Abstract
Re/spl acute/nyi entropy has been proposed as an effective measure of signal information content and complexity on the time-frequency plane. The previous work concerning Re/spl acute/nyi entropy in the time-frequency plane has focused on measuring the complexity of a given deterministic signal. In this paper, the properties of Re/spl acute/nyi entropy for random signals are examined. The upper and lower bounds on the expected value of Re/spl acute/nyi entropy are derived and ways of minimizing the entropy of time-frequency distributions by putting constraints on the time-frequency kernel are explored. It is proven that the quasi-Wigner kernel has the minimum entropy among all positive time-frequency kernels with finite time-support and correct marginals. A general class of minimum entropy kernels is presented. The performance of minimum entropy kernels in signal representation and component counting is also demonstrated.
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