World record in terrestrial radio transmission: Multi-Gigabit wireless communication
Transmitting the contents of a conventional DVD in under ten seconds by radio transmission is incredibly fast — and a new world record in wireless data transmission. With a data rate of 6 Gigabit per second over a distance of 37 kilometers, a collaborative project with the participation of researchers from the University of Stuttgart and the Fraunhofer Institute for Applied Solid State Physics IAF exceeded the state of the art by a factor of 10.
The collaborative project ACCESS (Advanced E Band Satellite Link Studies) was carried out by a research group headed by Professor Ingmar Kallfass from the Institute of Robust Power Semiconductor Systems (ILH) from the University of Stuttgart, the Institut für Hochfrequenztechnik und Elektronik (IHE) from KIT, Radiometer Physics GmbH, and the Fraunhofer Institute for Applied Solid State Physics IAF.
The team achieved the record data transmission on a stretch between Cologne and the 36.7 km distant town of Wachtberg. The stations were located on the 45-story Uni-Center in Cologne and the site of the Space Observation Radar TIRA at the Fraunhofer Institute for High Frequency Physics and Radar Techniques FHR in Wachtberg.
Record through using the latest technology
The extremely high data rates of 6 Gbit/s was achieved by the group through efficient transmitters and receivers at a radio frequency of 71-76 GHz in the so-called E band, regulated for terrestrial and satellite broadcasting. Only in this frequency range of millimeter waves are the required high effective bandwidths available. Only here can the enormous data rates be realized. A further difficulty is the weakening of the signals over larger distances. The transmission has to be especially powerful, and the amplifiers have to be correspondingly efficient. The key to the unique combination of gigabit data rates and highest distance are the efficient transmitters and receivers in the form of fully monolithically integrated millimeter wave circuits (MMICs).
The circuits are based on two innovative transistor technologies developed and manufactured by the project partner Fraunhofer IAF. In the transmitter the broadband signals are amplified to a comparatively high transmission power of up to 1 W with the help of power amplifiers on the basis of the novel compound semiconductor gallium-nitride. A highly directive parabolic antenna emits the signals. Built into the receiver are low-noise amplifiers on the basis of high-speed transistors using indium-gallium-arsenide-semiconductor layers with very high electron mobility. They ensure the detection of the weak signals at high distance.
Numerous areas of application
The transmission of high quantities of data by radio over large distances serves a high number of important application areas: the next generation of satellite communication requires an ever-increasing data offload from earth observation satellites down to earth. Supplying the rural area and remote regions with fast Internet is possible as shown in the trial. 250 Internet connections can be supplied with 24 Mbit/s ADSL. Terrestrial radio transmissions in E-band are suitable as a cost-effective replacement for deployment of optical fiber or as ad-hoc networks in the case of crises and catastrophe, and for connecting base stations in the backhaul of mobile communication systems.
Demand increasing unabatedly
The unabatedly increasing demand for ever-higher data rates in fiber-based and wireless communication networks can only be mastered by technological innovations in the network infrastructure. What’s more, modern developments such as the Internet of Things and Industry 4.0 are only in their early stages. They will demand unprecedented aggregated data quantities. Their processing and transmission in cloud-based services is already today taking the communication infrastructure to its limits. In satellite communication as well, the progress in earth observation and space research as well as plans for a planet-scale satellite network are leading to yet unsolved challenges for the communication infrastructure.
An overview of the project
ACCESS was finished on April 30 and is being continued in the follow-up project ELIPSE (E Band Link Platform and Test for Satellite Communication). The aim is the next generation of communication systems for the fast connection of satellites. A further application, however, also lies in terrestrial fixed wireless links.
The above post is reprinted from materials provided by Fraunhofer Institute for Applied Solid State Physics IAF. Note: Materials may be edited for content and length.