(Image courtesy of Thinkstock).
(Image courtesy of Thinkstock).
(Image courtesy of Thinkstock).
(Image courtesy of Thinkstock).
(Image courtesy of Thinkstock).

Ka-Band Antennas Link Mobile Satcom Users

May 2, 2016
Two different antenna designs were developed for Ka-band satellite communications applications.

Satellite communications (satcom) technology is moving far beyond the simple reception of video from orbiting geosynchronous satellites and into full bidirectional mobile satcom services. To accomplish this at Ka-band frequencies, efficient antenna designs are needed for mobile satcom terminals. Researchers from the RF and Microwave Research Laboratory at the Technische Universitat Ilmenau (Ilmenau, Germany) and the Fraunhofer Institute for Integrated Circuits IIS, Design Automation Division EAS (Dresden, Germany) attempted to compare two different Ka-band antenna terminal setups for mobile satcom applications. The two antennas traded size for performance: one was a larger, high-gain antenna, the other a lower-gain, lower-profile antenna.

The researchers point out the growing interest in Ka-band frequencies at 29.5 to 30.0 GHz for uplinks and 19.7 to 20.2 GHz for downlinks because of their healthy capacity and compact terminal antennas. In emergency situations where terrestrial communications systems may not be available or reliable, the use of geosynchronous satellites can provide a means of communications. The two antenna designs explore the classic tradeoff of size for performance. The larger of the two designs is a Cassegrain double-reflector antenna mounted on a mechanically adjusted, two-axis positioner on a carrier vehicle. The reflector diameter is 60 cm, but it provides large gain of about 40 dBi in support of high data rates for bidirectional satcom links. While moving, the antenna tracks satellite direction by means of multimode monopulse tracking. It can be mounted on large vehicles, such as pickup trucks.

The smaller antenna is designed for greater mobility, with a maximum height of only 15 cm. The smaller profile and size yields less gain, at about 20 dBi, and a correspondingly broader beamwidth. The low profile of the antenna design makes possible a compact satellite terminal outdoor unit (ODU) with a mechanical azimuth positioned that operates effectively while maintaining the aforementioned height, even when the vehicle is in motion. The design was evaluated by means of an antenna ODU demonstrator capable of adjusting azimuth for both uplink and downlink operations. In contrast to the larger, high-gain antenna, this low-profile satcom antenna is suitable for mounting on smaller vehicles, including standard automobiles. See “Ka-Band User Terminal Antennas for Satellite Communications,” IEEE Antennas & Propagation Magazine, February 2016, p. 76.

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