Radar Basics and Estimating Precipitation Jon W. Zeitler Science and Operations Officer
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Radar Basics and Estimating Precipitation Jon W. Zeitler Science and Operations Officer National Weather Service Austin/San Antonio Forecast Office Radar Beam Basics Energy Scattering As pulse volumes within the radar beam encounter targets, energy will be scattered in all directions. A very small portion of the intercepted energy will be backscattered toward the radar. The degree or amount of backscatter is determined by target: size (radar cross section) shape (round, oblate, flat, etc.) state (liquid, frozen, mixed, dry, wet) concentration (number of particles per unit volume) We are concerned with two types of scattering, Rayleigh and non-Rayleigh. Rayleigh scattering occurs with targets whose diameter (D) is much smaller (D < /16) than the radar wavelength. The WSR-88D's wavelength is approximately 10.7 cm, so Rayleigh scattering occurs with targets whose diameters are less than or equal to about 7 mm or ~0.4 inch. Raindrops seldom exceed 7 mm so all liquid drops are Rayleigh scatters. Potential problem: Nearly all hailstones are non-Rayleigh scatterers due to their larger diameters. Probert-Jones Radar Equation Simplified Radar Equation Equivalent Reflectivity (Ze) Since we technically don't know the drop-size distribution or physical makeup of all targets within a sample volume, radar meteorologists oftentimes refer to radar reflectivity as equivalent reflectivity, Ze. The assumption is that all backscattered energy is coming from liquid targets whose diameters meet the Rayleigh approximation. Obviously, this assumption is invalid in those cases when large, water-coated hailstones are present in a sample volume. Hence, the term equivalent reflectivity instead of actual reflectivity is more valid. Reflectivity (Z) vs. Decibels of Reflrectivity (dBZ) (Equation 5) dBZ = 10log10Z Beam-Filling Sending vs. Listening Sending vs. Listening 99.843% of the time the WSR-88D is listening for signal returns. The Doppler Dilemna A low PRF is desirable for target range and power, while a high PRF is desirable for target velocity. The inability to satisfy both needs with a single PRF is known as the Doppler Dilemma. The Doppler Dilemma is addressed by the WSR88D with algorithms. Range Folding Subrefraction: dry adiabatic, moisture increases with height. In addition to underestimated echo heights, this phenomenon tends to reduce ground clutter in the lowest elevation cuts. Superrefraction: temperature inversion. In addition to overestimated echo heights, increases ground clutter in the lowest elevation cuts and is the cause of what we normally refer to as anomalous propagation or AP echoes. The Earth is Round! Storms Too Close! Each pulse has a volume with dimensions of ~ 500 meters (~ 1500 meters) in length by ~ 1° wide in short pulse (long pulse) mode. This means that two targets along a radial must be at least 250 (750) meters apart for the radar to be able to distinguish and display them as two separate targets (i.e., more than H/2 range separation distance). Storms or Bats? Strategies to Fix Problems Drop Size Distribution Drop Size Distribution Rainfall Rate Rainfall Rate Rainfall Rate R(Z) Relationships (Battan 1973) BREAK! What is Dual Polarimetric Radar? Sends and receives horizontal & vertical polarized radiation Image courtesy Terry Schuur Polarimetric Variables Depend on Several Things Hydrometeor: • Shape • Orientation • Dielectric constant • Distribution of sizes Applications of Dual Polarization Radar •Rainfall Estimation (vast improvement) •Bright Band Detection (vast improvement) •Clutter Filtering/Data Quality Improvement (vast improvement) •Rain/Snow Discrimination (vast improvement) •Hail Detection (some improvement) •Updraft Location (some improvement) •Tornado Detection (some improvement) Polarimetric Variables Backscattering: Zh - reflectivity factor for horizontal polarization ZDR - differential reflectivity |ρhv(0)| - co-polar correlation coefficient Propagation - forward scattering: ΦDP - differential phase KDP - specific differential phase (range derivative of ΦDP) Shapes of Large Drops in Equilibrium Differential Reflectivity (ZDR) • Definition: the ratio of the power returns from the horizontal and vertical polarizations • Units: decibels (dB) Z hh Z DR 10 log 10 Z vv Simple ZDR Calculation for a Sample of Raindrop Sizes What does ZDR Mean? Ev Eh • ZDR > 0 Horizontallyoriented mean profile Ev Eh Ev Eh • ZDR < 0 Vertically-oriented mean profile • ZDR ~ 0 Near-spherical mean profile Differential Reflectivity (ZDR) -4 -3.5 -3 -2.5 -2 -1.5 -1 -0.5 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 5.5 Small (Spherical) <<< RAIN >>> Large (Oblate) Dry <<< GRAUPEL >>> Wet Dry (Prolate) <<<<< HAIL >>>>> Melting (Oblate) Aggregated/Low-Density <<< CRYSTALS >>> Pristine/Well-Oriented Dry <<< SNOW >>> Wet GROUND CLUTTER / ANOMALOUS PROPAGATION BIOLOGICAL SCATTERERS DEBRIS CHAFF 6 ZDR is a Good Indicator of: 1. median liquid drop size (ZDR↑,median drop diameter↑) 2. hail shafts (ZDR ~ 0dB or negative coincident with high Zh) 3. areas of large rain drops or liquidcoated ice (ZDR ~3-6 dB) 4. convective updrafts (ZDR ~1-5 dB) above 0oC level 5. tornado debris ball ZDR Limitations (Gotchas) •Values are biased towards the larger hydrometeors (D6 dependence) •Tumbling/Random orientation will bias toward 0 ZDR •Can be noisy if: -Low / Insufficient sampling (low SNR) - Reduced correlation coefficient (CC) May 9th tornadic supercell: Intense ZDR Column 0oC level in-cloud ~17 kft ρhv Correlation Coefficient (ρ hv): A correlation between the reflected horizontal and vertical power returns. It is a good indicator of regions where there is a mixture of precipitation types, such as rain and snow. Affected by: • Hydrometeor types, phases, shapes, orientations • Presence of large hail ρhv Usage • Identify hail growth regions in deep moist convection (mixtures of hydrometeors) • Reduce ground clutter/AP contamination (ρhv very low in these areas) • Identify giant hail ??? ρhv SNOW ~0.85-1.00 CLUTTER ~0.5-0.85 CHAFF ~0.2-0.5 Reflectivity (Zh) Correlation Coefficient (rhv) ρhv Minimum…in Theory Giant Hail, Protuberances, Mie Scattering: min ρhv Differential Phase Shift (ΦDP) • Definition: the difference in the phase shift between the horizontally and vertically polarized waves • Units: degrees (o) DP H V Differential Phase Shift fDP fDP = fh – fv (fh, fv ≥ 0) [deg] The difference in phase between the horizontallyand vertically-polarized pulses at a given range along the propagation path. - Independent of partial beam blockage, attenuation, absolute radar calibration, system noise What Affects Differential Phase? Forward Propagation has its Advantages • Immune to partial (< 40%) beam blockage, attenuation, calibration, presence of hail Gradients Most Important Specific Differential Phase Shift (KDP) • Definition: range derivative of the differential phase shift • Units: degrees per kilometer (o/km) f (r ) f (r ) K 2r r DP 2 DP DP 2 1 1 Specific Differential Phase: KDP Specific Differential Phase (KDP): A comparison of the returned phase difference between the horizontal and vertical pulses. This phase difference is caused by the difference in the number of wave cycles (or wavelengths) along the propagation path for horizontal and vertically polarized waves. This is the range derivative of typically calculated in 1-5 km increments along the radial. f DP, • Provides a good estimate of liquid water in a rain/hail mixture • Indicates the onset of melting Specific Differential Phase Shift (KDP) -0.5 0 0.5 1 1.5 2 2.5 3 4 Small <<< RAIN >>> Large Dry <<< GRAUPEL >>> Wet Dry (Prolate) <<<<< HAIL >>>>> Melting (Oblate) Dry/Aggregated <<< CRYSTALS >>> Pristine/Well-Oriented Dry <<< SNOW >>> Wet *** Non-meteorological values not shown here because they are removed anywhere CC < 0.90 (or 0.85) *** 5 Kdp Usage • To isolate the presence of rain from hail R(Z, Zdr, Kdp) much better than R(Z) Most sensitive to amount of liquid water • To locate regions of drop shedding, “Kdp columns” • Drops are shed from melting or growing hailstones near the updraft, forming a Kdp column • To distinguish between snow/rain • Kdp in wet, heavy snow is almost always larger at a fixed value of Zh than that observed for rain KDP Limitations (Gotchas) • KDP values set to “No Data” at CC < 0.90, or 0.85) • Sensitive to non-uniform beam filling • Unreliable at far ranges • KDP Smoothing techinque: Compare Z and KDP fields at each gate 1. 2. < 40 dBZ, KDP computed at each gate from 12 adjacent gates either side (6.25 km) > 40 dBZ, KDP computed at each gate from 4 adjacent gates either side (2.25 km) to preserve heavy cores Marginally Severe Supercell 14 May 2003 ρHV Z HCA Z DR 5.25” diameter hail Beam Height ~ 4600 ft AGL Correlation Coefficient (CC) • Definition: how similarly the horizontally and vertically polarized backscattered energy are behaving within a resolution volume for Rayleigh scattering • Units: none (0-1.00) r HV (0) * S vv S hh S 2 hh 1/ 2 S 2 1/ 2 vv Sij = An element of the backscatter matrix Think Spectrum Width for Hydrometeors Correlation Coefficient Values • 0.96 ≤ CC ≤ 1 Small hydrometeor diversity* • 0.80 ≤ CC < 0.96 Large hydrometeor diversity* • CC < 0.70 Non-hydrometeors present * Types, sizes, shapes, orientations, etc. Correlation Coefficient (CC) 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.85 0.9 0.91 0.92 0.93 0.94 0.95 0.96 0.97 0.98 0.99 Large <<< RAIN >>> Small Wet <<< GRAUPEL >>> Dry Wet / Large <<<<< HAIL >>>>> Dry / Small CRYSTALS <<Melting Layer>> Wet <<< SNOW >>> Dry GROUND CLUTTER / ANOMALOUS PROPAGATION BIOLOGICAL SCATTERERS DEBRIS CHAFF NonMeteorological Regime Overlap Meteorological Regime 1 What is CC Used for? • Not-met targets (LOW CC < 0.70) – Best discriminator • Melting layer detection (Ring of reduced CC ~ 0.80 – 0.95) • Giant hail? (LOW CC < 0.70 in the midst of high Z/Low ZDR) Marginally Severe Supercell Precip What about the re All > 0.97 Insects CC Limitations (Gotchas) • High error in low signal-to-noise ratios (SNR) • If low, errors increase in other dual-pol variables Polarimetric Rainfall Algorithm vs. Conventional One hour point measurements: Radar estimates vs. gages R(Z) R(Z, KDP, ZDR) Polarimetric Rainfall Algorithm vs. Conventional Bias of radar areal rainfall estimates Spring hail cases Cold season stratiform rain QPE Process in a Nutshell Step 1 1. Hybrid scan the variables into Polar, 1 degree azimuth, 250 m bins Hybrid Hydroclass QPE Process in a Nutshell 2. Apply an instantaneous Rate: R(Z), R(KDP), and R(Z,ZDR) But which one is accepted? R(Z ) 0.017 Z 0.714 R( KDP) 44.0 KDP R(Z , ZDR ) 0.0142 Z 0.882 sign ( KDP) 0.770 ZDR 1.67 QPE Process in a Nutshell 3. Assign a variation of 1 of those 3 rates to each bin based on HCA precip type Based on 43 events (179 hrs) of radar rainfall data Rate Designation Table R (mm/hr) Conditions Echo Classes Not computed Nonmeteorological echo (Ground Clutter or Unknown) is classified GC ,UK 0 Classification is No Echo or Biological NE, BI R(Z, ZDR) Light/Moderate Rain is classified RA R(Z, ZDR) Heavy Rain or Big Drops are classified HR, BD R(KDP) Rain/Hail is classified and echo is below the top of the melting layer RH 0.8*R(Z) Rain/Hail is classified and echo is above the top of the melting layer RH 0.8*R(Z) Graupel is classified GR 0.6*R(Z) Wet Snow is classified WS R(Z) Dry Snow is classified and echo is in or below the top of the melting DS layer 2.8*R(Z) Dry Snow classified and is echo above the top of the melting layer DS 2.8*R(Z) Ice Crystals are classified IC QPE Output (all produced via hybrid scan) • • • • 4bit, 250 m Hybrid-scan Hydro Class 8bit, 250 m Rate 4 bit, 250 m 1hr Accum 4 bit & 8bit versions of 250 m STP Accum (G-R bias applied) • 8 bit, 250 m no G-R bias applied STP • 8 bit, 250 m User Selectable (will be used for any and all accumulation time periods) • 8 bit, 250 m 1hr and STP Difference field vs. Legacy Hydrometeor Classification Algorithm Challenges • Typical Radar sampling limitations (snow at 2000 ft AGL may not be snow at the surface) • Verification • “Fuzzy” Logic and cross over between types • Differentiating between light rain and dry snow in weak echoes Melting layer detection can help Melting Layer Detection • Mixed phase hydrometeors: Easy detection for dual-pol! – Z typically increases – ZDR and KDP definitely increase – Coexistence of ice and water will reduce the correlation coefficient (CC ~0.95-0.85) Melting Layer Detection Algorithm Methodology • Precipitation echoes – stratiform or convective regions – with high SNR • Middle tilts (4°-10° elevation angles) • Limitation: Overshoot precip • “Project” results to other tilts in time and space ML Product in AWIPS Hail Detection • Dual-Pol Hail Signature – High Z (> 45 dBZ) – Low ZDR (-0.5 to 1 dB), Low KDP (-0.5 to 1 o/km) if dry or mostly dry – Reduced CC (0.85 to 0.95) • Limitations – Size detection? – Hail signatures may get diluted by • Rain mixing with hail • Far range Rain/Snow Discrimination Z RAIN < 45 dBZ SNOW < 45 dBZ ZDR 0 to 2 dB -0.5 to 6 dB KDP 0 to 0.6 deg/km -0.6 to 1 deg/km CC >0.95 >0.95 (can be less if wet) If the variables overlap so much, how can polarimetric radar discriminate between rain and snow??? Rain/Snow Discrimination: It’s all in trends with height • Rain – Polarimetric signatures (ZDR and KDP) have a direct dependence on Z – ZDR and KDP do not typically increase with height – Almost always a pronounced melting layer above rain • Snow – Polarimetric signatures (ZDR and KDP) do not have dependence on Z – ZDR and KDP typically increase with height – Differences between “warm” and “cold” snow • “Cold” snow has higher polarimetric variables than “warm” snow Warm vs. Cold vs. Wet Snow • Temperature determines this – < -5oC = “Cold” – ~+1oC > T > -5oC = “Warm” – > +1oC = “Wet” Crystals (plates, columns, needles) Aggregate Crystals (Dry) Aggregate Crystals (Wet) Radar Cross Section Characteristics Z/ZDR/CC Characteristics High Density High Concentration Oblate, Horizontal Orientation Small size Z < 35 dBZ ZDR 0-6 dB CC > 0.95 Decreasing density Decreasing Concentration Less oblate Larger size Z increasing ZDR decreasing 0 > ZDR > 0.5 dB CC > 0.95 Rapid increase in density Rapid increase in oblateness Z increasing but < 45 dBZ ZDR rapidly increasing 0.50 > CC > 0.9 Surface. Assume temperatures decrease steadily with height Rain Snow Discrimination Z Snow ZDR Rain KDP CC One Hour Later… Z -SN KDP ZDR CC Data Quality Improvement • Ground clutter/Anomalous propagation – High reflectivity (Z) -- (> 35 dBZ) – Near zero or slightly negative ZDR – Noisy, lower correlation coefficient (CC) -- (< 0.90) • Insects/Biological scatterers – Low reflectivity (Z) -- (< 35 dBZ) – Horizontally-oriented with elongated shape: very high ZDR (> 2 dB up to 6 dB) – Heterogeneity causes very low correlation coefficients (< 0.70) Tornado Detection • Tornado debris is large (from radar perspective), irregularly shaped and randomly oriented – Z > 45 dBZ – ZDR near 0 dB – CC very low (< 0.8) • A good sign that a tornado is already in progress! – Diagnostic ONLY – Has only been verified for EF-1 or greater tornadoes at relatively close ranges Tornadic Debris Signature (TDS) Z ZDR TDS! CC Debris cloud near GM Plant
