Atornadic debris signature (TDS), often colloquially referred to as adebris ball,^[1] is an area of highreflectivity onweather radar caused bydebris lofting into the air, usually associated with atornado.^[1][2] A TDS may also be indicated by dual-polarizationradar products, designated as apolarimetric tornado debris signature (PTDS). Polarimetric radar can discern meteorological and nonmeteorologicalhydrometeors and the co-location of a PTDS with the enhanced reflectivity of a debris ball are used by meteorologists as confirmation that a tornado is occurring.^[3]

Debris balls can be a result ofanthropogenic orbiomass debris and are more likely to occur if a tornado crosses a "target-rich" environment such as a forest or populated area. A TDS is most likely to be observed when a tornado is closer to a radar site and the farther away from the radar that a TDS is observed the more likely that the tornado is stronger. As a result of the strongwinds required to damage structures and loft debris into the air, debris balls are normally the result of EF3 or stronger tornadoes on theEnhanced Fujita Scale. Weaker tornadoes may also not cause debris balls due to their mostly short-lived nature and thus any debris may not be sampled by radar.^[4] However, not all tornadoes meeting such strength requirements exhibit debris balls, depending on their vicinity to sources of debris and distance from the radar site.^[1] A debris ball on radar images can verify tornadoes 70–80% of the time.^[5]

PTDS output from a tornado in Tennessee.

Debris balls are seen on radar reflectivity images as a small, roundish area of high reflectivity values. Research conducted on debris balls that were noted during the2011 Super Outbreak suggested that horizontal reflectivity from debris balls ranged from 51 to 72dBZ during those outbreaks. Reflectivity values also decreased with increasing height.^[1] Due to the irregular and variable size, shapes, and dielectric constants of debris particles, debris balls typically produce acorrelation coefficient (ρ_hv) less than 0.80. Differential reflectivity (Z_DR) values associated with debris balls are typically near or below 0 dB due to the random, tumbling nature of tornadic debris. Debris balls are almost always associated with a strong velocity couplet and the corresponding algorithm based detection, thetornado vortex signature (TVS) or tornado detection algorithm (TDA).^[6]

An algorithm, calledPolarimetric Tornado Debris Signature (PTDS), was developed by researchers by combining polarimetric data with reflectivity and velocity data, showing areas with a probability of detection greater than 80%. It is used on the USNational Weather Service weather radar outputs.^[7]

• Tornado vortex signature
• Convective storm detection
• Mesocyclone
• Debris fallout

• Dual-Polarization Radar Training for NWS Partners includingTornado Debris Signature module by the NWSWarning Decision Training Branch (WDTB)
• Van Den Broeke, Matthew S.; S. T. Jauernic (2014)."Spatial and Temporal Characteristics of Polarimetric Tornadic Debris Signatures".J. Appl. Meteorol. Climatol.53 (10):2217–31.Bibcode:2014JApMC..53.2217V.doi:10.1175/JAMC-D-14-0094.1.
• Bodine, David J.; R. D. Palmer; G. Zhang (2014)."Dual-Wavelength Polarimetric Radar Analyses of Tornadic Debris Signatures".J. Appl. Meteorol. Climatol.53 (2):242–61.Bibcode:2014JApMC..53..242B.doi:10.1175/JAMC-D-13-0189.1.

• Radar meteorology
• Severe weather and convection
• Tornado

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