Performanceanalysisofalowpowerlownoisetunablebandpassfilterformultiband RF front end

Performanceanalysisofalowpowerlownoisetunablebandpassfilterformultiband RF front end

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摘要 This paper presents a low power tunable active inductor and RF band pass filter suitable for multiband RF front end circuits. The active inductor circuit uses the PMOS cascode structure as the negative transconductor of a gyrator to reduce the noise voltage. Also, this structure provides possible negative resistance to reduce the inductor loss with wide inductive bandwidth and high resonance frequency. The RF band pass filter is realized using the proposed active inductor with suitable input and output buffer stages. The tuning of the center frequency for multiband operation is achieved through the controllable current source. The designed active inductor and RF band pass filter are simulated in 180 nm and 45 nm CMOS process using the Synopsys HSPICE simulation tool and their performances are compared. The parameters, such as resonance frequency, tuning capability, noise and power dissipation, are analyzed for these CMOS technologies and discussed. The design of a third order band pass filter using an active inductor is also presented. This paper presents a low power tunable active inductor and RF band pass filter suitable for multiband RF front end circuits. The active inductor circuit uses the PMOS cascode structure as the negative transconductor of a gyrator to reduce the noise voltage. Also, this structure provides possible negative resistance to reduce the inductor loss with wide inductive bandwidth and high resonance frequency. The RF band pass filter is realized using the proposed active inductor with suitable input and output buffer stages. The tuning of the center frequency for multiband operation is achieved through the controllable current source. The designed active inductor and RF band pass filter are simulated in 180 nm and 45 nm CMOS process using the Synopsys HSPICE simulation tool and their performances are compared. The parameters, such as resonance frequency, tuning capability, noise and power dissipation, are analyzed for these CMOS technologies and discussed. The design of a third order band pass filter using an active inductor is also presented.

作者 J.Manjula S.Malarvizhi

机构地区 Department of ECE

出处《Journal of Semiconductors》 EI CAS CSCD 2014年第3期102-108,共7页 半导体学报（英文版）

关键词 active inductor RF band pass filter quality factor center frequency tuning multi band RF front end 0.18 υm and 45 nm CMOS technology active inductor RF band pass filter quality factor center frequency tuning multi band RF front end 0.18 υm and 45 nm CMOS technology

分类号 TN713 [电子电信—电路与系统]

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Journal of Semiconductors

2014年第3期

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Performanceanalysisofalowpowerlownoisetunablebandpassfilterformultiband RF front end

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