Broadband 400-GHz InGaAs mHEMT Transmitter and Receiver S-MMICs

Broadband 400-GHz InGaAs mHEMT Transmitter and Receiver S-MMICs

The modeling, design, and experimental evaluation of both a 400-GHz transmitter and receiver submillimeter-wave monolithic integrated circuit (S-MMIC) is presented in this article. These S-MMICs are intended for a radar-based system in the aforementioned operating frequency. The transmitter occupies...

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Veröffentlicht in:IEEE transactions on terahertz science and technology 2021-11, Vol.11 (6), p.660-675
Hauptverfasser: Gashi, Bersant, John, Laurenz, Meier, Dominik, Rosch, Markus, Wagner, Sandrine, Tessmann, Axel, Leuther, Arnulf, Ambacher, Oliver, Quay, Rudiger
Format: Artikel
Sprache:eng
Schlagworte:
Broadband
Engineering
Engineering, Electrical & Electronic
Frequencies
Indium gallium arsenides
InGaAs
Integrated circuits
Logic gates
low-noise amplifier (LNA)
metamorphic HEMT
mHEMTs
Microstrip transmission lines
MMIC (circuits)
Modelling
multiplier-by-four
Optics
Physical Sciences
Physics
Physics, Applied
power amplifier (PA)
Power amplifiers
Radio frequency
Radio transmitters
receiver
Receivers
Science & Technology
Semiconductor devices
Solid modeling
subharmonic mixer
Submillimeter waves
Technology
Transistors
transmitter
Transmitters
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Zusammenfassung:The modeling, design, and experimental evaluation of both a 400-GHz transmitter and receiver submillimeter-wave monolithic integrated circuit (S-MMIC) is presented in this article. These S-MMICs are intended for a radar-based system in the aforementioned operating frequency. The transmitter occupies a total chip area of 750\times 2750\,{\mu {\rm m}^2}. It consists of a multiplier-by-four, generating the fourth-harmonic of the WR-10 input signal, which drives the integrated WR-2.2 power amplifier. The latter has an output-gate width of 128 \mum. The receiver S-MMIC, 750\times 2750\,{\mu {\rm m}^2}, consists of a multiplier-by-two, providing the second harmonic of the WR-10 input signal for the local-oscillator port of the subsequent integrated subharmonic mixer. The radio-frequency port of the latter, connects via a Lange coupler to a WR-2.2 low-noise amplifier (LNA). All the components included, are processed on a 35-nm {\text{InAlAs}}/{\text{InGaAs}} metamorphic high-electron-mobility transistor integrated-circuit technology, utilizing two-finger transistors and thin-film microstrip lines (TFMSLs). The modeling approach of the amplifier cores and the respective design decisions taken are listed and elaborated-on in this work. Accompanying measurements and simulations of the transmitter and receiver are presented. The individual components of the aforementioned S-MMICs, are characterized and the results are included in this article. The state-of-the-art, for S-MMIC based circuits operating in the WR-2.2 band, is set by the LNA, on one side, spanning an operational 3-dB bandwidth (BW) of 310 to 475 GHz, with a peak gain of 23 dB and, on the other side, by the final transmitter design, which covers an operating range of 335 to 425 GHz with a peak-output power of 9.0 dBm and accompanying transducer gain of 11 dB. The included transmitter- and receiver-designs represent a first-time implementation in the mentioned technological process, utilizing solely TFMSLs, boasting the integration level, operating in the WR-2.2 frequency band, and setting the state of the art-to the authors' best knowledge-for all S-MMIC based solutions in the respective frequency band, in terms of output powe
ISSN:2156-342X
2156-3446
DOI:10.1109/TTHZ.2021.3099064