1 / 18

A Refresher on Super-Resolution Radar Data

A Refresher on Super-Resolution Radar Data. Audra Hennecke , Dave Beusterien. Base Data Resolution: Legacy vs. Super-Res. Base Reflectivity : Legacy Range Resolution: 1, 2, 4 km (0.54, 1.1, 2.2 nm) Azimuthal Resolution: 1.0 degree Super-Res Range Resolution: 0.25 km (0.13 nm)

duc
Download Presentation

A Refresher on Super-Resolution Radar Data

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. A Refresher on Super-Resolution Radar Data Audra Hennecke, Dave Beusterien

  2. Base Data Resolution: Legacy vs. Super-Res • Base Reflectivity: • Legacy • Range Resolution: 1, 2, 4 km (0.54, 1.1, 2.2 nm) • Azimuthal Resolution: 1.0 degree • Super-Res • Range Resolution: 0.25 km (0.13 nm) • Azimuthal Resolution: 0.5 degree • Base Velocity: • Legacy • Range Resolution: 0.25, 0.50, 1km (0.13, 0.27, 0.54 nm) • Azimuthal Resolution: 1.0 degree • Super-Res • Range Resolution: 0.25 km (0.13 nm) • Azimuthal Resolution: 0.5 degree

  3. Display Ranges • Base Reflectivity • Legacy and Super-Res: • Both available to 248 nm • Base Velocity • Legacy: • Available to 124 nm • Super-Res: • Available to 162 nm

  4. Super-Res Characteristics • Available at lower elevation angles • Base data generated for only the Split Cut elevations of the VCPs • Retains the highest reflectivity value for display in courser resolutions; preserves important features • i.e. maximum reflectivity values in the cores of strong thunderstorms

  5. 8-bit 1 deg azimuth Reflectivity product Maximum range = 248 nm Super-Res Reflectivity product Maximum range = 248 nm Source: WDTB DLOC Topic 5

  6. Super-Res Base Data • Super-Res Base Data, compared to all the base reflectivity/velocity products: • Highest number of data levels (256) • Greatest range resolution (250 m, 0.13 nm) • Best azimuthal resolution (0.5 degree) • Base data signatures easier to discern when viewing these higher resolution base data products

  7. Super-Res Base Data • Two signal processing techniques used to produce Super-Res base data • Overlapping radials and windowing • Windowing process introduces more error in the base data estimate • Results in SR base products being visually noisier than legacy resolution base products • However, it supports visual detection of smaller scale features at longer ranges

  8. Noisy Super-Res Base Data • Most apparent with reflectivity (compared to legacy resolution) • 8 SR reflectivity bins for every 1 legacy resolution reflectivity bin • More apparent in areas of stratiform precipitation and low returned power • Not as apparent in convective areas when compared to stratiform precipitation

  9. Example of Noisiness for Convective Rainfall Legacy Base Reflectivity Product SR Base Reflectivity Product Source: WDTB DLOC Topic 3

  10. Example of Noisiness for Stratiform Rainfall Legacy Base Reflectivity Product SR Base Reflectivity Product Source: WDTB DLOC Topic 3

  11. Super-Res Base Velocity • Range: 162 nm • 256 data levels • Important velocity features will more readily appear and look clearer with Super-Res products • Super-Res velocity magnitudes associated with important signatures may need to be adjusted • May show stronger velocity values than those normally associated with many velocity signatures in the 1 degree data.

  12. Super-Res: SRM • 250 m (0.25 km, 0.13 nm) x 0.5 degree • Range: 162 nm • 256 data levels • Displays the highest resolution velocity data available from the radar out to 162 nm for the split cut elevation angles.

  13. Super-Res: SRM • High detail (spatially and in data magnitude) provides improved detection of TVSs, mesocyclones, microbursts, and boundaries. • Very useful for examining the velocity structure of fast moving storms (> 10kts) • Significant advantage compared to base velocity products of the same resolution

  14. Super-Res: Storm-Scale Features • Storm-scale features show up more often and more clearlyin Super-Res products. • BWERs, hook echoes, TBSSs, low-level boundaries, hail cores, mesocyclones, TVSs, inflow notches

  15. Super-Res: Mesocyclone Identification • Super-res velocity data: typically easier to identify small-scale features, i.e. mesocyclones • Velocity magnitudes associated with these features may appear stronger because of the finer resolution in the azimuthal direction

  16. Source: WDTB DLOC Topic 5 Super-Res SRM Legacy, 1 deg. Azimuth SRM • For Super-Res, the strongest velocities associated with the mesocyclone cover a smaller area. • Super-res image has a significantly stronger outbound component of the mesocyclone (+43 ktsvs+21 kts) . • Overall storm identification is enhanced.

  17. Super-Res: TVSs • Super-Res velocity: available on the lowest 2-3 elevation angles • Exactly where you would want to look for TVSs • Gate-to-gate shear will often have a greater magnitude in Super-Res data than indicated in the TVS definition. • Additional research is needed to understand the relationship between super-res gate-to-gate shear magnitudes and tornadic events.

  18. TVS graphic product; Super-Res 0.5 SRM Source: WDTB DLOC Topic 5

More Related