The Atmospheric Radiation Measurement Program Cloud Radars: Operational Modes

Clothiaux, Eugene E.; Moran, K. P.; Martner, Brooks E.; Ackerman, Thomas P.; Mace, Gerald G.; Uttal, Taneil; Mather, J. H.; Widener, Kevin B.; Miller, Mark A.; Rodriguez, Daniel J.

doi:10.1175/1520-0426(1999)016<0819:tarmpc>2.0.co;2

Cited by 88 publications

(82 citation statements)

References 7 publications

(13 reference statements)

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“…We analyse observations from two sites with zenith-pointing millimeter-wavelength Doppler cloud radars; the Atmospheric Radiation Measurement (ARM) Southern Great Plains (SGP) site in central Oklahoma, US (Clothiaux et al, 1999), and the Deutscher Wetterdienst (DWD) observatory in Lindenberg, Germany. Both sites are also equipped with co-located lidars, ceilometers, and complemented by a suite of surface instruments.…”

Section: Observationsmentioning

confidence: 99%

“…The Doppler cloud radar at SGP is the 35 GHz millimeterwavelength cloud radar, MMCR (Clothiaux et al, 1999), which has a number of operational modes; we therefore use the Active Remote Sensing of Clouds (ARSCL) dataset (Clothiaux et al, 2000(Clothiaux et al, , 2001 as input to the Cloudnet processing scheme. The ensuing vertical resolution is approximately 90 m. The Doppler cloud radar at Lindenberg is the 35.5 GHz MIRA and the vertical resolution of the Cloudnet product is approximately 30 m. The intrinsic error in the mean Doppler velocity is smaller than the bin width of the measured Doppler spectrum and, hence, for both Doppler cloud radars, the Doppler velocity resolution is on the order of 2 cm s −1 .…”

Section: Observationsmentioning

confidence: 99%

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Cloud base vertical velocity statistics: a comparison between an atmospheric mesoscale model and remote sensing observations

et al. 2011

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Abstract. The statistics of cloud base vertical velocity simulated by the non-hydrostatic mesoscale model AROME are compared with Cloudnet remote sensing observations at two locations: the ARM SGP site in central Oklahoma, and the DWD observatory at Lindenberg, Germany. The results show that AROME significantly underestimates the variability of vertical velocity at cloud base compared to observations at their nominal resolution; the standard deviation of vertical velocity in the model is typically 4-8 times smaller than observed, and even more during the winter at Lindenberg. Averaging the observations to the horizontal scale corresponding to the physical grid spacing of AROME (2.5 km) explains 70-80 % of the underestimation by the model. Further averaging of the observations in the horizontal is required to match the model values for the standard deviation in vertical velocity. This indicates an effective horizontal resolution for the AROME model of at least 10 km in the presented case. Adding a TKE-term on the resolved grid-point vertical velocity can compensate for the underestimation, but only for altitudes below approximately the boundary layer top height. The results illustrate the need for a careful consideration of the scales the model is able to accurately resolve, as well as for a special treatment of sub-grid scale variability of vertical velocities in kilometer-scale atmospheric models, if processes such as aerosol-cloud interactions are to be included in the future.

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Section: Observationsmentioning

confidence: 99%

Section: Observationsmentioning

confidence: 99%

Cloud base vertical velocity statistics: a comparison between an atmospheric mesoscale model and remote sensing observations

et al. 2011

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“…It cycles through four different operational modes, each with different sensitivity, spatial and temporal resolution, and aliasing characteristics. Details of the operational parameters of the MMCR at each ARM site are given by Clothiaux et al [1999]. The Active Remote Sensing of Clouds (ARSCL) product described by Clothiaux et al [2000] combines information from all modes of the MMCR with MPL and CEIL data to produce a best estimate of cloud boundaries, hydrometeor reflectivities and vertical velocities at 10 s temporal and 45 m vertical resolution.…”

Section: Remote Sensing Observationsmentioning

confidence: 99%

“…It depends on the mode used and the distance of the hydrometeors from the antenna. For each mode, we estimate the sensitivity at each range gate based on the parameters of the operational modes at Nauru given by Clothiaux et al [1999]. If radar reflectivity is expressed in units of mm 6 /m 3 , then the calibration error is multiplicative while the receiver noise error is additive.…”

Section: Forward Probability Density Functionmentioning

confidence: 99%

“…Advances in instrumentation within the last 5 years have led to the development of unattended millimeter wavelength cloud radars with the vertical resolution ($45 m) and sensitivity (À60 dBZ) required to study boundary layer clouds [Moran et al, 1998;Clothiaux et al, 1999]. Several algorithms have been developed that seek to relate measured radar reflectivity to liquid water content.…”

Section: Introductionmentioning

confidence: 99%

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A Bayesian algorithm for the retrieval of liquid water cloud properties from microwave radiometer and millimeter radar data

2002

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[1] We present a new algorithm for retrieving optical depth and liquid water content and effective radius profiles of nonprecipitating liquid water clouds using millimeter wavelength radar reflectivity and dual-channel microwave brightness temperatures. The algorithm is based on Bayes' theorem of conditional probability and combines prior information on cloud microphysics with the remote sensing observations. Prior probability distribution functions for liquid water clouds were derived from the second, third, and sixth moments of droplet size distributions measured by in situ aircraft probes in shallow tropical cumuli. The algorithm also calculates error bars for each retrieved parameter. To assess the algorithm, we perform retrieval simulations using radar reflectivity and brightness temperatures simulated from tropical cumulus fields calculated by a large eddy simulation model with explicit microphysics. These retrieval simulations show that the Bayesian algorithm has similar magnitude errors to current retrieval methods for liquid water content and liquid water path retrievals but has much smaller errors for effective radius and optical depth. We also perform retrievals on three months of data from the Atmospheric Radiation Measurement (ARM) Program's site on Nauru in the tropical west Pacific. For nonprecipitating liquid water clouds over Nauru during June-August 1999 we retrieve a mean optical depth of 9.2, mean liquid water content of 0.112 g/m 3 , and mean effective radius of 7.8 mm. The Bayesian method is a flexible approach to cloud profile remote sensing and could be expanded to other sites or cloud types.

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RemoteRaman Spectroscopy. Profiling Water Vapor and Aerosols in the Troposphere UsingRaman Lidars

Turner¹,

Whiteman²

2001

Handbook of Vibrational Spectroscopy

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The Atmospheric Radiation Measurement Program Cloud Radars: Operational Modes

Cited by 88 publications

References 7 publications

Cloud base vertical velocity statistics: a comparison between an atmospheric mesoscale model and remote sensing observations

Cloud base vertical velocity statistics: a comparison between an atmospheric mesoscale model and remote sensing observations

A Bayesian algorithm for the retrieval of liquid water cloud properties from microwave radiometer and millimeter radar data

RemoteRaman Spectroscopy. Profiling Water Vapor and Aerosols in the Troposphere UsingRaman Lidars

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