Low probability of intercept radar
A low-probability-of-intercept radar (LPIR) is designed to be difficult to detect by passive radar detection equipment (such as a radar warning receiver – RWR) while it is searching for a target or engaged in target tracking. This characteristic is desirable in a radar because it allows finding and tracking an opponent without alerting them to the radar's presence.
Ways of reducing the profile of a radar include using wider-frequency bandwidth (wideband), frequency hopping, using a frequency-modulated continuous-wave signal, and using only the minimum power required for the task. Using pulse compression also reduces the probability of detection, since the peak transmitted power is lower while the range and resolution is the same.
Constructing a radar so as to emit minimal side and back lobes may also reduce the probability of interception when it is not pointing at the radar warning receiver. However, when the radar is sweeping a large volume of space for targets, it is likely that the main lobe will repeatedly be pointing at the RWR. Modern phased-array radars not only control their side lobes, they also use very thin, fast-moving beams of energy in complicated search patterns. This technique may be enough to confuse the RWR so it does not recognize the radar as a threat, even if the signal itself is detected.
In addition to stealth considerations, reducing side and back lobes is desirable as it makes the radar more difficult to characterise. This can increase the difficulty in determining which type it is (concealing information about the carrying platform) and make it much harder to jam.
Systems that feature LPIR include modern active electronically scanned array (AESA) radars such as that on the F/A-18E/F Super Hornet and the passive electronically scanned array (PESA) on the S-300PMU-2 missile.
- F-22 Avionics / GlobalSecurity.org
- Low Probability of Intercept Radar (LPIR) / GlobalSecurity.org
- Detection and jamming Low Probability of Intercept (LPI) RADARS, MasterThesis by Aytug Denk, 2006.