Title :
Maximal Invariants and Performance of Some Invariant Hypothesis Tests for an Adaptive Detection Problem
Author_Institution :
Air Force Res. Lab., Wright-Patterson Air Force Base, Dayton, OH, USA
Abstract :
Maximal invariants for adaptive detection of a signal in unknown interference from multiple observations is derived. Given coherent samples from P sets of observations, it is shown that a maximal invariant statistic for the detection problem is a 2P × 1-dimensional vector comprising the eigenvalues of two Hermitian positive definite matrices obtained from the data set. Two invariant detectors, well known for P=1, are generalized for the case of multiple observations and closed form expressions for the probability of detection and probability of false alarm are derived along with the distributions of the signal-to-interference-plus-noise loss factors. Several novel invariant detectors are constructed from the maximal invariants and the receiver operating characteristics of the detectors compared.
Keywords :
Hermitian matrices; eigenvalues and eigenfunctions; probability; signal detection; statistical testing; vectors; 2P × 1D vector; Hermitian positive definite matrices; adaptive signal detection problem; detection probability; eigenvalues; false alarm probability; generalized likelihood ratio test; invariant detectors; invariant hypothesis tests; maximal invariant statistic; signal-to-interference-plus-noise loss factor distributions; unknown interference; Adaptive Matched Filter Test (AMFT); Generalized Likelihood Ratio Test (GLRT); Invariant hypothesis tests for multiple observations; Maximal invariants; Probability of detection; adaptive detection; loss factor; signal-to-interference-plus-noise ratio (SINR);
Journal_Title :
Signal Processing, IEEE Transactions on
DOI :
10.1109/TSP.2013.2260332
