Title :
A noncoherent adaptive detection technique
Author :
Monticciolo, P. ; Kelly, E.J. ; Porakis, J.G.
Author_Institution :
MIT Lincoln Lab., Lexington, MA, USA
fDate :
1/1/1992 12:00:00 AM
Abstract :
An adaptive detection technique suitable for both stationary and nonstationary noise environments based upon a generalized likelihood ratio test (GLRT) formulation is presented. The detector, which is statistically equivalent to a special form of the Wilks´s lambda test, noncoherently combines the information contained in a pulse train of arbitrary length for decision-making purposes. The probability density function of the test under the noise only hypothesis is shown to be central χ2. Under the signal plus noise hypothesis, an exact statistical characterization of the test cannot be obtained, and, therefore, a Chernoff bound is derived. Results in terms of the probability of detection versus signal-to-noise ratio (SNR) obtained from Monte Carlo simulation, the Chernoff bound, and the optimal matched filter case are examined. The performance of the noncoherent detector is shown to be a function of the covariance matrix estimate and the number of data samples
Keywords :
Monte Carlo methods; adaptive systems; probability; random noise; signal detection; signal processing; Chernoff bound; Monte Carlo simulation; Wilks´s lambda test; covariance matrix estimate; decision-making; generalized likelihood ratio test; noise only hypothesis; noncoherent adaptive detection; nonstationary noise environments; optimal matched filter; probability density function; probability of detection; signal plus noise hypothesis; signal-to-noise ratio; stationary noise environments; Covariance matrix; Detectors; Matched filters; Probability density function; Pulse modulation; Radar; Signal design; Signal to noise ratio; Testing; Working environment noise;
Journal_Title :
Aerospace and Electronic Systems, IEEE Transactions on
