Research on RCS measurement of ship targets based on conventional radars

[1] Chandran A R, Mathew T, Aanandan C K, et al., Frequency Tunable Metallo-Dielectric Structure for Back Scattering Reduction. Electronic Letters, 2004, 40(20), 1245–1246. ChandranA R MathewT AanandanC K Frequency Tunable Metallo-Dielectric Structure for Back Scattering Reduction Electronic Letters 2004 40 20 1245 1246 Search in Google Scholar

[2] Li Ya-Ping, Qi Meng, Li Xi-Min, et al., A SBR-IEM Hybrid Method for Solution of Electrically Large Size and Composite Electromagnetic Scattering from Soil/Sea Surface. Journal of Naval University of Engineering, 2016, 28(4), 85–91. LiYa-Ping QiMeng LiXi-Min A SBR-IEM Hybrid Method for Solution of Electrically Large Size and Composite Electromagnetic Scattering from Soil/Sea Surface Journal of Naval University of Engineering 2016 28 4 85 91 Search in Google Scholar

[3] Peng Peng, Li Xin, A Facet-Based Simulation of the Multipath Effect on the EM Scattering and Doppler Spectrum of a Low-Flying Target at Maritime Scene. IEEE Geoscience & Remote Sensing Letters, 2018, 15(10), 1495–1499. PengPeng LiXin A Facet-Based Simulation of the Multipath Effect on the EM Scattering and Doppler Spectrum of a Low-Flying Target at Maritime Scene IEEE Geoscience & Remote Sensing Letters 2018 15 10 1495 1499 Search in Google Scholar

[4] Knott E F, Shaeffer J F, Tuley M T, Radar Cross Section (2nd ed.). Scitech Publishing Inc., Raleigh, NC, 2004. KnottE F ShaefferJ F TuleyM T Radar Cross Section 2nd ed. Scitech Publishing Inc. Raleigh, NC 2004 Search in Google Scholar

[5] Cai Hong-Hao, Wang Xiao-Bing, Xue Zheng-Guo, et al., Sea Surface Laboratory Analog and Electromagnetic Scattering Measurement Technology. Guidance and Fuze, 2009, 30(2), 1–6. CaiHong-Hao WangXiao-Bing XueZheng-Guo Sea Surface Laboratory Analog and Electromagnetic Scattering Measurement Technology Guidance and Fuze 2009 30 2 1 6 Search in Google Scholar

[6] Smith J R, Russell S J, Brown B E, et al., Electromagnetic Forward-Scattering Measurements Over a Known, Controlled Sea Surface at Grazing. IEEE Transactions on Geoscience and Remote Sensing, 2004, 42, 1197–1207. SmithJ R RussellS J BrownB E Electromagnetic Forward-Scattering Measurements Over a Known, Controlled Sea Surface at Grazing IEEE Transactions on Geoscience and Remote Sensing 2004 42 1197 1207 Search in Google Scholar

[7] Giovanangeli J P, Bliven L F, Calve O L, A Wind-Wave Tank Study of the Azimuthal Response of a Ka- Band Scatterometer. IEEE Transactions on Geoscience and Romote Sensing, 1991, 29(1), 143–148. GiovanangeliJ P BlivenL F CalveO L A Wind-Wave Tank Study of the Azimuthal Response of a Ka- Band Scatterometer IEEE Transactions on Geoscience and Romote Sensing 1991 29 1 143 148 Search in Google Scholar

[8] Wu Nan, Chen Jiong, Discussion on the RCS Simulation Test of Naval Ships on Water Surface. Chinese Journal of Ship Research, 2012, 7(5), 103–106, 118. WuNan ChenJiong Discussion on the RCS Simulation Test of Naval Ships on Water Surface Chinese Journal of Ship Research 2012 7 5 103 106 118 Search in Google Scholar

[9] Li X Z, Lu Y G, Xu Z M, et al., Radar Cross Section Measurement and Imaging RRelated to Ship Target in the Sea Environment. Procedia Computer Science, 2019, 147, 550–555. LiX Z LuY G XuZ M Radar Cross Section Measurement and Imaging RRelated to Ship Target in the Sea Environment Procedia Computer Science 2019 147 550 555 Search in Google Scholar

[10] Trizna D, Xu L, Target Classification and Remote Sensing of Ocean Current Shear Using a Dual-Use Multifrequency HF Radar. IEEE Journal of Oceanic Engineering, 2007, 31(4), 904–918. TriznaD XuL Target Classification and Remote Sensing of Ocean Current Shear Using a Dual-Use Multifrequency HF Radar IEEE Journal of Oceanic Engineering 2007 31 4 904 918 Search in Google Scholar

[11] Dzvonkovskaya A, Rohling H, Cargo Ship RCS Estimation based on HF Radar Measurements. In 4th Microwave and Radar Week MRW-2010-11th International Radar Symposium, IRS 2010-Conference Proceedings, 2010, 160–163. DzvonkovskayaA RohlingH Cargo Ship RCS Estimation based on HF Radar Measurements In 4th Microwave and Radar Week MRW-2010-11th International Radar Symposium, IRS 2010-Conference Proceedings 2010 160 163 Search in Google Scholar

[12] Lu Y, Xu Z, Li X, et al., Research on Ship Target Radar Scattering Characteric Measurement in Sea Battlefield. Procedia Computer Science, 2020, 174, 84–88. LuY XuZ LiX Research on Ship Target Radar Scattering Characteric Measurement in Sea Battlefield Procedia Computer Science 2020 174 84 88 Search in Google Scholar

[13] Uchiyama K, Motomura T, Kajiwara A, RCS of Road Objects are Measured on 79GHz UWB Radar for Vehicle-Location Estimation [J]. IEEJ Transactions on Electronics Information & Systems, 2018, 138(2), 106–111. UchiyamaK MotomuraT KajiwaraA RCS of Road Objects are Measured on 79GHz UWB Radar for Vehicle-Location Estimation [J] IEEJ Transactions on Electronics Information & Systems 2018 138 2 106 111 Search in Google Scholar

[14] Lainer M, Ventura J, Schauwecker Z, et al., Insights into Wind Turbine Reflectivity and Radar Cross-Section (RCS) and Their Variability using X-band Weather Radar Observations [J]. Atmospheric Measurement Techniques, 2021, 14(5), 3541–3560. LainerM VenturaJ SchauweckerZ Insights into Wind Turbine Reflectivity and Radar Cross-Section (RCS) and Their Variability using X-band Weather Radar Observations [J] Atmospheric Measurement Techniques 2021 14 5 3541 3560 Search in Google Scholar

[15] Pavan G, Wasserzier C, Galati G, Multipath Effect on Radar Cross Section Measurements in Natural Environment and Related Correction. 2019 20th International Radar Symposium (IRS). IEEE, 2019, 1–6. PavanG WasserzierC GalatiG Multipath Effect on Radar Cross Section Measurements in Natural Environment and Related Correction 2019 20th International Radar Symposium (IRS) IEEE 2019 1 6 Search in Google Scholar

[16] Xu Xiao-Jian, New Techniques for Radar Target Scattering Signature Measurement and Processing. Beijing: National Defense Industry Press, 2017, 33–49. XuXiao-Jian New Techniques for Radar Target Scattering Signature Measurement and Processing Beijing National Defense Industry Press 2017 33 49 Search in Google Scholar

[17] Chen Yong, Dong Chun-Zhu, Wang Chao, et al., Fast Algorithm based on HPP/PO for Calculating Coupling EM Scattering from Ship Over Sea Surface. Systems Engineering and Electronics, 2008, 30(4), 589–592. ChenYong DongChun-Zhu WangChao Fast Algorithm based on HPP/PO for Calculating Coupling EM Scattering from Ship Over Sea Surface Systems Engineering and Electronics 2008 30 4 589 592 Search in Google Scholar

[18] Zhu Hong, Pan Yujian, Wu Weiwei, et al., Effects of Compound K-distributed Sea Clutter on Angle Measurement of Wideband Monopulse Radar. Mathematical Problems in Engineering: Theory, Methods and Applications, 2017, 1–19. ZhuHong PanYujian WuWeiwei Effects of Compound K-distributed Sea Clutter on Angle Measurement of Wideband Monopulse Radar Mathematical Problems in Engineering: Theory, Methods and Applications 2017 1 19 Search in Google Scholar

[19] Liu Liang. Study on Radar Angle Measurement Methods. Xidian University, 2013. LiuLiang Study on Radar Angle Measurement Methods Xidian University 2013 Search in Google Scholar

[20] Skolnik M. Introduction to Radar Systems (3rd ed.). New York: Mc Graw-Hill, 2001. SkolnikM Introduction to Radar Systems 3rd ed. New York Mc Graw-Hill 2001 Search in Google Scholar

[21] Legault S R, An Overview of the DRDC Ottawa RCS Measurement System. 2004 10th International Symposium on Antenna Technology and Applied Electromagnetics and URSI Conference. IEEE, 2004, 1–3. LegaultS R An Overview of the DRDC Ottawa RCS Measurement System 2004 10th International Symposium on Antenna Technology and Applied Electromagnetics and URSI Conference IEEE 2004 1 3 Search in Google Scholar