Large-signal dynamic modelling of III-V FETs cannot be simply based on dc i/v characteristics, when accurate performance prediction is needed. In fact, dispersive phenomena due to self-heating and/or traps (surface state densities and deep level traps) must be taken into account since they cause important deviations in the dynamic drain current. In this paper, a recently proposed large-signal i/v measurement setup is exploited to extract an empirical model for low-frequency dispersive phenomena in microwave electron devices. This i/v model is then embedded into a microwave large-signal PHEMT model. Eventually, a Ka-band highly linear power amplifier, designed by Ericsson using the triquint GaAs 0.25/spl mu/m PHEMT process, is used for model validation. Excellent intermodulation distortion predictions are obtained with different loads despite the extremely low power level of IMD products involved. This entitles the proposed model to be also used in the PA design process instead of conventional load-pull techniques whenever the high-linearity specifications play a major role.
Improvement of PHEMT Intermodulation Prediction Through the Accurate Modelling of Low-Frequency Dispersion Effects
RAFFO, Antonio;VANNINI, Giorgio;
2005
Abstract
Large-signal dynamic modelling of III-V FETs cannot be simply based on dc i/v characteristics, when accurate performance prediction is needed. In fact, dispersive phenomena due to self-heating and/or traps (surface state densities and deep level traps) must be taken into account since they cause important deviations in the dynamic drain current. In this paper, a recently proposed large-signal i/v measurement setup is exploited to extract an empirical model for low-frequency dispersive phenomena in microwave electron devices. This i/v model is then embedded into a microwave large-signal PHEMT model. Eventually, a Ka-band highly linear power amplifier, designed by Ericsson using the triquint GaAs 0.25/spl mu/m PHEMT process, is used for model validation. Excellent intermodulation distortion predictions are obtained with different loads despite the extremely low power level of IMD products involved. This entitles the proposed model to be also used in the PA design process instead of conventional load-pull techniques whenever the high-linearity specifications play a major role.I documenti in SFERA sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.