Study of Methods for Three-Dimensional Multiple-Radar Reflectivity Mosaics 被引量：5

Study of Methods for Three-Dimensional Multiple-Radar Reflectivity Mosaics

导出

摘要 This paper investigated several approaches to remapping and combining multiple-radar reflectivity fields onto a unified 3D Cartesian grid with high spatial and temporal resolutions, and analyzed systematic observation differences among multiple radars. The remapping approaches were evaluated by inspecting the spatial consistency of the reflectivity fields on vertical and horizontal cross sections on the equidistant line of radars, and the intensity change of 1-h accumulated precipitation before and after interpolation. The combining approaches were evaluated by continuity examination. The results show that for remapping schemes, the vertical interpolation with nearest neighbor on the range-azimuth plane is the most reasonable scheme that provides consecutive reflectivity fields and retains the high-resolution structure comparable to that of the raw data; for multiple-radar data mosaics, the distance-exponential-weighted mean scheme provides spatially consistent reflectivity mosaics. The mosaics can mitigate various problems caused by the radar beam geometry such as the cone of silence. This paper investigated several approaches to remapping and combining multiple-radar reflectivity fields onto a unified 3D Cartesian grid with high spatial and temporal resolutions, and analyzed systematic observation differences among multiple radars. The remapping approaches were evaluated by inspecting the spatial consistency of the reflectivity fields on vertical and horizontal cross sections on the equidistant line of radars, and the intensity change of 1-h accumulated precipitation before and after interpolation. The combining approaches were evaluated by continuity examination. The results show that for remapping schemes, the vertical interpolation with nearest neighbor on the range-azimuth plane is the most reasonable scheme that provides consecutive reflectivity fields and retains the high-resolution structure comparable to that of the raw data; for multiple-radar data mosaics, the distance-exponential-weighted mean scheme provides spatially consistent reflectivity mosaics. The mosaics can mitigate various problems caused by the radar beam geometry such as the cone of silence.

作者肖艳姣刘黎平石燕

机构地区 Institute of Heavy Rain State Key Laboratory of Severe Weather

出处《Acta meteorologica Sinica》 SCIE 2008年第3期351-361,共11页

基金 the National Major Basic Researched Programe of China(2004CB418305) the National Natural Foundation of China(40375008)

关键词 REFLECTIVITY 3D multiple-radar mosaics interpolation method reflectivity, 3D multiple-radar mosaics, interpolation method

分类号 P412.25 [天文地球—大气科学及气象学]

引文网络
相关文献

参考文献13

1孙建华,张小玲,齐琳琳,张高英,赵思雄,陶诗言.2002年6月20～24日梅雨锋中尺度对流系统发生发展分析[J].气象学报,2004,62(4):423-438. 被引量：54
2郑媛媛,俞小鼎,方翀,鲍文中,谢亦峰,周昆,陆大春,刘勇.一次典型超级单体风暴的多普勒天气雷达观测分析[J].气象学报,2004,62(3):317-328. 被引量：299
3万玉发,陈少林,罗建国.数字化天气雷达联网拼图与卫星云图综合实时处理系统[J].气象,1994,20(8):26-31. 被引量：9
4Askelson,M.A.,J-P.Aubagnac,,J.M.Straka.An adaptation of the Barnes filter applied to the objective analysis of radar data[].Monthly Weather Review.2000
5Carrie,L.,Zhang J,K.Howard.Four- dimensional dynamic radar mosaic[].The th Con- ference on AviationRangeand Aerospace Mete- orology.2004
6Doviak,R.J.,D.S.Zrnic.Doppler Radar and Weather Observations[]..1993
7Droegemeie,K.K.Toward a science of storm-scale prediction[].th Confon Severe Local Storms.1990
8Fulton,R.WSR-88D polar to HRAP mapping[]..1998
9Gao J,Xue M,Shapiro A,Droegemeier K.K.A variational method for the analysis of three- dimensional wind fields from two Doppler radars[].Monthly Weather Review.1999
10Serafin,R.J,Wilson J.W.Operational weather radar in the United States:Progress and opportunity[].Bulletin of the American Meteorological Society.2000

二级参考文献45

1冯斌贤,罗建国,万定祥.武汉天气信息分发服务系统的特性和应用[J].气象,1994,20(8):32-36. 被引量：1
2石定朴,朱文琴,王洪庆,陶祖钰,顾雷.中尺度对流系统红外云图云顶黑体温度的分析[J].气象学报,1996,54(5):600-611. 被引量：56
3[1]Browning KA. Cellular structures of convective storms. Meteor Mag, 1962, 91:341～350
4[2]Browning K A, Ludlam F H. Airflow in convective storms. Quart J Roy Meteor Soc, 1962, 88:117～135
5[3]Browning K A, Ludlam F H, Macklin W C. The density and structure of hailstones. Quart J Roy Meteor Soc, 1963, 89:75～84
6[4]Browning K A. The growth of large hail within a steady updraught. Quart J Roy Meteor Soc, 1963, 89:490～506
7[5]Browning K A, Donaldson R J. Airflow and structure of a tornadic storm. J Atmos Sci, 1963, 20:533～545
8[6]Browning K A. Airflow and precipitation trajectories within severe local storms which travel to the right of the winds. J Atmos Sci, 1964, 21:634～639
9[7]Browning K A. The evolution of tornadic storms. J Atmos Sci, 1965, 22:664668
10[8]Browning K A, Foote G B. Airflow and hail growth in supercell storms and some implication for hail suppression. Quart J Roy Meteor Soc, 1976,102:499～533

共引文献357

1刘嘉慧敏,郑然,梁绵,张煦庭,娄盼星.2018年陕西商洛一次罕见强雹暴环境条件及雷达特征分析[J].陕西气象,2020(2):1-11. 被引量：10
2居圆圆,徐昕,唐滢.华南“4.21”弓状回波的γ-中尺度涡旋雷达观测分析[J].南京大学学报（自然科学版）,2022,58(5):780-788. 被引量：2
3冯爽,娄小芬,陈列.2019年浙江省一次春季强对流天气及雷达回波特征分析[J].科技通报,2020(11):8-15. 被引量：1
4张玉,王程昱.桃仙机场一次冰雹天气过程诊断分析[J].大众标准化,2022(6):98-100. 被引量：1
5吴书君,王凤娇,王立静.一次多单体风暴的雷达回波特征分析[J].山东气象,2006,26(2):8-11.
6罗清,周和生.云贵高原对流回波的速度特征及其发展趋势[J].高原气象,2004,23(z1):124-129. 被引量：4
7赵俊荣,晋绿生,郭金强,杨景辉.天山北坡中部一次强对流天气中小尺度系统特征分析[J].高原气象,2009,28(5):1044-1050. 被引量：15
8张俊岚,史红政,陈颖,杨柳,曹立新.一次雹暴天气的CINRAD/CC的观测资料分析[J].沙漠与绿洲气象,2005(z1):59-61. 被引量：1
9刁秀广,王月兰,朱君鉴.Analysis of Supercell Storm Structure and Mesocyclone Parameters[J].Meteorological and Environmental Research,2010,1(4):61-64.
10俞小鼎.强对流天气的多普勒天气雷达探测和预警[J].气象科技进展,2011,1(3):31-41. 被引量：90

同被引文献104

1刘继东,胡新波,刘士军,陈峰,赵培林,孔德胤.解密713C天气雷达平显dBZ数据文件内部格式[J].科技资讯,2008,6(7). 被引量：3
2杨军,许健民,董超华.风云气象卫星40年:国际背景下的发展足迹[J].气象科技进展,2011,1(1):6-13. 被引量：25
3郑永光,陈炯.A CLIMATOLOGY OF DEEP CONVECTION OVER SOUTH CHINA AND THE ADJACENT WATERS DURING SUMMER[J].Journal of Tropical Meteorology,2013,19(1):1-15. 被引量：5
4曹渐华,刘熙明,李国平,邹海波.鄱阳湖地区湖陆风特征及成因分析[J].高原气象,2015,34(2):426-435. 被引量：21
5郑永光,薛明,陶祖钰.美国NOAA试验平台和春季预报试验概要[J].气象,2015,41(5):598-612. 被引量：10
6郑媛媛,俞小鼎,方翀,鲍文中,谢亦峰,周昆,陆大春,刘勇.一次典型超级单体风暴的多普勒天气雷达观测分析[J].气象学报,2004,62(3):317-328. 被引量：299
7王笑芳,丁一汇.北京地区强对流天气短时预报方法的研究[J].大气科学,1994,18(2):173-183. 被引量：77
8万军山,吕丹苗,刘福基.夏季鄱阳湖水体温度场及其气温效应[J].应用气象学报,1994,5(3):374-379. 被引量：14
9魏文秀,赵亚民.中国龙卷风的若干特征[J].气象,1995,21(5):36-40. 被引量：94
10刘黎平,莫月琴,沙雪松,苏涛.C波段双多基地多普勒雷达资料处理和三维变分风场反演方法研究[J].大气科学,2005,29(6):986-996. 被引量：20

引证文献5

1于雪涛,余志伟,芮小平,奚砚涛,董前林.基于GIS的内蒙古中部地区多源雷达回波拼图[J].科技导报,2011,29(28):37-42. 被引量：2
2Haibo ZOU,Shuwen ZHANG,Xudong LIANG,Xueting YI.Improved Algorithms for Removing Isolated Non-Meteorological Echoes and Ground Clutters in CINRAD[J].Journal of Meteorological Research,2018,32(4):584-597. 被引量：7
3Haibo ZOU,Shuwen ZHANG,Yanan LIU,Weidong ZHANG,Xixi YANG.Analysis of a Convective Storm Crossing Poyang Lake in China[J].Journal of Meteorological Research,2020,34(3):529-545. 被引量：6
4Xiaoling ZHANG,Jianhua SUN,Yongguang ZHENG,Yuanchun ZHANG,Ruoyun MA,Xinlin YANG,Kanghui ZHOU,Xuqing HAN.Progress in Severe Convective Weather Forecasting in China since the 1950s[J].Journal of Meteorological Research,2020,34(4):699-719. 被引量：5
5Haibo ZOU,Shanshan WU,Jiusheng SHAN.Sensitivity of Lake-Effect Convection to the Lake Surface Temperature over Poyang Lake in China[J].Journal of Meteorological Research,2022,36(2):342-359.

二级引证文献19

1朱雷平,朱黎明,于雪涛,江皖,陈卫林.基于CINRAD/CB雷达基数据的反射率因子地学可视化研究[J].科技导报,2014,32(19):43-47. 被引量：2
2李辉,牛睿平,符伟杰.基于GIS的X波段面雨量雷达数据提取研究[J].地理空间信息,2018,16(2):12-13.
3易雪婷,傅文兵,邹海波,贺志明,李蕾.基于江西省雷达回波拼图的TREC方法应用及效果检验[J].气象与减灾研究,2019,42(1):16-23. 被引量：2
4邹海波,章毅之,解震华,李蕾.COTREC方法在江西地区的应用和检验[J].气象与减灾研究,2019,42(2):105-112. 被引量：3
5刘雅楠,邹海波,吴琼.基于FY-2G产品的江西省总云量最小二乘法建模与分析[J].气象与环境学报,2020,36(2):105-111. 被引量：4
6Haibo ZOU,Shuwen ZHANG,Yanan LIU,Weidong ZHANG,Xixi YANG.Analysis of a Convective Storm Crossing Poyang Lake in China[J].Journal of Meteorological Research,2020,34(3):529-545. 被引量：6
7邹海波,张述文,张卫东,汪兰.WRF模式陆面过程和边界层方案对鄱阳湖湖效应降水模拟的影响[J].兰州大学学报（自然科学版）,2021,57(1):72-81. 被引量：3
8Yan ZHANG,Zhong JI,Bing XUE,Ping WANG.A Novel Fusion Forecast Model for Hail Weather in Plateau Areas Based on Machine Learning[J].Journal of Meteorological Research,2021,35(5):896-910.
9Anyuan XIONG,Na LIU,Yujia LIU,Shulin ZHI,Linlin WU,Yongjian XIN,Yan SHI,Yunjian ZHAN.QpefBD:A Benchmark Dataset Applied to Machine Learning for Minute-Scale Quantitative Precipitation Estimation and Forecasting[J].Journal of Meteorological Research,2022,36(1):93-106. 被引量：1
10Haibo ZOU,Shanshan WU,Jiusheng SHAN.Sensitivity of Lake-Effect Convection to the Lake Surface Temperature over Poyang Lake in China[J].Journal of Meteorological Research,2022,36(2):342-359.

1肖登攀,陶福禄,Moiwo Juana P.全球变化下地表反照率研究进展[J].地球科学进展,2011,26(11):1217-1224. 被引量：60
2林之森.驱走卷云给地球降温[J].大科技（科学之谜）（A）,2014(10):22-22.
3小峰.六月谈雪——雪花镶嵌的秘密[J].时尚时间,2010(6):64-67.
4王亮,王绪本,李正文.地质雷达方法检测隧道衬砌质量研究[J].物探化探计算技术,2007,29(6):516-519. 被引量：8
5Zhiwei HE,Qinghong ZHANG,Jun SUN.The Contribution of Mesoscale Convective Systems to Intense Hourly Precipitation Events during the Warm Seasons over Central East China[J].Advances in Atmospheric Sciences,2016,33(11):1233-1239. 被引量：1
6冯炜.脆弱的安逸读Mosaics：West 8[J].风景园林,2008,15(5):127-129. 被引量：1
7工巧业作见魂魄一玉一禅一匠心[J].中国宝玉石,2016,0(B09):69-69.
8任常青,王清丽,韩鹏飞,张伟.基于EPT的大作业室传统DOM工艺流程改进[J].测绘标准化,2012,28(4):41-43.
9龙良碧.重庆市主要旅游气象气候灾害及防治对策[J].重庆教育学院学报,2004,17(6):56-59. 被引量：7
10尚品[J].中国收藏,2012(12):83-83.

Acta meteorologica Sinica

2008年第3期

浏览历史

内容加载中请稍等...