K.W. Kobayashi scite author profile

This letter reports on a 50-MHz-55-GHz multidecade bandwidth InP-based heterojunction bipolar transistor (HBT) MMIC distributed amplifier (DA) which achieves the widest bandwidth and highest frequency of operation so far demonstrated for a bipolar amplifier. The HBT MMIC DA was fabricated using a high-speed 1-m InAlAs/InGaAs-InP HBT base-undercut technology with peak fT 's and fmax's of 80 and 200 GHz, respectively, in order to obtain broad-band gain. Key to this work is the successful employment of HBT active load terminations used on both the input and output DA transmission lines in order to extend the low-frequency gain performance down to baseband. With only 82 mW of dc power consumption, the amplifier obtains measured gains of 7.6 dB at 50 MHz, 5.7 dB at 30 GHz, 5.8 dB at 50 GHz, and 3.1 dB at 55 GHz. Simulations of a monolithically integrated InGaAs p-i-n photodetector predicts a baseband 47-GHz photoreceiver response with an effective transimpedance of 38-dB. The baseband millimeter-wave capability of the InP-based HBT DA and its compatibility with InGaAs photodetectors makes this technology attractive for future generation (>40 Gb/s) high-datarate light-wave applications.

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Ultra-low dc power GaAs HBT S- and C-band low noise amplifiers for portable wireless applications

Kobayashi

Oki

Tran

et al. 1995

IEEE Trans. Microwave Theory Techn.

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A 44-GHz-high IP3 InP HBT MMIC amplifier for low DC power millimeter-wave receiver applications

Kobayashi

Cowles²,

Tran³

et al. 1999

IEEE J. Solid-State Circuits

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A Cascode Feedback Bias Technique for Linear CMOS Power Amplifiers in a Multistage Cascode Topology

Jeon

Lee

et al. 2013

IEEE Trans. Microwave Theory Techn.

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K.W. Kobayashi

A Novel 100 MHz–45 GHz Input-Termination-Less Distributed Amplifier Design With Low-Frequency Low-Noise and High Linearity Implemented With A 6 Inch <inline-formula> <tex-math notation="LaTeX">$0.15~ {\mu }\text{m}$ </tex-math> </inline-formula> GaN-SiC Wafer Process Technology

A 108-GHz InP-HBT monolithic push-push VCO with low phase noise and wide tuning bandwidth

A novel HBT distributed amplifier design topology based on attenuation compensation techniques

A 2 Watt, Sub-dB Noise Figure GaN MMIC LNA-PA Amplifier with Multi-octave Bandwidth from 0.2-8 GHz

A 50-MHz-55-GHz multidecade InP-based HBT distributed amplifier

Ultra-low dc power GaAs HBT S- and C-band low noise amplifiers for portable wireless applications

A 44-GHz-high IP3 InP HBT MMIC amplifier for low DC power millimeter-wave receiver applications

A Cascode Feedback Bias Technique for Linear CMOS Power Amplifiers in a Multistage Cascode Topology

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