مرکز منطقه ای اطلاع رساني علوم و فناوري - Nonparametric detection using spectral data

Abstract :

A detection system is considered that analyzes the spectrum of the time-series output from a sensing element. The spectral data consist of a matrix of estimates of the energy in many small time-frequency cells. A decision procedure is formulated that is based on the multiple use of a two-sample statistic operating on the columns of the matrix. If the input noise is Gaussian with unknown power, the asymptotically optimum statistic $t$ is a ratio of two sample means. Since in certain applications the Gaussian input assumption may be unreliable, nonparametrie techniques based on the Mann-Whitney $U$ and Savage $T$ statistics are studied. Asymptotic relative efficiency (ARE) is computed for general positive spectral noise data and a scale alternative. This alternative is appropriate since it includes, for SNR $\\rightarrow 0$ , a Gaussian input with either a sinusoidal or Gaussian target. For a Gaussian input $ARE_{U/t} \\geq frac{3}{4}$ and $ARE_{T/t} \\geq$ 0.816. Non-Gaussian examples indicate that $U$ and $T$ can be much better than $t$ . It is shown that, subject to a reasonable restriction on the noise cumulative distribution function (cdf), $ARE_{U/t} \\geq frac{27}{64}$ . The results obtained here for noncoherent detection, though not quite as strong, are analogous to the known bounds on ARE for linear coherent detection (a translation alternative).