DOCSLIB.ORG

Radar Basics Radar Basics Radio Detection and Ranging Important

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Radar Basics Radar Basics Radio Detection and Ranging Important RadarRadar BasicsBasics Strengths,Strengths, LimitationsLimitations andand MythsMyths 2009 DuPage County Advanced Spotter Training Wheaton College Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training RadioRadio DetectionDetection andand RangingRanging NEXRADNEXRAD – – Next Next Generation Generation Radar Radar WSR-88DWSR-88D – – Weather Weather Surveillance Surveillance Radar, Radar, 1988 1988 Doppler Doppler Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training ImportantImportant AnglesAngles The azimuth angle is the compass angle from north (360°) Targets are indicated by A/R (Azimuth/Range) Birds eye view is displayed on a PPI (Planned Position Indicator) A cross sectional display is an RHI (Range Height Indicator) Volume scan Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training 1 ReflectivityReflectivity Reflectivity is a measure of how much power is returned from a radar’s pulse. The information is displayed in pixel-like units of area called “gates” The unit of reflectivity is a decibel of reflectivity or dBZ. Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training ClearClear AirAir ModeMode RangeRange from from -28 -28 to to 28 28 dBZ dBZ 1616 4dBz 4dBz increments increments Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training PrecipitationPrecipitation ModeMode RangeRange from from 5 5 to to 75 75 dBZ dBZ 1616 5dBz 5dBz increments increments Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training 2 ModeMode isis ControlledControlled byby NWSNWS andand CanCan BeBe ProblematicProblematic Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training NIDSNIDS --Nexrad NexradInformation Information DisseminationDissemination ServiceService BaseBase Reflectivity Reflectivity – – Various Various Elevation Elevation Angles Angles Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training NIDSNIDS --Nexrad NexradInformation Information DisseminationDissemination ServiceService BaseBase (or (or Storm Storm Relative) Relative) Velocity Velocity – – VariousVarious Elevation Elevation Angles Angles Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training 3 NIDSNIDS --Nexrad NexradInformation Information DisseminationDissemination ServiceService 11 Hour Hour Precipitation Precipitation Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training NIDSNIDS --Nexrad NexradInformation Information DisseminationDissemination ServiceService StormStorm Total Total Precipitation Precipitation Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training NIDSNIDS --Nexrad NexradInformation Information DisseminationDissemination ServiceService Composite Reflectivity Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training 4 InterpretingInterpreting DopplerDoppler RadarRadar RadialRadial Velocity Velocity is is the the velocity velocity toward toward or or away away from from a a radar radar Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training AutomatedAutomated DetectionDetection ofof MeteorologicalMeteorological PhenomenaPhenomena Algorithms help detect significant features • MDA – Mesocyclone Detection Algorithm • Meso - “donut” • Persistent, strong and detected over a large depth of the storm • TDA – Tornado Detection Algorithm • TVS – Tornado Vortex Signature • Strong gate to gate shear • HDA – Hail Detection Algorithm SCIT - Storm Cell Identification and Tracking Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training CompositeComposite ReflectivityReflectivity withwith StormStorm AttributeAttribute TableTable Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training 5 CompositeComposite ReflectivityReflectivity withwith SymbolsSymbols Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training VelocityVelocity AliasingAliasing andand DealiasingDealiasing Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training APAP andand GroundGround ClutterClutter AP is enhanced by strong returns from buildings (ground clutter) Cooling in the evening hours results in a low-level nocturnal inversion and AP Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training 6 MythMyth 1:1: AllAll StormsStorms areare SupercellsSupercells (Wouldn(Wouldn’t’t thatthat bebe nice!)nice!) Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training MythMyth 2:2: II CanCan IdentifyIdentify SupercellsSupercells byby LookingLooking atat ReflectivityReflectivity 1 2 3 4 5 WhichWhich are are supercells? supercells? Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training MythMyth 3:3: SizeSize MattersMatters Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training 7 MythMyth 4:4: SupercellsSupercells areare IsolatedIsolated StormsStorms Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training TruthTruth 1:1: AlwaysAlways UseUse VelocityVelocity DataData toto DetectDetect thethe MesocycloneMesocyclone Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training MythMyth 5:5: RedRed NextNext toto GreenGreen MeansMeans RotationRotation Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training 8 TruthTruth 2:2: AzimuthalAzimuthalShear Shear ImpliesImplies RotationRotation Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training AA TVSTVS isis StrongStrong ““Gate-to-Gate”Gate-to-Gate” AzimuthalAzimuthalShear Shear Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training TVSTVS Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training 9 BiggestBiggest RadarRadar MythMyth Ever!Ever! RadarRadar WillWill SeeSee AllAll TornadoesTornadoes Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training MostMost ImportantImportant Truth:Truth: SpottersSpotters areare VitalVital ToTo SuccessSuccess Radar is a very powerful tool It helps meteorologists understand what might be happening in the storm Only a good spotter can verify that info Radar is prone to a lot of errors and mistakes in interpretation Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training WhereWhere toto GetGet RadarRadar InfoInfo http://weather.cod.edu/analysis http://radar.weather.gov/ http://grlevelx.com/ Other private vendors Professor Paul Sirvatka – College of DuPage 2009 DuPage Advanced Spotter Training 10.
Load more

Recommended publications
  • NEWSLETTER National Weather Association No
    NEWSLETTER National Weather Association No. 10 – 12 December 2010 Tracking the Storms the PLOWS Way Adverse road conditions as- sociated with winter storms are re- sponsible for a large portion of the nearly 7000 deaths, 600,000 inju- Inside This Edition ries and 1 4. million accidents that occur in the United States each Internet Based GIS year . Improving cool season quan- Remote Sensing and Storm titative precipitation forecasting Chasing . .2 depends largely on developing a greater understanding of the me- President’s Message . .3 soscale structure and dynamics of cyclonic weather systems . The Pro- This C-130 Hercules Aircraft flies PLOWS missions. New Learning Opportunities filing of Winter Storms (PLOWS) project is aimed at doing just that. During the 2008- from the EJOM . 4. 2009 and 2009-2010 winter seasons, the University of Illinois (UI), the University of Alabama at Huntsville (UAH) and the University of Missouri (UM) placed teams of Scholarship Fundraising . 4. researchers in the field to study winter cyclones across the Midwestern United States NWA on Twitter and Facebook . .5 as part of the PLOWS project . PLOWS was designed to be a comprehensive field campaign, with complementary National Academy of Sciences to numerical modeling studies, that will address outstanding scientific questions targeted Study NWS . .7 at improving our understanding of precipitation substructures in the northwest and warm frontal quadrants of continental extratropical cyclones. The field strategy Professional Development was designed to answer questions about the mesoscale structure of winter storms Opportunities . .7 including: • What are the predominant spatial patterns of organized precipitation NWA Mission and Vision substructures, such as bands and generating cells, in these quadrants and how Statements .
    [Show full text]
  • Polarimetric Radar Characteristics of Tornadogenesis Failure in Supercell Thunderstorms
    atmosphere Article Polarimetric Radar Characteristics of Tornadogenesis Failure in Supercell Thunderstorms Matthew Van Den Broeke Department of Earth and Atmospheric Sciences, University of Nebraska-Lincoln, Lincoln, NE 68588, USA; [email protected] Abstract: Many nontornadic supercell storms have times when they appear to be moving toward tornadogenesis, including the development of a strong low-level vortex, but never end up producing a tornado. These tornadogenesis failure (TGF) episodes can be a substantial challenge to operational meteorologists. In this study, a sample of 32 pre-tornadic and 36 pre-TGF supercells is examined in the 30 min pre-tornadogenesis or pre-TGF period to explore the feasibility of using polarimetric radar metrics to highlight storms with larger tornadogenesis potential in the near-term. Overall the results indicate few strong distinguishers of pre-tornadic storms. Differential reflectivity (ZDR) arc size and intensity were the most promising metrics examined, with ZDR arc size potentially exhibiting large enough differences between the two storm subsets to be operationally useful. Change in the radar metrics leading up to tornadogenesis or TGF did not exhibit large differences, though most findings were consistent with hypotheses based on prior findings in the literature. Keywords: supercell; nowcasting; tornadogenesis failure; polarimetric radar Citation: Van Den Broeke, M. 1. Introduction Polarimetric Radar Characteristics of Supercell thunderstorms produce most strong tornadoes in North America, moti- Tornadogenesis Failure in Supercell vating study of their radar signatures for the benefit of the operational and research Thunderstorms. Atmosphere 2021, 12, communities. Since the polarimetric upgrade to the national radar network of the United 581. https://doi.org/ States (2011–2013), polarimetric radar signatures of these storms have become well-known, 10.3390/atmos12050581 e.g., [1–5], and many others.
    [Show full text]
  • Article Usage of Color Scales on Radar Maps
    Bryant, B., M. Holiner, R. Kroot, K. Sherman-Morris, W. B. Smylie, L. Stryjewski, M. Thomas, and C. I. Williams, 2014: Usage of color scales on radar maps. J. Operational Meteor., 2 (14), 169179, doi: http://dx.doi.org/10.15191/nwajom.2014.0214. Journal of Operational Meteorology Article Usage of Color Scales on Radar Maps BRITTNEY BRYANT, MATTHEW HOLINER, RACHAEL KROOT, KATHLEEN SHERMAN-MORRIS, WILLIAM B. SMYLIE, LISA STRYJEWSKI, MEAGHAN THOMAS, and CHRISTOPHER I. WILLIAMS Mississippi State University, Mississippi State, Mississippi (Manuscript received 3 October 2013; review completed 14 April 2014) ABSTRACT The visualization of rainfall rates and amounts using colored weather maps has become very common and is crucial for communicating weather information to the public. Little research has been done to investigate which color scales lead to the best understanding of a weather map; however, research has been performed on the general use of color and the theory behind it. Applying color theory specifically to weather maps, we designed this project to see if there was a statistically significant difference in an individual’s interpretation of weather data presented in two different color scales. We used a radar map and a storm-total precipitation map, each presented in both a rainbow scale and a monochromatic green scale, for a total of four images. A survey based on these images was distributed online to students at Mississippi State University. After analyzing the results, we found that people who received the radar image with the green scale were more likely to answer questions associated with that image correctly. However, there was no significant difference in accuracy between the two color scales on the storm-total precipitation map.
    [Show full text]
  • A Preliminary Investigation of Derecho-Producing Mcss In
    P 3.1 TROPICAL CYCLONE TORNADO RECORDS FOR THE MODERNIZED NWS ERA Roger Edwards1 Storm Prediction Center, Norman, OK 1. INTRODUCTION and BACKGROUND since 1954 was attributable to the weakest (F0) bin of damage rating (Fig. 1). This is the very class of Tornadoes from tropical cyclones (hereafter TCs) tornado that is most common in TC records, and most pose a specialized forecast challenge at time scales difficult to detect in the damage above that from the ranging from days for outlooks to minutes for concurrent or subsequent passage of similarly warnings (Spratt et al. 1997, Edwards 1998, destructive, ambient TC winds. As such, it is possible Schneider and Sharp 2007, Edwards 2008). The (but not quantifiable) that many TC tornadoes have fundamental conceptual and physical tenets of gone unrecorded even in the modern NWS era, due midlatitude supercell prediction, in an ingredients- to their generally ephemeral nature, logistical based framework (e.g., Doswell 1987, Johns and difficulties of visual confirmation, presence of swaths Doswell 1992), fully apply to TC supercells; however, of sparsely populated near-coastal areas (i.e., systematic differences in the relative magnitudes of marshes, swamps and dense forests), and the moisture, instability, lift and shear in TCs (e.g., presence of damage inducers of potentially equal or McCaul 1991) contribute strongly to that challenge. greater impact within the TC envelope. Further, there is a growing realization that some TC tornadoes are not necessarily supercellular in origin (Edwards et al. 2010, this volume). Several major TC tornado climatologies have been published since the 1960s (e.g., Pearson and Sadowski 1965, Hill et al.
    [Show full text]
  • Three-Body Scatter Spike
    RADAR OBSERVATIONS OF A RARE “TRIPLE” THREE-BODY SCATTER SPIKE Phillip G. Kurimski NOAA/National Weather Service Detroit/Pontiac, Michigan Weather Forecast Office Abstract afternoon and evening across northeast Wisconsin. The hail storms were responsible forOn 1over July 10.3 2006, million several dollars supercell of damage. thunderstorms The most produced intense storm significant produced hail during hail up the to late 4 in. in diameter that damaged over 100 cars and numerous homes in Oconto County, Wisconsin. This storm exhibited a rare, triple three-body scatter spike (TBSS) and a very long, impressive 51 mile TBSS. This paper will diagnose the structure and character of the paperhail cores will responsibleconnect the forunusually the multiple large TBSSscattering using angle several associated different with tools, the illustrating 51 mile longthat TBSSTBSS areto the 3-D increased features thatscattered are not energy confined responsible to a single for elevation the long TBSS.slice. In addition, Corresponding Author: Phillip G. Kurimski NOAA/ National Weather Service, 9200 White Lake Road, White Lake, Michigan 48386-1126 E-mail: [email protected] Kurimski 1. Introduction Since the early days of weather radar, radar operators three distinct TBSS signatures in a single volume scan andsignatures elevation has angle been is observed a phenomenon (Stan-Sion that haset al. yet 2007), to be result from large hail in a thunderstorm (Wilson and Reum documented and is the main motivation for this paper. The 1988).have noticed When athe “flare radar echo” beam down encounters the radial large believed hailstones to with a coating of liquid water, power from the radar is throughout this paper.
    [Show full text]
  • Forensic Analysis
    FORENSIC ANALYSIS CLAIM Location: 123 Sample Road, Brooklyn Center, MN ​ ​ Event Date(s): June 29, 2015 Prepared for: Sample PLLC Scope: Determine the possibility of severe, damaging hail impacting the Property on June 29, 2015. All data, observations and conclusions included in this report are based on the following data and materials: ● Watches, warnings and storm reports issued by the National Weather Service (NWS) in the Twin Cities accessed via Iowa Environmental Mesonet (IEM) ● Historical KMPX Doppler Radar located in Chanhassen, MN accessed via GR2Analyst ● National Weather Service (NWS) hourly reporting stations accessed via the Iowa Environmental Mesonet (IEM) ● Archived social media reports via Twitter ● Eye witness reports and photographs (Sample PLLC) ● Sample Engineering Report (Sample PLLC) 6569 City West Parkway, Eden Prairie, MN 55344 (952) 401 1005 www.praedictix.com 1 | Page FORENSIC ANALYSIS OVERVIEW Sample PLLC has requested a professional meteorological analysis of strong thunderstorms and subsequent hail damage that occurred at their Property located at or around 123 Sample Road, Brooklyn ​ ​ Center, Minnesota. We refer to this location as “the Property” in this report. We have been asked to review the weather conditions on June 29, 2015. Based on our analysis, the Property was subject to a severe thunderstorm on the evening of June 29, 2015. A series of strong storms impacted the north Minneapolis metro late that afternoon/evening with multiple Severe Thunderstorm Warnings in the region. Large, damaging hail was confirmed with these thunderstorms as a sequence of storm damage reports recorded by trained weather spotters (Figure 1). The Property was grazed by a core of large hail produced by a severe thunderstorm between 7:14 PM and 7:19 PM on June 29, 2015.
    [Show full text]
  • A Case Study of the 15 March 2008 South Carolina Supercell Outbreak David A
    A Case Study of the 15 March 2008 South Carolina Supercell Outbreak David A. Glenn*, Hunter Coleman*, Anthony W. Petrolito, Michael W. Cammarata NOAA/National Weather Service, Weather Forecast Office, Columbia, South Carolina *Email: [email protected] or [email protected] Introduction Science in Operations An important aspect of this poster is to illustrate how well certain scientific applications performed during the 15 March event. Forecast hodographs showed 2100 2100 the classic veering wind direction and increased speed with height (Fig. 8). Forecasters produced and interpreted cross sections and three-dimensional plots Background: On the afternoon of 15 March 2008, a significant tornado outbreak occurred across the NWS Columbia, SC forecast area. Seven long-track UTC UTC of 0.5 degree reflectivity and storm relative velocity (SRV) fields for each supercell from the Columbia, SC (KCAE) WSR-88D (Figs. 9 and 10). The three- supercells spawned numerous minor tornadoes and several strong (EF2-EF3) tornadoes causing an estimated 40 million dollars in damage (Fig. 1). There dimensional radar representation of the Edgefield County supercell (Fig. 9a) depicts the classic supercell hook, inflow notch, BWER, and elevated core. The were multiple reports of golf ball size hail as well as significant structural damage that occurred in the cities of Prosperity and Branchville, SC. The potential SRV shows Vr shear values of 50 kts. (Fig. 9a), and resulting damage of a home in Edgefield County (Fig. 9b). The Orangeburg County supercell’s reflectivity for supercell development leading up to the event was due to strong mid- and low-level wind shear coupled with ample lift, surface convergence, and pattern in three-dimensions illustrates a BWER and elevated hail shaft, while the SRV shows Vr shear values of 53 kts (Fig.
    [Show full text]
  • Article Reflectivity Vortex Hole in a Tornadic Supercell
    Schultz, C. J., 2014: Reflectivity vortex hole in a tornadic supercell. J. Operational Meteor., 2 (9), 103109, doi: http://dx.doi.org/10.15191/nwajom.2014.0209. Journal of Operational Meteorology Article Reflectivity Vortex Hole in a Tornadic Supercell CHAUNCY J. SCHULTZ National Weather Service, Billings, Montana (Manuscript received 25 June 2013; review completed 20 February 2014) ABSTRACT The Weather Surveillance Radar-1988 Doppler (WSR-88D) at Thedford, Nebraska, detected a distinct reflectivity minimum in the hook echo of a tornadic supercell over north-central Nebraska on 11 August 2011. This “eye-like” feature was co-located with a tornadic vortex signature and was detectable to an altitude exceeding 8 km above ground level. A literature review of eye-like features in radar imagery in association with tornadic storms revealed that these signatures have been documented since the 1950s, but may have only recently become more commonly observed by WSR-88Ds with the change to super-resolution grid spacing. The reflectivity vortex hole observed on 11 August 2011 was analyzed using both constant- elevation and three-dimensional radar imagery. Polarimetric radar data from WSR-88Ds in close proximity to four prominent tornadoes in May and June 2013 revealed at least brief reflectivity vortex holes with each of those cases, and suggested that recognition of vortex holes by meteorologists may supplement information from polarimetric tornadic debris signatures. 1. Introduction hole by Lemon and Umscheid (2008). Apparently the An intense supercell over north-central Nebraska KLNX WSR-88D reflectivity imagery associated with on the evening of 11 August 2011 produced an inter- the supercell near Purdum, Nebraska, on 11 August esting and unique “eye” within its hook echo during 2011 also contained one of these vortex holes.
    [Show full text]
  • A Rare Supercell Outbreak in Western Nevada: 21 July 2008
    National Weather Association, Electronic Journal of Operational Meteorology, 2009-EJ6 A Rare Supercell Outbreak in Western Nevada: 21 July 2008 CHRIS SMALLCOMB National Weather Service, Weather Forecast Office, Reno, Nevada (Manuscript received 30 June 2009, in final form 29 September 2009) ABSTRACT A rare outbreak of organized severe thunderstorms took place in western Nevada on 21 July 2008. This paper will examine the environment antecedent to this event, including unusual values of shear, moisture, and instability. An analysis of key radar features will follow focusing primarily on WSR-88D base data analysis. The article demonstrates several locally developed parameters and radar procedures for identifying severe convection, along with addressing challenges encountered in warning operations on this day. 1. Introduction – Event Synopsis A rare outbreak of organized severe thunderstorms took place in the National Weather Service (NWS) Reno forecast area (FA) on 21 July 2008. Based on forecaster experience, this has been subjectively classified as a “one in ten” year event for the western Great Basin (WGB), which being located in the immediate lee of the Sierra Nevada Mountains, is unaccustomed to widespread severe weather. Unorganized pulse type convection is a much more frequent occurrence in this portion of the country. On 21 July 2008, numerous instances of large hail and heavy rainfall were associated with severe thunderstorms (Fig. 1). The maximum hail size reported was half-dollar (3.2 cm, 1.25”), however there is indirect evidence even larger hail occurred. Several credible reports of funnel clouds were received from spotters, though a damage survey the following day found no evidence of tornado touchdowns.
    [Show full text]
  • Observations of Terrestrial Gamma Flashes with TETRA and LAGO
    Louisiana State University LSU Digital Commons LSU Doctoral Dissertations Graduate School 2014 Observations of Terrestrial Gamma Flashes with TETRA And LAGO Rebecca Ringuette Louisiana State University and Agricultural and Mechanical College, [email protected] Follow this and additional works at: https://digitalcommons.lsu.edu/gradschool_dissertations Part of the Physical Sciences and Mathematics Commons Recommended Citation Ringuette, Rebecca, "Observations of Terrestrial Gamma Flashes with TETRA And LAGO" (2014). LSU Doctoral Dissertations. 2934. https://digitalcommons.lsu.edu/gradschool_dissertations/2934 This Dissertation is brought to you for free and open access by the Graduate School at LSU Digital Commons. It has been accepted for inclusion in LSU Doctoral Dissertations by an authorized graduate school editor of LSU Digital Commons. For more information, please [email protected]. OBSERVATIONS OF TERRESTRIAL GAMMA FLASHES WITH TETRA AND LAGO A Dissertation Submitted to the Graduate Faculty of the Louisiana State University and Agricultural and Mechanical College in partial fulfillment of the requirements for the degree of Doctor of Philosophy in The Department of Physics & Astronomy by Rebecca A. Ringuette B. S., Louisiana State University, 2007 M. S., Louisiana State University, 2013 August 2014 This dissertation is dedicated primarily to the God of Abraham, Isaac and Jacob who blessed me with this opportunity and gave me the strength to complete it. I also dedicate this work to my husband, my child and my mother, without whom it would have been extremely difficult. ii ACKNOWLEDGEMENTS The lightning data were provided by the United States Precision Lightning Network Unidata Program. The radar data used for the automated daily analysis described in chapter 4 were automatically downloaded in real time from http://www.wunderground.com using code developed by S.
    [Show full text]
  • P5.3 the Utility of Three-Dimensional Radar Displays in Severe Weather Warning Operations
    P5.3 THE UTILITY OF THREE-DIMENSIONAL RADAR DISPLAYS IN SEVERE WEATHER WARNING OPERATIONS Daniel D. Nietfeld NOAA/National Weather Service Valley, NE 1. INTRODUCTION Edition (GR2AE) (http://www.grlevelx.com/) to interrogate severe storms during 16 separate Traditional methods of interrogating severe episodes spanning from 30 March, 2006 through 3 thunderstorms using radar data have primarily September, 2006. This software was used only as utilized two-dimensional displays (2-D). The 2-D an additional tool to the AWIPS Display 2 displays were either a quasi-horizontal plane of x-y Dimension (D2D) software (MacDonald, 1996), coordinates (north vs. south), or a vertical plane of which is the traditional software used for warning x-z coordinates (horizontal distance from the radar operations. The D2D software only allows the vs. height above ground). Using these displays, user to view 2-D perspectives, and most meteorologists have been able to assess the commonly the quasi-horizontal tilts of each vertical and horizontal structure of thunderstorms elevation scan. These views were used either in a by viewing multiple images of either: each 4-panel method which displayed 4 different elevation angle of the radar, or multiple vertical elevation angles (See Fig. 1), or in an “all-tilts” cross sections through the storms. method in which each new elevation angle was Recently, software and hardware advances displayed as it arrived in the AWIPS workstation. have allowed for the display of radar data in three- dimensions (3-D), using an earth-centered coordinate system. This enables the software to display the complete vertical and horizontal distribution of radar data within one image, of which the viewing perspective can be altered by the user.
    [Show full text]
  • Radar Identified Severe Storms Varied from Discrete Supercells to Narrow
    13B.7 THE CLIMATOLOGY, CONVECTIVE MODE, AND MESOSCALE ENVIRONMENT OF COOL SEASON SEVERE THUNDERSTORMS IN THE OHIO AND TENNESSEE VALLEYS, 1995-2006 Bryan T. Smith*, Jared L. Guyer, and Andrew R. Dean NOAA/NWS/NCEP/Storm Prediction Center, Norman, OK 1. INTRODUCTION Forecasting severe weather in the cool season Center hourly mesoanalysis data (Bothwell et al. (October-March) can pose a difficult challenge even for 2002). experienced severe weather forecasters. Parts of the United States, including Illinois, Indiana, Ohio, 2. DATA AND METHODOLOGY Kentucky, and Tennessee, are occasionally impacted by deadly severe weather outbreaks that occur in the cool 2.1 Severe report climatology season. According to Galway and Pearson (1981), cool season tornado outbreaks are rare but significant The 1995-2006 severe weather report events. A recent noteworthy cool season outbreak was dataset was gathered using the Severeplot program the 5 February 2008 Super Tuesday tornado outbreak in (Hart and Janish 2003). The cool season severe which 57 fatalities occurred (U.S. Department of report data from the Ohio and Tennessee Valleys Commerce, StormData 2008). were then compiled and analyzed in a Geographic Aspects of severe weather research have Information System (GIS). Using these data, we evolved over the past decade. Some severe weather define a tornado day as a 24 hr period beginning at studies have focused on severe and tornadic the first reported tornado time and a tornado outbreak thunderstorm environments (e.g., Thompson et al. (Galway 1977) as an event consisting of ten or more 2003), others developed storm mode climatologies tornadoes beginning and ending at separations (Hocker and Basara 2008), and some focused on the between synoptic systems.
    [Show full text]