Title :
Low probability of intercept (LPI) techniques and implementations for radar systems
Author :
Carlson, Eric J.
Author_Institution :
Motorola Inc., Tempe, AZ, USA
Abstract :
After a brief overview of optimal low-probability of intercept (LPI) radar design criteria, it is shown that for a given radar signal code length, many more codes are available by using higher-order Galois fields; that is, polyphase coding will supply the required diversity. Various aspects of polyphase coding are described because Doppler compensation of the returned signal is a polyphase process. It is shown that radiated spectral components are minimized if the code modulation is restricted to codes that have two-level autocorrelation functions. In addition, polyphase code modulation assignments allow the peak correlation sidelobes to be minimized in contrast to biphase coding that relies only on the best choice for the starting code element. The RMS sidelobe values are likewise reduced, so clutter rejection is actually improved with polyphase coding
Keywords :
codes; encoding; radar clutter; radar systems; radar theory; Doppler compensation; LPI; biphase coding; clutter rejection; code modulation; higher-order Galois fields; optimal low-probability of intercept; peak correlation sidelobes; polyphase coding; radar design criteria; radar signal code length; radar systems; radiated spectral components; two-level autocorrelation functions; Broadband antennas; Chirp modulation; Driver circuits; Matched filters; Modulation coding; Radar antennas; Radar applications; Radar signal processing; Signal processing; Spread spectrum radar;
Conference_Titel :
Radar Conference, 1988., Proceedings of the 1988 IEEE National
Conference_Location :
Ann Arbor, MI
DOI :
10.1109/NRC.1988.10930
