DC and thermal modeling: III–V FETs and HBTs

doi:10.1017/CBO9781139014960.003

2 - DC and thermal modeling: III–V FETs and HBTs

Published online by Cambridge University Press: 25 October 2011

Jianjun Xu and

Edited by

Christian Fager and

Masaya Iwamoto: Affiliation:
Agilent Technologies, Santa Rosa, California, USA
Jianjun Xu: Affiliation:
Agilent Technologies, Santa Rosa, California, USA
David E. Root: Affiliation:
Agilent Technologies, Santa Rosa, California, USA
Matthias Rudolph: Affiliation:
Brandenburg University of Technology
Christian Fager: Affiliation:
Chalmers University of Technology, Gothenberg
David E. Root: Affiliation:
Agilent Technologies, Santa Rosa

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Summary

Introduction

A brief overview and selected topics on DC and thermal compact modeling of III–V compound semiconductor transistors are discussed. Specifically, characteristics of field-effect transistors (GaAs MESFET and pseudomorphic HEMT (pHEMT)) and heterojunction bipolar transistors (GaAs and InP HBTs) are presented. Basic DC characteristics of III–V FETs and HBTs are reviewed, and parameter extraction techniques and methods pertinent to compact modeling are shown. Properly extracted parameters, in turn, can be used for process control and optimization by monitoring device characteristics within and across many wafers. Thermal modeling pertinent to compact modeling is also presented with two approaches demonstrated: physics-based and measurement based. Finally, device reliability evaluation is presented as an example where both DC parameters and thermal modeling are extensively utilized.

The DC model serves as a foundation for any compact model. In the most fundamental sense, DC simulation results based on an accurate model provide detailed bias point information for circuits such as current density, output voltage, and power dissipation to enable robust and well-optimized circuit designs. Furthermore, the DC model serves as the foundation for RF characteristics such as S-parameters. For example in an HBT, S11 and S21 at low frequencies are related to the small-signal model parameters rπ and gm, respectively.

Type: Chapter
Information: Nonlinear Transistor Model Parameter Extraction Techniques , pp. 18 - 42

DOI: https://doi.org/10.1017/CBO9781139014960.003 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2011

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References

[1] Curtice, W. R., “A MESFET model for use in the design of GaAs integrated circuits,” IEEE Trans. Microw. Theory Tech., vol. 28, pp. 448–456, 1980.CrossRef Google Scholar

[2] Tuyl, R. and Liechti, C., “Gallium arsenide digital integrated circuits,” Techn. Rep. AFL-TR-74-40, Air Force Avionics Lab., Mar. 1974.

[3] Gummel, H. K. and Poon, R. C., “An integral charge control model of bipolar transistors,” Bell Syst. Tech. J., vol. 49, pp. 827–852, May–June 1970.CrossRef Google Scholar

[4] Angelov, I., Zirath, H., and Rosman, N., “A new empirical nonlinear model for HEMT and MESFET devices,” IEEE Trans. Microw. Theory Tech., vol. 40, 1992, pp. 2258–2266.CrossRef Google Scholar

[5] ,Agilent Technologies, “Circuit components: nonlinear devices,” Advanced Design System 2008 Manual, pp. 261–308, 2008.Google Scholar

[6] Golio, J. M, Microwave MESFETs & HEMTs, Norwood, MA: Artech House, 1991, ch. 2.Google Scholar

[7] McAndrew, C. C., Seitchik, J. A., Bowers, D. F., Dunn, M., Foisy, M., Getreu, I., McSwain, M., Moinian, S., Parker, J., Roulston, D. J., Schroter, M., Wijnen, P., and Wagner, L. F., “VBIC95, The Vertical Bipolar Inter-Company Model,” IEEE J. Solid/state Circuits, vol. 31, pp. 1476–1483, Oct. 1996.CrossRef Google Scholar

[8] Schröter, M. and Lee, T-Y., “Physics-based minority charge and transit time modeling for bipolar transistors,” IEEE Trans. Electron Devices, vol. 46, pp. 288–300, Feb. 1999.CrossRef Google Scholar

[9] Rudolph, M., Introduction to Modeling HBTs, Norwood, MA: Artech House, 2006, pp. 232–250.Google Scholar

[10] Rudolph, M., Introduction to Modeling HBTs, Norwood, MA: Artech House, 2006, pp. 250–263.Google Scholar

[11] Tiwari, S., “Aneweffect at high currents in heterostructure bipolar transistors,” IEEE Electron Device Lett., vol. 9, pp. 142–144, Mar. 1999.CrossRef Google Scholar

[12] Rudolph, M., Introduction to Modeling HBTs, Norwood, MA: Artech House, 2006, pp. 263–276.Google Scholar

[13] Yeats, B., “Inclusion of topsidemetal heat spreading in the determination of HBT temperatures by electrical and geometrical methods,” IEEE GaAs IC Symp., pp. 59–62, 1999.Google Scholar

[14] Yeats, B., “Assessing the reliability of silicon nitride capacitors in a GaAs IC process,” IEEE Trans. Electron Devices, vol. 45, pp. 939–946, Apr. 1998.CrossRef Google Scholar

[15] Alt, K., Shirley, T., Hutchinson, C., Iwamoto, M., Yeats, B., Gierhart, B., Bonse, M., Shimon, R., Kellert, F., and D'Avanzo, D., “Use of a transistor array to predict infant transistor mortality rate in InGaP/GaAs HBT technology,” Reliability of Compound Semiconductor Workshop, Oct. 2008.Google Scholar

[16] Li, J. C., Hussain, T., Hitko, D. A., Asbeck, P. A., and Sokolich, M., “Characterization and modeling of thermal effects in sub-micron InP HBTs,” IEEE Compound Semiconductor IC Symp., pp. 65–68, Nov. 2005.Google Scholar

[17] Smith, D. H., Fraser, A., and O'Neil, J., “Measurement and prediction of operating temperatures for GaAs ICs,” Proc. SEMITHERM, pp. 1–20, Dec. 1986.Google Scholar

[18] Curtice, W. R., Hietala, V. M., Gebara, E., and Laskar, J., “The thermal gain effect in GaAs-based HBTs,” IEEE Int. Microw. Symp. Dig., pp. 639–641, June 2003.Google Scholar

[19] Dawson, D. E., Gupta, A. K., and Salib, M. L., “CW measurement of HBT thermal resistance,” IEEE Trans. Electron Devices, vol. 39, pp. 2235–2239, 1992.CrossRef Google Scholar

[20] Yeats, B., 1992 GaAs Re1 Workshop, paper IV–I.

[21] Dawson, D. E., “Thermal modeling, measurements and design considerations of GaAs microwave devices,” IEEE GaAs IC Symp., pp. 285–290, 1994.Google Scholar

[22] Jenkins, K. A. and Rim, K., “Measurement of the effect of self-heating in strained-silicon MOSFETs,” IEEE Electron Device Lett., vol. 23, pp. 360–362, June 2002.CrossRef Google Scholar

[23] Zhang, Q. J. and Gupta, K. C., Neural Networks for RF and Microwave Design, Norwood, MA: Artech House, 2000.Google Scholar

[24] DiLorenzo, J. V. and Khandelwal, D. D., GaAs FET Principles and Technology, Dedham, MA: Artech House, 1982, ch. 6.

[25] Black, J. R., “Electromigration – a brief survey and some recent results,” IEEE Trans. Electron Devices, vol. 16, pp. 338–347, 1969.CrossRef Google Scholar

[26] Yeats, B., Chandler, P., Culver, M., D'Avanzo, D., Essilfie, G., Hutchinson, C., Kuhn, D., Low, T., Shirley, T., Thomas, S., and Whiteley, W., “Reliability of InGaP-Emitter HBTs,” GaAs Manufacuring Technology Conf., 2000, pp. 131–135.Google Scholar

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2 - DC and thermal modeling: III–V FETs and HBTs

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