Assimilation of water‐vapour airborne lidar observations: impact study on the COPS precipitation forecasts

Bielli, Soline; Grzeschik, Matthias; Richard, Évelyne; Flamant, Cyrille; Champollion, Cédric; Kiemle, Christoph; Dorninger, Manfred; Brousseau, Pierre

doi:10.1002/qj.1864

Cited by 22 publications

(31 citation statements)

References 49 publications

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“…As several studies have already demonstrated a strong and positive impact of the water vapor lidar data on the initial water vapor field of the numerical weather prediction mesoscale model by using the three-or four-dimensional variational method (Wulfmeyer et al, 2006;Grzeschik et al, 2008;Bielli et al, 2012), the MRL-measured data can be assimilated into a nonhydrostatic mesoscale model (NHM) (Saito et al, 2007) by the local ensemble transform Kalman filter (LETKF) method (Kunii, 2014) to improve the initial condition of the water vapor field and consequently the rainfall forecast. Given the temporal and vertical resolutions of the model and the assim-ilation window length, the required measurement resolutions are at most 30 min in time and 200 m in the vertical direction.…”

Section: Introductionmentioning

confidence: 99%

Automated compact mobile Raman lidar for water vapor measurement: instrument description and validation by comparison with radiosonde, GNSS, and high-resolution objective analysis

et al. 2019

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We developed an automated compact mobile Raman lidar (MRL) system for measuring the vertical distribution of the water vapor mixing ratio (w) in the lower troposphere, which has an affordable cost and is easy to operate. The MRL was installed in a small trailer for easy deployment and can start measurement in a few hours, and it is capable of unattended operation for several months. We describe the MRL system and present validation results obtained by comparing the MRL-measured data with collocated radiosonde, Global Navigation Satellite System (GNSS), and high-resolution objective analysis data. The comparison results showed that MRL-derived w agreed within 10 % (rootmean-square difference of 1.05 g kg −1 ) with values obtained by radiosonde at altitude ranges between 0.14 and 1.5 km in the daytime and between 0.14 and 5-6 km at night in the absence of low clouds; the vertical resolution of the MRL measurements was 75-150 m, their temporal resolution was less than 20 min, and the measurement uncertainty was less than 30 %. MRL-derived precipitable water vapor values were similar to or slightly lower than those obtained by GNSS at night, when the maximum height of MRL measurements exceeded 5 km. The MRL-derived w values were at most 1 g kg −1 (25 %) larger than local analysis data. A total of 4 months of continuous operation of the MRL system demonstrated its utility for monitoring water vapor distributions in the lower troposphere.Published by Copernicus Publications on behalf of the European Geosciences Union.

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Section: Introductionmentioning

confidence: 99%

Automated compact mobile Raman lidar for water vapor measurement: instrument description and validation by comparison with radiosonde, GNSS, and high-resolution objective analysis

et al. 2019

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“…Moreover, the verification of forecast performance can be more difficult at convective than at global scales; observation networks are too sparse to easily validate all the field scales present in a high‐resolution model simulation. In the AROME–France framework, OSEs experiments have been made concerning total zenith delays from ground‐based GPS stations (Yan et al , 2009; Boniface et al , 2009), radial winds from doppler radars (Montmerle and Faccani, 2009), radar reflectivities (Wattrelow et al , 2008), brightness temperatures from IASI (Infrared Atmospheric Sounding Interferometer; Guidard et al , 2011), water vapour mixing ratios from airborne lidars (Bielli et al , 2012). …”

Section: Introductionmentioning

confidence: 99%

A posteriori diagnostics of the impact of observations on the AROME‐France convective‐scale data assimilation system

Brousseau

Desroziers

Bouttier

et al. 2013

Quart J Royal Meteoro Soc

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AROME-France is an operational convective-scale numerical weather prediction system which uses a 3D-Var assimilation scheme in order to determine its initial conditions. In addition to conventional and satellite observations, regional high-resolution observations are assimilated, such as screen-level observations, total zenith delays from ground-based GPS stations and radar measurements (radial winds and reflectivities). The impact of the various observation types on AROME-France analyses is assessed using an a posteriori diagnostic, the reduction of the estimation error variance. This diagnostic, estimated using a randomization technique, allows one to investigate observation impact depending on the control variable field, model levels, date, analysis time, and spatial scales considered. This highlights the importance of screen-level observations (2 m temperature and relative humidity, 10 m wind) for the lowest layers, of aircraft measurements for temperature and wind field analyses and of radar observations for wind and specific humidity in middle and high troposphere. Only the last mentioned observations appear to be informative regarding the horizontal length-scale below 200 km, while all observations are mostly informative for length-scales above 200 km. The results from two diagnostics, namely the variance reduction and the Degrees of Freedom for Signal (DFS), are compared and found to be largely similar. The variance reduction appears to be an interesting diagnostic to improve the understanding of how observations are used. 1 2 χ ) T R −1 (d − HB 1 2 χ).

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“…Due to its capabilities the WALES airborne demonstrator has become a state-of-the-art instrument for climate and meteorological research. Over the past decade it successfully completed several hundreds of flight hours in national and international field campaigns (Schäfler et al, 2010;Bhawar et al, 2011;Kiemle et al, 2011;Bielli et al, 2012;Fischer et al, 2013;Groß et al, 2014;Trickl et al, 2016).…”

Section: The Dlr Airborne Water Vapor Lidarmentioning

confidence: 99%

Airborne Lidar Observations of Water Vapor Variability in Tropical Shallow Convective Environment

et al. 2017

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An airborne downward-pointing water vapor lidar provides two-dimensional, simultaneous curtains of atmospheric backscatter and humidity along the flight track with high accuracy and spatial resolution. In order to improve the knowledge on the coupling between clouds, circulation and climate in the trade wind region, the DLR (Deutsches Zentrum für Luft-und Raumfahrt) water vapor lidar was operated on board the German research aircraft HALO during the NARVAL (Next Generation Aircraft Remote Sensing for Validation Studies) field experiment in December 2013. Out of the wealth of about 30 flight hours or 25000 km of data over the Tropical Atlantic Ocean east of Barbados, three ~2 h long, representative segments from different flights were selected. Analyses of Meteosat Second Generation (MSG) images and dropsondes complement this case study. All observations indicate a high heterogeneity of the humidity in the lowest 4 km of the tropical troposphere, as well as of the depth of the cloud (1-2 km thick) and sub-cloud layer (~1 km thick). At the trade inversion with its strong humidity jump of up to 9 g/kg in water vapor mixing ratio, the mixing ratio variance can attain 9 (g/kg)² while below it typically ranges between 1 and 3 (g/kg)². Layer depths and partial water vapor columns within the layers vary by up to a factor of 2. This affects the total tropospheric water vapor column, amounting on average to 28 kg/m², by up to 10 kg/m² or 36 %. The dominant scale of the variability is given by the extent of regions with higherthan-average humidity and lies between 300-600 km. The variability mainly stems from the alternation between dry regions and moisture lifted by convection. Occasionally, up to 100 km large dry regions are observed. In between, convection pushes the trade inversion upward, sharpening the vertical moisture gradient that is co-located with the trade inversion. In most of the water vapor profiles this gradient is stronger than the one located at the top of the sub-cloud layer. Lidar observations, in concert with models accurately reproducing the observed variability are expected to help evaluate the role these details play for climate.

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Assimilation of water‐vapour airborne lidar observations: impact study on the COPS precipitation forecasts

Cited by 22 publications

References 49 publications

Automated compact mobile Raman lidar for water vapor measurement: instrument description and validation by comparison with radiosonde, GNSS, and high-resolution objective analysis

Automated compact mobile Raman lidar for water vapor measurement: instrument description and validation by comparison with radiosonde, GNSS, and high-resolution objective analysis

A posteriori diagnostics of the impact of observations on the AROME‐France convective‐scale data assimilation system

Airborne Lidar Observations of Water Vapor Variability in Tropical Shallow Convective Environment

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