In civil aviation, Automatic Dependent Surveillance - Broadcast (ADS-B) is expected to become the main surveillance technology. Nevertheless, to ensure that accurate surveillance services can be provided when failures of this cooperative surveillance system occur or when non-cooperative aircraft localization is required, a backup system needs to be made available. This paper addresses this problem using the Multiple-Input Multiple-Output (MIMO) radar technology. Specifically, we propose to reuse the infrastructure and signals of the future L-band digital aeronautical communications system type 1 (LDACS1) for implementing a MIMO radar with widely distributed antennas. In its broad interpretation, a MIMO radar represents a multiple antenna radar system able to send arbitrary waveforms from each transmit antenna and to jointly process the target returns received at multiple receiving sites. For the purpose of this work, a MIMO radar configuration with widely separated transmit and receive antennas is of interest. One key advantage of this configuration arises from its distributed nature, which allows for the target to be simultaneously “seen” from different angles. The resulting spatial diversity gain can be used to improve the target detection and parameter estimation process.
[1]
L.J. Cimini,et al.
MIMO Radar with Widely Separated Antennas
,
2008,
IEEE Signal Processing Magazine.
[2]
Hugh Griffiths,et al.
Advances in Bistatic Radar
,
2007
.
[3]
A. W. Rihaczek.
Principles of high-resolution radar
,
1969
.
[4]
August W. Rihaczek,et al.
Delay-Doppler Ambiguity Function for Wideband Signals
,
1967,
IEEE Transactions on Aerospace and Electronic Systems.
[5]
R. Jehlen.
Integrated communications navigation and surveillance (ICNS) conference
,
2013,
ICNS 2013.
[6]
Dmitriy Shutin,et al.
LDACS1 ranging performance - An analysis of flight measurement results
,
2013,
2013 IEEE/AIAA 32nd Digital Avionics Systems Conference (DASC).