References
- Niu B, Gu L, Gong C. Measure the performance of cooperative detection of sea-skimming target. 2012 IEEE 11th International Conference on signal processing; 2012, 3, 2262–2263.
- Gini F, Greco M. A suboptimum approach to adaptive coherent radar detection in compound-Gaussian clutter. IEEE Trans Aerosp Electron Syst. 1999;35(3):1095–1104. doi:10.1109/7.784077
- Conte E, Lops M. Asymptotically optimum radar detection in compound-Gaussian clutter. IEEE Trans Aerosp Electron Syst. 1995;31(2):617–625. doi:10.1109/7.381910
- Franceschetti G. Scattering from a fractal sea surface. Atti Fondazione Ronchi 1999;3-4:455–462.
- Franceschetti G, Migliaccio M, Riccio D. An electromagnetic fractal-based model for the study of the fading. Radio Sci Special Issue on EM Theory. 1996;31(6):1794–1759. doi:10.1029/96RS02811
- Winebrenner DP, Ishimaru A. Application of the phase perturbation technique to randomly rough surfaces. J Opt Soc Am. 1985;2(12):2285–2229. doi:10.1364/JOSAA.2.002285
- Holliday D. Resolution of a controversy surrounding the Kirchhoff approach and the small perturbation method in rough surface scattering theory. IEEE Trans Antennas Propag. 1987;35(1):120–122. doi:10.1109/TAP.1987.1143978
- Tian G, Tong C. Improved hybrid algorithm for composite scattering from multiple 3D objects above a 2D random dielectric rough surface. IEEE Access. 2021;9:4435–4436. doi:10.1109/ACCESS.2020.3048072
- Tian J, Tong J. A new approximate fast method of computing the scattering from multilayer rough surfaces based on the kirchhoff approximation. Radio Sci. 2017;52(2):186–190. doi:10.1002/2016RS006151
- Pinel N, Le Bastard C, Modeling of EM wave coherent scattering from a rough multilayered medium with the scalar kirchhoff approximation for GPR applications. IEEE Trans Geosci Remote Sens. 2020;58(3):1654–1190. doi:10.1109/TGRS.2019.2947356
- Franceschetti G, Iodice A, Migliaccio M, et al. Fractals and the small perturbation scattering model. Radio Sci. 1999;34(5):1043–1054. doi:10.1029/1999RS900053
- Broschat HL. The phase perturbation approximation for rough surface scattering from a Pierson-Moskowitz sea surface. IEEE Trans Geosci Remote Sensing. 1993;31(1):278–279. doi:10.1109/36.210467
- Afifi S, Dusséaux R. Scattering from 2-D perfect electromagnetic conductor rough surface: analysis with the small perturbation method and the small-slope approximation. IEEE Trans Antennas Propag. 2018;66(1):340–343. doi:10.1109/TAP.2017.2772027
- Xiaoyan X, Shuxi G. The forward-backward IPO algorithm for calculating open-ended cavities. Space Electronic Technol. 2008;(1):72–75.
- Kucharski AA. The FIT-MoM hybrid method for analysis of electromagnetic scattering by dielectric bodies of revolution. IEEE Trans Antennas Propag. 2018;66(3):1384–1388.
- Ozgun O, Kuzuoglu M. A domain decomposition finite-element method for modeling electromagnetic scattering from rough sea surfaces with emphasis on near-forward scattering. IEEE Trans Antennas Propag. 2019;67(1):335–345. doi:10.1109/TAP.2018.2874766
- Smith DR, Sean B, Simpson JJ. FDTD modeling of scattered ultra-low frequency electromagnetic waves from objects submerged in the ocean. IEEE Trans Antenn Propag. 2019;67(4):2534–2535.
- Iodice A. Forward-backward method for scattering from dielectric rough surface. IEEE Trans Antenn Propag. 2002;50(7):902–910.
- Liang Y, Guo L. The EPILE combined with the generalized-FBM for analyzing the scattering from targets above and on a rough surface. IEEE Antenn Wireless Propag Lett. 2010;9:809–813. doi:10.1109/LAWP.2010.2068270
- Li Z, Yaqiu J. Bistatic scattering from a fractal dynamic rough sea surface with a ship presence at low grazing angle incidence using the GFBM/SAA. Microwave Opt Techn Lett. 2001;31(2):146–151.
- Kubicke G, Bourlier C, Saillard J. Scattering by an object above a randomly rough surface from a fast numerical method: extended PILE method combined with FB-SA. Waves Random Complex Media. 2008;18(3):495–519. doi:10.1080/17455030802087057
- Ye H, Jin Y. Fast iterative approach to difference scattering from the target above a rough surface. IEEE Trans Geosci Remote Sens. 2006;44(l):108–115.
- Ye H. A hybrid KA-MOM algorithm for computation of scattering from a 3D PEC target above a dielectric rough surface. Radio Sci. 2008;43(3):3008–3018.
- Pham-Xuan V, Trinh D. Novel iterative algorithm for the solution of electromagnetic scattering from layered random rough surfaces. IEEE Trans Antenn Propag. 2018;66(7):3810–3811. doi:10.1109/TAP.2018.2835525
- Zhang M, Zhao Y. Reliable approach for composite scattering calculation from ship over a sea surface based on FBAM and GO-PO models. IEEE Trans Antenn Propag. 2017;65(2):775–780. doi:10.1109/TAP.2016.2633066
- Yunhua W, Lixin G, Zhensen W. The application of an improved 2D fractal model for electromagnetic scattering from the sea surface. Acta Phys Sin. 2006;55(10):5193–5195.
- Berizzi F, Enzo DM. Fractal analysis of the signal scattered from the sea surface. IEEE Trans Antenn Propag. 1999;47(2):325–327.
- Shay NR, Weile DS. Balanced electric-magnetic absorber green’s function method for MoM matrix thinning and conditioning. IEEE Trans Antenn Propag. 2018;66(6):29–327.
- Guan B, Zhang JF. Electromagnetic scattering from objects above a rough surface using the method of moments with half-space green’s function. IEEE Trans Geosci Remote Sens. 2009;47(10):3399–3405. doi:10.1109/TGRS.2009.2022169
- Guerin CA, Soriano G, Chapron B. The weighted curvature approximation in scattering from sea surfaces. Waves Random Complex Media. 2010;20(3):364–384. doi:10.1080/17455030903563824
- Migliaccio M, Reppucci A. A review of sea wind vector retrieval by means of microwave remote sensing. Proceedings of the European microwave association, 2, 136–140, 2006.
- Guissard A, Baufays C, Sobieski P. Sea surface description requirements for electromagnetic scattering calculations. J Geophys Res. 1986;91(C2):2477–2492.