A Radar Radial Velocity Dealiasing Algorithm for Radar Data Assimilation and its Evaluation with Observations from Multiple Radar Networks

A Radar Radial Velocity Dealiasing Algorithm for Radar Data Assimilation and its Evaluation with Observations from Multiple Radar Networks

Automated and accurate radar dealiasing algorithms are very important for their assimilation into operational numerical weather forecasting models. A radar radial velocity dealiasing algorithm aimed at radar data assimilation is introduced and assessed using from several S-band and C-band radar obse...

Full description

Bibliographic Details
Main Authors: Guangxin He, Juanzhen Sun, Zhuming Ying, Lejian Zhang
Format: Article
Language:English
Published: MDPI AG 2019-10-01
Series:Remote Sensing
Subjects:
dealiasing
typhoon
radial velocity
data assimilation
Online Access:https://www.mdpi.com/2072-4292/11/20/2457
id doaj-105e431f990b4d4584f4ee36d6b412bf
record_format Article
spelling doaj-105e431f990b4d4584f4ee36d6b412bf2020-11-25T02:01:24ZengMDPI AGRemote Sensing2072-42922019-10-011120245710.3390/rs11202457rs11202457A Radar Radial Velocity Dealiasing Algorithm for Radar Data Assimilation and its Evaluation with Observations from Multiple Radar NetworksGuangxin He0Juanzhen Sun1Zhuming Ying2Lejian Zhang3Key Laboratory of Meteorological Disaster, Ministry of Education (KLME)/ Joint International Research Laboratory of Climate and Environment Change (ILCEC)/ Collaborative Innovation Center on Forecast and Evaluation of Meteorological Disasters (CIC-FEMD), Nanjing University of Information Science & Technology, Nanjing 210044, ChinaNational Center for Atmospheric Research, Boulder, CO 80304, USANational Center for Atmospheric Research, Boulder, CO 80304, USAMeteorological Observation center of CMA, China Meteorological Administration, Beijing 100081, ChinaAutomated and accurate radar dealiasing algorithms are very important for their assimilation into operational numerical weather forecasting models. A radar radial velocity dealiasing algorithm aimed at radar data assimilation is introduced and assessed using from several S-band and C-band radar observations under the severe weather conditions of hurricanes, typhoons, and deep continental convection in this paper. This dealiasing algorithm, named automated dealiasing for data assimilation (ADDA), is a further development of the dealiasing algorithm named the China radar network (CINRAD) improved dealiasing algorithm (CIDA), originally developed for China’s CINRAD (China Next Generation Weather Radar) radar network. The improved scheme contains five modules employed to remove noisy data, select the suitable first radial, preserve the convective regions, execute multipass dealiasing in both azimuthal and radial directions and conduct the final local dealiasing with an error check. This new dealiasing algorithm was applied to two hurricane cases, two typhoon cases, and three intense-convection cases that were observed from the CINRAD of China, Taiwan‘s radar network, and NEXRAD (Next Generation Weather Radar) of the U.S. with a continuous period of more than 12 h for each case. The dealiasing results demonstrated that ADDA performed better than CIDA for all selected cases. This algorithm not only produced a high success rate for the S-band radar, but also a reasonable performance for the C-band radar.https://www.mdpi.com/2072-4292/11/20/2457dealiasingtyphoonradial velocitydata assimilation
collection DOAJ
language English
format Article
sources DOAJ
author Guangxin He
Juanzhen Sun
Zhuming Ying
Lejian Zhang
spellingShingle Guangxin He
Juanzhen Sun
Zhuming Ying
Lejian Zhang
A Radar Radial Velocity Dealiasing Algorithm for Radar Data Assimilation and its Evaluation with Observations from Multiple Radar Networks
Remote Sensing
dealiasing
typhoon
radial velocity
data assimilation
author_facet Guangxin He
Juanzhen Sun
Zhuming Ying
Lejian Zhang
author_sort Guangxin He
title A Radar Radial Velocity Dealiasing Algorithm for Radar Data Assimilation and its Evaluation with Observations from Multiple Radar Networks
title_short A Radar Radial Velocity Dealiasing Algorithm for Radar Data Assimilation and its Evaluation with Observations from Multiple Radar Networks
title_full A Radar Radial Velocity Dealiasing Algorithm for Radar Data Assimilation and its Evaluation with Observations from Multiple Radar Networks
title_fullStr A Radar Radial Velocity Dealiasing Algorithm for Radar Data Assimilation and its Evaluation with Observations from Multiple Radar Networks
title_full_unstemmed A Radar Radial Velocity Dealiasing Algorithm for Radar Data Assimilation and its Evaluation with Observations from Multiple Radar Networks
title_sort radar radial velocity dealiasing algorithm for radar data assimilation and its evaluation with observations from multiple radar networks
publisher MDPI AG
series Remote Sensing
issn 2072-4292
publishDate 2019-10-01
description Automated and accurate radar dealiasing algorithms are very important for their assimilation into operational numerical weather forecasting models. A radar radial velocity dealiasing algorithm aimed at radar data assimilation is introduced and assessed using from several S-band and C-band radar observations under the severe weather conditions of hurricanes, typhoons, and deep continental convection in this paper. This dealiasing algorithm, named automated dealiasing for data assimilation (ADDA), is a further development of the dealiasing algorithm named the China radar network (CINRAD) improved dealiasing algorithm (CIDA), originally developed for China’s CINRAD (China Next Generation Weather Radar) radar network. The improved scheme contains five modules employed to remove noisy data, select the suitable first radial, preserve the convective regions, execute multipass dealiasing in both azimuthal and radial directions and conduct the final local dealiasing with an error check. This new dealiasing algorithm was applied to two hurricane cases, two typhoon cases, and three intense-convection cases that were observed from the CINRAD of China, Taiwan‘s radar network, and NEXRAD (Next Generation Weather Radar) of the U.S. with a continuous period of more than 12 h for each case. The dealiasing results demonstrated that ADDA performed better than CIDA for all selected cases. This algorithm not only produced a high success rate for the S-band radar, but also a reasonable performance for the C-band radar.
topic dealiasing
typhoon
radial velocity
data assimilation
url https://www.mdpi.com/2072-4292/11/20/2457
work_keys_str_mv AT guangxinhe aradarradialvelocitydealiasingalgorithmforradardataassimilationanditsevaluationwithobservationsfrommultipleradarnetworks
AT juanzhensun aradarradialvelocitydealiasingalgorithmforradardataassimilationanditsevaluationwithobservationsfrommultipleradarnetworks
AT zhumingying aradarradialvelocitydealiasingalgorithmforradardataassimilationanditsevaluationwithobservationsfrommultipleradarnetworks
AT lejianzhang aradarradialvelocitydealiasingalgorithmforradardataassimilationanditsevaluationwithobservationsfrommultipleradarnetworks
AT guangxinhe radarradialvelocitydealiasingalgorithmforradardataassimilationanditsevaluationwithobservationsfrommultipleradarnetworks
AT juanzhensun radarradialvelocitydealiasingalgorithmforradardataassimilationanditsevaluationwithobservationsfrommultipleradarnetworks
AT zhumingying radarradialvelocitydealiasingalgorithmforradardataassimilationanditsevaluationwithobservationsfrommultipleradarnetworks
AT lejianzhang radarradialvelocitydealiasingalgorithmforradardataassimilationanditsevaluationwithobservationsfrommultipleradarnetworks
_version_ 1724957186791047168

Similar Items