Title :
An improved empirical large-signal model for high-power GaN HEMTs including self-heating and charge-trapping effects
Author :
Yuk, Kelvin ; Branner, G.R. ; McQuate, David
Author_Institution :
Univ. of California, Davis, CA, USA
Abstract :
A new empirical large-signal model for high-power GaN HEMTs utilizing an improved drain current (Ids) model is presented. The new Ids formulation accurately predicts the asymmetric bell-shaped transconductance (gm) over a large drain-source bias range which is crucial in modeling high-power GaN HEMTs. A method of utilizing a combination of pulsed-gate (PGIV) and pulsed-gate-and-drain (PIV) IV measurements to characterize the dispersive behavior of GaN HEMT nonlinear Ids characteristics is developed. Dispersion due to self heating is modeled by modifying Ids parameters as a function of the temperature change and drain-source bias. Dispersion due to trapping is modeled using an effective gate-source voltage model. Accurate predictions of the RF small-signal and large-signal performance are demonstrated for two quiescent biases.
Keywords :
gallium compounds; high electron mobility transistors; power transistors; semiconductor device models; wide band gap semiconductors; GaN; drain current model; drain-source bias; gate-source voltage model; high-power high electron mobility transistors; large-signal model; pulsed-gate-and-drain IV measurements; self heating; Dispersion; Gallium nitride; HEMTs; Heating; Intrusion detection; MODFETs; Predictive models; Pulse measurements; Temperature; Transconductance; AlGaN/GaN; GaN; Gallium Nitride; HEMT; high power; large-signal; model;
Conference_Titel :
Microwave Symposium Digest, 2009. MTT '09. IEEE MTT-S International
Conference_Location :
Boston, MA
Print_ISBN :
978-1-4244-2803-8
Electronic_ISBN :
0149-645X
DOI :
10.1109/MWSYM.2009.5165806
