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| Citation: | Liu Xia, Han Yanfei, Li Hai Lu, Xiaoguang, Wu Renbiao. Polarization Characteristics Simulation of Airborne Weather Radar Rainfall Target Based on Numerical Weather Prediction[J]. Journal of Radars, 2016, 5(2): 190-199. doi: 10.12000/JR16048
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Polarization Characteristics Simulation of Airborne Weather Radar Rainfall Target Based on Numerical Weather Prediction
DOI: 10.12000/JR16048
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Abstract
Meteorological target simulation using polarization information is the foundation of the theoretical research and design application of dual-polarization Doppler weather radar. Currently, the theoretical research of airborne dual-polarization weather radar is in the development stage. To provide high-fidelity simulation data required for airborne dual-polarization weather radar detection technology, in this study, a simulation method of the polarization characteristics of rainfall determined using airborne weather radar based on numerical weather prediction is proposed. The numerical weather prediction model is used to realize the modeling and simulation of meteorological scenarios and provide information on meteorological parameters such as temperature, particle concentration, and mixing ratio of rainfall. In the analysis of the microphysical properties of rainfall, the electromagnetic scattering matrix is calculated and the simulation of the polarization characteristics of rainfall is achieved. The simulation results for different microphysical property parameters have led to the establishment of a high-fidelity rainfall model and demonstrated (via comparison with the real radar data) that the simulation of polarization characteristics using the proposed method is effective and reliable. -
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References
[1] Lupidi A, Moscardini C, Garzelli A, et al.. Polarimetry applied to avionic weather radar: improvement on meteorological phenomena detection and classification[C]. 2011 Tyrrhenian International Workshop on Digital Communications-Enhanced Surveillance of Aircraft and Vehicles (TIWDC/ESAV), Capri, 2011: 7377.[2] Woodell D L, West J B, Elsallal W A, et al.. Weather radar system and method using dual polarization antenna[P]. US, 008098189B1, 2012.[3] Bunch B P and Christianson P. System and method to identify regions of airspace having ice crystals using an onboard weather radar system[P]. US, 20130234884A1, 2013.[4] Khatwa R and Mathan S. Enhanced alerting of characteristic weather hazards[P]. US, 008395541B2, 2013.[5] Ratan K and Dave P. Methods and systems for presenting weather hazard information on an in-trial procedures display[P]. EP, 2354805A1, 2011.[6] Waterman P C. Matrix formulation of electromagnetic scattering[J]. Proceedings of the IEEE, 1965, 53(8): 805812.[7] Yee K S. Numerical solution of initial boundary value problems involving Maxwell's equations in isotropic media[J]. IEEE Transactions on Antennas and Propagaction,[8] 1966, 14(3): 302307.[9] 许丽生, 陈洪滨, 丁继烈, 等. 非球形粒子光散射计算研究的进展综述[J]. 地球科学进展, 2014, 29(8): 903912.[10] Xu Li-sheng, Chen Hong-bin, Ding Ji-lie, et al.. Summary of non-spherical particles in progress calculation of light scattering[J]. Advances in Earth Science, 2014, 29(8): 903912.[11] Li Z Z, Zhang Y, Zhang G, et al.. A microphysics-based simulator for advanced airborne weather radar development[J]. IEEE Transactions on Geoscience and Remote Sensing, 2011, 49(4): 13561373.[12] Lupidi A, Moscardini C, Berizzi F, et al.. Simulation of X-band polarimetric weather radar returns based on the Weather Research and Forecast Model[C]. 2011 IEEE Radar Conference (RADAR), Kansas, 2011: 734739.[13] Augros C, Caumont O, Ducrocq V, et al.. Development and validation of a full polarimetric radar simulator[C]. 36 th Conference on Radar Meteorology, Breckenridge, 2013: 387.[14] Lischi S, Lupidi A, Martorella M, et al.. Advanced polarimetric Doppler weather radar simulator[C]. IEEE 2014 15th International Radar Symposium (IRS), Gdansk, 2014: 16.[15] Andsager K, Beard K V, and Laird N F. Laboratory measurements of axis ratios for large raindrops[J]. Journal of the Atmospheric Sciences, 1999, 56(15): 26732683.[16] Zhang G, Vivekanandan J, and Brandes E. A method for estimating rain rate and drop size distribution from polarimetric radar measurements[J]. IEEE Transactions on Geoscience and Remote Sensing, 2001, 39(4): 830841.[17] Keenan T D, Carey L D, Zrnic D S, et al.. Sensitivity of 5-cm wavelength polarimetric radar variables to raindrop axial ratio and drop size distribution[J]. Journal of Applied Meteorology, 2001, 40(3): 526545.[18] Brandes E A, Zhang G, and Vivekanandan J. Experiments in rainfall estimation with a polarimetric radar in a subtropical environment[J]. Journal of Applied Meteorology, 2002, 41(6): 674685.[19] Thurai M, Huang G J, Bringi V N, et al.. Drop shapes, model comparisons, and calculations of polarimetric radar parameters in rain[J]. Journal of Atmospheric and Oceanic Technology, 2007, 24(6): 10191032.[20] Leinonen J. High-level interface to T-matrix scattering calculations: architecture, capabilities and limitations[J]. Optics Eexpress, 2014, 22(2): 16551660.[21] Bringi V N and Chandrasekar V. Polarimetric Doppler Weather Radar: Principles and Applications[M]. Cambridge University Press, 2001: 161210.[22] Jameson A R and Mueller E A. Estimation of propagation-differential phase shift from sequential orthogonal linear polarization radar measurements[J]. Journal of Atmospheric and Oceanic Technology, 1985, 2(2): 133137. -
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