Abstract

The cluster structure of the distance profile of an anthropogenic 3D object in a monostatic laser location system is investigated using a digital simulation method. A physically valid method for decomposing the pulsed reflectance profile of a target into continuous and discontinuous components is proposed. A real-time model for the structural components of the temporal profile of the pulsed reflectance profile of the object is realized based on a finite combination of standard pulses. The results of the identification of the parameters of a finite combination of standard pulses using a modified expectation-maximization algorithm are presented.

© 2020 Optical Society of America

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