Polarization Diversity for Millimeter Spaceborne Doppler Radars: An Answer for Observing Deep Convection?

Battaglia, Alessandro; Tanelli, Simone; Kollias, Pavlos

doi:10.1175/jtech-d-13-00085.1

Cited by 39 publications

(50 citation statements)

References 37 publications

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“…Incidentally, the mean Doppler velocities appear very noisy in correspondence to the areas characterized by strong MS enhancement, even if the signal is significantly above noise (not shown). This is connected to a decorrelation effect of MS, which is known to broaden the Doppler spectrum [e.g., Battaglia et al , ]. Further investigations of this aspect are left for future work.…”

Section: Retrieval Resultsmentioning

confidence: 99%

Using a multiwavelength suite of microwave instruments to investigate the microphysical structure of deep convective cores

et al. 2016

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Due to the large natural variability of its microphysical properties, the characterization of solid precipitation is a longstanding problem. Since in situ observations are unavailable in severe convective systems, innovative remote sensing retrievals are needed to extend our understanding of such systems. This study presents a novel technique able to retrieve the density, mass, and effective diameter of graupel and hail in severe convection through the combination of airborne microwave remote sensing instruments. The retrieval is applied to measure solid precipitation properties within two convective cells observed on 23–24 May 2014 over North Carolina during the IPHEx campaign by the NASA ER‐2 instrument suite. Between 30 and 40 degrees of freedom of signal are associated with the measurements, which is insufficient to provide full microphysics profiling. The measurements have the largest impact on the retrieval of ice particle sizes, followed by ice water contents. Ice densities are mainly driven by a priori assumptions, though low relative errors in ice densities suggest that in extensive regions of the convective system, only particles with densities larger than 0.4 g/cm3 are compatible with the observations. This is in agreement with reports of large hail on the ground and with hydrometeor classification derived from ground‐based polarimetric radars observations. This work confirms that multiple scattering generated by large ice hydrometeors in deep convection is relevant for airborne radar systems already at Ku band. A fortiori, multiple scattering will play a pivotal role in such conditions also for Ku band spaceborne radars (e.g., the GPM Dual Precipitation Radar).

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Section: Retrieval Resultsmentioning

confidence: 99%

Using a multiwavelength suite of microwave instruments to investigate the microphysical structure of deep convective cores

et al. 2016

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“…Simulating cloud and precipitation processes requires improved observations to better identify the conditions wherein particular microphysical processes are active, as well as dominant. In response to the high cost associated with in situ aircraft observations, two‐way interactive studies between cloud microphysical process observations and modeling have looked to draw insights from radar signatures known to be sensitive to changes in bulk or spectral particle distribution properties that may be useful for improving cloud process parameterizations [e.g., Kollias et al , , ; Kumjian and Ryzhkov , , ; Ryzhkov et al , , ; Kumjian et al , ; Battaglia et al , ; Andric et al , ; Kumjian and Prat , ; Kalesse et al , ].…”

Section: Introductionmentioning

confidence: 99%

Insights into riming and aggregation processes as revealed by aircraft, radar, and disdrometer observations for a 27 April 2011 widespread precipitation event

et al. 2016

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This study presents aircraft spiral ascent and descent observations intercepting a transition to riming processes during widespread stratiform precipitation. The sequence is documented using collocated scanning and profiling radar, including longer-wavelength dual polarization measurements and shorter-wavelength Doppler spectra. Riming regions are supported using aircraft measurements recording elevated liquid water concentrations, spherical particle shapes, and saturation with respect to water. Profiling cloud radar observations indicate riming regions during the event as having increasing particle fall speeds, rapid time-height changes, and bimodalities in Doppler spectra. These particular riming signatures are coupled to scanning dual polarization radar observations of higher differential reflectivity (Z DR ) aloft. Reduced melting layer enhancements and delayed radar bright-band signatures in the column are also observed during riming periods, most notably with the profiling radar observations. The bimodal cloud radar Doppler spectra captured near riming zones indicate two time-height spectral ice peaks, one rimed particle peak, and one peak associated with pristine ice needle generation and/or growth between À4°C and À7°C also sampled by aircraft probes. This pristine needle population gives a partial explanation for the enhanced Z DR we observe near this rimed particle region. The riming signatures aloft and radar measurements within the melting level are weakly lag correlated (r~0.6) with smaller median drop sizes at the surface, as compared with later times when aggregation of larger particle sizes was believed dominant.

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“…It is therefore timely to investigate what is the added value of the Ka radar channel when observing deep convection. Spaceborne radar observations of convective cores are particularly challenging for at least two reasons (see also discussion in Battaglia et al [, ]). First, they often exhibit 3‐D structure variability at spatial scales smaller than the DPR instrument footprint (4 × 4 km 2 ) with consequential nonuniform beam filling issues [ Takahashi et al , ; Iguchi et al , ; Tanelli et al , ; Meneghini et al , ].…”

Section: Introductionmentioning

confidence: 99%

Multiple scattering in observations of the GPM dual‐frequency precipitation radar: Evidence and impact on retrievals

et al. 2015

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This paper illustrates how multiple scattering signatures affect Global Precipitation Measuring (GPM) Mission Dual-Frequency Precipitation Radar (DPR) Ku and Ka band reflectivity measurements and how they are consistent with prelaunch assessments based on theoretical considerations and confirmed by airborne observations. In particular, in the presence of deep convection, certain characteristics of the dual-wavelength reflectivity profiles cannot be explained with single scattering, whereas they are readily explained by multiple-scattering theory. Examples of such signatures are the absence of surface reflectivity peaks and anomalously small reflectivity slopes in the lower troposphere. These findings are relevant for DPR-based rainfall retrievals and stratiform/convective classification algorithms when dealing with deep convective regions. A path to refining the rainfall inversion problem is proposed by adopting a methodology based on a forward operator which accounts for multiple scattering. A retrieval algorithm based on this methodology is applied to a case study over Africa, and it is compared to the standard DPR products obtained with the at-launch version of the standard algorithms.

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Polarization Diversity for Millimeter Spaceborne Doppler Radars: An Answer for Observing Deep Convection?

Cited by 39 publications

References 37 publications

Using a multiwavelength suite of microwave instruments to investigate the microphysical structure of deep convective cores

Using a multiwavelength suite of microwave instruments to investigate the microphysical structure of deep convective cores

Insights into riming and aggregation processes as revealed by aircraft, radar, and disdrometer observations for a 27 April 2011 widespread precipitation event

Multiple scattering in observations of the GPM dual‐frequency precipitation radar: Evidence and impact on retrievals

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