Title :
Physical modelling of microwave field effect transistors: a review
Author :
Zimmermann, J. ; Salmer, G. ; Fauquenbergue, R. ; Cappy, A.
Author_Institution :
Centre Hyperfrequences et Semicond., Lille Univ., Villeneuve d´´Ascq, France
Abstract :
The accurate modelling of GaAs FETs and related heterojunction structures requires that a number of physical phenomena and technological parameters be considered. Among these, electron dynamics in a two-dimensional gas, the influence of deep traps in substrates and AlGaAs layers, the source parasitic access impedance, surface potential effect, and velocity overshoot in submicrometer devices are of interest. A series of simulation models exist which can take a number of these effects into consideration in a more or less accurate way: the Monte Carlo or particle models, the two-dimensional solving methods for semiconductor equations, and the simpler one-dimensional or analytical models. These are reviewed and their main ranges of applicability are compared and discussed.<>
Keywords :
Monte Carlo methods; Schottky gate field effect transistors; high electron mobility transistors; reviews; semiconductor device models; solid-state microwave devices; 1-D model; FETs; GaAs-AlGaAs; HEMT; MESFET; Monte Carlo method; analytical models; deep traps; electron dynamics; heterojunction structures; microwave field effect transistors; modelling; particle models; review; semiconductor equations; simulation models; source parasitic access impedance; submicrometer devices; surface potential; two-dimensional gas; two-dimensional solving methods; velocity overshoot; Analytical models; Doping; Electron traps; Frequency; Gallium arsenide; HEMTs; Integrated circuit technology; MODFET integrated circuits; Microwave FETs; Predictive models;
Conference_Titel :
Circuits and Systems, 1988., IEEE International Symposium on
Conference_Location :
Espoo, Finland
DOI :
10.1109/ISCAS.1988.15344
