A51G-0150
C3Winds: A Novel 3D Wind Observing System to Characterize Severe Weather Events
Friday, 18 December 2015
Poster Hall (Moscone South)
Michael A Kelly1, Dong Liang Wu2, Jeng-Hwa Yee1, John Boldt1, Robert Demajistre1, Edward Reynolds1, Gregory J Tripoli3, Luke Oman2, Nikki Prive2, Andrew K Heidinger4 and Steve Wanzong5, (1)Applied Physics Laboratory Johns Hopkins, Laurel, MD, United States, (2)NASA Goddard Space Flight Center, Greenbelt, MD, United States, (3)University of Wisconsin Madison, Madison, WI, United States, (4)NOAA/NESDIS, Madison, WI, United States, (5)UW-Madison/SSEC/CIMSS, Madison, WI, United States
Abstract:
The CubeSat Constellation Cloud Winds (C3Winds) is a NASA Earth Venture Instrument (EV-I) concept with the primary objective to resolve high-resolution 3D dynamic structures of severe wind events. Rapid evolution of severe weather events highlights the need for high-resolution mesoscale wind observations. Yet mesoscale observations of severe weather dynamics are quite rare, especially over the ocean where extratropical and tropical cyclones (ETCs and TCs) can undergo explosive development. Measuring wind velocity at the mesoscale from space remains a great challenge, but is critically needed to understand and improve prediction of severe weather and tropical cyclones. Based on compact, visible/IR imagers and a mature stereoscopic technique, C3Winds has the capability to measure high-resolution (~2 km) cloud motion vectors and cloud geometric heights accurately by tracking cloud features from two formation-flying CubeSats, separated by 5-15 minutes. Complementary to lidar wind measurements from space, C3Winds will provide high-resolution wind fields needed for detailed investigations of severe wind events in occluded ETCs, rotational structures inside TC eyewalls, and ozone injections associated with tropopause folding events. Built upon mature imaging technologies and long history of stereoscopic remote sensing, C3Winds provides an innovative, cost-effective solution to global wind observations with the potential for increased diurnal sampling via CubeSat constellation.