Title :
An Empirical Bipolar Device Nonlinear Noise Modeling Approach for Large-Signal Microwave Circuit Analysis
Author :
Traverso, Pier Andrea ; Florian, Corrado ; Borgarino, Mattia ; Filicori, Fabio
Author_Institution :
Ist. di Elettrotecnica, Bologna Univ.
Abstract :
An empirical bipolar transistor nonlinear noise model for the large-signal (LS) noise analysis of microwave circuits is described. The model is derived according to the charge-controlled nonlinear noise behavioral modeling approach, and includes nonlinearly controlled equivalent noise (EN) generators describing the low-frequency (LF) noise up-conversion encountered in LS RF operation. LS-modulated shot-noise sources and parametric LF noise in parasitic resistors are also taken into account for improved model accuracy. Details for the implementation of the proposed cyclostationary EN generators in the framework of a computer-aided design tool are presented. As an application example, a simplified version of the proposed nonlinear noise model for two GaInP-GaAs HBTs has been formulated and empirically characterized on the basis of both bias-dependent LF noise and phase-noise measurements. Measured and simulated noise performance of a monolithic voltage-controlled oscillator over a set of different operating conditions is shown for the validation of the proposed approach
Keywords :
III-V semiconductors; MMIC oscillators; gallium arsenide; gallium compounds; microwave bipolar transistors; nonlinear network analysis; phase noise; semiconductor device models; semiconductor device noise; shot noise; voltage-controlled oscillators; GaInP-GaAs; HBT; bipolar transistor; computer-aided design tool; cyclostationary noise; equivalent noise generators; large-signal noise analysis; microwave circuit analysis; noise up-conversion; nonlinear noise model; parametric LF noise; parasitic resistors; phase noise; phase-noise measurements; shot noise sources; voltage-controlled oscillator; Bipolar transistors; Circuit analysis; Circuit noise; Low-frequency noise; Microwave circuits; Microwave devices; Noise generators; Noise measurement; Radio frequency; Resistors; Cyclostationary noise; low phase noise (LPN); low-frequency (LF) noise; noise up-conversion; nonlinear noise model;
Journal_Title :
Microwave Theory and Techniques, IEEE Transactions on
DOI :
10.1109/TMTT.2006.885991
