Keywords: wavelet transform, computer modeling, super-resolution, target search, simulation model
Conducting numerical experiments to evaluate detection characteristics with the aid of a mathematical radar model
UDC 51-74
DOI: 10.26102/2310-6018/2022.36.1.016
The task of detecting and observing targets has always been relevant. One of the most important objectives of radar development is to improve target recognition. There are two ways to achieve this – firstly, the installation of more powerful radar systems, which is very expensive and hard to implement under the conditions of limited space, for example, on airplanes; secondly, the quality of the received signal can be enhanced with the aid of mathematical methods, which allows to considerably save on setting up additional equipment. One of the main problems of recognition is the fact that the number and angular location of targets can be difficult to determine from the signal received by the radar system. This problem can be addressed by employing a wavelet transform. This method enables to overcome the Rayleigh criterion, that makes it possible to obtain an angular super-resolution (to surmount the classical diffraction limit of the spatial resolution of an image focused by a lens that is less than half the radiation wavelength). The article uses a mathematical model of a radar station to present the results of numerical experiments to achieve super-resolution by means of algebraic methods at a significant noise level. We examine the suitability of utilizing different types of wavelets, namely the Haar wavelet, the symmetric Haar wavelet, and the Wave wavelet.
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Keywords: wavelet transform, computer modeling, super-resolution, target search, simulation model
For citation: Shchukin A.A., Pavlov A.E. Conducting numerical experiments to evaluate detection characteristics with the aid of a mathematical radar model. Modeling, Optimization and Information Technology. 2022;10(1). URL: https://moitvivt.ru/ru/journal/pdf?id=968 DOI: 10.26102/2310-6018/2022.36.1.016 (In Russ).
Received 23.12.2021
Revised 31.01.2022
Accepted 18.02.2022
Published 31.03.2022