Abstract
Abstract. Ground-based microwave radiometers (MWRs) offer the capability to provide continuous, high-temporal-resolution observations of the atmospheric thermodynamic state in the planetary boundary layer (PBL) with low maintenance. This makes MWR an ideal instrument to supplement radiosonde and satellite observations when initializing numerical weather prediction (NWP) models through data assimilation. State-of-the-art data assimilation systems (e.g. variational schemes) require an accurate representation of the differences between model (background) and observations, which are then weighted by their respective errors to provide the best analysis of the true atmospheric state. In this perspective, one source of information is contained in the statistics of the differences between observations and their background counterparts (O–B). Monitoring of O–B statistics is crucial to detect and remove systematic errors coming from the measurements, the observation operator, and/or the NWP model. This work illustrates a 1-year O–B analysis for MWR observations in clear-sky conditions for an European-wide network of six MWRs. Observations include MWR brightness temperatures (TB) measured by the two most common types of MWR instruments. Background profiles are extracted from the French convective-scale model AROME-France before being converted into TB. The observation operator used to map atmospheric profiles into TB is the fast radiative transfer model RTTOV-gb. It is shown that O–B monitoring can effectively detect instrument malfunctions. O–B statistics (bias, standard deviation, and root mean square) for water vapour channels (22.24–30.0 GHz) are quite consistent for all the instrumental sites, decreasing from the 22.24 GHz line centre ( ∼ 2–2.5 K) towards the high-frequency wing ( ∼ 0.8–1.3 K). Statistics for zenith and lower-elevation observations show a similar trend, though values increase with increasing air mass. O–B statistics for temperature channels show different behaviour for relatively transparent (51–53 GHz) and opaque channels (54–58 GHz). Opaque channels show lower uncertainties (< 0.8–0.9 K) and little variation with elevation angle. Transparent channels show larger biases ( ∼ 2–3 K) with relatively low standard deviations ( ∼ 1–1.5 K). The observations minus analysis TB statistics are similar to the O–B statistics, suggesting a possible improvement to be expected by assimilating MWR TB into NWP models. Lastly, the O–B TB differences have been evaluated to verify the normal-distribution hypothesis underlying variational and ensemble Kalman filter-based DA systems. Absolute values of excess kurtosis and skewness are generally within 1 and 0.5, respectively, for all instrumental sites, demonstrating O–B normal distribution for most of the channels and elevations angles.
Highlights
The new generation of high-resolution (∼ 1 km grid size) weather forecast models operational over Europe promises to improve predictions of high-impact weather, ranging from flash floods to episodes of poor air quality
Observations are TB measured by the HATPRO at zenith, while background are TB simulated with Radiative Transfer for TOVS (RTTOV)-gb from the 3 h forecast profiles at the model grid column closest to JOYCE
Similar misbehaviours were detected and later confirmed by instrument operators at other sites: (i) at CESAR at all the channels below 54 GHz between 15 June and 18 September 2014, corresponding again to a period after a faulty calibration; (ii) at CESAR at channel 22.24 GHz and elevation angles below 42 degrees due to radio frequency interference leaking into the channel bandpass filter; (iii) at Payerne at 26.24 GHz for the whole period due to an unknown malfunction possibly related to hardware components causing large observed TB variations
Summary
The new generation of high-resolution (∼ 1 km grid size) weather forecast models operational over Europe promises to improve predictions of high-impact weather, ranging from flash floods to episodes of poor air quality. The United States National Research Council (NRC) recently reported that continuous planetary boundary layer (PBL) thermodynamic observations provide a practical and cost-effective means to improve local high-impact weather forecasting (National Research Council, 2008, 2010). They stated that the structure and variability of the lower troposphere is currently not well known because vertical profiles of water vapour, temperature, and winds are not systematically observed. More than 30 MWR are currently installed in Europe, most of which are operating continuously, and the number is increasing In this framework, MWR are candidates to supplement radiosonde and satellite observations to feed modern numerical weather prediction (NWP) models through assimilation of their data. The development of the ground-based version of the fast radiative transfer model Radiative Transfer for TOVS (RTTOV), i.e. RTTOV-gb (De Angelis et al, 2016), allows the fast simulation of ground-based MWR TB, paving the way towards the operational assimilation of MWR TB into NWP models
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