A cloud detection algorithm using the downwelling infrared radiance measured by an infrared pyrometer of the ground-based microwave radiometer

Ahn, Myoung Hwan; Han, D.; Won, Hye Young; Morris, V. R.

doi:10.5194/amt-8-553-2015

Cited by 7 publications

(1 citation statement)

References 31 publications

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“…Thus, for an accurate assessment of the calibration characterization, we need to select data points free from cloud contamination, even at these oxygen channels. For the cloudy data screening, an algorithm using the downwelling infrared radiation measured by the IRT radiometer along with the surface temperature and humidity is used (Ahn et al, 2015a).…”

Section: Measured T B Vs Simulated T Bmentioning

confidence: 99%

Characterization of downwelling radiance measured from a ground-based microwave radiometer using numerical weather prediction model data

et al. 2016

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Abstract. The ground-based microwave sounding radiometers installed at nine weather stations of Korea Meteorological Administration alongside with the wind profilers have been operating for more than 4 years. Here we apply a process to assess the characteristics of the observation data by comparing the measured brightness temperature (T b ) with reference data. For the current study, the reference data are prepared by the radiative transfer simulation with the temperature and humidity profiles from the numerical weather prediction model instead of the conventional radiosonde data. Based on the 3 years of data, from 2010 to 2012, we were able to characterize the effects of the absolute calibration on the quality of the measured T b . We also showed that when clouds are present the comparison with the model has a high variability due to presence of cloud liquid water therefore making cloudy data not suitable for assessment of the radiometer's performance. Finally we showed that differences between modeled and measured brightness temperatures are unlikely due to a shift in the selection of the center frequency but more likely due to spectroscopy issues in the wings of the 60 GHz absorption band. With a proper consideration of data affected by these two effects, it is shown that there is an excellent agreement between the measured and simulated T b . The regression coefficients are better than 0.97 along with the bias value of better than 1.0 K except for the 52.28 GHz channel which shows a rather large bias and variability of − 2.6 and 1.8 K, respectively.

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Section: Measured T B Vs Simulated T Bmentioning

confidence: 99%

Characterization of downwelling radiance measured from a ground-based microwave radiometer using numerical weather prediction model data

et al. 2016

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Through thick and thin: quantitative classification of photometric observing conditions on Paranal

Kerber

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et al. 2016

Observatory Operations: Strategies, Processes, and Systems VI

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Cloud-Base Height Derived from a Ground-Based Infrared Sensor and a Comparison with a Collocated Cloud Radar

Wang

Cao

Mao

et al. 2018

Journal of Atmospheric and Oceanic Technology

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An improved algorithm to calculate cloud-base height (CBH) from infrared temperature sensor (IRT) observations that accompany a microwave radiometer was described, the results of which were compared with the CBHs derived from ground-based millimeter-wavelength cloud radar reflectivity data. The results were superior to the original CBH product of IRT and closer to the cloud radar data, which could be used as a reference for comparative analysis and synergistic cloud measurements. Based on the data obtained by these two kinds of instruments for the same period (January–December 2016) from the Beijing Nanjiao Weather Observatory, the results showed that the consistency of cloud detection was good and that the consistency rate between the two datasets was 81.6%. The correlation coefficient between the two CBH datasets reached 0.62, based on 73 545 samples, and the average difference was 0.1 km. Higher correlations were obtained for thicker clouds with a larger echo intensity. A low-level thin cloud cannot be regarded as a blackbody because of its high transmittance, which results in higher CBHs derived from IRT data. Because of a smaller cloud radiation effect for high-level thin cloud above 8 km, the contribution of the atmospheric downward radiation below the cloud base to the IRT cannot be ignored, as it results in lower CBHs derived from IRT data. Owing to the seasonal variation of atmospheric downward radiation reaching the IRT, the difference between the two CBHs also has a seasonal variation. The IRT CBHs are generally higher (lower) than the cloud radar CBHs in winter (summer).

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A cloud detection algorithm using the downwelling infrared radiance measured by an infrared pyrometer of the ground-based microwave radiometer

Cited by 7 publications

References 31 publications

Characterization of downwelling radiance measured from a ground-based microwave radiometer using numerical weather prediction model data

Characterization of downwelling radiance measured from a ground-based microwave radiometer using numerical weather prediction model data

Through thick and thin: quantitative classification of photometric observing conditions on Paranal

Cloud-Base Height Derived from a Ground-Based Infrared Sensor and a Comparison with a Collocated Cloud Radar

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