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Today, many military users of radar are specifying Low Probability of Intercept (LPI) as an important technical and tactical requirement. The Low Probability of Intercept technique is based on the property of radar that due to its low power, wide bandwidth, frequency variability and other design attributes makes it difficult to be detected and classify by means of conventional Electronic Support Measure/ Electronic Intelligence (ESM/ELINT) systems. LPI radar attempts to provide detection of targets at longer ranges than intercept receivers can accomplish detection of the radar. The success of LPI radar is measured by how hard it is for the receiver to detect the radar emission parameters. The Electronic warfare (EW) scenario has become complex and in particular the radar frequency spectrum consists of different types of digital modulation [1]. This paper deals one of the technique for autonomous extraction of the parameters of the Low Probability of Intercept (LPI) signal.

Low Probability of Intercept (LPI), ESM, ELINT, EW, Radar.

Hejazi, M.R., Shevlyakov, G., and Ho, Y-S., ―Modified discrete radon transforms and their application to rotation-invariant image analysis,‖ IEEE 8th Workshop on Multimedia Signal Processing, pp. 429—434, Oct. 2006.

Gulum, T. O., Pace, P. E. and Cristi, R. ―Extraction of Polyphase Radar Modulation Parameters Using a Wigner-Ville Distribution Radon Transform,‖ IEEE International Conf. on Acoustics, Speech and Signal Processing, Las Vegas, NV, March 2008.

Minsheng Wang, Andrew K. Chan, Charles K. Chui, ―Linear Frequency-Modulated Signal Detection Using Radon-Ambiguity Transform‖, IEEE Transactions on Signal Processing, VOL. 46, NO. 3, MARCH 1998.

L. Anjaneyulu, N.S.Murthy, N.V.S.N.Sarma ―Identification of LPI Radar Signals by Higher Order Spectra and Neural Network Techniques‖, IEEE International Conference on Electronic Design, 2008

Phillip E. Pace ―Detecting and Classifying Low Probability of Intercept Radar‖ ,2nd Edition, 2009, ARTECH HOUSE

GEORGE W. STIMSON: ―Introduction to Airborne Radar‖, 2nd Edition, SciTech publishing,Inc.1998.

P R Milne and P E Pace, ―Wigner distribution detection and analysis of FMCW and p4 polyphase LPI waveforms‖, IEEE conference 2002.

D B Copeland and P E Pace, ―Detection and analysis of FMCW and p4 polyphase LPI waveforms using Quadrature mirror filter trees‖, IEEE conference 2002.

Dong –hyuk shin –Hong park ―Block based noise estimation using adaptive Gaussian filtering‖ IEEE transaction on consumer electronics, Vol.51,No.1 feb 2005.

A.M.Tekalp, digital viedo processing, upper saddle river, NJ.prentice-hall,1995.

Perrson.C ―Classification and analysis of low probability of intercept radar signals using image processing‖Master Thesis, Naval postgraduate School,Monterey, Calfornia,2003.

Boashash.B and Black.P.J.‖An efficient real time implementation of the Wigner ville distribution‖ IEEE transaction on acoustics sppech and signal processing,Vol.ASSP-35, No.11,pp.1611-1618,Nov.1987.

Barborossa.S ‖Parameter estimation of undersampled signals by Wigner –Ville analysis‖ IEEE conference on acoustics speech and signal processing ICASSP-91,Vol.5,pp.3944-3947, 2002.

Gao.H.Y & Bruce.A.G, Waveshrink with firm shrinkage .Statistica Sinica 7,pp 855-874,1997.

Taboada.F ‖Intercept receiver signal processing techniques to detect low probability of intercept radar signals‖ Proceedings of the fifth Nordic signal processing symposium, Hurtigruta Tromso-Trondheim,Norway,4-7 Oct.2002.

G.De Hann,T.Kwaaitaal-Spassova and O.A.Ojo, ‖Automatic 2-D and 3-D noise filtering for high quality television receivers‖. Proceedings of the International workshop signal processing and HDTV, Turin, Italy,March1996,Vol.VI,pp 221-230.