Algorithms for Doppler Spectral Density Data Quality Control and Merging for the Ka-Band Solid-State Transmitter Cloud Radar

The Chinese Ka-band solid-state transmitter cloud radar (CR) can operate in three different work modes with different pulse widths and coherent integration and non-coherent integration numbers to meet the requirement for long-term cloud measurements. The CR was used to observe cloud and precipitation data in southern China in 2016. In order to resolve the data quality problems caused by coherent integration and pulse compression, which are used to detect weak cloud in the cloud radar, this study focuses on analyzing the consistencies of reflectivity spectra using the three modes and the influence of coherent integration and pulse compression, developing an algorithm for Doppler spectral density data quality control (QC) and merging based on multiple-mode observation data. After dealiasing Doppler velocity and artefact removal, the three types of Doppler spectral density data were merged. Then, Doppler moments such as reflectivity, radial velocity, and spectral width were recalculated from the merged reflectivity spectra. Performance of the merging algorithm was evaluated. Three conclusions were drawn. Firstly, four rounds of coherent integration with a pulse repetition frequency (PRF) of 8333 Hz underestimated the reflectivity spectra for Doppler velocities exceeding 2 m·s−1, causing a large negative bias in the reflectivity and radial velocity when large drops were present. In contrast, two rounds of coherent integration affected the reflectivity spectra to a lesser extent. The reflectivity spectra were underestimated for low signal-to-noise ratios in the low-sensitivity mode. Secondly, pulse compression improved the radar sensitivity and air vertical speed observation, whereas the precipitation mode and coherent integration led to an underestimation of the number concentration of big raindrops and an overestimation of the number concentration of small drops. Thirdly, a comparison of the individual spectra with the merged reflectivity spectra showed that the Doppler moments filled in the gaps in the individual spectra during weak cloud periods, reduced the effects of coherent integration and pulse compression in liquid precipitation, mitigated the aliasing of Doppler velocity, and removed the artefacts, yielding a comprehensive and accurate depiction of most of the clouds and precipitation in the vertical column above the radar. The recalculated moments of the Doppler spectra had better quality than those merged from raw data.

[1]  Earl E. Gossard,et al.  Measurement of Cloud Droplet Size Spectra by Doppler Radar , 1994 .

[2]  Pavlos Kollias,et al.  Radar Observations of Updrafts, Downdrafts, and Turbulence in Fair-Weather Cumuli , 2001 .

[3]  Liu Lipin Examination and Application of Doppler Spectral Density Data in Drop Size Distribution Retrieval in Weak Precipitation by Cloud Radar , 2014 .

[4]  R. Lhermitte Observation of rain at vertical incidence with a 94 GHz Doppler radar: An insight on Mie scattering , 1988 .

[5]  Jiafeng Zheng,et al.  A Ka-band solid-state transmitter cloud radar and data merging algorithm for its measurements , 2017, Advances in Atmospheric Sciences.

[6]  E. Clothiaux,et al.  The Atmospheric Radiation Measurement Program Cloud Profiling Radars: An Evaluation of Signal Processing and Sampling Strategies , 2005 .

[7]  P. Kollias,et al.  Cloud radar observations of vertical drafts and microphysics in convective rain , 2003 .

[8]  Liping Liu,et al.  A Method for Retrieving Vertical Air Velocities in Convective Clouds over the Tibetan Plateau from TIPEX-III Cloud Radar Doppler Spectra , 2017, Remote. Sens..

[9]  E. Clothiaux,et al.  The Atmospheric Radiation Measurement Program Cloud Profiling Radars: Second-Generation Sampling Strategies, Processing, and Cloud Data Products , 2007 .

[10]  P. Hildebrand,et al.  Objective Determination of the Noise Level in Doppler Spectra , 1974 .

[11]  Brooks E. Martner,et al.  An Unattended Cloud-Profiling Radar for Use in Climate Research , 1998 .

[12]  Peter Czechowsky,et al.  Complementary Code and Digital Filtering for Detection of Weak VHF Radar Signals from the Mesosphere , 1979, IEEE Transactions on Geoscience Electronics.

[13]  E. Clothiaux,et al.  THE ATMOSPHERIC RADIATION MEASUREMENT PROGRAM CLOUD RADARS : OPERATIONAL MODES , 1999 .

[14]  Zhiqun Hu,et al.  Comprehensive radar observations of clouds and precipitation over the Tibetan Plateau and preliminary analysis of cloud properties , 2015, Journal of Meteorological Research.

[15]  Monique Petitdidier,et al.  Statistical characteristics of the noise power spectral density in UHF and VHF wind profilers , 1997 .

[16]  Pavlos Kollias,et al.  On Deriving Vertical Air Motions from Cloud Radar Doppler Spectra , 2008 .

[17]  P. Kollias,et al.  Deriving Mixed-Phase Cloud Properties from Doppler Radar Spectra , 2004 .

[18]  E. Clothiaux,et al.  Objective Determination of Cloud Heights and Radar Reflectivities Using a Combination of Active Remote Sensors at the ARM CART Sites , 2000 .

[19]  Petr Novák,et al.  Classification of Hydrometeors Using Measurements of the Ka-Band Cloud Radar Installed at the Milešovka Mountain (Central Europe) , 2018, Remote. Sens..