TY - GEN
AU - Peter Bauer
AU - Philippe Lopez
AU - Angela Benedetti
AU - Deborah Salmond
AU - E. Moreau
AB - This paper presents the operational implementation of a 1D+4D-Var assimilation system of rain affected satellite observations at ECMWF. The first part describes the methodology and performance analysis of the 1D-Var retrieval scheme in clouds and precipitation that uses SSM/I microwave radiance observations for the estimation of total column water vapor. The second part shows the global and long-term impact of these observations on both model 4D-Var analyses and medium-range forecasts. The 1D-Var scheme employs a complex observation operator that consists of linearized moist physics parameterization schemes and a multiple scattering radiative transfer model. The observation operator shows a rather linear behavior in most situations except in the presence of very intense precipitation suggesting a possible use even for a direct assimilation of radiances in 4D-Var. A bias correction and observation error estimation method were implemented and indicate stable error behavior. The 1D-Var algorithm quality control shows the largest failure number in areas with mostly frozen precipitation where the SSM/I channels have little sensitivity to changes in hydrometeor contents. From test analyses on a global scale, a small moisture increase was computed that was greatest in dry subtropical areas. Large-scale and convective precipitation were increased similarly but showed a significantly different geographical distribution. The large-scale precipitation scheme has a stronger sensitivity to moisture changes and therefore moisture increments mainly affect stratiform precipitation distributions. While the global mean moisture fields are only weakly affected by the assimilation of rain affected observations, the impact on local systems may be quite large. The forecast of synoptic system development through the 4D-Var analysis can be significant.
BT - ECMWF Technical Memoranda
CY - Shinfield Park, Reading
DA - 02/2006
DO - 10.21957/es9zz9zyx
LA - eng
M1 - 487
N2 - This paper presents the operational implementation of a 1D+4D-Var assimilation system of rain affected satellite observations at ECMWF. The first part describes the methodology and performance analysis of the 1D-Var retrieval scheme in clouds and precipitation that uses SSM/I microwave radiance observations for the estimation of total column water vapor. The second part shows the global and long-term impact of these observations on both model 4D-Var analyses and medium-range forecasts. The 1D-Var scheme employs a complex observation operator that consists of linearized moist physics parameterization schemes and a multiple scattering radiative transfer model. The observation operator shows a rather linear behavior in most situations except in the presence of very intense precipitation suggesting a possible use even for a direct assimilation of radiances in 4D-Var. A bias correction and observation error estimation method were implemented and indicate stable error behavior. The 1D-Var algorithm quality control shows the largest failure number in areas with mostly frozen precipitation where the SSM/I channels have little sensitivity to changes in hydrometeor contents. From test analyses on a global scale, a small moisture increase was computed that was greatest in dry subtropical areas. Large-scale and convective precipitation were increased similarly but showed a significantly different geographical distribution. The large-scale precipitation scheme has a stronger sensitivity to moisture changes and therefore moisture increments mainly affect stratiform precipitation distributions. While the global mean moisture fields are only weakly affected by the assimilation of rain affected observations, the impact on local systems may be quite large. The forecast of synoptic system development through the 4D-Var analysis can be significant.
PB - ECMWF
PP - Shinfield Park, Reading
PY - 2006
EP - 29
T2 - ECMWF Technical Memoranda
TI - Implementation of 1D+4D-Var assimilation of precipitation affected microwave radiances at ECMWF, Part I: 1D-Var.
UR - https://www.ecmwf.int/node/7995
ER -