Title :
Transistor design for predictable power gain at maximum frequency
Author :
McGregor, Joel M. ; Roulston, David J.
Author_Institution :
Dept. of Electr. & Comput. Eng., Waterloo Univ., Ont., Canada
fDate :
2/1/1992 12:00:00 AM
Abstract :
Equations which define the neutral base width, collector doping, and epitaxial collector thickness of a bipolar transistor giving a specified unilateral power gain at the highest frequency, possible are derived. Emitter-base capacitance, emitter delay, emitter stripe width, base doping, and the operating base-collector voltage are assumed to be known and fixed. The hybrid-π equivalent circuit is assumed valid up to the transition frequency ft. Peak fmax (maximum oscillation frequency) is examined as a function of the collector doping. Maximizing fmax at all costs leads to a design with an ft which approaches zero. In designing a transistor, the two figures of merit must be traded off against each other. A simple expression giving maximum fmax/ft is derived and used to define the transistor design which gives some specified power gain at the highest possible frequency
Keywords :
bipolar transistors; semiconductor device models; solid-state microwave devices; base doping; bipolar transistor; collector doping; design tradeoffs, transistor design; emitter base capacitance; emitter delay; emitter stripe width; epitaxial collector thickness; figures of merit; highest possible frequency; hybrid-π equivalent circuit; maximum frequency; maximum oscillation frequency; microwave transistors; modelling; neutral base width; operating base-collector voltage; predictable power gain; specified power gain; transition frequency; Analog integrated circuits; Application specific integrated circuits; Bipolar transistors; Capacitance; Current density; Delay; Doping; Frequency; Kirk field collapse effect; Voltage;
Journal_Title :
Electron Devices, IEEE Transactions on
