WSR-88D Dual Polarization Initial Operational Capabilities WSR-88D Dual Polarization Initial Operational Capabilities 25th AMS Conference on International.

Slides:

Advertisements

Similar presentations

POLARIMETRIC RADAR IMPROVEMENTS

Advertisements

Future Radar and Satellite Technology Daniel C. Miller National Weather Service Columbia, SC.

Report of the Q2 Short Range QPF Discussion Group Jon Ahlquist Curtis Marshall John McGinley - lead Dan Petersen D. J. Seo Jean Vieux.

NEXRAD or WSR-88D [Next Generation Radar] [Weather Surveillance Radar, 1988, Doppler]

ATS 351 Lecture 9 Radar. Radio Waves Electromagnetic Waves Consist of an electric field and a magnetic field Polarization: describes the orientation.

MPING: Citizen Science Research Kim Elmore (NSSL/CIMMS)

NEXRAD TAC Norman, OK March 21-22, 2006 Clutter Mitigation Decision (CMD) system Status and Demonstration Studies Mike Dixon, Cathy Kessinger, and John.

21 September th Southwest Hydrometeorology Symposium, Tucson, AZ Future QPE: Dual-Pol and Gap-Filler Radars Kevin Scharfenberg University of Oklahoma/CIMMS.

National Weather Association 31 st Annual Meeting 18 October 2006 Cleveland, Ohio Kevin Scharfenberg University of Oklahoma Cooperative Institute for Mesoscale.

Clear air echoes (few small insects) -12 dBZ. Echoes in clear air from insects Common is summer. Watch for echoes to expand area as sun sets and insects.

DUAL-POLARIZATION OF WSR-88D NETWORK

Radar-Derived Rainfall Estimation Presented by D.-J. Seo 1 Hydrologic Science and Modeling Branch Hydrology Laboratory National Weather Service Presented.

The WSR-88D at the National Severe Storms Laboratory, KOUN, was upgraded to add polarization diversity in KOUN transmits each EM pulse with an orientation.

Rainfall Monitioring Using Dual-polarization Radars Alexander Ryzhkov National Severe Storms Laboratory / University of Oklahoma, USA.

Rainfall Rate Relationships in WSR-88D Rainfall Estimation Algorithms Dan Berkowitz Applications Branch Radar Operations Center.

New Concepts in Utilization of Polarimetric Weather Radars Alexander Ryzhkov (CIMMS) February 25–27, 2015 National Weather Center Norman, Oklahoma.

Anomalous Propagation Greater density slows the waves more. Less dense air does not slow the waves as much. Since density normally decreases with height,

What can Dual-Polarization Doppler Radar Do for You? Neil Fox Department of Atmospheric Science University of Missouri - Columbia.

Surveillance Weather Radar 2000 AD. Weather Radar Technology- Merits in Chronological Order WSR-57 WSR-88D WSR-07PD.

Basic RADAR Principles Prof. Sandra Cruz-Pol, Ph.D. Electrical and Computer Engineering UPRM.

The Future of NWS Technology – NEXRAD The Future of NWS Technology – NEXRAD 1st NWS Severe Weather Technology User Meeting July 12-14, 2005 Mike Istok.

Data Windowing in ORDA Technical Briefing Sebastián Torres 1,2, Chris Curtis 1,2, Rodger Brown 2, and Michael Jain 2 1 Cooperative Institute for Mesoscale.

Comparison of PPS and QPE Rainfall Estimates for Summer 2013 Heavy Precipitation Events Comparison of PPS and QPE Rainfall Estimates for Summer 2013 Heavy.

Similar in concept to JDOP, except with the goal to operationally demonstrate the value of the polarimetric upgrade of the 88D. Multi-seasonal to study.

A Doppler Radar Emulator and its Application to the Detection of Tornadic Signatures Ryan M. May.

Dual Polarization Martin Hagen, Elena Saltikoff Deutsches Zentrum für Luft- und Raumfahrt (DLR) Oberpfaffenhofen, Germany Finnish Meteorological Institute.

Introduction to the Dual-Polarized WSR-88D

CARPE-DIEM 13/6/02, slide 1German Aerospace Center Microwaves and Radar Institute CARPE-DIEM Besprechung Helsinki, June 2004 Ewan.

Radar Basics and Estimating Precipitation Jon W. Zeitler Science and Operations Officer National Weather Service Austin/San Antonio Forecast Office Science.

National Weather Service Dual-Polarization Radar Technology Photo courtesy of NSSL.

Severe Weather Operations. Severe Weather Staffing (Positions in orange are minimum needed) Severe Weather Coordinator – oversees the operations of the.

Dual-Polarization Operations Assessment Status Update on Development Process Progress on RDA work Progress on RPG work Where we are with Beta and Deployment.

Dual Polarization Technology: The KICT Upgrade Paul Schlatter Warning Decision Training Branch Paul Schlatter Warning Decision Training Branch AMS/NWA.

Dual-Pol Radar Data: A Brief Primer and A Few Brief Pseudo-Operational Exercises (Courtesy of) Dan Miller Science and Operations Officer NWS/WFO Duluth,

COMET HYDROMET Enhancements to PPS Build 10 (Nov. 1998) –Terrain Following Hybrid Scan –Graphical Hybrid Scan –Adaptable parameters appended to.

The Role of Polarimetric Radar for Validating Cloud Models Robert Cifelli 1, Timothy Lang 1, Stephen Nesbitt 1, S.A. Rutledge 1 S. Lang 2, and W.K. Tao.

National Lab for Remote Sensing and Nowcasting Dual Polarization Radar and Rainfall Nowcasting by Mark Alliksaar.

Correlation Coefficient (CC)

Technical Interchange Meeting Spring 2008: Status and Accomplishments.

Noise is estimated [NEXRAD technical manual] at elevation >20  and scaled. Data with low Signal/Noise are determined and censored (black or white on PPI).

Radar Quality Control and Quantitative Precipitation Estimation Intercomparison Project Status Paul Joe Environment Canada Commission of Instruments, Methods.

Radar Palet e Home Dual Polarized Analysis & Diagnosis 1 Precipitation Phase – Radar Signatures Radar characteristics of precipitation types –Stratiform.

RAdio Detection And Ranging. Was originally for military use 1.Sent out electromagnetic radiation (Active) 2.Bounced off an object and returned to a listening.

What to make of this new radar technology Luke Madaus, UW Atmospheric Sciences 11/2/2011.

Aaron Reynolds WFO Buffalo

Quantitative Precipitation Estimation by WSR-88D Radar Dan Berkowitz Applications Branch Radar Operations Center.

WSR-88D Radar Rainfall Estimation Present and Near Future Daniel S. Berkowitz Applications Branch NWS Radar Operations Center Norman, Oklahoma 1.

Radar Palet e Home Dual Polarized Analysis & Diagnosis 1 Dual Polarized Radar What is polarimetric radar Polarimetric products Uses of these ‘raw’ outputs.

Alexander Ryzhkov Weather Radar Research Meteorological Applications of Dual-polarization Radar.

Dual-Polarization Radars

National Weather Association 31 st Annual Meeting 17 October 2006 Cleveland, Ohio Kevin Scharfenberg University of Oklahoma Cooperative Institute for Mesoscale.

WSR-88D PRECIPITATION ESTIMATION FOR HYDROLOGIC APPLICATIONS DENNIS A. MILLER.

Radar Requirements David J. Stensrud NOAA/National Severe Storms Laboratory 2013 Warn-on-Forecast Workshop and Technical Guidance Meetings.

Mark Ratzer February 26 th, 2011 WFO Chicago 2 nd Annual Aviation Weather Workshop.

Principals of Radar. F NWS Radar Characteristics 28 foot dish Pulse Width 0.95° Peak Power 750kW –Avg. Power 1.5kW Discrete Pulse Transmissions.

NEXRAD Data Quality 25 August 2000 Briefing Boulder, CO Cathy Kessinger Scott Ellis Joe VanAndel Don Ferraro Jeff Keeler.

WSR-88D Data Status And Plans Michael Istok NWS Office of Science & Technology and Tim Crum WSR-88D Radar Operations Center 21 June 2012 National Weather.

DUAL-POLARIZATION RADAR UPGRADE Emergency Manager Workshop Feb Chad Entremont.

Radar Interpretation Chad Entremont National Weather Service Jackson, MS.

Estimating Rainfall in Arizona - A Brief Overview of the WSR-88D Precipitation Processing Subsystem Jonathan J. Gourley National Severe Storms Laboratory.

Observations of Specific Differential Phase, KDP Chris Collier Acknowledgements: Lindsay Bennett, Alan Blyth and David Dufton.

NEXRAD Product Improvement- Update 2008 Bob Saffle: Noblis, Inc. Mike Istok: National Weather Service Greg Cate: National Weather Service AMS 24 th IIPS.

Travis Smith U. Of Oklahoma & National Severe Storms Laboratory Severe Convection and Climate Workshop 14 Mar 2013 The Multi-Year Reanalysis of Remotely.

A Moment Radar Data Emulator: The Current Progress and Future Direction Ryan M. May.

Future Radar and Satellite Technology

DUAL POLARIZATION AND ZDR CALIBRATION IMPROVEMENTS 5.2(6)

A dual-polarization QPE method based on the NCAR Particle ID algorithm Description and preliminary results Michael J. Dixon1, J. W. Wilson1, T. M. Weckwerth1,

NEXRAD Data Quality Optimization AP Clutter Mitigation Scheme

High resolution radar data and products over the Continental United States National Severe Storms Laboratory Norman OK, USA.

the University of Oklahoma

Presentation transcript:

WSR-88D Dual Polarization Initial Operational Capabilities WSR-88D Dual Polarization Initial Operational Capabilities 25th AMS Conference on International Interactive Information and Processing Systems (IIPS) for Meteorology, Oceanography, and Hydrology 15 January 2009 Michael J. Istok NOAA/NWS/Office of Science and Technology Systems Engineering Center, Silver Spring, MD 25 th IIPS 15.5

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES WSR-88D Dual Polarization Initial Operational Capabilities Coauthors: Mark Fresch, NOAA/NWS/Office of Hydrologic Development Zack Jing, Steven Smith, Richard Murnan, NOAA/NWS/OOS/Radar Operations Center Alexander Ryzhkov, John Krause, and Michael Jain, NOAA/OAR/National Severe Storms Laboratory Paul Schlatter (Training Division), John Ferree (Meteorological Services Division), NOAA/NWS/OCWWS Brian R. Klein, Daniel Stein III, Wyle Information Systems Gregory Cate, NOAA/NWS/Office of Science and Technology/Programs and Plans Division Robert E. Saffle, Noblis, Inc. Acknowledgments: Ning Shen, Yukuan Song, Zihou Wang, James Ward, Jihong Lui, Zhan J Zhang, Wyle Information Systems Cham Pham, NOAA/NWS/Office of Hydrologic Development Jim Ramer, Joanne Edwards, Xiangbao Jing, NOAA/OAR/ESRL/Global Systems Division

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES Introduction Mission benefits by adding dual polarization capability to the WSR-88D –Improved hail detection for severe thunderstorm warnings, –Improved rainfall estimation for flood and flash flood warnings, –Rain/snow discrimination for winter weather warnings and advisories, –Data retrieval from areas of partial beam blockage to improve services in mountainous terrain, and –Removal of non-weather artifacts such as birds and ground clutter to improve overall data quality for algorithms and numerical model input. Dual Polarization program lead by NWS OST –Contract awarded September 2007 to develop and deploy changes to the RDA. – Begin System and Beta test in October 2009 and June 2010 – 2-year deployment starts in October 2010 –RPG and AWIPS changes implemented through NOAA collaboration – RPG Build 12: NWS OST, OHD, ROC, OCWWS, and OAR NSSL. –Test and deploy with RDA upgrade – AWIPS OB 8.3 & 9: NWS OST, OHD, OCWWS, and OAR ESRL GSD. –Deploy in early 2009 to support WSR-88D testing and AWIPS-2 program. –NWS OCWWS involved in product requirements & WDTB has begun training development

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES WSR-88D RDA Simultaneous transmission of horizontal and vertically polarized pulses to acquire dual polarization data. –Minimizes dwell time, therefore will not lengthen volume scans –Splitting the power results in a return signal with reduced sensitivity – Scientific analysis and WFO usage reports indicated no significant operational impact – Hardware design and signal processing techniques should recover some of the reduced sensitivity Differential Reflectivity (Zdr), Correlation Coefficient (CC), and Differential Phase (Phi) will be added to the base data fields –At range resolution of 250 m, up to maximum range of 300 km –On low elevation split cuts, radials will be provided at 0.5 deg azimuth. –The other two data enhancements introduced in WSR-88D Build 10 will be extended to all the remaining elevations of all VCP’s – 250 m range resolution for reflectivity data – 300 km maximum range for Doppler moments

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES WSR-88D RPG: Algorithms Recombination Algorithm –Creates 1 degree azimuth data from 0.5 degree data on split cuts Dual Polarization Preprocessing Algorithm –Inputs recombined base data (1 degree by 250m) –Unwrap PHI –Estimate specific differential phase (Kdp) –Correct reflectivity and differential reflectivity with differential phase –Calculate signal-to-noise ratio and the spatial variability (the texture) of both the reflectivity and the differential phase –Smooth dual polarization fields and base moments along the radial to reduce the variances from noise and ground clutter contamination –Output to the dual polarization initial operational capability (IOC) algorithms and products

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES WSR-88D RPG: Algorithms - continued Hydrometeor Classification (HC) Algorithms –Quality Index Algorithm (QIA) – Calculate quality index for six of HCAs input data fields – Estimate of the impact from the following five factors: –Attenuation, non-uniform beam filling effects, magnitude of the correlation coefficient, signal-to-noise ratio and partial beam blockage. – Data with a quality index value less than 1.0 indicates the data is degraded by one or more of the five factors. –HC Algorithm (HCA) – Fuzzy logic to classify each sample bin to one of 12 categories – Proximity to Melting Layer constrains classification possibilities – Weighting factors control influence of data variables on classification – Hard Rules (e.g., HA > 30 dBZ, BI < 0.97 CC) – Computes aggregate score for each allowable hydrometeor classification –Melting Layer Detection Algorithm (MLDA) – HCA output is used to eliminate bins of GC, BI, UK, ND – Reflectivity and CC of remaining bins are used to search for ML signatures –Elevation angles 4.5 to 10 degrees; Altitude below 6km; SNR > 5 dB – If data is sparse, uses 0 deg C altitude from RUC model or manually entered

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES WSR-88D RPG: Algorithms - continued HCA Categories GC Ground clutter / anomalous propagation BI Biological DS Dry snow WS Wet snow IC Ice crystals BD Big drops RA Rain (light and moderate) HR Heavy rain GR Graupel HA Hail (mixed with rain) UK Unknown ND No data (less than threshold) Melting Layer Constrains HCA Completely below: –GC, BI, BD, RA, HR, HA, UK, ND Partly below: –GC, BI, WS, BD, RA, GR, HR, HA, UK, ND Mostly within: –GC, BI, DS, WS, BD, GR, HA, UK, ND Partly above: –GC, BI, DS, WS, IC, BD, GR, HA, UK, ND Completely above: –DS, IC, GR, HA, UK, ND

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES WSR-88D RPG: Algorithms - Continued Quantitative Precipitation Estimation (QPE) Algorithm –Constructs hybrid scan of precipitation rate based on terrain data, hydrometeor classes, MLDA, and Dual Polarization data fields – Smoothes elevations of HCA data with 9 point Mode Filter – Reject GC or UK bins and look to next elevation – Rate of zero is assigned to BI or ND bins – Reject data if CC < 0.85, or blocked by 70%, and look to next elevation – Compute rate based on hydrometeor class & height relative to melting layer –0 [mm hr-1]nonmeteorological echo (BI, ND) –R(Z, ZDR)Light/Moderate Rain (RA) –R(Z, ZDR)Heavy Rain or Big Drops (HR, BD) –R(KDP)Hail, mixed with rain (HA) below the top of the melting layer –0.6 * R(Z)Wet Snow (WS) –0.8 * R(Z)Graupel (GR) –0.8 * R(Z)Hail, mixed with rain above the top of the melting layer –R(Z)Dry Snow (DS) below the top of the melting layer –2.8 * R(Z)Dry Snow (DS) above the top of the melting layer –2.8 * R(Z)Ice Crystals (IC) –Begins and ends storm total accumulation based on rate and area thresholds

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES WSR-88D RPG: Algorithms - Concluded The QPE algorithm should improve precipitation estimation in the following situations: –Where the radar beam is partially blocked –For nearly all hydrometeor classes –By greatly reducing contamination from non-precipitation echoes –By identifying the bright-band (melting layer) –By discriminating between rain and snow –By identifying hail and mitigating hail contamination

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES WSR-88D RPG: Products Elevation Based Products –Base Products (Zdr, CC, Kdp) – Built from output of preprocessor algorithm –Hydrometeor Classification –Melting Layer Precipitation –Hybrid Scan Hydrometeor Classification –Precipitation Rate –One-Hour Accumulation –Storm-Total Accumulation –User Selectable Accumulation Period – Specify (hh:mm) end time and span within previous 24 hour period –Difference Products: Dual Pol QPE minus Legacy PPS – One-Hour Difference – Storm-Total Difference

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES WSR-88D Dual Polarization Product Suite

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES Marginally Severe Supercell

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES Marginally Severe Supercell What about the rest? All > 0.97 What about the rest? All > 0.97 Precip Insects

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES Marginally Severe Supercell

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES SOO-DOH Images\kcri_0.5_HC_ _0638.png ft MSL

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES ML Product in AWIPS

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES Dual- Polarization QPE Products

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES AWIPS Enhancements Reorganized radar menus Four-Panel display operations –All-Tilts –Panel/Combo Rotate –All-Panel Sample Four Dimensional Storm Cell Investigator State scale mosaics Volume Browser CAPPI’s of radar products –Height above radar level –Height above mean sea level –At a temperature level

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES AWIPS Radar Menu Redesign

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES AWIPS All Panel Sample

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES AWIPS Dual Pol Display via FSI

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES AWIPS Volume Browser CAPPI Displays

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES Future Development Optimize HCA for transitional and winter weather Adjust MLDA for cold season storms when melting level is low Add classes by splitting Hail/Rain Mixture into small hail, large hail and adding freezing rain. Improving accuracy of precipitation at longer distances and in the presence of partial beam blockage Quantitative estimate of snow Identifying location of convective cells in projecting areas with higher melting layers and different hydrometeor characteristics Rain gage bias correction Improve data quality and automatically identify & assess features –Include dual polarization data in AP and clutter mitigation schemes –Bird-specific data and/or data with bird returns removed –Liquid water equivalent and In-flight icing –Tornado debris cloud

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES For Additional Information Michael Istok –National Weather Service Office of Science and Technology Systems Engineering Center, Silver Spring, MD – x103

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES Data and Product Distribution and Archive Level II Data (Top Tier Sites, NCDC) –Message 31 introduced for super-res, also supports dual-pol data –Changes to Metadata include VCP, Alarms, P/M data messages –Currently, 10 to 180 kbps per radar, depending on VCP & weather, and resulting in a network max hourly load near 7 mbps –Worst case dual pol increase by factor of 2.1 (per radar & network) –Version numbers will be expanded for new data characteristics –Resource constraints cause a mixture of Level II data versions – Full resolution, recombined, and dual pol removed – Exploring options to overcome constraints to provide additional data Level III Products (RPCCDS, NOAAPORT, NCDC) –Currently, 3 to 21 kbps per radar, depending on VCP & weather, and resulting in network max hourly load near 1.6 mbps. –Dual pol product types, elevations, and resolution will drive increase –Requirements formulation in progress –Dual pol to increase product load by at least a factor of 2

Slide AMS: 25th IIPS (15.5) WSR-88D DUAL POLARIZATION INITIAL OPERATIONAL CAPABILITIES Elevation Based Dual Polarization Products