A new method is proposed for the empirical characterization of the nonlinear thermal resistance in GaN HEMTs. Low-Frequency dispersion due to self-heating is used as the sensing parameter of the channel temperature changes deriving from dissipated power variations. Since GaN HEMTs are also affected by LF dispersive charge-trapping phenomena, the thermal resistance description is embedded into a full electrothermal model, in order to extract the parameters by bestfitting the measured data. The method involves only multi-bias small-signal S-parameter and dc I/V measurements at different base plate temperatures. It is non-invasive, does neither require special-purpose device geometries/structures nor measurements in the conduction region of the gate junction. Preliminary validation of the method is based on comparisons with measured electrothermal data, with data from the literature on similar devices and on results provided by a large-signal RF device model embedding the thermal resistance description.
Nonlinear Thermal Resistance Characterization for Compact Electrothermal GaN HEMT Modelling / A. Santarelli; V. Di Giacomo; R. Cignani; S. D’Angelo; D. Niessen; F. Filicori. - STAMPA. - (2010), pp. 82-85. (Intervento presentato al convegno 5th European Microwave Integrated Circuits conference (EuMIC 2010) - European Microwave Week 2010 tenutosi a Paris (France) nel 26 Sep - 1 Oct, 2010).
Nonlinear Thermal Resistance Characterization for Compact Electrothermal GaN HEMT Modelling
SANTARELLI, ALBERTO;CIGNANI, RAFAEL;NIESSEN, DANIEL;FILICORI, FABIO
2010
Abstract
A new method is proposed for the empirical characterization of the nonlinear thermal resistance in GaN HEMTs. Low-Frequency dispersion due to self-heating is used as the sensing parameter of the channel temperature changes deriving from dissipated power variations. Since GaN HEMTs are also affected by LF dispersive charge-trapping phenomena, the thermal resistance description is embedded into a full electrothermal model, in order to extract the parameters by bestfitting the measured data. The method involves only multi-bias small-signal S-parameter and dc I/V measurements at different base plate temperatures. It is non-invasive, does neither require special-purpose device geometries/structures nor measurements in the conduction region of the gate junction. Preliminary validation of the method is based on comparisons with measured electrothermal data, with data from the literature on similar devices and on results provided by a large-signal RF device model embedding the thermal resistance description.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
