References
- Chauveau J, de Beaucoudrey N, Saillard J. Selection of contributing natural poles for the characterization of perfectly conducting targets in resonance region. IEEE Trans. Antennas Propag. 2007;55:2610–2617.
- Sarrazin F, Chauveau J, Pouliguen P, Potier P, Sharaiha A. Accuracy of singularity expansion method in time and frequency domains to characterize antennas in presence of noise. IEEE Trans. Antennas Propag. 2014;62:1261–1269.
- Lee WJ, Sarkar TK, Moon HS, Brown L. Detection and identification using natural frequency of the perfect electrically conducting (PEC) sphere in the frequency and time domain. In: IEEE International Symposium on Antennas and Propagation. Spokane, WA; 2011. p. 2334–2337.
- Lee WJ, Sarkar TK, Moon HS, Salazar-Palma M. Identification of multiple objects using their natural resonant frequencies. IEEE Antennas Wirel. Propag. Lett. 2013;12:54–57.
- Chen W, Shuley N. Robust target identification using a modified generalized likelihood ratio test. IEEE Trans. Antennas Propag. 2014;62:264–273.
- Lee J-H, Jeong S-H, Park G-S, Lee Y-C, Cho S-W. Performance analysis of natural frequency-based multiple radar target recognition for multiple-input–multiple-output radar application. IET Radar, Sonar Navigat. 2014;8:457–464.
- Lee J-H, Moon H-J, Jeong S-H. Numerically efficient determination of the optimal threshold in natural frequency-based radar target recognition. IEEE Trans. Antennas Propag. 2014;62:5889–5894.
- Mooney JE, Ding Z, Riggs LS. Performance analysis of a GLRT in late-time radar target detection. Prog. Electromagn. Res. 1999;24:77–96.
- Lee J-H, Jeong S-H. Recursive implementation of natural frequency-based radar detection using the LRT scheme. Prog. Electromagn. Res. 2013;137:219–247.
- Baum CE. On the singularity expansion method for the solution of electromagnetic interaction problems. Air Force Weapons Lab, Interaction Note 88; 1971 Dec; Albuquerque.
- Burden RL, Faires JD. Numerical analysis. Boston: Cengage Learning; 2010.