Projects and activities

An overview of project activities in the RF & Microwave Laboratory. 

S-parameter traceability

Since 2006 the laboratory is involved in a series of projects with partners from industry and academia to improve the quality of coaxial measurements with vector network analyzers (VNA). It has established SI traceability through the mechanical characterization of calculable primary calibration standards, not only airlines but also offset shorts. It has investigated the effects of connectors with the help of numerical EM field simulations. It has invented new calibration algorithms for the electrical characterization of the primary standards.

The work has resulted in a more accurate definition of the 50 Ohm reference plane of a VNA after calibration. It has eliminated inconsistencies between different calibration schemes and has led to a better understanding and control of influences that affect VNA measurements. An important supporting role in this process plays the VNA metrology software VNA Tools.

The laboratory is currently extending its measurement capabilities to 220 GHz or even 250 GHz by establishing traceability for the new PC-0.5 mm connector. This is done in the framework of the RF46G project and in close cooperation with Keysight Technologies.

RF+MW Power

The laboratory has extended its power measurement capabilities in the coaxial line system to 110 GHz in collaboration with industry. The software has been modernized by using synergies with METAS UncLib and METAS VNA Tools. Current R&D work is exploring the possibility to employ the electro-optical effect for a novel power standard in the coaxial line system. This work is carried out in the frame work of an Innosuisse project in collaboration with an industrial partner.

Terahertz Metrology

METAS has explored the 500 to 750 GHz wave guide band in the project TEMMT. This included traceability for S-parameter, power and material parameter measurements in rectangular wave guide. The activity was performed in METAS has explored the 500 to 750 GHz wave guide band in the project TEMMT. This included traceability for S-parameter, power and material parameter measurements in rectangular wave guide. The activity was performed in collaboration with the photonics, time & frequency lab at METAS, which addressed the traceability of the generation and detection of THz frequencies in free field using laser based approaches.

This activity is currently not pursued further. 

Electrical Nanometrology

Near field scanning microwave microscopy (NFSMM) is a fairly novel measurement technique that combines an atomic force microscope (AFM) with a vector network analyzer (VNA). The device can be used to characterize electromagnetic material parameters at the nanoscale. Further information can be found here. 

Quantum Sensing with Rydberg atoms

METAS is establishing quantum sensing activities. A dedicated laboratory is being set up for that purpose. The first step aims at using atomic Rydberg states to detect electro-magnetic field patterns on planar circuits. The goal is to explore alternative on-wafer probing techniques with the help of quantum effects. This is pursued within the project OnMicro.

Data Science for Metrology

The Horizon Europe project Digicell deals with digital modelling to support battery manufacturing and testing. The RF&MW lab is dealing with the analysis of electrochemical impedance spectra by means of machine learning algorithms.