Abstract
Obtaining Radar Cross Section (RCS) data, one of the essential parameters for aircraft design, generally takes a lot of time and cost. Measurement time and accuracy of measurement results may be affected depending on the RCS measurement method and environment. When it comes to the RCS measurement method, the direct approach, which measures RCS on a real item, is more accurate than the indirect approach, which is implemented through simulation. However, in consideration of balancing accuracy, time and cost, the indirect approach is more generally used due to its efficiency. In this paper, in order to find an optimized method for more improved prediction results of indirect approach in the high-frequency band, three prediction methods are proposed: the Prony method, the Matrix pencil method (MPM) and the Rational Function method. It is confirmed that the RCS prediction result utilizing the Prony method in the high-frequency band has the minimum error in the case of Prony and MPM Methods, which have not been utilized for RCS prediction in the high-frequency band, and the Rational function method with currently applicable cases are employed. The prediction methods are, respectively, applied to a model based on three military aircraft models such as Jet Plane, F-117 and Transport Plane, and its simulation is performed under identical conditions. The original data and the extrapolated data obtained from the methods are compared at a certain angle for each model, and the errors between the extrapolated data are also compared in order to verify the efficacy of the prediction methods.
Funder
National Research Foundation of Korea
iitp
Reference37 articles.
1. Hu, C., Li, N., Chen, W., and Guo, S. (2020, January 27–31). Improving Precision of RCS Measurement Based on Spectral Extrapolation Method. Proceedings of the 2020 International Applied Computational Electromagnetics Society Symposium, Monterey, CA, USA.
2. Constructing a 3D model of a complex object from 2D images for the purpose of estimating its Radar Cross Section (RCS);J. Comput. Modeing,2017
3. Radar Cross Section Measurements (8–12 GHz) of Magnetic and Dielectric Microwave Absorbing Thin Sheets;Rev. Fısica Apl. Instrum.,2002
4. Öztürk, A.K. (2002). Implementation of Physical Theory of Diffraction for Radar Cross Section Calculations. [Master’s Thesis, Bilkent University].
5. Ray tracing with PO/PTD for RCS modeling of large complex objects;IEEE Trans. Antennas Propag.,2006
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