Abstract
We present a statistical framework for the fixed-frequency computational time- reversal imaging problem assuming point scatterers in a known background medium. Our statistical measurement models are based on the physical models of the multistatic response matrix, the dis- torted wave Born approximation and Foldy-Lax multiple scattering models. We develop maximum likelihood (ML) estimators of the locations and reflection parameters of the scatterers. Using a sim- plified single-scatterer model, we also propose a likelihood time-reversal imaging technique which is suboptimal but computationally ecient and can be used to initialize the ML estimation. We gener- alize the fixed-frequency likelihood imaging to multiple frequencies, and demonstrate its eectiveness in resolving the grating lobes of a sparse array. This enables to achieve high resolution by deploying a large-aperture array consisting of a small number of antennas while avoiding spatial ambiguity. Numerical and experimental examples are used to illustrate the applicability of our results.
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