Title :
An accurate large-signal model of GaAs MESFET which accounts for charge conservation, dispersion, and self-heating
Author :
Wei, Ce-Jun ; Tkachenko, Yevgeniy A. ; Bartle, Dylan
Author_Institution :
Alpha Ind. Inc., Woburn, MA, USA
fDate :
11/1/1998 12:00:00 AM
Abstract :
A comprehensive large-signal model of a GaAs MESFET is presented to account for charge conservation and effects of dispersion and self-heating. An improved set of capacitance and charge equations, along with an enhanced Triquint Own model (TOM)-like drain current model, is used for consistent small- and large-signal simulations. Charge conservation is satisfied by deriving the capacitance part of the model from charge equations. Transconductance and output conductance dispersion is modeled by combination of a feedback network and a subcircuit, which describes the self-heating effect. An improved description of the near-pinchoff characteristics, high-voltage breakdown, and gain compression in the high-current region in the TOM is introduced. The new model accurately predicts the I-V, CV, bias-dependent S-parameter, waveform, power, and linearity characteristics of the MESFET
Keywords :
III-V semiconductors; S-parameters; Schottky gate field effect transistors; capacitance; electric admittance; electric charge; equivalent circuits; gallium arsenide; microwave field effect transistors; semiconductor device breakdown; semiconductor device models; C-V characteristics; GaAs; GaAs MESFET; I-V characteristics; Triquint Own model; accurate large-signal model; bias-dependent S-parameter characteristics; capacitance equations; charge conservation; charge equations; drain current model; feedback network; gain compression; high-current region; high-voltage breakdown; linearity characteristics; near-pinchoff characteristics; output conductance dispersion; power characteristics; self-heating effect; transconductance; waveform characteristics; Capacitance; Dispersion; Electric breakdown; Equations; Gallium arsenide; MESFETs; Output feedback; Predictive models; Scattering parameters; Transconductance;
Journal_Title :
Microwave Theory and Techniques, IEEE Transactions on
