%0 Journal Article %1 Umeda_MTT1996 %A Umeda, Y. %A Enoki, T. %A Osafune, K. %A Ito, H. %A Ishii, Y. %D 1996 %J IEEE Transactions on Microwave Theory and Techniques %K 12.05 4.49 GHz;0.1 ICs;low-noise MIMIC;millimetre amplifiers;Indium amplifiers;SCFL amplifiers;frequency analog-digital analogue-digital analysis arsenide;Frequency arsenide;III-V circuit circuits;field circuits;mixed compounds;Indium compounds;aluminium compounds;gallium computing;indium conversion;Low-noise dB;11.55 dB;InAlAs-InGaAs-InP;Indium design design;HEMT dividers;T-shaped dividers;circuit effect frequency gain;fabrication gallium gate;recess-etch integrated micron;4.11 noise;Circuit optimization;Circuit phosphide;HEMTs;Fabrication;Design resistance;circuit semiconductors;design semiconductors;high-yield simulation;60 stability static stopper;III-V technologies;HEMT to wave yield;integrated yield;load %N 12 %P 2361-2368 %R 10.1109/22.554560 %T High-yield design technologies for InAlAs/InGaAs/InP-HEMT analog-digital ICs %V 44 %X Sixty-GHz-band two-stage monolithic low-noise amplifiers and ultrahigh-speed SCFL static frequency dividers have been fabricated using the same InAlAs/InGaAs/InP HEMT process. This process assures uniformity by taking advantage of a 0.1-/spl mu/m T-shaped gate and an InP recess-etch stopper. Circuits are designed with priorities on stable operation, high yield, and uniformity. For the low-noise amplifier, the stabilization is optimized so as to minimize noise for the design gain while maintaining stability at all frequencies. The resultant amplifiers show a fabrication yield of 75% and at 62 GHz have a noise figure of 4.3/spl plusmn/0.19 dB and a gain of 11.8/spl plusmn/0.25 dB. For the frequency divider, the load resistance is set to be large enough to assure stable operation (circuit simulation shows that increasing the load resistance has little effect on the maximum toggle frequency). Frequency dividers designed with the optimum load resistance for stable and high-speed operation show a fabrication yield of 63% and have a maximum toggle frequency of 36.7/spl plusmn/0.55 GHz. These results demonstrate the feasibility of using this HEMT process to monolithically integrate analog and digital circuits on one chip.

@article{Umeda_MTT1996, abstract = {Sixty-GHz-band two-stage monolithic low-noise amplifiers and ultrahigh-speed SCFL static frequency dividers have been fabricated using the same InAlAs/InGaAs/InP HEMT process. This process assures uniformity by taking advantage of a 0.1-/spl mu/m T-shaped gate and an InP recess-etch stopper. Circuits are designed with priorities on stable operation, high yield, and uniformity. For the low-noise amplifier, the stabilization is optimized so as to minimize noise for the design gain while maintaining stability at all frequencies. The resultant amplifiers show a fabrication yield of 75% and at 62 GHz have a noise figure of 4.3/spl plusmn/0.19 dB and a gain of 11.8/spl plusmn/0.25 dB. For the frequency divider, the load resistance is set to be large enough to assure stable operation (circuit simulation shows that increasing the load resistance has little effect on the maximum toggle frequency). Frequency dividers designed with the optimum load resistance for stable and high-speed operation show a fabrication yield of 63% and have a maximum toggle frequency of 36.7/spl plusmn/0.55 GHz. These results demonstrate the feasibility of using this HEMT process to monolithically integrate analog and digital circuits on one chip.}, added-at = {2022-11-04T11:48:46.000+0100}, author = {{Umeda}, Y. and {Enoki}, T. and {Osafune}, K. and {Ito}, H. and {Ishii}, Y.}, bdsk-url-1 = {https://doi.org/10.1109/22.554560}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/201fa44b1b19015b74f56a95f06130c0e/ingmarkallfass}, date-added = {2020-11-22 12:18:38 +0100}, date-modified = {2020-11-22 12:18:53 +0100}, doi = {10.1109/22.554560}, interhash = {28c1f4a7bd81b489d62ea3a09047e53d}, intrahash = {01fa44b1b19015b74f56a95f06130c0e}, issn = {1557-9670}, journal = {IEEE Transactions on Microwave Theory and Techniques}, keywords = {12.05 4.49 GHz;0.1 ICs;low-noise MIMIC;millimetre amplifiers;Indium amplifiers;SCFL amplifiers;frequency analog-digital analogue-digital analysis arsenide;Frequency arsenide;III-V circuit circuits;field circuits;mixed compounds;Indium compounds;aluminium compounds;gallium computing;indium conversion;Low-noise dB;11.55 dB;InAlAs-InGaAs-InP;Indium design design;HEMT dividers;T-shaped dividers;circuit effect frequency gain;fabrication gallium gate;recess-etch integrated micron;4.11 noise;Circuit optimization;Circuit phosphide;HEMTs;Fabrication;Design resistance;circuit semiconductors;design semiconductors;high-yield simulation;60 stability static stopper;III-V technologies;HEMT to wave yield;integrated yield;load}, month = Dec, number = 12, pages = {2361-2368}, timestamp = {2022-11-04T10:48:46.000+0100}, title = {High-yield design technologies for InAlAs/InGaAs/InP-HEMT analog-digital ICs}, volume = 44, year = 1996 }