Impact of Mass–Size Parameterizations of Frozen Hydrometeors on Microphysical Retrievals: Evaluation by Matching Radar to In Situ Observations from GCPEx and OLYMPEx

a. Datasets

GCPEx took place in Ontario, Canada, between January and March 2012, and was led by NASA and Environment Canada (EC). As shown in Table 1, the meteorological events sampled consisted mostly of light precipitation in the form of snowfall (Skofronick-Jackson et al. 2015). OLYMPEx, led by NASA with significant contributions from EC, took place in Washington State, between November 2015 and February 2016. OLYMPEx sampled a variety of heavy precipitation ranging from stratiform to convective systems (see Table 1) (Houze et al. 2017).

Table 1.

Meteorological events during GCPEx and OLYMPEx and number of radar observations with collocated CIT (at all temperatures) for collocation margins (δ_r = 0.5 km, δ_h = 50 m, δ_t = 5 min).

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GCPEx and OLYMPEx were ground-validation experiments to improve the snowfall retrieval algorithms of GPM. In both experiments, the CIT measured the state of the atmosphere using sensors for temperature, King and Nevzorov probes for the water content, and High Volume Precipitation Spectrometer, version 3 (HVPS3), and two-dimensional stereo (2DS) particle imaging probes. The particle images were processed to derive PSD and aspect ratio spectra, for D ∈ [0.8, 30] mm (D ∈ [0.1, 1.28] mm) for HVPS3 (2DS) (Skofronick-Jackson et al. 2015). The 2DS and HVPS3 observations were combined at 1 mm to produce a PSD for D ∈ [0.1, 30] mm. The significant quality control of the image processing included corrections for shattered particles, removal of coincident particles in the same frame, and rejection of particles due to poor focus or instrument malfunction (Heymsfield and Parrish 1978; Field et al. 2006; McFarquhar et al. 2017).

Radar observations were acquired by APR flown on NASA’s DC8 aircraft, and by the ground-based D3R. During GCPEx, APR was in its “second generation” (APR2) version and recorded Ku- and Ka-band data. OLYMPEx marked the first deployment of APR3 (third generation), with observations at Ku, Ka, and W bands (Durden et al. 2020). This article will focus on Ku- and Ka-band reflectivities, since these channels are common to GCPEx and OLYMPEx and to APR and D3R, respectively. Some results of W-band measurements (only available from APR in OLYMPEx) will be shown but only for illustration purposes. APR is a cross-track scanning (±25°) radar with a 30-m range sampling (Sadowy et al. 2003). D3R (Ku- and Ka-band radar), with a range sampling of 150 m and maximum range of 30 km, was operated from the Centre for Atmospheric Research Experiments (CARE) site (in Barrie, Ontario) during GCPEx, and from the NPOL site (near Taholah, Washington) during OLYMPEx. Owing to the spatial resolution and sensitivity of APR (detection thresholds of ~(0, −20, −30) dBZ, at 10-km distance for Ku, Ka, and W bands), it can detect fine atmospheric features that can be challenging to detect by D3R (thresholds at ~(−15, 5) dBZ at 10-km range for Ku and Ka bands in GCPEx, and ~(−10, 5) dBZ in OLYMPEx), especially when D3R is pointed at a high elevation angle.

APR and D3R records have been calibrated independently. For APR, the absolute calibration of the Ku band was done using surface returns from clear-air profiles over water bodies (Great Lakes in GCPEx, Pacific Ocean in OLYMPEx); Ka and W bands were calibrated relative to Ku band by ensuring the consistency between 1) surface returns over water and 2) echoes from cloud tops where all channels should be in Rayleigh scattering regime (Durden et al. 2020). For D3R, the reflectivity was calibrated “absolutely” using a metal sphere and a tower-mounted corner reflector. For the relative calibration, the reflectivity estimates were verified for consistency using light-rain measurements close to the radar (Vega et al. 2014). Both for APR and D3R, calibration absolute errors are within 1 dB.

Given the observing geometries of APR (top-down) and D3R (bottom-up), attenuation affects the observed precipitation in different ways. We correct for gaseous attenuation using a standard millimeter-wave propagation model (Liebe 1985). The required profiles of temperature, pressure and relative humidity are obtained from MERRA (Rienecker et al. 2011). We do not attempt to correct for attenuation by condensed water to avoid introducing errors that could bias our analyses. Instead, we screen the profiles where the attenuation due to liquid or mixed-phase particles is severe and use only profiles where the path attenuations at Ku and Ka bands are negligible (see details in section 4a and appendix A).

b. Collocation strategy

We adopt a radar-centric approach to collocate in situ measurements with radar observations. This allows us to identify all in situ samples that are relevant to each radar observation, and establishes an invariant mapping of the in situ data on the radar data, so that there is no need to recollocate in situ data after each reprocessing of the radar data. To clarify the description, let P_RAD(t_RAD) = [r_RAD(t_RAD), h_RAD(t_RAD)] be the spatial coordinates of a valid radar record (APR or D3R) at time t_RAD, with $r_{\text{RAD}}\left(t_{\text{RAD}}\right)\in {\mathrm{ℝ}}^2$ the vector of local horizontal coordinates and h_RAD(t_RAD) the altitude. Similarly, let P_CIT(t_CIT) = [r_CIT(t_CIT), h_CIT(t_CIT)] be the coordinates of the CIT aircraft at time t_CIT. We adopt collocation margins (δ_r = 0.5 km, δ_h = 50 m, δ_t = 5 min) derived by an analysis of the spatiotemporal decorrelation of the radar signal. For every P_RAD(t_RAD), we find all the P_CIT such that |r_CIT − r_RAD| ≤ δ_r, |h_CIT − h_RAD| ≤ δ_h and |t_CIT − t_RAD| ≤ δ_t: these constitute the “close” CIT points. The data at the close points are uniformly averaged, which mitigates the impact of extreme values.

While the chosen collocation margins are tight, to warrant the simultaneity of the measurements from the various instruments, we still obtain large datasets, as shown by Table 1: more than 90 000 (50 000) airborne records and more than 80 000 (50 000) ground-based records for GCPEx (OLYMPEx). In what follows, we will replace the “RAD” subscript with “A” and “D” to specify APR and D3R data, respectively. Even though all the quantities (reflectivity factor, PSD) used in our article are normalized by the sampled volume, the volume sampled by the CIT is necessarily different (and smaller) than the RV of the radar. This could cause issues in terms of spatiotemporal representativeness. One way to mitigate this issue is to integrate in time the CIT measurements to increase the volume sampled by the in situ probes and obtain measurements that are more representative of the content of the RV. Here, the CIT data, initially sampled every second, are integrated over 5 s (which represents a sampled length between 600 and 1000 m for typical aircraft speeds).

Figure 1 shows the radar profiles of all cases of triple collocation APR–CIT–D3R in OLYMPEx. To find these profiles, we first consider the coordinates of the CIT–APR and CIT–D3R collocated samples, and require that the distance between CIT locations be within the (δ_r, δ_t, δ_h) margin. The resulting 435 profiles displayed in Fig. 1 illustrate the capabilities of the radars. The W-band reflectivity of APR [top row, shown only for illustration purposes as the article focuses on (Ku, Ka)-band data] is highly sensitive to particles in the top of clouds, but heavily attenuated toward the surface (the surface echo disappears). On 2 December 2015 (the dates are indicated as labels in top row of Fig. 1 and separated by dashed red lines), Z_A,W was unavailable. The Ka band of APR, Z_A,Ka (row 2), has a sensitivity similar to that of Z_A,W, as can be seen in the cloud tops, and it is less attenuated. Owing to the tight collocation margins, there is a good agreement between Z_A,Ka and Z_D,Ku the D3R observations at Ku band (row 3). The main differences appear in the profiles of the dual-wavelength ratios (DWR) Z_D,Ku−Ka (row 4) and Z_A,Ku−Ka (row 5): for D3R, since Z_D,Ka has less sensitivity than Z_D,Ku, there are places with missing DWR in the top parts of Z_D,Ku−Ka; conversely, for APR, Z_A,Ku has less sensitivity than Z_A,Ka and there are empty spots in the top parts of Z_A,Ku−Ka (above 6 km in the stratiform event of 12 November 2015). The ground-based DWR Z_D,Ku−Ka (row 4) shows how liquid scatterers increase the attenuation significantly. For instance, on 12 November 2015, for the first 90 profiles, Z_D,Ka is strongly attenuated above the melting layer (clearly visible with a bright band around 2 km of altitude), whereas for the next profiles, the attenuation of Z_D,Ka increases drastically from the surface upward, most likely due to liquid or mixed-phase precipitation. The presence of liquid precipitation can be inferred from the temperature (row 6) measured by CIT (position indicated by black dots in the top five panels). The DWR of APR (row 5) is less affected by attenuation since, above the melting layer, the attenuation is mostly caused by low-density frozen hydrometeors. Instead, higher values of Z_A,Ku−Ka, indicative of larger scatterers, show the growth of particles in the melting layer, for example, on 12 November and 2 December 2015. The bottom row displays the PSD obtained from 2DS and HVPS3 [denoted N(D) with D the maximum particle size] and shows the abundance of smaller frozen particles (D < 1 mm and T < −7°C), for example, on 13 November 2015. Even though this triple-collocation example shows that D3R’s Ka-band measurements are severely affected by attenuation, there are many more cases of D3R–CIT collocations where the attenuation is not as severe (more than 55 000 and 19 000 in GCPEx and OLYMPEx, respectively; see Fig. 4).

Triple collocations APR–CIT–D3R during OLYMPEx. Radar profiles measured (first, second, and fifth rows) by APR3 and (third and fourth rows) by D3R: W-band (Z_A,W) and Ka-band (Z_A,Ka) reflectivity from APR in the top two rows, Ku-band reflectivity (Z_D,Ku) from D3R in the third row; DWR (Z_Ku–Ka) from D3R in the fourth row and APR in the fifth row. In situ measurements in the bottom two rows: air temperature in the sixth row and particle size distribution N(D) derived from 2DS and HVPS3 vs the maximum particle size D in the bottom row. The altitude of CIT is shown as black dots in rows 1 to 5, and the dates (month-day format) are labeled in the top row and separated by dashed red lines in all rows.

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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Triple collocations APR–CIT–D3R during OLYMPEx. Radar profiles measured (first, second, and fifth rows) by APR3 and (third and fourth rows) by D3R: W-band (Z_A,W) and Ka-band (Z_A,Ka) reflectivity from APR in the top two rows, Ku-band reflectivity (Z_D,Ku) from D3R in the third row; DWR (Z_Ku–Ka) from D3R in the fourth row and APR in the fifth row. In situ measurements in the bottom two rows: air temperature in the sixth row and particle size distribution N(D) derived from 2DS and HVPS3 vs the maximum particle size D in the bottom row. The altitude of CIT is shown as black dots in rows 1 to 5, and the dates (month-day format) are labeled in the top row and separated by dashed red lines in all rows.

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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Triple collocations APR–CIT–D3R during OLYMPEx. Radar profiles measured (first, second, and fifth rows) by APR3 and (third and fourth rows) by D3R: W-band (Z_A,W) and Ka-band (Z_A,Ka) reflectivity from APR in the top two rows, Ku-band reflectivity (Z_D,Ku) from D3R in the third row; DWR (Z_Ku–Ka) from D3R in the fourth row and APR in the fifth row. In situ measurements in the bottom two rows: air temperature in the sixth row and particle size distribution N(D) derived from 2DS and HVPS3 vs the maximum particle size D in the bottom row. The altitude of CIT is shown as black dots in rows 1 to 5, and the dates (month-day format) are labeled in the top row and separated by dashed red lines in all rows.

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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a. Modeling approach assuming a fixed mass–size parameterization

b. Uncertainties due to the MSP

To quantify the effect of the uncertain mass of the particles, the simulations are perturbed by considering 56 different MSPs, which are power laws denoted {P_k}_k=1,...,56 (Pruppacher and Klett 1996). More explicitly, if the parameterization index is written as k = 8(j − 1) + i,

$m_k\left(D\right)=a_i{D}^{b_j},\text{for}i=1,\dots ,8\text{and}j=1,\dots ,7,$(5)

with a₁ = 0.005, a₂ = 0.0010, a₃ = 0.0019, a₄ = 0.0037, a₅ = 0.0071, a₆ = 0.0139, a₇ = 0.0269, a₈ = 0.0524 in cgs units (i.e., a_i is in $\text{g}\hspace{0.17em}{\text{cm}}^{-b_j}$), and b₁ = 1.01, b₂ = 1.34, b₃ = 1.67, b₄ = 2, b₅ = 2.34, b₆ = 2.67 and b₇ = 3. One can convert the prefactors to MKS units as follows $a_{i,\left(\text{MKS}\right)}=a_{i,\left(\text{cgs}\right)}{10}^{2b_j-3}$, where the corresponding m, D, and a_i,(MKS) would be expressed in kilograms, meters, and $\text{kg}\hspace{0.17em}{\text{m}}^{-b_j}$, respectively. All these m(D) relationships have merits of their own as they were generally derived from field or laboratory experiments. In particular, P₅₆ (with a = 0.0524 and b = 3) corresponds to assuming a constant density of 0.1 g cm⁻³, which is common in GPM algorithms (Liao et al. 2005; Grecu et al. 2011). Based on observational evidence, the exponent b should range between ~1.7 and 3 (Pruppacher and Klett 1996; Haddad et al. 2017). However, in this article, a wider range of values is considered, with b as low as 1.01, to test whether such coefficients still produce accurate scattering computations. This approach is similar to the one of Fontaine et al. (2014), who assumed b as low as 1.04. Thus, for every in situ measurement, the T-matrix simulations produce 56 realizations of reflectivities at Ku and Ka band, and moments (M, D_m, S_m). Table 2 shows the effect of the MSP uncertainty on the simulations. Given a parameterization P_k, a CIT record time t, and a variable X_k (reflectivity or moment in decibels), the spread of X_k at time t due to the MSP perturbation is

$s_X\left(t\right)=\max \left[X_k\left(t\right)]\hspace{0.17em}-\min [X_k\left(t\right)\right].$(6)

Table 2 confirms that the MSP perturbation affects mostly the IWC and the reflectivities. Since the MSP perturbation modifies neither the shape nor size of the scatterers, the DWR, D_m and S_m are marginally affected by the MSP perturbation. The robustness of D_m and S_m comes also from their definition as mass-normalized averages [see Eq. (4)].

Table 2.

Effect of the MSP perturbation on the simulated radar reflectivities and bulk moments. The metric s_X is the range of variation of variable X, as defined in Eq. (6) and expressed in dB (statistics of s_X smaller than 0.5 dB are rounded off to 0 dB). The slight differences between GCPEx and OLYMPEx results are due to the differences between the measured PSDs.

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a. Screening radar profiles for liquid attenuation

First, the radar profiles are screened to eliminate those severely attenuated by liquid particles. The attenuation by frozen particles is not addressed because 1) GCPEx and OLYMPEx are devoid of high-density hydrometeors (such as hail or graupel) and the attenuation at Ku and Ka bands by low-density snow/ice is not as strong as the liquid attenuation, and 2) the attenuation by frozen particles depends on the yet unknown masses of the scatterers. As explained in appendix A, the correction uses collocated profiles of temperature from MERRA (“MERRA300. prod.assim.inst3_3d_asm_Cp” product), and k–Z relationships derived from GCPEx and OLYMPEx PSDs. The resulting liquid path-integrated attenuation (PIA_liq) between the radar and CIT allows us to eliminate all the collocated samples where PIA_liq > PIA_max = 0.5 dB. The liquid water content (LWC) measured by the King probe (designed to measure LWC ∈ [0.02, 5.0] g m⁻³) is also used to eliminate all CIT records where LWC > 5 × 10⁻² g m⁻³.

b. MSP optimization

c. Retrieved bulk moments (M, D_m, S_m) and references

d. Microphysical dashboard: Illustration using triple collocations APR–CIT–D3R

We now introduce the retrieval dashboard used to analyze the OMSPs: it is a figure (see, e.g., Fig. 2) consisting of four panels (labeled by yellow boxes) that allow us to jointly study the parameters of the OMSPs (Fig. 2a), the collocated radar reflectivities (Figs. 2b,d), the bulk moments (Figs. 2b,c), and to compare various retrievals. The dashboard is illustrated in Fig. 2 for OMSPs obtained using triple-collocation data from GCPEx, that is, (Ku, Ka) data from APR and D3R in cases where APR, CIT, and D3R measurements are collocated.

Retrieval dashboard from triple collocations in GCPEx (APR vs D3R). (a) Distribution of optimal MSPs as a function of (a, b) (marker size represents the occurrence frequency, and solid line is fit b_fit = K₁a_dB + K₂ for OMSP “diagonal”). (b) Mean values, conditional to (Z_Ku, Z_Ku−Ka) measured by (top),(middle) APR and (bottom) D3R, of bulk moments [references (M_Nev, D₀, S₀) in top row, retrievals (M, D_m, S_m) in bottom two rows]: IWC M or M_Nev (marker color), mean diameter D_m or D₀ (marker size), and spread S_m or S₀ (marker type). (c) Scatterplots comparing bulk moments [(left) M, (center) D_m, and (right) S_m] retrieved from APR (horizontal axis) to those from D3R and references (vertical axis, marker size represents the occurrence frequency). (d) Profiles where retrievals from APR and D3R agree within 20% of relative error: vertical profiles of quantiles of (left) Z_Ku and (center) Z_Ka, and (right) number of samples.

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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Retrieval dashboard from triple collocations in GCPEx (APR vs D3R). (a) Distribution of optimal MSPs as a function of (a, b) (marker size represents the occurrence frequency, and solid line is fit b_fit = K₁a_dB + K₂ for OMSP “diagonal”). (b) Mean values, conditional to (Z_Ku, Z_Ku−Ka) measured by (top),(middle) APR and (bottom) D3R, of bulk moments [references (M_Nev, D₀, S₀) in top row, retrievals (M, D_m, S_m) in bottom two rows]: IWC M or M_Nev (marker color), mean diameter D_m or D₀ (marker size), and spread S_m or S₀ (marker type). (c) Scatterplots comparing bulk moments [(left) M, (center) D_m, and (right) S_m] retrieved from APR (horizontal axis) to those from D3R and references (vertical axis, marker size represents the occurrence frequency). (d) Profiles where retrievals from APR and D3R agree within 20% of relative error: vertical profiles of quantiles of (left) Z_Ku and (center) Z_Ka, and (right) number of samples.

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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Retrieval dashboard from triple collocations in GCPEx (APR vs D3R). (a) Distribution of optimal MSPs as a function of (a, b) (marker size represents the occurrence frequency, and solid line is fit b_fit = K₁a_dB + K₂ for OMSP “diagonal”). (b) Mean values, conditional to (Z_Ku, Z_Ku−Ka) measured by (top),(middle) APR and (bottom) D3R, of bulk moments [references (M_Nev, D₀, S₀) in top row, retrievals (M, D_m, S_m) in bottom two rows]: IWC M or M_Nev (marker color), mean diameter D_m or D₀ (marker size), and spread S_m or S₀ (marker type). (c) Scatterplots comparing bulk moments [(left) M, (center) D_m, and (right) S_m] retrieved from APR (horizontal axis) to those from D3R and references (vertical axis, marker size represents the occurrence frequency). (d) Profiles where retrievals from APR and D3R agree within 20% of relative error: vertical profiles of quantiles of (left) Z_Ku and (center) Z_Ka, and (right) number of samples.

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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e. Microphysical dashboard for triple collocations from OLYMPEx

Figure 3 shows the retrieval dashboard for triple collocations from OLYMPEx. These results correspond to the profiles shown in Fig. 1, where the liquid PIA and local LWC are lower than the thresholds described in section 4a. Figure 3a shows that there are half as many usable samples than in the GCPEx case due to more severe liquid attenuation (2276 APR and 802 D3R samples in OLYMPEx vs 4911 APR and 1901 D3R samples in GCPEx). The preferential MSPs are still clustered around a diagonal of the (a, b) plane; however, this diagonal is different from the diagonal in the GCPEx collocations (Fig. 2). There are also differences between APR- and D3R-based diagonals. These discrepancies are due to differences in the observed reflectivities, which can be seen in Fig. 3b: the APR observations (top two rows) occupy a larger domain of the (Z_Ku, Z_Ku−Ka) plane than the D3R observations, particularly for Z_Ku ≥ 20 dBZ. A comparison between retrieved microphysics in Fig. 3c shows a good agreement between retrievals and with the references. The saturation of the Nevzorov probe for larger IWC can be seen through the negative bias between M_Nev and the retrieved M. Figure 3d shows a remarkable resemblance between profiles of Z_Ku and Z_Ka measured by APR and D3R (all from 5 December 2015; see Fig. 1), which again comforts the idea of a suitable cross calibration between the two radars.

Retrieval dashboard from triple collocations in OLYMPEx (APR vs D3R). (a) Distribution of OMSPs as a function of (a, b) (marker size represents the occurrence frequency, and solid line is fit for OMSP “diagonal”). (b) Mean values, conditional to (Z_Ku, Z_Ku−Ka) measured by (top),(middle) APR and (bottom) D3R, of bulk moments (references in top row, retrievals in middle and bottom): IWC M or M_Nev (marker color), mean diameter D_m or D₀ (marker size), and spread S_m or S₀ (marker type). (c) Scatterplots comparing bulk moments [(left) M, (center) D_m, and (right) S_m] retrieved from APR (horizontal axis) to those from D3R and references (vertical axis, marker size represents the occurrence frequency). (d) Profiles where retrievals from APR and D3R agree within 20% of relative error: vertical profiles of quantiles of (left) Z_Ku and (center) Z_Ka, and (right) number of samples.

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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Retrieval dashboard from triple collocations in OLYMPEx (APR vs D3R). (a) Distribution of OMSPs as a function of (a, b) (marker size represents the occurrence frequency, and solid line is fit for OMSP “diagonal”). (b) Mean values, conditional to (Z_Ku, Z_Ku−Ka) measured by (top),(middle) APR and (bottom) D3R, of bulk moments (references in top row, retrievals in middle and bottom): IWC M or M_Nev (marker color), mean diameter D_m or D₀ (marker size), and spread S_m or S₀ (marker type). (c) Scatterplots comparing bulk moments [(left) M, (center) D_m, and (right) S_m] retrieved from APR (horizontal axis) to those from D3R and references (vertical axis, marker size represents the occurrence frequency). (d) Profiles where retrievals from APR and D3R agree within 20% of relative error: vertical profiles of quantiles of (left) Z_Ku and (center) Z_Ka, and (right) number of samples.

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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Retrieval dashboard from triple collocations in OLYMPEx (APR vs D3R). (a) Distribution of OMSPs as a function of (a, b) (marker size represents the occurrence frequency, and solid line is fit for OMSP “diagonal”). (b) Mean values, conditional to (Z_Ku, Z_Ku−Ka) measured by (top),(middle) APR and (bottom) D3R, of bulk moments (references in top row, retrievals in middle and bottom): IWC M or M_Nev (marker color), mean diameter D_m or D₀ (marker size), and spread S_m or S₀ (marker type). (c) Scatterplots comparing bulk moments [(left) M, (center) D_m, and (right) S_m] retrieved from APR (horizontal axis) to those from D3R and references (vertical axis, marker size represents the occurrence frequency). (d) Profiles where retrievals from APR and D3R agree within 20% of relative error: vertical profiles of quantiles of (left) Z_Ku and (center) Z_Ka, and (right) number of samples.

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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While all the dashboards discussed so far are built using an “observation” hypercube (Z_Ku, Z_Ku−Ka, T), one could also build a dashboard conditioned by other parameters. For instance, with a “thermodynamic” hypercube [(T, RH, EDR) with RH the relative humidity with respect to ice, and EDR the eddy dissipation rate], one could compare retrievals from single- and dual-frequency radar observations, or from non-Doppler and Doppler radar observations.

a. OMSPs constrained by collocated D3R observations: GCPEx versus OLYMPEx

First, all acceptable D3R observations from GCPEx and OLYMPEx are used, separately, to constrain T-matrix simulations. Figure 4a shows that many more samples are accurately simulated in GCPEx than in OLYMPEx (more than 16 000 vs ~4800). This results from the lower impact of attenuation on the radar observations in GCPEx (lighter precipitation) than in OLYMPEx. Similar to Figs. 2 and 3, the preferential MSPs are mostly along a slanted line of the (a, b) plane, and the OMSP diagonals of GCPEx and OLYMPEx are almost identical. D3R observations in both field campaigns occupy the same region of the (Z_Ku, Z_Ku−Ka) space (see Fig. 4b, second row for GCPEx and bottom row for OLYMPEx). The Nevzorov probe does not capture the higher values of IWC seen in GCPEx, most likely due to saturation of the probe. Figure 4c shows a good agreement between GCPEx- and OLYMPEx-trained retrievals of M and D_m. For S_m, the correlation between GCPEx and OLYMPEx results is weaker. Thus, while the retrievals of the lower-order moments seem robust to the change in training dataset, the retrieved spread seems to depend on the meteorological regime being measured. Figure 4d is slightly modified compared to Figs. 2d and 3d. It still shows vertical profiles of reflectivity for cases where GCPEx and OLYMPEx retrievals agree well (less than 20% relative error for all bulk moments); however, the left column shows the median profile of Z_Ku (thin line) and Z_Ka (thick line) as a function of the altitude [similar to a contour-frequency-by-altitude diagram (CFAD)], whereas the right column shows the same profiles but as a function of temperature (CFTD). In both plots, the vertical distribution of the collocated samples (equivalent to the histograms shown in the right column of Figs. 2d and 3d) is shown as circles, with sizes proportional to the number of collocated samples (the alternative would have been to plot one distribution vs T and another one vs the altitude, which would clutter Fig. 4d). The CFAD representation hardly shows any resemblance between GCPEx and OLYMPEx: the samples in GCPEx and OLYMPEx are located at different altitudes (red circles for OLYMPEx mostly above 3 km, whereas the blue circles for GCPEx are all below 3.5 km), and the reflectivities from OLYMPEx are significantly higher (more than 10 dB) than those from GCPEx. On the other hand, the CFTD representation shows that the collocated samples are at the same temperatures (overlapping circles), and there is a high resemblance between Ka-band profiles for T ∈ [−25, −8]°C.

Retrievals from D3R (Ku, Ka) observations (GCPEx vs OLYMPEx). (a) Distribution of OMSPs as a function of (a, b) (marker size represents the occurrence frequency, and solid line is fit for OMSP “diagonal”). (b) Mean values of bulk moments [(top) references, (middle),(bottom) retrievals], conditional to (Z_Ku, Z_Ku−Ka) measured by D3R in (top),(middle) GCPEx and (bottom) OLYMPEx: IWC (marker color), mean diameter (marker size), and spread (marker type). (c) Scatterplots comparing bulk moments retrieved from D3R-GCPEx (horizontal axis) to those from D3R-OLYMPEx and references (vertical axis, marker size represents the occurrence frequency). (d) Profiles where retrievals from D3R-GCPEx and D3R-OLYMPEx agree within 20% of relative error: profiles, as a function of (left) altitude and (right) temperature of the median of Z_Ku (thick line) and Z_Ka (thin line), and number of collocated samples (circles with sizes representing the number of samples).

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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Retrievals from D3R (Ku, Ka) observations (GCPEx vs OLYMPEx). (a) Distribution of OMSPs as a function of (a, b) (marker size represents the occurrence frequency, and solid line is fit for OMSP “diagonal”). (b) Mean values of bulk moments [(top) references, (middle),(bottom) retrievals], conditional to (Z_Ku, Z_Ku−Ka) measured by D3R in (top),(middle) GCPEx and (bottom) OLYMPEx: IWC (marker color), mean diameter (marker size), and spread (marker type). (c) Scatterplots comparing bulk moments retrieved from D3R-GCPEx (horizontal axis) to those from D3R-OLYMPEx and references (vertical axis, marker size represents the occurrence frequency). (d) Profiles where retrievals from D3R-GCPEx and D3R-OLYMPEx agree within 20% of relative error: profiles, as a function of (left) altitude and (right) temperature of the median of Z_Ku (thick line) and Z_Ka (thin line), and number of collocated samples (circles with sizes representing the number of samples).

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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Retrievals from D3R (Ku, Ka) observations (GCPEx vs OLYMPEx). (a) Distribution of OMSPs as a function of (a, b) (marker size represents the occurrence frequency, and solid line is fit for OMSP “diagonal”). (b) Mean values of bulk moments [(top) references, (middle),(bottom) retrievals], conditional to (Z_Ku, Z_Ku−Ka) measured by D3R in (top),(middle) GCPEx and (bottom) OLYMPEx: IWC (marker color), mean diameter (marker size), and spread (marker type). (c) Scatterplots comparing bulk moments retrieved from D3R-GCPEx (horizontal axis) to those from D3R-OLYMPEx and references (vertical axis, marker size represents the occurrence frequency). (d) Profiles where retrievals from D3R-GCPEx and D3R-OLYMPEx agree within 20% of relative error: profiles, as a function of (left) altitude and (right) temperature of the median of Z_Ku (thick line) and Z_Ka (thin line), and number of collocated samples (circles with sizes representing the number of samples).

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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b. OMSPs constrained by collocated APR observations: GCPEx versus OLYMPEx

Figure 5 displays a similar dashboard (GCPEx vs OLYMPEx) built using collocated APR observations. Figure 5b clearly illustrates the correlation between retrieved particle size and DWR Z_A,Ku−Ka, and, the dependency of M on both Z_A,Ku and Z_A,Ku−Ka. While the reference D₀ has a similar behavior as the retrievals, one can note the limited range of the Nevzorov measurements for Z_A,Ku ≥ 22 dBZ (Z_A,Ku ≤ 5 dBZ), where M_Nev underestimates (overestimates) the IWC. There are some differences between the reflectivities measured during the two campaigns: specific to GCPEx are the small particles for Z_Ku ≤ −5 dBZ and larger particles for (Z_Ku ≥ 15 dBZ, Z_Ku−Ka ≥ 10 dB); on the other hand, in OLYMPEx, there are heavier particles for (Z_Ku ≥ 25 dBZ, Z_Ku−Ka ≤ 4 dB). All these differences explain the intercampaign differences in Fig. 5a: in general, the exponents b of the OMSPs of GCPEx are larger than those of OLYMPEx (blue line above red line). Figure 5c confirms the correlation between GCPEx and OLYMPEx retrievals of M and D_m, and the lower correlation between retrieved S_m, consistent with the D3R dashboard (Fig. 4). The median of the profiles where GCPEx and OLYMPEx retrievals agree are plotted in Fig. 5d as a function of altitude (left) and temperature (right). These graphs confirm the high resemblance between the APR profiles of GCPEx and OLYMPEx (especially at Ku band), particularly in the representation as a function of the temperature.

Retrievals from APR (Ku, Ka) observations (GCPEx vs OLYMPEx). (a) Distribution of OMSPs as a function of (a, b) (marker size represents the occurrence frequency, and solid line is fit for OMSP “diagonal”). (b) Mean values of bulk moments [(top) references, (middle),(bottom) retrievals], conditional to (Z_Ku, Z_Ku−Ka) measured by APR in (top),(middle) GCPEx and (bottom) OLYMPEx: IWC (marker color), mean diameter (marker size), and spread (marker type). (c) Scatterplots comparing bulk moments retrieved from APR-GCPEx (horizontal axis) to those from APR-OLYMPEx and references (vertical axis, marker size represents the occurrence frequency). (d) Profiles where retrievals from APR-GCPEx and APR-OLYMPEx agree within 20% of relative error: profiles, as a function of (left) altitude and (right) temperature of the median of Z_Ku (thick line) and Z_Ka (thin line), and number of collocated samples (circles with sizes representing the number of samples).

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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Retrievals from APR (Ku, Ka) observations (GCPEx vs OLYMPEx). (a) Distribution of OMSPs as a function of (a, b) (marker size represents the occurrence frequency, and solid line is fit for OMSP “diagonal”). (b) Mean values of bulk moments [(top) references, (middle),(bottom) retrievals], conditional to (Z_Ku, Z_Ku−Ka) measured by APR in (top),(middle) GCPEx and (bottom) OLYMPEx: IWC (marker color), mean diameter (marker size), and spread (marker type). (c) Scatterplots comparing bulk moments retrieved from APR-GCPEx (horizontal axis) to those from APR-OLYMPEx and references (vertical axis, marker size represents the occurrence frequency). (d) Profiles where retrievals from APR-GCPEx and APR-OLYMPEx agree within 20% of relative error: profiles, as a function of (left) altitude and (right) temperature of the median of Z_Ku (thick line) and Z_Ka (thin line), and number of collocated samples (circles with sizes representing the number of samples).

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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Retrievals from APR (Ku, Ka) observations (GCPEx vs OLYMPEx). (a) Distribution of OMSPs as a function of (a, b) (marker size represents the occurrence frequency, and solid line is fit for OMSP “diagonal”). (b) Mean values of bulk moments [(top) references, (middle),(bottom) retrievals], conditional to (Z_Ku, Z_Ku−Ka) measured by APR in (top),(middle) GCPEx and (bottom) OLYMPEx: IWC (marker color), mean diameter (marker size), and spread (marker type). (c) Scatterplots comparing bulk moments retrieved from APR-GCPEx (horizontal axis) to those from APR-OLYMPEx and references (vertical axis, marker size represents the occurrence frequency). (d) Profiles where retrievals from APR-GCPEx and APR-OLYMPEx agree within 20% of relative error: profiles, as a function of (left) altitude and (right) temperature of the median of Z_Ku (thick line) and Z_Ka (thin line), and number of collocated samples (circles with sizes representing the number of samples).

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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a. Sensitivity to the quantization of the space of mass–size parameters

Five sets of MSP parameterizations are studied to assess how sensitive the retrievals are to the quantization of the MSP space [set of values for a and b in m(D) = aD^b]:

• “AfBf” (fine sampling of a and b): It is the full set of power laws used so far (baseline); as described in section 3b, it consists of eight values for a and seven values for b;

• “AcBc” (coarse sampling of a and b): This set retains every other prefactor and exponent of AfBf [a₁ = 0.0005, a₃ = 0.0019, a₅ = 0.0071, a₇ = 0.0269 (in g cm^−b), and b₁ = 1.01, b₃ = 1.67, b₅ = 2.34, and b₇ = 3];

• “AuBf” (unique a = 0.0037 g cm^−b, fine sampling of b): Only varying the exponent b;

• “AfBu” (fine sampling of a, unique b = 1.67): Only varying the prefactor a;

• “AuBu” (a = 0.0037 g cm^−1.67 and b = 1.67): Not allowing for any MSP variation.

The retrievals are compared on a dashboard, where the AfBf configuration is the baseline. Table 3 summarizes the results through the number of collocated APR observations accurately approximated by the chosen MSP set, the correlation coefficient C and relative bias B of the bulk moments (M, D_m, S_m), and the equation of the OMSP “diagonal.”

Table 3.

Global and local sensitivities to the MSP space. Effect of quantization: the various MSP sets are “AfBf” (fine sampling, chosen as baseline), “AcBc” (coarse sampling), “AuBf” [fixed prefactor a in m(D) = aD^b], “AfBu” (fixed exponent b), and “AuBu” (fixed a = 0.0037 g cm^−1.67 and b = 1.67). For a local sensitivity analysis around “AuBu,” the following sets are considered: “AmBu” (fixed a = 0.0019 g cm^−1.67 and b = 1.67), “ApBu” (fixed a = 0.0071 g cm^−1.67 and b = 1.67), “AuBm” (fixed a = 0.0037 g cm^−1.34 and b = 1.34), and “AuBp” (fixed a = 0.0037 g cm⁻² and b = 2). APR observations from OLYMPEx are used to constrain T-matrix simulations at (Ku, Ka). N_accurate is the proportion (in %) of the 25 589 collocated APR samples that are accurately approximated by at least one of the T-matrix simulations.

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All the retrieved moments are strongly correlated to those of AfBf: even in the AuBu case, where the MSP is kept fixed, C is higher than 78%. The main difference is in the number of collocated records that are accurately approximated by the simulations: the coarser the set of MSPs, the smaller the number of accurate approximations of reflectivities (from 60% with AfBf to less than 20% for the AuBu case). The variability of the exponent b seems to have a stronger impact on the range of accuracy of the simulated reflectivities, since AuBf approximates accurately more collocated records than AfBu, and the retrievals from AuBf have smaller biases than the retrievals from AfBu.

The equations of the OMSP “diagonals” of AfBf and AcBc are different due to the quantization. In the univariate cases, the MSPs that have the highest frequency of occurrence are close to the AfBf diagonal (defined by b_AfBf = 0.133a_dB + 5.030): in the AuBf case (i.e., a = a_AuBf = 0.0037 g cm^−b), b_AuBf = 1.67 is the exponent with the highest frequency of occurrence (~60%), which is close to the corresponding value on the diagonal b_AfBf(a_AuBf) = 1.80; on the other hand, in the AfBu case (i.e., b = b_AfBu = 1.67), a_AfBu = 0.0037 g cm^−1.67 is the prefactor with the highest frequency of occurrence (~75%), which is close to the corresponding value on the diagonal a_AfBu(b_AfBu) = 0.0030 g cm^−1.67. All these similarities show that the optimization converges to OMSPs that have characteristics similar to those of AfBf.

b. Local sensitivity to the mass–size parameters

We now study the effect of local perturbations of the MSP parameters around AuBu, which has fixed a = 0.0037 g cm^−1.67 and b = 1.67. The four fixed MSPs considered are

• “AmBu”: a = 0.0019 g cm^−1.67 and b = 1.67;

• “ApBu”: a = 0.0071 g cm^−1.67 and b = 1.67;

• “AuBm”: a = 0.0037 g cm^−1.34 and b = 1.34;

• “AuBp”: a = 0.0037 g cm⁻² and b = 2.

The results of comparisons to the AfBf configuration (baseline) are provided in Table 3 (bottom rows). The retrieved moments still have high correlations to those of AfBf (higher than 72%); however, there are clear differences with respect to the performance of AuBu both in terms of the number of accurately approximated records (all smaller than 6% of the total), and in terms of bias (except for AuBp, which has small biases). Thus, the choice of the MSP coefficients has a significant impact on the ability to approximate radar observations.

c. Sensitivity to the scattering model

So far, a T-matrix code was used to compute the radar reflectivities according to Eq. (1). In this framework (denoted “TM_in”), the scatterers are modeled as oblate spheroids of maximum size D and aspect ratio R_ASP(D) derived from the imaging probes. The approach is now extended to include Mie and discrete-dipole approximation (DDA) scattering models. The Mie calculations, correspond to T-matrix calculations where scatterers are modeled as spheres of diameter D. The Mie reflectivities are therefore computed using TM_in with a fixed aspect ratio of 1. The DDA model computes the scattering properties of irregularly shaped scatterers by dividing them into dipoles (Purcell and Pennypacker 1973). The DDA is therefore conformal to the geometry of irregularly shaped particles. For the DDA calculations, we use the OpenSSP lookup table (LUT) built using the DDSCAT software (Draine and Flatau 1994; Kuo et al. 2016). OpenSSP (available online at https://storm.pps.eosdis.nasa.gov/storm/OpenSSP.jsp) consists of 9053 ice particles of varying shapes (from pristine ice to aggregates) and sizes (D ∈ [0.15, 17.27] mm). To compute the backscattering cross sections, we read OpenSSP using D and the mass m(D) assumed by the simulated MSP and average over all the habits in the LUT. With the three scattering models (Mie, TM_in and DDA) and the PSDs measured during OLYMPEx, reflectivity factors are computed at Ku and Ka bands, for all the MSPs. Collocated (Ku, Ka)-band observations from APR then allow us to identify the OMSPs. Although the same in situ and radar data are used in these simulations, the intrinsic assumptions of the three scattering models are different, and therefore, the models will produce radar reflectivities that are not identical. Thus, the OMSPs of the various scattering models will not be identical (the MSPs such that Δ_Ku,Ka ≤ 1.5 dB may vary from one model to the other).

The retrieval dashboard is shown in Fig. 6. Of 25 589 collocated APR samples (this number corresponds to collocated samples such that T ≤ −1°C, with low liquid PIA and LWC), the Mie approach accurately approximates 51% of the samples, whereas TM_in and DDA both accurately approximate ~60% of the samples (~2000 more samples than Mie). There are therefore advantages in using scattering models that account for the morphological diversity of frozen hydrometeors.

Sensitivity of retrievals to the scattering models (T matrix vs DDA vs Mie), with simulations constrained by APR (Ku, Ka) data from OLYMPEx: (a) Distribution of OMSPs as a function of (a, b) (marker size represents the occurrence frequency, and solid line is OMSP “diagonal”). (b) Mean values of bulk moments [(top) references, (bottom three rows) retrievals], conditional to (Z_Ku, Z_Ku−Ka) measured by APR in OLYMPEx, based on scattering simulations from (top two rows) TM_in, (third row) DDA, and (bottom) Mie: IWC (marker color), mean diameter (marker size), and spread (marker type). (c) Scatterplots comparing bulk moments retrieved from TM_in (horizontal axis) to those from DDA and Mie and references (vertical axis, marker size represents occurrence frequency). (d) Profiles where retrievals from TM_in, DDA and Mie agree within 20% of relative error: vertical profiles of quantiles of (left) Z_Ku and (center) Z_Ka, and (right) number of samples.

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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Sensitivity of retrievals to the scattering models (T matrix vs DDA vs Mie), with simulations constrained by APR (Ku, Ka) data from OLYMPEx: (a) Distribution of OMSPs as a function of (a, b) (marker size represents the occurrence frequency, and solid line is OMSP “diagonal”). (b) Mean values of bulk moments [(top) references, (bottom three rows) retrievals], conditional to (Z_Ku, Z_Ku−Ka) measured by APR in OLYMPEx, based on scattering simulations from (top two rows) TM_in, (third row) DDA, and (bottom) Mie: IWC (marker color), mean diameter (marker size), and spread (marker type). (c) Scatterplots comparing bulk moments retrieved from TM_in (horizontal axis) to those from DDA and Mie and references (vertical axis, marker size represents occurrence frequency). (d) Profiles where retrievals from TM_in, DDA and Mie agree within 20% of relative error: vertical profiles of quantiles of (left) Z_Ku and (center) Z_Ka, and (right) number of samples.

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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Sensitivity of retrievals to the scattering models (T matrix vs DDA vs Mie), with simulations constrained by APR (Ku, Ka) data from OLYMPEx: (a) Distribution of OMSPs as a function of (a, b) (marker size represents the occurrence frequency, and solid line is OMSP “diagonal”). (b) Mean values of bulk moments [(top) references, (bottom three rows) retrievals], conditional to (Z_Ku, Z_Ku−Ka) measured by APR in OLYMPEx, based on scattering simulations from (top two rows) TM_in, (third row) DDA, and (bottom) Mie: IWC (marker color), mean diameter (marker size), and spread (marker type). (c) Scatterplots comparing bulk moments retrieved from TM_in (horizontal axis) to those from DDA and Mie and references (vertical axis, marker size represents occurrence frequency). (d) Profiles where retrievals from TM_in, DDA and Mie agree within 20% of relative error: vertical profiles of quantiles of (left) Z_Ku and (center) Z_Ka, and (right) number of samples.

Citation: Journal of Atmospheric and Oceanic Technology 37, 6; 10.1175/JTECH-D-19-0104.1

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The three models produce very similar preferential MSPs (Fig. 6a). The OMSP diagonals are slightly different between DDA (higher b) and Mie (lower b), with TM_in bracketed by these two models: the TM_in diagonal transitions from being similar to the Mie diagonal for lower a and b to being closer to the DDA diagonal for larger a and b. Figure 6b shows the bulk moments (reference in top row, retrievals below) as a function of the collocated APR observations (Z_Ku, Z_Ku−Ka), for simulations done using TM_in (top two rows), DDA (third row), and Mie (bottom row). Figure 6b confirms the features seen in the previous dashboards, namely, 1) the saturation of M_Nev for lower and larger IWCs, 2) a joint dependency of M on (Z_Ku, Z_Ku−Ka), 3) increasing D_m with increasing Z_Ku−Ka, and 4) larger spreads S_m for larger Z_Ku. Among the slight intermodel differences, one can note the presence, only in the Mie results, of samples for (Z_Ku < 10 dBZ, Z_Ku−Ka ≥ 8 dB), which correspond to larger particles with a low mass and narrow spread. Figure 6c shows a very strong correlation between the retrieved moments. However, there are also nonnegligible biases between Mie results and the results from the other scattering models: to match a given radar observation simulated by TM_in or DDA (a bin in the (Z_Ku, Z_Ku−Ka, T)–hypercube), the Mie approach uses smaller (D_m smaller by −10%) but heavier (M larger by +31%) spheres than the particles used in TM_in and DDA. Figure 6d shows that the closest agreements between the three scattering models are observed at temperatures colder than −10°C.