Title :
Nonlinear Design Technique for High-Power Switching-Mode Oscillators
Author :
Jeon, Sanggeun ; Suárez, Almudena ; Rutledge, David B.
Author_Institution :
Dept. of Electr. Eng., California Inst. of Technol., Pasadena, CA
Abstract :
A simple nonlinear technique for the design of high-efficiency and high-power switching-mode oscillators is presented. It combines existing quasi-nonlinear methods and the use of an auxiliary generator (AG) in harmonic balance. The AG enables the oscillator optimization to achieve high output power and dc-to-RF conversion efficiency without affecting the oscillation frequency. It also imposes a sufficient drive on the transistor to enable the switching-mode operation with high efficiency. Using this AG, constant-power and constant-efficiency contour plots are traced in order to determine the optimum element values. The oscillation startup condition and the steady-state stability are analyzed with the pole-zero identification technique. The influence of the gate bias on the output power, efficiency, and stability is also investigated. A class-E oscillator is demonstrated using the proposed technique. The oscillator exhibits 75 W with 67% efficiency at 410 MHz
Keywords :
UHF oscillators; circuit optimisation; circuit stability; nonlinear network analysis; poles and zeros; 410 MHz; 75 W; auxiliary generator; class-E oscillator; contour plots; dc-to-RF conversion; gate bias effect; harmonic balance; high-power oscillator; nonlinear design; oscillator optimization; pole-zero identification; quasinonlinear methods; steady-state stability; switching-mode operation; switching-mode oscillators; Circuits; Feedback; Frequency; Microwave oscillators; Power generation; Steady-state; Thermal management; Thermal stresses; Topology; Voltage; Class-E tuning; high-efficiency oscillator; nonlinear optimization; oscillation stability; startup criterion;
Journal_Title :
Microwave Theory and Techniques, IEEE Transactions on
DOI :
10.1109/TMTT.2006.882406
