Title :
A Quasi-Two-Dimensional Model for High-Power RF LDMOS Transistors
Author :
Everett, John P. ; Kearney, Michael J. ; Rueda, Hernan ; Johnson, Eric M. ; Aaen, Peter H. ; Wood, John ; Snowden, Christopher M.
Author_Institution :
Adv. Technol. Inst., Univ. of Surrey, Guildford, UK
Abstract :
A new quasi-2-D model for laterally diffused metal-oxide-semiconductor radio-frequency power transistors is described in this paper. We model the intrinsic transistor as a series laterally diffused p-channel and n-type drift region network, where the regional boundary is treated as a reverse-biased p+-n diode. A single set of 1-D energy transport equations is solved across a 2-D cross section in a “current-driven” form, and specific device features are modeled without having to solve regional boundary node potentials using numerical iteration procedures within the model itself. This fast process-oriented nonlinear physical model is scalable over a wide range of device widths and accurately models direct-current and microwave characteristics.
Keywords :
iterative methods; microwave power transistors; power MOSFET; semiconductor device models; 1D energy transport equation; current-driven form; direct-current characteristics; high-power RF LDMOS transistor; intrinsic transistor; laterally diffused metal-oxide-semiconductor radio-frequency power transistor; microwave characteristics; numerical iteration procedure; process-oriented nonlinear physical model; quasi-2D model; reverse-biased p+-n diode; Doping; Equations; Integrated circuit modeling; Logic gates; Mathematical model; Numerical models; Transistors; Field-effect transistor (FET); laterally diffused metal–oxide–semiconductor (LDMOS); quasi-2-D (Q2-D); transistor model;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2011.2160546
