Design of wide-IF-band CMOS mixer with LO multiplier

Tsai, Han-Ting; Tseng, Pei-Ling; Chang, Che‐Wei; Hu, Robert; Jou, Christina F.

doi:10.1109/apmc.2013.6695085

2013 Asia-Pacific Microwave Conference Proceedings (APMC) 2013

DOI: 10.1109/apmc.2013.6695085

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Design of wide-IF-band CMOS mixer with LO multiplier

Han-Ting Tsai

Pei-Ling Tseng

Che‐Wei Chang

et al.

Abstract: This paper reports the development of K-band wide-IF-band CMOS mixer with LO multiplier suitable for wideband applications. To achieve such broad bandwidth, several design techniques-such as current-reuse differentialpair with LC resonance circuit, and simultaneous in-band gain peaking and off-band gain tailoring-have been analyzed and employed. The on-wafer measurement of this 17.4-26.1GHz TSMC 0.18 m CMOS mixer with LO doubler shows a -1dB conversion gain, 11dB noise figure, -6dBm input-referred 1dB compress… Show more

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2021

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A 90 nm-CMOS broadband receiver with 10 dB conversion gain and 15 dB noise figure in 80–110 GHz suitable for multi-pixel imaging arrays

Chu-Chen

Hsieh

2021

Review of Scientific Instruments

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This paper describes the latest development of a W-band 90 nm-CMOS receiver chip that is suitable for use in radio-astronomical multi-pixel imaging arrays and other broadband scientific instruments. This circuit includes an RF-low-noise amplifier (LNA), mixer, intermediate-frequency amplifier (IF-Amp), local-oscillator (LO) tripler, and driving amplifier. With a tripler integrated into the circuit, the incoming 80–110 GHz spectrum can be directly down-converted to 2–32 GHz by the applied 26 GHz LO signal. The system architecture will be presented, with the corresponding sub-circuits discussed in detail. In the on-wafer measurement at room temperature, this receiver has around 10 dB gain and 15 dB noise figure across the whole frequency range, with 400 mW power dissipation under 1.8 V DC bias. By adding a compound-semiconductor LNA in front of this CMOS receiver chip, compact low-noise receiver modules can be easily constructed and deployed.

show abstract

A 90 nm-CMOS broadband receiver with 10 dB conversion gain and 15 dB noise figure in 80–110 GHz suitable for multi-pixel imaging arrays

Chu-Chen

Hsieh

2021

Review of Scientific Instruments

View full text Add to dashboard Cite

show abstract

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Design of wide-IF-band CMOS mixer with LO multiplier

Cited by 1 publication

References 3 publications

A 90 nm-CMOS broadband receiver with 10 dB conversion gain and 15 dB noise figure in 80–110 GHz suitable for multi-pixel imaging arrays

A 90 nm-CMOS broadband receiver with 10 dB conversion gain and 15 dB noise figure in 80–110 GHz suitable for multi-pixel imaging arrays

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