For mobile broadband satellite communications steerable antennas with high gain are required. They can be steered mechanically, electronically or by the combination of these two possibilities. For aviation applications it is very important that the antennas have low profile. In the recent years, avionic satellite communications systems up to the Ku-band have been proposed [1], [2]. However, for broadband communications higher frequencies are required, since only at higher frequencies broad frequency bands for delivering high data rate are still available. Concepts of fully electronically steerable or hybrid (mechanical-electronic) antennas at Ka band have been already proposed, see e.g. [3],[4], but such antennas are very expensive and not all technological hurdles have been overcome yet. In contrast, adaptive antennas for communication between aircrafts (intra-flight) can have lower gain and therefore they can be produced with acceptable costs.
[1]
A. Dreher,et al.
Tx-terminal phased array for satellite communication at Ka-band
,
2007,
2007 European Microwave Conference.
[2]
Fan Yang,et al.
Linear Antenna Array Synthesis Using Taguchi's Method: A Novel Optimization Technique in Electromagnetics
,
2007,
IEEE Transactions on Antennas and Propagation.
[3]
A. D. Monk,et al.
Calibration and RF test of Connexion by Boeing/sup SM/ airborne phased arrays
,
2003,
IEEE International Symposium on Phased Array Systems and Technology, 2003..
[4]
A. D. Monk,et al.
Two-way airborne broadband communications using phased array antennas
,
2003,
2003 IEEE Aerospace Conference Proceedings (Cat. No.03TH8652).
[5]
S. Holzwarth,et al.
Ka-band DBF terminal concepts for broadband satellite communications
,
2002
.