PDF下载分享

[1]张双,张福贵,杨金红.负仰角观测对新一代天气雷达( CINRAD) 探测降水的意义[J].成都信息工程大学学报,2016,(01):49-53.
　ZHANG Shuang,ZHANG Fu-gui,YANG Jin-hong.The Significance of Negative Elevation Observation to the Precipitation of the New Generation Weather Radar[J].Journal of Chengdu University of Information Technology,2016,(01):49-53.

点击复制

负仰角观测对新一代天气雷达( CINRAD) 探测降水的意义

成都信息工程大学学报[ISSN:1006-6977/CN:61-1281/TN] 卷: 期数: 2016年01期页码: 49-53 栏目: 电子信息科学与技术出版日期: 2016-01-20

Title:: The Significance of Negative Elevation Observation to the Precipitation of the New Generation Weather Radar

文章编号:: 2096-1618(2016)01-0049-05

作者:: 张双¹; 张福贵¹; 2; 杨金红²; 3; (1. 成都信息工程大学电子工程学院,四川成都610225;2. 中国气象局大气探测重点开放实验室,四川成都610225;3. 中国气象局气象探测中心,北京100081)

Author(s):: ZHANG Shuang¹; ZHANG Fu-gui¹; 2; YANG Jin-hong²; 3; (1. College of Electronic Engineering,Chengdu University of Information Technology, Chengdu 610225,China; 2. The Key Laboratory of China Meteorological Administartion, Chengdu 610225, China; 3. China Meteorological Administration Meteorological Observation Ccenter, Beijing 100081,China)

关键词:: 天气雷达; 负仰角; 估测降水

Keywords:: weather radar; negative elevation angle; precipitation estimation

分类号:: TN959. 4

文献标志码:: A

摘要:: 新一代天气雷达观测模式使用观测的仰角都在0. 5毅以上,而在0. 5毅以下是没有仰角的,这样就导致雷达估测降水时反射率因子Z 值场的取值精度降低和取值范围缩小,致使雷达估测降水的能力降低,而Z 值场的取值往往以零度层亮带以下的中低层范围为宜。计算并分析正、负仰角下雷达的最低探测高度,得到雷达在-0. 3毅仰角的最低探测高度明显低于0毅仰角和0. 5毅仰角,表明采用负仰角探测可以有效的降低最小探测高度;读取VCP11 和 VCP22 两种体扫模式下的雷达仰角数据信息,分析在0. 48毅、0毅以及-0. 31毅仰角下雷达探测降水回波的能力,发现仰角越低探测到的降水回波越多。

Abstract:: The most elevations of new generation of weather radar observation mode are above 0. 5 毅, and there is no ele- vation under 0. 5 毅, thus causing loss of accuracy and reducingvalues range of radar reflectivityfactor Z during radar rain- fall estimation , decreasing the ability of the radar to estimate precipitation . But the value of Z field is often with zero layer bright band in the middle and lower range is appropriate. This paper calculates and analyses the positive and nega- tive elevation radar detection minimum height, The lowest detection altitude of radar in -0. 3毅elevation was significantly lower than that of 0毅elevation and 0. 5毅elevation, indicating that the negative elevation detection can effectively reduce the height of the minimum detection ;Read the radar elevation data information in the VCP11 and VCP22 scanning mode, the analysis of radar detection of precipitation echoes at 0. 48毅, 0毅and -0. 31 毅elevation, found that the lower the elevation, the more precipitation echo.

参考文献/References:

[1] Rodger A Brown, Janelle M Janish, Vincent T. Wood. Impact of WSR-88D strategies on severe storm algorithms[ J]. Wea. Farecasting,2001,15 (2):90-102.
[2] Brown RA,Janish JM,Wood VT. Impact of WSR- 88D scanning strategies on severe storm algorithms. Weather Forecasting[J].2000,15: 90 – 102.
[3] Vincent T Wood,Rodger ABrown,Steven V Vasi- loff. Improved detection using negative angles for mountaintop WSR-88Ds: simulation of the three radars covering Utah [ J ]. Wea. Farecasting, 2003,18(6):393-403.
[4] 刘应军,顾松山,周雨华,等. 新一代天气雷达体扫模式对比分析[J]. 气象. 2005,(1).
[5] 徐八林,刘黎平,徐文君,等. 利用低仰角扫描改进高山雷达低层回波探测能力[ J]. 气象, 2008,34(9):28-33.
[6] 徐八林,刘黎平,王改利. 超低仰角扫描改进高山雷达降水估测[ J]. 高原气象,2011,30(5): 1337-1345.
[7] 俞小鼎,姚秀萍,熊廷南,等. 多普勒天气雷达原理与业务应用[M]. 北京:气象出版社.2006:22-31.
[8] 张扬成,游文华,高翔宇,等. 新一代天气雷达负仰角探测能力分析[J]. 气象出科技,2013,41(2).
[9] 杨金红,陈大任,王署东,等. 改进新一代天气雷达低层探测能力研究探[ J]. 气象. 2013,39 (4):494-499.
[10] 陈森. 多普勒天气雷达不同仰角数据定量估测降水对比分析[ J]. 广东水利水电,2011,2 (2):28-40.
[11] 张林,杨洪平,邓鑫,等. 基于模板匹配法的长乐雷达强超折射回波识别[J]. 气象,2014,(3).
[12] 周志文,王艳兰,李耀先. 雷达降水估测优化及其在暴雨预警中的应用[ J]. 气象科技,2009, 37(4):407-411.
[13] 刘昉,丁明星, 张俊. 天气雷达低仰角杂波干扰区域性能分析[J]. 电子科学与技术,2016,(2).
[14] 程明虎,刘黎平. 暴雨系统的多普勒雷达反演理论和方法[M]. 北京:气象出版社,2004.
[15] 王红艳,刘黎平. 新一代天气雷达降水估算的区域覆盖能力评估[J]. 电高原气象,2015,(12).
[16] 戴铁丕,傅德胜. 天气雷达-雨量计网联合探测区域降水量的精度[ J]. 南京气象学院学报,1990,13(4):592-597.

相似文献/References:

[1]王翔弘,何建新,王旭,等.太原CINRAD/CC雷达与X波段雷达观测一致性分析[J].成都信息工程大学学报,2018,(03):236.[doi:10.16836/j.cnki.jcuit.2018.03.003]
　WANG Xiang-hong,HE Jian-xin,WANG Xu,et al.Observation Consistency Analysis of the Taiyuan CINRAD/CCWeather Radar and the X-band Radar[J].Journal of Chengdu University of Information Technology,2018,(01):236.[doi:10.16836/j.cnki.jcuit.2018.03.003]
[2]王海江,刘玟宏,邓洋洋,等.S 波段多普勒天气雷达回波模拟[J].成都信息工程大学学报,2016,(01):12.
　WANG Hai-jiang,LIU Wen-hong,DENG Yang-yang,et al.S Band Doppler Weather Radar Echo Simulation[J].Journal of Chengdu University of Information Technology,2016,(01):12.
[3]赵亮.龙卷过程中雷达合成切变产品的分析[J].成都信息工程大学学报,2017,(03):269.[doi:10.16836/j.cnki.jcuit.2017.03.007]
　ZHAO Liang.Analysis of Radar Composite Shear Products in the Process of Tornado[J].Journal of Chengdu University of Information Technology,2017,(01):269.[doi:10.16836/j.cnki.jcuit.2017.03.007]
[4]蒋秋菲,王旭,何建新,等.天气雷达遮挡区域识别[J].成都信息工程大学学报,2017,(05):469.[doi:10.16836/j.cnki.jcuit.2017.05.001]
　JIANG Qiu-fei,WANG Xu,HE Jian-xin,et al.Identification of Weather Radar Shielding Region[J].Journal of Chengdu University of Information Technology,2017,(01):469.[doi:10.16836/j.cnki.jcuit.2017.05.001]
[5]周淑玥,李静,鲜林,等.基于数字高程模型和反射率因子垂直廓线的天气雷达波束遮挡订正算法[J].成都信息工程大学学报,2023,38(05):497.[doi:10.16836/j.cnki.jcuit.2023.05.001]
　ZHOU Shuyue,LI Jing,XIAN Lin,et al.Weather Radar Beam Block Correction Algorithm based on DEM Model and Vertical Profile of Reflectivity[J].Journal of Chengdu University of Information Technology,2023,38(01):497.[doi:10.16836/j.cnki.jcuit.2023.05.001]
[6]沈邦跃,何建新,曾强宇.基于超分辨率的相控阵天气雷达数据压缩算法[J].成都信息工程大学学报,2023,38(06):621.[doi:10.16836/j.cnki.jcuit.2023.06.001]
　SHEN Bangyue,HE Jianxin,ZENG Qiangyu.Data Compression Algorithm of Phased Array Weather Radar based on Super Resolution[J].Journal of Chengdu University of Information Technology,2023,38(01):621.[doi:10.16836/j.cnki.jcuit.2023.06.001]
[7]许洋,李学华,王俊,等.基于AD9361的天气雷达回波模拟与硬件系统[J].成都信息工程大学学报,2024,39(03):283.[doi:10.16836/j.cnki.jcuit.2024.03.004]
　XU Yang,LI Xuehua,WANG Jun,et al.Weather Radar Echo Simulation and Hardware System based on AD9361[J].Journal of Chengdu University of Information Technology,2024,39(01):283.[doi:10.16836/j.cnki.jcuit.2024.03.004]

备注/Memo

收稿日期:2016-01-10 基金项目:国家公益性行业(气象)科研专项资助项目(GYHY201406038)

更新日期/Last Update: 2016-01-20