Shakeel Asharaf, Derek J. Posselt, Faozi Said, Christopher S. Ruf
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引用次数: 2
摘要
基于全球导航卫星系统反射(GNSS-R)的风反演技术利用海面前方散射的全球定位系统(GPS)信号,可以在所有天气条件下工作。综述了气旋全球导航卫星系统(CYGNSS) 2级地面风产品的最新进展。为此,利用来自热带浮标阵列的高质量数据,对CYGNSS公开发布的四个地面风产品——科学数据记录(SDR) v2.1、SDR v3.0、气候数据记录(CDR) v1.1和科学风速产品NOAA v1.1进行了定量验证。最新发布的CYGNSS风产品(如CDR v1.1, SDR v3.0, NOAA v1.1)与这些热带浮标数据相比,显著优于SDR v2.1。此外,发现这些产品之间的不确定度小于2 m s−1均方根差,满足NASA科学任务对风速低于20 m s−1的不确定度要求。在低风和大尺度对流区域的不同降水条件下,进一步评估CYGNSS风的质量。结果表明,在所有CYGNSS数据中,降雨的存在似乎导致了轻微的正风速偏差。尽管如此,对于最近发布的CYGNSS风产品总体而言,以及对于深对流降水区域的CYGNSS数据来说,结果是令人鼓舞的。总体比较表明,从旧版本到任何新数据集,风速质量和样本量都有显着改善。
Updates on CYGNSS Ocean Surface Wind Validation in the Tropics
Abstract Global Navigation Satellite System Reflectometry (GNSS-R)-based wind retrieval techniques use the global positioning system (GPS) signals scattered from the ocean surface in the forward direction, and can potentially work in all weather conditions. An overview of recent progress made in the Cyclone Global Navigation Satellite System (CYGNSS) level-2 surface wind products is given. To this end, four publicly released CYGNSS surface wind products—Science Data Record (SDR) v2.1, SDR v3.0, Climate Data Record (CDR) v1.1, and science wind speed product NOAA v1.1—are validated quantitatively against high-quality data from tropical buoy arrays. The latest released CYGNSS wind products (e.g., CDR v1.1, SDR v3.0, NOAA v1.1), as compared with these tropical buoy data, significantly outperform the SDR v2.1. Moreover, the uncertainty among these products is found to be less than 2 m s −1 root-mean-squared difference, meeting the NASA science mission level-1 uncertainty requirement for wind speeds below 20 m s −1 . The quality of the CYGNSS wind is further assessed under different precipitation conditions in low winds, and in large-scale convective regions. Results show that the presence of rain appears to cause a slightly positive wind speed bias in all CYGNSS data. Nonetheless, the outcomes are encouraging for the recently released CYGNSS wind products in general, and for CYGNSS data in regions with precipitating deep convection. The overall comparison indicates a significant improvement in wind speed quality and sample size when going from the older version to any of the newer datasets.
期刊介绍:
The Journal of Atmospheric and Oceanic Technology (JTECH) publishes research describing instrumentation and methods used in atmospheric and oceanic research, including remote sensing instruments; measurements, validation, and data analysis techniques from satellites, aircraft, balloons, and surface-based platforms; in situ instruments, measurements, and methods for data acquisition, analysis, and interpretation and assimilation in numerical models; and information systems and algorithms.
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