This comprehensive resource provides readers with the tools necessary to perform analysis of various waveforms for use in radar systems. It provides information about how to produce synthetic aperture (SAR) images by giving a tomographic formulation and implementation for SAR imaging. Tracking filter fundamentals, and each parameter associated with the filter and how each affects tracking performance are also presented. Various radar cross section measurement techniques are covered, along with waveform selection analysis through the study of the ambiguity function for each particular waveform from simple linear frequency modulation (LFM) waveforms to more complicated coded waveforms.
The text includes the Python tool suite, which allows the reader to analyze and predict radar performance for various scenarios and applications. Also provided are MATLAB® scripts corresponding to the Python tools. The software includes a user-friendly graphical user interface (GUI) that provides visualizations of the concepts being covered. Users have full access to both the Python and MATLAB source code to modify for their application. With examples using the tool suite are given at the end of each chapter, this text gives readers a clear understanding of how important target scattering is in areas of target detection, target tracking, pulse integration, and target discrimination.
Introduction; Electromagnetic Fields and Waves; Antenna Systems; The Radar Range Equation; Radar Receivers; Target Detection; Radar Cross Section; Pulse Compression; Target Tracking; Tomographic Synthetic Aperture Radar; Countermeasures.
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Lee Andrew (Andy) Harrison
is a principal systems engineer for a radar systems and applications lab. He has been an instructor at Johns Hopkins University Applied Physics Lab, Naval Surface Warfare Center Crane Division, the University of Alabama Huntsville, and the University of Mississippi. He is a senior member of the IEEE and received his Ph.D. in electrical engineering from the University of Mississippi.