Scaled-Model Radar Cross-Section Measurement: The Influence of the Scattered Field under Gaussian Beam Illumination—A Theoretical Analysis
Author:
Ang Yi Xuan1, Lui Hoi-Shun12ORCID
Affiliation:
1. School of Electrical Engineering and Computer Science, The University of Queensland, St. Lucia, QLD 4072, Australia 2. School of Engineering, University of Tasmania, Sandy Bay, TAS 7005, Australia
Abstract
At microwave frequencies, radar cross-section (RCS) measurements are usually performed by placing the target in the far-field region of the antenna. The wavefront of the radiating field from the antenna can be approximated as planar, ensuring that the incident field and the power interact with the target independently of the antenna. However, for electrically large targets, the required distance becomes significant, posing challenges for implementation. Scaled-model RCS measurements offer an alternative solution. RCS measurements at terahertz and optical frequencies typically require a collimated beam as the source, where the intercepted power and RCS become dependent on the excitation. To address this dependency, researchers have proposed modifying the RCS definition to account for the intercepted power and to analytically formulate the scattering problem. However, such modifications require prior knowledge of the target’s geometry and material properties, which are often not readily available in practice. This also limits the study to only canonical targets. In this paper, we propose an alternative approach for modelling the intercepted power. The Gaussian beam is decomposed into a number of plane waves travelling to different directions using the theory of plane wave spectrum. The scattering problem is solved using the full-wave method of moment. Through theoretical proofs and numerical examples involving spheres and a non-canonical target, with a scaled-model aircraft, we demonstrate that the original RCS definition can serve as a good approximation for scaled measurements, provided that the beam waist is approximately four times the target’s dimensions. These findings provide valuable guidelines for radar engineers when performing scaled measurements using collimated beams. The results, which match those obtained from full-model measurements, enable us to predict the RCS of full-scale targets. This capability facilitates various target-related applications, such as target characterization, classification, detection, and even recognition.
Subject
Electrical and Electronic Engineering,Biochemistry,Instrumentation,Atomic and Molecular Physics, and Optics,Analytical Chemistry
Reference46 articles.
1. Sholnik, M. (1980). Introduction to Radar Systems, McGraw-Hill. [2nd ed.]. 2. Sullivan, R.J. (2004). Radar Foundations for Imaging and Advanced Concepts, Sci Tech Publishing. 3. Terahertz Inverse Synthetic Aperture Radar Imaging using Self-mixing Interferometry with a Quantum Cascade Laser;Lui;Opt. Lett.,2014 4. Fayazi, S.S., Lui, H.-S., and Yang, J. (2012, January 8–14). Microwave Imaging of Near-Field Objects Using SAR Algorithm. Proceedings of the 2012 IEEE International Symposium on Antennas and Propagation, Chicago, IL, USA. 5. Fayazi, S.S., Yang, J., and Lui, H.-S. (2013, January 8–11). UWB SAR Imaging of Near-Field Objects for Industrial Process Application. Proceedings of the 7th European Conference on Antennas and Propagation (EUCAP), Gothenburg, Sweden.
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