Assessing Real-Time Tornado Information Disseminated through NWS Products

Blair, Scott F.; Leighton, Jared W.

doi:10.1175/waf-d-13-00126.1

Cited by 7 publications

(7 citation statements)

References 37 publications

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“…15). 1) real-time comparison of available observations with the model-based estimates of the storm environment, 2) real-time monitoring of storm structure and rotational characteristics via WSR-88D sampling, and 3) supporting evidence of a tornado via the development of a dual-polarization tornadic debris signature (DPTDS; e.g., Bodine et al 2013;Schultz et al 2012a,b; Bunkers and Baxter 2011) with vertical and temporal continuity, since a majority of tornadoes are not reported to local National Weather Service offices in real time (Blair and Leighton 2014). 13.…”

Section: Summary and Discussionmentioning

confidence: 99%

“…Newman et al (2013) found utility in applying range correction to the local, linear least squares derivatives (LLSDs; Smith and Elmore 2004) azimuthal shear algorithm, and this procedure aided in differentiating between nontornadic and tornadic radar scans for a small number of events. Blair and Leighton (2014) noted the need for robust, scientific guidance for real-time tornado intensity estimates in their assessment of event confirmation in NWS warnings and statements across the central continental United States (CONUS) from 2007 to 2011. The early studies investigating the relationship between tornado intensity and radar (e.g., Kingfield et al 2012;LaDue et al 2012;Toth et al 2013) have shown some ability to identify different levels of tornado intensity in a diagnostic manner, thereby lending credence to the underlying idea of tornado intensity identification, from which IBW is based.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Diagnosing the Conditional Probability of Tornado Damage Rating Using Environmental and Radar Attributes

Smith¹,

Thompson²,

Dean³

et al. 2015

Weather and Forecasting

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Radar-identified convective modes, peak low-level rotational velocities, and near-storm environmental data were assigned to a sample of tornadoes reported in the contiguous United States during 2009-13. The tornado segment data were filtered by the maximum enhanced Fujita (EF)-scale tornado event per hour using a 40-km horizontal grid. Convective mode was assigned to each tornado event by examining full volumetric Weather Surveillance Radar-1988 Doppler data at the beginning time of each event, and 0.58 peak rotational velocity (V rot ) data were identified manually during the life span of each tornado event. Environmental information accompanied each grid-hour event, consisting primarily of supercell-related convective parameters from the hourly objective mesoscale analyses calculated and archived at the Storm Prediction Center. Results from examining environmental and radar attributes, featuring the significant tornado parameter (STP) and 0.58 peak V rot data, suggest an increasing conditional probability for greater EF-scale damage as both STP and 0.58 peak V rot increase, especially with supercells. Possible applications of these findings include using the conditional probability of tornado intensity as a real-time situational awareness tool.

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Section: Summary and Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Diagnosing the Conditional Probability of Tornado Damage Rating Using Environmental and Radar Attributes

Smith¹,

Thompson²,

Dean³

et al. 2015

Weather and Forecasting

View full text Add to dashboard Cite

show abstract

“…Therefore, given a sufficiently short distance and clear line of sight between the radar and the tornado, identification of existing tornadoes in Doppler weather radar data is nearly ubiquitous. The TVS and TDS serve as useful tornado proxies both for forecasters issuing warnings (e.g., Blair and Leighton 2014) and for researchers conducting observational studies (e.g., Trapp et al 1999).…”

Section: Introductionmentioning

confidence: 99%

Dissipation Characteristics of Tornadic Vortex Signatures Associated with Long-Duration Tornadoes

French

Kingfield

2019

Journal of Applied Meteorology and Climatology

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Weather Surveillance Radar–1988 Doppler (WSR-88D) data from 36 tornadic supercell cases from 2012 to 2016 are investigated to identify common tornadic vortex signature (TVS) behaviors prior to tornado dissipation. Based on the results of past case studies, four characteristics of TVSs associated with tornado dissipation were identified: weak or decreasing TVS intensity, rearward storm-relative motion of the TVS, large or increasing TVS vertical tilt, and large or increasing TVS horizontal displacement from the main storm updraft. Only cases in which a TVS was within 60 km of a WSR-88D site in at least four consecutive volumes at the end of the tornado life cycle were examined. The space and time restrictions on case selection ensured that the aforementioned quantities could be determined within ~500 m of the surface at several time periods despite the relatively coarse spatiotemporal resolution of WSR-88D systems. It is found that prior to dissipation, TVSs become increasingly less intense, tend to move rearward in a storm-relative framework, and become increasingly more separated from the approximate location of the main storm updraft. There is no clear signal in the relationship between tornado tilt, as measured in inclination angle, and TVS dissipation. The frequency of combinations of TVS dissipation behaviors, the impact of increased low-level WSR-88D scanning on dissipation detection, and prospects for future nowcasting of tornado life cycles also are discussed.

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“…Last, a TDS often persists for a significant time after tornado demise, which makes sense given observations of long-range debris transport (e.g., Magsig and Snow 1998). Even with these limitations, the TDS remains a good indicator of lofted debris and is especially useful in the absence of a spotter network (e.g., Blair and Leighton 2014).…”

Section: Introductionmentioning

confidence: 99%

Spatial and Temporal Characteristics of Polarimetric Tornadic Debris Signatures

Broeke

Jauernic

2014

Journal of Applied Meteorology and Climatology

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Nonmeteorological scatter, including debris lofted by tornadoes, may be detected using the polarimetric radar variables. For the 17 months from January 2012 to May 2013, radar data were examined for each tornado reported in the domain of an operational polarimetric Weather Surveillance Radar-1988 Doppler (WSR-88D). Characteristics of the tornadic debris signature (TDS) were recorded when a signature was present. Approximately 16% of all tornadoes reported in Storm Data were associated with a debris signature, and this proportion is shown to vary regionally. Signatures were more frequently seen with tornadoes that were rated higher on the enhanced Fujita (EF) scale, with tornadoes causing higher reported total property damage, with tornadoes that were closer to the radar and thus intercepted by the beam at lower altitude, and associated with tornadoes with greater total pathlength. Tornadic debris signatures were most common in spring, when more strong tornadoes occur, and in autumn, when natural debris is more available. Debrissignature areal extent is shown to increase consistently with EF-scale rating and tornado longevity. Vertical extent of a TDS is shown to be greatest for strong, long-lived tornadoes with large radii of damaging wind. Land cover is also shown to exhibit some control over TDS characteristics-in particular, a large percentage of tornadoes with substantial track over urban land cover exhibited a TDS and do so very quickly after reported tornadogenesis, as compared with tornadoes over other land-cover classifications. TDS characteristics over grassland and cropland tended to be similar.

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Assessing Real-Time Tornado Information Disseminated through NWS Products

Cited by 7 publications

References 37 publications

Diagnosing the Conditional Probability of Tornado Damage Rating Using Environmental and Radar Attributes

Diagnosing the Conditional Probability of Tornado Damage Rating Using Environmental and Radar Attributes

Dissipation Characteristics of Tornadic Vortex Signatures Associated with Long-Duration Tornadoes

Spatial and Temporal Characteristics of Polarimetric Tornadic Debris Signatures

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