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Home Research activities

Research activities

Research of the Chair of High Frequency Electronics is within high speed electronic components, circuits and systems for future communication and remote sensing applications.

The research spans from frequencies below 1 GHz to above 100 GHz with the aim of enhancing the performance, lowering power consumption and cutting the cost of high speed wireless/wire-line communication, sensing systems, interconnects, etc. Particular interests include techniques for improving the electrical efficiency of microwave high power amplifiers and transmitters for wireless infrastructure applications.

To demonstrate innovative microwave components, circuits and systems we employ various technologies spanning from conventional III-V to Silicon VLSI, Graphene MMIC processes and state-of-the-art equipment in our measurement laboratory.

Novel transmitter architectures for nanoscale CMOS integration

Simulation results RF-DAC

With every new standard for wireless mobile communications, there is a demand for even higher data rates and bandwidth. Within the framework of UMIC, the Mixed-Signal CMOS Circuits group (MSCC) in collaboration with the Chair of Integrated Analog Circuits (IAS) does research on possible architectures for broadband RF transmitters. These have to be power- and cost-efficient while being compatible with digital-centric nanoscale CMOS technologies.

Advanced wireless transmitter architectures for next generation mobile terminals

In order to provide customers with higher data rates, more and better services in a more flexible way, as well as extended coverage the trend in modern wireless communication equipment is to cover multiple communication standards and frequencies with a single piece of hardware. This approach reduces physical size, complexity and, hence, implementation costs for future wireless telecommunication transceivers. As standard linear wireless transmitter architectures are replaced by more advanced topologies, due to their considerably higher efficiency for a given linearity, efficient wide- and multiband power amplifiers (PAs) are key building blocks for the development of future energy-efficient flexible terminals, software defined and cognitive radios. The aim of this project is to investigate these critical RF building blocks. 

DSM

 

Virtual RF system modelling in SystemC 

In this project we simulate complete mixed-signal systems in SystemC.

High dynamic LINC-like RF transmitters