A.O. Olsen scite author profile

Current research on heterostructure barrier varactors (HBVs) devotes much effort to the generation of very high power levels in the millimeter wave region. One way of increasing the power handling capacity of HBVs is to stack several barriers epitaxially. However, the small device dimensions lead to very high temperatures in the active layers, deteriorating the performance. We have derived analytical expressions and combined those with finite element simulations, and used the results to predict the maximum effective number of barriers for HBVs. The thermal model is also used to compare the peak temperature and power handling capacity of GaAs and InP-based HBVs. It is argued that InP-based devices may be inappropriate for high-power applications due to the poor thermal conductivity of the InGaAs modulation layers.

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11% efficiency 100 GHz InP-based heterostructure barrier varactor quintupler

Bryllert

Olsen

Vukušić

et al. 2005

Electron. Lett.

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HBV tripler with 21% efficiency at 102 GHz

et al. 2006

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A.O. Olsen

An electro-thermal HBV model

Thermal Constraints for Heterostructure Barrier Varactors

11% efficiency 100 GHz InP-based heterostructure barrier varactor quintupler

HBV tripler with 21% efficiency at 102 GHz

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