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 0.15~ \text GaN-SiC Wafer Process Technology

This paper describes a novel low-noise input-termination-less cascode distributed amplifier (DA) monolithic microwave integrated circuit (MMIC) design. The design was implemented with a 0.15 μm gate gallium nitride on silicon carbide GaN-SiC high electron mobility transistor (HEMT) 6 inch wafer proc...

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Bibliographic Details
Published in:IEEE journal of solid-state circuits 2016-09, Vol.51 (9), p.2017-2026
Main Authors: Kobayashi, Kevin W., Denninghoff, Dan, Miller, Dain
Format: Article
Language:English
Subjects:
6 inch GaN-SiC
Active load
baseband
distributed amplifier
Gallium nitride
Impedance
Linearity
Logic gates
low noise
mm-wave
Noise measurement
power
Topology
Transistors
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Summary:This paper describes a novel low-noise input-termination-less cascode distributed amplifier (DA) monolithic microwave integrated circuit (MMIC) design. The design was implemented with a 0.15 μm gate gallium nitride on silicon carbide GaN-SiC high electron mobility transistor (HEMT) 6 inch wafer process technology. The GaN MMIC achieves a bandwidth from 100 MHz-45 GHz with greater than 10 dB gain and previously benchmarked the first published mm-wave MMIC results produced on a 6 inch GaN on SiC wafer process technology. The unique input-gate-termination-less DA topology reduces the low-frequency noise figure (NF) of the conventional resistive-terminated DA without compromising the third order intercept point (IP3) linearity. The new design achieves 1.6 dB NF at 250 MHz and a NF improvement of at least 1 dB and as much as 4 dB or greater for frequencies below 5 GHz compared to the conventional DA approach. The GaN MMIC also achieves an average mid-band NF of 2.5-3 dB, a saturated output power (Psat) of 1 Watt, and a mid-band output IP3 of 38 dBm. The new design architecture combined with the inherent device characteristics of GaN-SiC technology can provide performance benefits for next-generation coherent fiber optic, instrumentation and advanced broadband radio architecture applications.
ISSN:0018-9200
1558-173X
DOI:10.1109/JSSC.2016.2558488