.

作者 Yonggen Tu Libo Qian Yinshui Xia

机构地区 School of Information Science and Engineering

出处《Journal of Semiconductors》 EI CAS CSCD 2017年第2期89-95,共7页 半导体学报（英文版）

基金 Project supported by the National Natural Science Foundation of China(Nos.61131001,61404077,61571248) the Science and Technology Fund of Zhejiang Province(No.2015C31090) the Natural Science Foundation of Ningbo(No.2014A610147) State Key Laboratory of ASIC&System(No.2015KF006) the K.C.Wong Magna Fund in Ningbo University

关键词 CNFET technology rectifier power conversion efficiency biomedical implantable applications CNFET technology rectifier power conversion efficiency biomedical implantable applications

分类号 TN386 [电子电信—物理电子学]

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CNFET-based voltage rectifier circuit for biomedical implantable applications

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