An experimental 2D-Var retrieval using AMSR2
Journal article, 2019

A two-dimensional variational retrieval (2D-Var) is presented for a passive microwave imager. The overlapping antenna patterns of all frequencies from the Advanced Microwave Scanning Radiometer 2 (AMSR2) are explicitly simulated to attempt retrieval of near-surface wind speed and surface skin temperature at finer spatial scales than individual antenna beams. This is achieved, with the effective spatial resolution of retrieved parameters judged by analysis of 2D-Var averaging kernels. Sea surface temperature retrievals achieve about 30 km resolution, with wind speed retrievals at about 10 km resolution. It is argued that multi-dimensional optimal estimation permits greater use of total information content from microwave sensors than other methods, with no compromises on target resolution needed; instead, various targets are retrieved at the highest possible spatial resolution, driven by the channels' sensitivities. All AMSR2 channels can be simulated within near their published noise characteristics for observed clear-sky scenes, though calibration and emissivity model errors are key challenges. This experimental retrieval shows the feasibility of 2D-Var for cloud-free retrievals and opens the possibility of stand-alone 3D-Var retrievals of water vapour and hydrometeor fields from microwave imagers in the future. The results have implications for future satellite missions and sensor design, as spatial oversampling can somewhat mitigate the need for larger antennas in the push for higher spatial resolution.

Author

David Duncan

Chalmers, Space, Earth and Environment, Microwave and Optical Remote Sensing

Patrick Eriksson

Chalmers, Space, Earth and Environment, Microwave and Optical Remote Sensing

Simon Pfreundschuh

Chalmers, Space, Earth and Environment, Microwave and Optical Remote Sensing

Atmospheric Measurement Techniques

1867-1381 (ISSN) 1867-8548 (eISSN)

Vol. 12 12 6341-6359

Subject Categories

Meteorology and Atmospheric Sciences

Other Physics Topics

Signal Processing

DOI

10.5194/amt-12-6341-2019

More information

Latest update

12/23/2019