GaAs FETs – physics, design, and models

Rob Davis

doi:10.1017/CBO9781139015349.004

2 - GaAs FETs – physics, design, and models

Published online by Cambridge University Press: 05 November 2011

Rob Davis

Edited by

John L. B. Walker

Show author details

Rob Davis: Affiliation:
RFMD

Book contents

Get access

Summary

Introduction

The manufacture of Gallium Arsenide FET devices and integrated circuits is now a mature industry. The GaAs FET was first developed in the 1960s and 1970s [1], with the impetus to establish a manufacturing capability coming in the 1980s driven by governmental support – most notably the comprehensive “MIMIC” programme in the United States. In the intervening time the GaAs FET became the default solid-state device for all manner of RF and microwave applications. However, the position of the GaAs FET in this arena has not gone unchallenged. It was soon joined by the GaAs HBT which has dominated the cellular handset power amplifier market. The upper frequency limit of silicon LDMOS technology has steadily increased over recent years as its highly mature technology was further refined with the result that this technology currently dominates high-power RF applications below 3 GHz. More recently, gallium nitride devices join the fray. The GaN FET is a device technology of great promise that is steadily being made available by more vendors as its reliability is established. Initially, gallium nitride is also targeting the lower frequency bands but is capable of being developed for applications across the whole microwave bandwidth. For the higher millimetre-wave frequencies indium phosphide technology has a place. However, GaAs FET technology is proven, competent, mature, and remains a good choice for many applications including high-frequency power and high linearity. GaAs technology also has significant cost advantages over its nonsilicon competitors. The economies of scale that the cellular communications market has brought to GaAs technology has revolutionized the manufacture of GaAs products and has given rise to dramatic reductions in cost. It is in the area of continued cost reduction that the most significant new developments in GaAs device and associated technologies are focused.

This chapter aims to introduce contemporary GaAs-based power FET technology. It is written with the perspective of the user of the technology in mind. The material properties and the pertinent device physics are reviewed and relevant concepts are recapped briefly as necessary. The device design issues are described followed by a section on fabrication with particular focus on low-cost manufacture. The chapter concludes with a discussion of device models for circuit design.

Type: Chapter
Information: Handbook of RF and Microwave Power Amplifiers , pp. 42 - 102

DOI: https://doi.org/10.1017/CBO9781139015349.004 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2011

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Aoki, Y.Hirano, Y.High-power GaAs FETsHigh-power GaAs FET AmplifiersWalker, J. L. B.Artech House 1993 43Google Scholar

Ioffe Physico-Technical Institutehttp://www.ioffe.ru/SVA/NSM/Semicond/

Sze, S. M.Physics of Semiconductor DevicesWiley, 1981Google Scholar

Dobaczewski, L.Peaker, A. R.Langer, J. M.DX defect centres in AlGaAsProperties of Aluminum Gallium ArsenideAdachi, S.IET/INSPEC 1993 278Google Scholar

Matthews, J.W.Blakeslee, A.E.Defects in epitaxial multilayersJ. Crystal Growth 27 118 1974Google Scholar

DiLorenzo, J.V.Wisseman, W.R.GaAs power MESFETs: design, fabrication and performanceIEEE Trans. Microw. Theory Tech. 27 367 1979CrossRef Google Scholar

Johnson, E.O.Physical limitations on frequency and power parameters of transistorsIRE Int. Conv. Rec. 13 27 1965CrossRef Google Scholar

Sauiner, P.Kopp, W. S.Tserng, H. Q.Kao, Y. C.Heston, D. D.635 1992

Cooper, S.Anderson, K.Salman, K.Culbertson, R.Mason, J.Bryant, D.Saunier, P. 1992 183

Takenaka, I.Ishikura, K.Takahashi, H.Asano, K.Morikawa, J.Satou, K.Kishi, K.Hasegawa, K.Tokunaga, K.Emori, F.Kuzuhara, M.L/S-band 140-W push–pull power AlGaAs/GaAs HFET's for digital cellular base stationsIEEE J. Solid-State Circuits 34 1181 1999CrossRef Google Scholar

Yang, M.Chan, Y.Device linearity comparisons between doped-channel and modulation-doped designs in pseudomorphic AlGaAs/InGaAs heterostructuresIEEE Trans. Electron Devices 43 1174 1996CrossRef Google Scholar

Morikawa, J.Asano, K.Ishikura, K.Oikawa, H.Kanamori, M.Kuzuhara, M.1413 1997

Lin, Y. C.Yi Chang, EdwardYamaguchi, H.Hirayama, Y.Chang, X. Y.Chang, C. Y.Device linearity comparison of uniformly doped and δ-doped In0.52Al0.48As/In0.6Ga0.4As metamorphic HEMTsIEEE Electron Device Lett. 27 535 2006CrossRef Google Scholar

Geiger, D.Mittermeier, E.Dickmann, J.Geng, C.Winterhof, R.Scholz, F.Kohn, E.InGaP/InGaAs HFET with high current density and high cut-off frequenciesIEEE Electron Device Letters 16 1995CrossRef Google Scholar

Drummond, T. J.Masselink, W. T.Morkoc, H.Modulation-doped GaAs/(Al,Ga)As heterojunction field-effect transistors: MODFETsProc. IEEE 74 773 1986CrossRef Google Scholar

Nguyen, L. D.Larson, L. E.Mishra, U. K.Ultra-high-speed modulation-doped field-effect transistors: a tutorial reviewProc. IEEE 80 494 1992CrossRef Google Scholar

DiLorenzo, J.V.Laterwasser, B. D.Zaitlin, M. 1994 1

Moll, N.Hueschen, M. R.Fischer-Colbrie, A.Pulse-doped AlGaAs/InGaAs pseudomorphic MODFETsIEEE Trans. Electron Devices 35 879 1988CrossRef Google Scholar

Snider, G.http://www.nd.edu/∼gsnider

Ladbrooke, P. H.MMIC Design: GaAs FETs and HEMTsArtech House 1989Google Scholar

Ladbrooke, P. H.Bridge, J. P.Goodship, N. J.Battison, D. J. 2000

Dunleavy, L.Clausen, W.Weller, T.Pulsed for nonlinear modelingMicrow. J. 46 68 2003Google Scholar

Rocchi, M.Status of the surface and bulk parasitic effects limiting the performances of GaAs IC'sPhysica B. 129 119 1985CrossRef Google Scholar

Lo, S.Lee, C.Analysis of surface state effect on gate lag phenomena in GaAs MESFET'sIEEE Trans. Electron Devices 41 1504 1994Google Scholar

Ladbrooke, P. H.Blight, S. R.Low-field low-frequency dispersion of transconductance in GaAs MESFET's with implications for other rate-dependent anomaliesIEEE Trans. Electron Devices 35 1988CrossRef Google Scholar

Canali, C.Magistrali, F.Paccagnella, A.Sangalli, M.Tedesco, C.Zanoni, E.Trap-related effects in AlGaAslGaAs HEMTsIEE Proc., Part G 38 104 1991Google Scholar

Binari, S. C.Klein, P. B.Kazior, T. E.Trapping effects in GaN and SiC microwave FETsProc. IEEE 90 1048 2002CrossRef Google Scholar

Hasumi, Y.Matsunaga, N.Oshima, T.Kodera, H.Characterization of the frequency dispersion of transconductance and drain conductance of GaAs MESFET, IEEE TransElectron Devices 50 2032 2003CrossRef Google Scholar

Izumi, T.Ohshima, T.Tsunotani, M.Kimura, T. 2002

Basile, A.F.Mazzanti, A.Manzini, E.Verzellesi, G.Canali, C.Pierobon, R.Lanzieri, C. 2002 63

Verzellesi, G.Mazzanti, A.Basile, A. F.Boni, A.Zanoni, E.Canali, C.Experimental and numerical assessment of gate-lag phenomena in AlGaAs–GaAs heterostructure field-effect transistors (FETs)IEEE Trans. Electron Devices 50 1733 2003CrossRef Google Scholar

Pajona, O.Aupetit-Berthelemot, C.Dumas, J. M. 2003 151

Wang, F.Jemison, W. D.Hwang, J. C. M.815 2001

Haruyama, J.Negishi, H.Nishimura, Y.Nashimoto, Y.Substrate-related kink effects with a strong light-sensitivity in AlGaAs/InGaAs PHEMT,IEEE Trans. Electron Devices 44 1997CrossRef Google Scholar

Kuang, J. B.Tasker, P. J.Wang, G. W.Chen, Y. K.Eastman, L. F.Aina, O. A.Hier, H.Fathimulla, A.Kink effect in submicrometer-gate MBE-Grown InAlAs/InGaAs/InAlAs heterojunction MESFET'sIEEE Electron Device Lett. 9 630 1988CrossRef Google Scholar

Ladbrooke, P. H.Bridge, J. P.Benign mechanism giving rise to kinks in GaAs MESFET and HEMT I(V) characteristicsElectron. Lett. 31 1947 1995CrossRef Google Scholar

Chen, J.-W.Thurairaj, M.Das, M. B.Optimization of gate-to-drain separation in submicron gate-length modulation doped FET's for maximum power gain performanceIEEE Trans. Electron Devices 41 465 1994CrossRef Google Scholar

Suemitsu, T.Enoki, T.Sano, N.Tomizawa, M.Ishii, Y.An analysis of the kink phenomena in InAlAs/InGaAs HEMT's using two-dimensional device simulationIEEE Trans. Electron Devices 45 2390 1998CrossRef Google Scholar

Somerville, M. H.Ernst, A.del Alamo, J. A.A physical model for the kink effect in InAlAs/InGaAs HEMT'sIEEE Trans. Electron Devices 47 922 2000CrossRef Google Scholar

Mazzanti, A.Verzellesi, G.Canali, C.Meneghesso, G.Zanoni, E.Physics-based explanation of kink dynamics in AlGaAs/GaAs HFETsIEEE Electron Device Letters 23 383 2002CrossRef Google Scholar

Somerville, M. H.del Alamo, J. A.Saunier, P.Off-state breakdown in power pHEMT's: the impact of the sourceIEEE Trans. Electron Devices 45 1883 1998CrossRef Google Scholar

Li, H. P.Hartin, O. L.Ray, M.An updated temperature-dependent breakdown coupling model including both impact ionization and tunneling mechanisms for AlGaAs/InGaAs HEMTsIEEE Trans. Electron Devices 49 1675 2002CrossRef Google Scholar

Menozzi, R.Off-state breakdown of GaAs PHEMTs: review and new dataIEEE Trans. Device and Materials Rel. 4 54 2004CrossRef Google Scholar

Trew, R. J.Mishra, U. K.Gate breakdown in MESFET's and HEMT'sIEEE Electron Device Lett. 12 524 1991CrossRef Google Scholar

Bahl, S. R.del Alamo, J. A.Physics of breakdown in InAlAs/n+-InGaAs heterostructure field-effect transistorsIEEE Trans. Electron Devices 41 2268 1994CrossRef Google Scholar

del Alamo, J. A.Somerville, M. H.Breakdown in millimeter-wave power InP HEMTs: a comparison with GaAs PHEMT'sIEEE J. Solid-State Circuits 34 1999CrossRef Google Scholar

Somerville, M. H.Blanchard, R.del Alamo, J. A.Duh, K. G.Chao, P. C.On-state breakdown in power HEMT's: measurements and modelingIEEE Trans. Electron Devices 46 1999CrossRef Google Scholar

van der Zanden, K.Schreurs, D. M. M.-P.Menozzi, R.Borgarino, M.Reliability testing of InP HEMT's using electrical stress methodsIEEE Trans. Electron Devices 46 1570 1999CrossRef Google Scholar

Di Carlo, A.Rossi, L.Lugli, P.Zandler, G.Meneghesso, G.Jackson, M.Zanoni, E.Monte Carlo study of the dynamic breakdown effects in HEMT'sIEEE Electron Device Letters 21 2000CrossRef Google Scholar

Sleiman, A.Di Carlo, A.Lugli, P.Meneghesso, G.Zanoni, E.Thobel, J. L.Channel thickness dependence of breakdown dynamic in InP-based lattice-matched HEMTsIEEE Trans. Electron Devices 50 2009 2003CrossRef Google Scholar

Bock, K.Russ, C.Badenes, G.Groeseneken, G.Influence of well profile and gate length on the ESD performance of a fully silicided 0.25 µm CMOS technologyIEEE Trans. Components, Packaging and Manufacturing Technol., Part C 24 286 1998CrossRef Google Scholar

Verhaege, K. G.Mergensb, M.Russb, C.Armerb, J.Jozwiak, P.Novel design of driver and ESD transistors with significantly reduced silicon areaMicroelectronics Rel. 42 3 2002CrossRef Google Scholar

Menozzi, RCova, P.Canali, C.Fantini, F.Breakdown walkout in pseudomorphic HEMTsIEEE Trans. Electron Devices 43 543 1996CrossRef Google Scholar

Verspecht, J.Schreurs, D. 1998

David, J. P. R.Sitch, J. E.Stern, M. S.Gate–drain avalanche breakdown in GaAs power MESFET'sIEEE Trans. Electron Devices 29 1548 1982CrossRef Google Scholar

Shirokov, M. S.Leoni, R. E.Wei, C. J.Hwang, J. C. M. 1996 34

Ladbrooke, P. H.Carroll, J. E.Dielectric relaxation as a limit on transistor switching speedElectron. Lett. 32 1511 1996CrossRef Google Scholar

Vendelin, G. D.Design of Amplifiers and Oscillators by the S-parameter MethodWiley-Blackwell 1982Google Scholar

Mason, S. J.Power gain in feedback amplifier,” IRE Professional Group on Circuit Theory 1 20 1954CrossRef Google Scholar

Vendelin, G. D.Shin, S.-C.Applying max, t, and for microwave transistor designs at microwave and millimeter-wave frequenciesIEEE Microw. Mag.84 2007Google Scholar

Long, S. I.A comparison of the GaAs MESFET and the AlGaAs/GaAs heterojunction bipolar transistor for power microwave amplificationIEEE Trans. Electron Devices 37 1274 1989CrossRef Google Scholar

Macksey, H. M.GaAs power FET designDiLorenzo, J. V.Khandelwal, D. D.GaAs FET Principles and TechnologyArtech House 1982 257Google Scholar

Grave, T. 1994

Macksey, H.M.Optimisation of the + ledge channel structure for GaAs power FETs,IEEE Trans. Electron Devices 33 1818 1986CrossRef Google Scholar

Boos, J. B.Kruppa, W.InAlAs/lnGaAs/lnP HEMTs with high breakdown voltages using double-recess gate processElectron. Lett. 27 1909 1991CrossRef Google Scholar

Huang, J. C.Jackson, G. S.Shanfield, S.Platzker, A.Saledas, P. K.Weichert, C.An AlGaAs/InGaAs pseudomorphic high electron mobility transistor with improved breakdown voltage for X and Ku-band power applicationsIEEE Trans. Microw. Theory Tech 41 752 1993CrossRef Google Scholar

Kohno, Y.Matsubayashi, H.Komaru, M.Takano, H.Ishihara, O.Mitsui, S.263 1994

Marsetz, W.Hiilsmann, A.Kleindienst, T.Fischer, S.Demmler, M.Bronner, W.Fink, T.Kohler, K.Schlechtweg, M.0.20.80.250.75 1997 1030

Chen, C.-HSkogen, J.Improvement of GaAs MESFET performance using surface P-layer doping (SPD) techniqueIEEE Electron Device Lett. 10 352 1989CrossRef Google Scholar

Hirose, M.Matsuzawa, K.Mihara, M.Nitta, T.Kameyama, A.Uchitomi, N.A lightly doped deep drain GaAs MESFET structure for linear amplifiers of personal handy-phone systemsIEEE Trans. Electron Devices 43 2062 1996CrossRef Google Scholar

Hori, YasukoKuzuhara, MasaakiAndo, YujiMizuta, MasashiAnalysis of electric field distribution in GaAs metal-semiconductor field effect transistor with a field modulating plateJ. Appl. Physics 87 2000CrossRef Google Scholar

Matsunaga, K.Ishikura, K.Takenaka, I.Contrata, W.Wakejima, A.Ota, K. 2000 393

Sakura, N.Matsunaga, K.Ishikura, K.Takenaka, I.Asano, K.Jwata, N.Kanamori, M.Kuzuhara, M.1715 2000

Wakejima, A.Ota, K.Matsunaga, K.Contrata, W.Kuzuhara, M.151 2001

Inoue, K.Nagahara, M.Ui, N.Haematsu, H.Sano, S.Fukaya, J.821 2004

Miller, M. 2005 236

Chiu, H.-C.Chiang, Y.-C.Wu, C.-S.High breakdown voltage AlGaInP/InGaAs quasi-enhancement-mode pHEMT with field-plate technologyIEEE Electron Device Lett. 26 2005Google Scholar

Kuvas, R. L.Equivalent circuit model of FET including distributed gate effectsIEEE Trans. Electron Devices 27 1193 1980CrossRef Google Scholar

Higashisaka, A.Takayama, YA high-power GaAs MESFET with experimentally optimized patternIEEE Trans. Electron Devices 27 1980CrossRef Google Scholar

Mondal, J. P.Distributed scaling approach of MESFETs and its comparison with lumped-element approachIEEE Trans. Microw. Theory Tech 37 1085 1989CrossRef Google Scholar

Teeter, D.Bouthillette, S.Aucoin, L.Platzker, AAlfaro, C.Bradford, D.High power, high efficiency PHEMTs for use at 8 GHzIEEE MTT-S Int. Symp. Dig323 1995Google Scholar

Hasegawa, F.Power GaAs FETsDiLorenzo, J. V.Khandelwal, D. D.GaAs FET Principles and TechnologyArtech House 1982 219Google Scholar

Walker, J. L. B.Combining techniquesWalker, J. L. B.High-Power GaAs FET AmplifiersArtech House 1993 263Google Scholar

Bahl, I. J. 1994 71

Derewonko, H.Laviron, M.Lepage, J.X- and Ku-band internally matched packaged GaAs F.E.TElectron. Lett. 15 1979CrossRef Google Scholar

Honjo, K.Takayama, Y.Higashisaka, A.Broad-band internal matching of microwave power GaAs MESFET’SIEEE Trans. Microw. Theory Tech. 27 1979CrossRef Google Scholar

Shichang, Z.Tangsheng, C.Gang, L.Fuxiao, L. 2006

Mori, K.Nishihara, J.Utsumi, H.Inoue, A.Miyazaki, M.315 2008

Fu, S. T.Komiak, J. J.Lester, L. F.Duh, K. H. G.Smith, P. M.Chao, P. C.Yu, T. H. 1993 355

Takenaka, I.Takahashi, H.Asano, K.Morikawa, J.Ishikura, K.Kanamori, M.Kuzuhara, M.Tsutsui, H.i1417 1997

Wakejima, A.Asano, T.Hirano, T.Funabashi, M.Matsunaga, K.C-band GaAs FET power amplifiers with 70-W output power and 50% PAE for satellite communication useIEEE J. Solid-State Circuits 40 2005CrossRef Google Scholar

Canali, C.Castaldo, F.Fantini, F.Ogliari, D.Umena, L.Zanoni, E.Gate metallization ‘sinking’ into the active channel in TilWlAu metallized power MESFET'sIEEE Electron Device Lett. 7 185 1986CrossRef Google Scholar

Kole, T. M. 2000 79

Webb, P. W.Thermal imaging of electronic devices with low surface emissivityIEE Proc., Part G 138 390 1991Google Scholar

Minot, Mark N.495 1986

Fukui, H. 1980 118

Webb, P. W.Measurement of thermal resistance using electrical methodsIEE Proc., Part I, 134 51 1987Google Scholar

Technologies, Agilent5966

Angelov, I.Kärnfelt, C.351 2007

Sarua, A.Ji, H.Kuball, M.Uren, M. J.Martin, T.Hilton, K. P.Balmer, R. S.Integrated micro-Raman/Infrared thermography probe for monitoring of self-heating in AlGaN/GaN transistor structuresIEEE Trans. Electron Devices 53 2438 1986CrossRef Google Scholar

Mittereder, J. A.Roussos, J. A.Anderson, W. T.Ioannou, D. E.Quantitative measurement of channel temperature of GaAs devices for reliable life-time predictionIEEE Trans. Rel. 51 482 2002CrossRef Google Scholar

Webb, P. W.Russell, I. A. D.Thermal resistance of gallium-arsenide field-effect transistorsIEE Proc. Part G 136 229 1989Google Scholar

Webb, P. W.Thermal modeling of power microwave integrated circuitsIEEE Trans. Electron Devices 40 867 1993CrossRef Google Scholar

Wilson, J.Decker, K. 1994 121

Batty, W. 2006 316

Cooke, H. F.Precise technique finds FET thermal resistanceMicrowave85 1986Google Scholar

Kokkas, A. G.Thermal analysis of multiple-layer structuresIEEE Trans. Electron Devices 21 674 1974CrossRef Google Scholar

Marsetz, W.Dammann, M.Kawashima, H.Rtidiger, J.Matthes, B.Hiilsmann, A.Schlechtweg, M. 1998 439

Williams, R.Modern GaAs Processing MethodsArtech House 1990Google Scholar

Chang, C. Y.Kai, F.GaAs High-speed Devices: Physics, Technology and CircuitWiley 1994Google Scholar

Schmukler, B. C.Brunemeier, P. E.Hitchens, W. R.Cantos, B. D.Strifler, W. A.Rosenblatt, D. H.Remba, R. D. 1993 325

Alavi, K.Ogut, S.Lyman, P.Hoke, W.Borkowski, M. 2002

Hanson, A. W.Danzilio, D.Bacher, K.Leung, L. 1998 195

Hays, D. C.Abernathy, C. R.Pearton, S. J.Ren, F.Hobson, W. S.Wet and dry etch selectivity for the GaAs/AlGaAs and GaAs/InGaP systemsElectrochemical Soc. Proc. 98 202 1998Google Scholar

Spooner, F.Quinn, W.Hanes, L.Woolsey, S.Smith, K.Mason, J. 2004

Chang, E. Y.Van Hove, J. M.Pande, K. P.A selective dry-etch technique for GaAs MESFET gate recessingIEEE Trans. Electron Devices 35 1580 1988CrossRef Google Scholar

Ren, F.Pearton, S. J.Abernathy, C. R.Wu, C. S.Hu, M.Pao, K.Wang, D. C.Wen, C. P.0.25-pm Pseudomorphic HEMT's processed with damage-free dry-etch gate-recess technologyIEEE Trans. Electron Devices 39 2701 1992CrossRef Google Scholar

Geissberger, A. E.Bahl, I. J.Griffin, E. L.Sadler, R. A.A new refractory self-aligned gate technology for gaas microwave power FET's and MMIC'sIEEE Trans. Electron Devices 35 615 1988CrossRef Google Scholar

Yanagihara, M.Ota, Y.Nishii, K.Ishikawa, O.Tamura, A.Highly efficient GaAs power MESFETs with + asymmetrical LDD structureElectronics Lett. 28 686 1992CrossRef Google Scholar

Ping, A. T.Liebl, W.Mahoney, G.Mahon, S.Berger, O. 2005

Hwu, M.-J.Chiu, H.-C.Yang, S.-C.Chan, Y.-J.A novel double-recessed 0.2 µm T-gate process for heterostructure InGaP-InGaAs doped channel FET fabricationIEEE Electron Device Letters 24 381 2003Google Scholar

Metze, G. M.Bass, J. F.Lee, T. T.Porter, D.Carlson, H. E.Laux, P. E.A dielectric-defined process for the formation of T-gate field-effect transistorsIEEE Microw. Guided Wave Lett. 1 198 1991CrossRef Google Scholar

Muller, J.-E.Grave, T.Siweris, H. J.Kärner, M.Schafer, A.Tischer, H.Riechert, H.Schleicher, L.Verweyen, L.Bangert, A.Kellner, W.Meier, T.A GaAs HEMT MMIC chip set for automotive radar systems fabricated by optical stepper lithographyIEEE J. Solid-State Circuits 32 1997CrossRef Google Scholar

Jones, S. K.Bazley, D. J.Brambley, D. R.Claxton, P. A.Cleverley, I. R.Davies, I.Davies, R. A.Hill, C.Phillips, W. A.Shorrocks, N. M.Stott, M.Vanner, K.Wallis, R. H.Warner, D. J. 2001

Chang, E. Y.Cibuzar, G. T.Pande, K. P.Passivation of GaAs FET's with PECVD silicon nitride films of different stress statesIEEE Trans. Electron Devices 35 1412 1988CrossRef Google Scholar

Mackenzie, K. D.Reelfs, B.DeVre, M. W.Westerman, R.lJohnson, D. J. 2004

Clausen, M.C.McMonagle, J. 2005

Fanning, D.Witkowski, L.Stidham, J.Tserng, H.Q.Muir, M.Saunier, P. 2002

O’Keefe, M. F.Atherton, J. S.Bösch, W.Burgess, P.Cameron, N. I.Snowden, C. M.GaAs pHEMT-based technology for microwave applications in a volume MMIC production environment on 150-mm WafersIEEE Trans Semicond. Manuf. 16 376 2003CrossRef Google Scholar

Yuan, C.-G.Hsieh, Y. Y.Yeh, T. J.Chen, C.-H.Tu, D. W.Wang, Y.-C.Murad, J. L. S. 2005

O’Keefe, M. F.Mayock, J. G.E.Brookbanks, D. M.McMonagle, J.Atherton, J. S. 2005

Lodhi, T.McMonagle, J.Davis, R. G.Brookbanks, D. M.Combe, S.Clausen, M.O’Keefe, M. F.Collar, A.Atherton, J. S. 2006 125

J Liu, S. M.Cheng-Guan, Y.Wu, T. D.-W. R.Huang, J.Shih-Wei, Y.Lai, W.Yu, P. 2008 1

Yuan, C.-G.Liu, S. M.Tu, D.-W.Wu, R.Huang, J.Chen, F.Wang, Y-C. 2009

Fujii, K.Stanback, J.Morkner, H. 2009 503

Steel, V. 1996 18

Ho, T.Santos, F.Uscola, R.Szymanowski, M.Marshall, S. 2009 1269

2008

Chiriac, V. A.Lee, T. T.Hause, V.Thermal performance optimisation of radio frequency packages for wireless communicationJ. Electron. Packaging 126 2004CrossRef Google Scholar

Krishnamoorthi, S.Goh, K. Y.Chong, Y. R.Kapoor, R.Sun, Y. S. 2003 485

Aihara, K.Chen, A. C.Pham, A. V.Roman, J. W. 2005 167

Wormald, R.David, S.Panaghiston, G.Jeffries, R. 2006

Aihara, K.Chen, M. J.Pham, A.-V.Development of thin-film liquid-crystal-polymer surface-mount packages for Ka-band applicationsIEEE Trans. Microw. Theory Tech. 56 2111 2008CrossRef Google Scholar

Suh, Y.-H.Richardson, D.Dadello, A.Mahon, S.Harvey, J. T. 2005 545

Ersland, P.Jen, H.-R.Yang, X. 2003 3

Roesch, W. J. 2005 111

Extance, A.25 2009

Dambrine, G.Cappy, A.Heliodore, F.Playez, E.A new method for determining the FET small-signal equivalent circuitIEEE Trans. Microw. Theory Tech. 36 1151 1988CrossRef Google Scholar

Trew, R. J.Steer, M. B.Millimetre-wave performance of state-of-the-art MESFET, MODFET and PBT transistorsElectron. Lett. 23 149 1987CrossRef Google Scholar

Akhtar, S.Tiwari, S.Non-quasi-static transient and small-signal two-dimensional modeling of GaAs MESFET's with emphasis on distributed effectsIEEE Trans. Electron Devices 40 2154 1993CrossRef Google Scholar

Tasker, P. J.Braunstein, J.611 1995

Crupi, G.Schreurs, D. M. M.-P.Raffo, A.Caddemi, A.Vannini, G.A new millimeter-wave small-signal modeling approach for pHEMTs accounting for the output conductance time delayIEEE Trans. Microw. Theory Tech 56 741 2008CrossRef Google Scholar

Brookbanks, D. M. 1990 109

Hajji, R.Shumaker, J.Camargo, E. 2004

Rauscher, C.Simulation of non-linear microwave FET performance using a quasi-static modelIEEE Trans. Microw. Theory Tech 27 834 1979CrossRef Google Scholar

McCamant, A. J.McCormack, G. D.An improved GaAs MESFET model for SPICEIEEE Trans. Microw. Theory Tech. 38 822 1990CrossRef Google Scholar

Angelov, I.Zirath, H.Rorsman, N.A new empirical nonlinear model for HEMT and MESFET devicesIEEE Trans. Microw. Theory Tech 40 2258 1992CrossRef Google Scholar

Parker, A. E.Skellern, D. J.A realistic large-signal MESFET model for SPICEIEEE Trans. Microw. Theory Tech. 45 1563 1997CrossRef Google Scholar

Angelov, I.Bengtsson, L.Garcia, M.Temperature and dispersion effect extensions of the Chalmers nonlinear HEMT and MESFET modelIEEE Radio Frequency Integrated Circuits Symp. Dig.1515 1995Google Scholar

Angelov, I.Bengtsson, L.Garcia, M.Extensions of the Chalmers nonlinear HEMT and MESFET modelIEEE Trans. Microw. Theory Tech. 44 1664 1996CrossRef Google Scholar

Staudinger, J.de Baca, M. CVaitkus, R. 1998 343

Hallgren, R. B.Litzenberg, P. H.TOM3 capacitance model: linking large and small-signal MESFET models in SPICEIEEE Trans. Microw. Theory Tech. 47 556 1999CrossRef Google Scholar

Tajima, Y. 2006

Aglient Technologies 2007

Snider, A. D.Charge conservation and the transcapacitance element: an expositionIEEE Trans. Educ. 38 376 1995CrossRef Google Scholar

Root, D. E. 2001 678

Wren, M.Brazil, T. J.31 2004

Root, D. E.Hughes, B.Principles of nonlinear active device modeling for circuit simulationARFTG Conf. Dig. 14 1 1988Google Scholar

Maas, S. A.Nonlinear Microwave and RF CircuitsArtech House 2003Google Scholar

Brookbanks, D. M.

Paggi, M.Williams, P. H.Borrego, J. M.Nonlinear GaAs MESFET modeling using pulsed gate measurementsIEEE Trans. Microw. Theory Tech. 36 1593 1988CrossRef Google Scholar

Platzker, A.Palevsky, A.Nash, S.Struble, W.Tajima, Y.1137 1990

Struble, W.Chu, S. L. G.Schindler, M. J.Tajima, Y.Huang, J. 1991 179

Staudinger, J.Golio, M.Woodin, C.de Baca, M. C.Considerations for improving the accuracy of large-signal GaAs MESFET models to predict power amplifier circuit performanceIEEE J. Solid-State Circuits 29 366 1994CrossRef Google Scholar

Ouarch, Z.Collantes, J. M.Teyssier, J. P.Quere, R.599 1998

Jardel, O.De Groote, F.Reveyrand, T.Jacquet, J.Charbonniaud, C.Teyssier, J.Floriot, D.Quéré, R.An electrothermal model for AlGaN/GaN power HEMTs including trapping effects to improve large-signal simulation results on high VSWRIEEE Trans. Microw. Theory Tech. 55 2660 2007CrossRef Google Scholar

Liu, L. S.Ma, J. G.Ng, G. I.749 2009

Codecasa, L.D’Amore, D.Maffezzoni, P.Modeling the thermal response of semiconductor devices through equivalent electrical networks, IEEE TransCircuits and Systems – I: Fundamental Theory and Applications 49 1187 2002CrossRef Google Scholar

Raffo, A.Vadalà, V.Vannini, G.Santarelli, A.1421 2008

Verzellesi, G.Bade, A.Mazzanti, A.Canali, C.Meneghesso, G.Zanoni, E.39 2003

Luniya, S.Batty, W.Caccamesit, V.Garcia, M.Christoffersen, C.Melamed, S.Davis, W. R.Steer, M.651 2006

Snowden, C. M. 2006 295

Root, D. E.Fan, S.Meyer, J. 1991 927

Angelov, I.Zirath, H.Rorsman, N.new empirical nonlinear model for HEMT and MESFET devicesIEEE Trans. Microw. Theory Tech. 40 2258 1992CrossRef Google Scholar

Xu, J.Gunyan, D.Iwamoto, M.Cognata, A.Root, D. E.469 2006

Root, D. E.Xu, J.Gunyan, D.Horn, J.Iwamoto, M. 2009

Schreurs, D. M. M.-P.Verspecht, J.Vandenberghe, S.Vandamme, E.Straightforward and accurate nonlinear device model parameter estimation method based on vectorial large-signal measurementsIEEE Trans. Microw. Theory Tech. 50 2315 2002CrossRef Google Scholar

Currás-Francos, M. C.Tasker, P. J.Fernández-Barciela, M.Campos-Roca, Y.Sánchez, E.Direct extraction of nonlinear FET Q–V functions from time domain large signal measurementsIEEE Microw. Guided Wave Lett. 10 531 2000CrossRef Google Scholar

Verspecht, J.Root, D. E.Polyharmonic distortion modelingIEEE Microw. Mag. 7 44 2006CrossRef Google Scholar

Qi, H.Benedikt, J.Tasker, P. J.Novel nonlinear model for rapid waveform-based extraction enabling accurate high power PA designIEEE MTT-S Int. Symp. Dig.2019 2007Google Scholar

Simpson, G.Horn, J.Gunyan, D.Root, D. E. 2008

Tsironis, C.Jurenas, A.Liu, W. 2001 1311

Aboush, Z.Jones, C.Knight, G.Sheikh, A.Lee, H.Lees, J.Benedikt, J.Tasker, P. J. 2005

Cripps, S. C.221 1983

Gupta, M. S.Power gain in feedback amplifiers, a classic revisitedIEEE Trans. Microw. Theory Tech 40 864 1992CrossRef Google Scholar

Book contents

2 - GaAs FETs – physics, design, and models

Summary

Access options

References

Save book to Kindle

Save book to Dropbox

Save book to Google Drive