Presentation is loading. Please wait.

Presentation is loading. Please wait.

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

Published byFerdinand Briggs Modified over 9 years ago

Similar presentations

Presentation on theme: "Surveillance Weather Radar 2000 AD. Weather Radar Technology- Merits in Chronological Order WSR-57 WSR-88D WSR-07PD."— Presentation transcript:

1 Surveillance Weather Radar 2000 AD

2 Weather Radar Technology- Merits in Chronological Order WSR-57 WSR-88D WSR-07PD

3 Technology Developments Digital receivers –Easy to achieve sampling rate higher than reciprocal of pulse (oversampling) Versatile circuits for transmitter control –Easy to phase code, to interleave PRTs (staggered and other), to compress pulse Signal processing on general purpose computers (PCs) –Easy to program algorithms and analyze Doppler spectra

4 Capability of the NSSL’s R&D weather surveillance radar Doppler and Dual Polarization Phase coding of transmitted pulses Transmission of arbitrary non uniform pulse sequence including staggered PRT Oversampling –by a factor of 5 in Dual Polarization Mode –By a factor of 10 in Single Polarization Mode Arbitrary scanning strategy (including RHI) Recording of time series data

5 Oversampling To increase speed of volume coverage To decrease errors in estimates of reflectivity, velocity, spectrum width, and polarimetric variables

6 Z, Standard Processing, Aug 04

7 Z, from Decorrelated Samples

8 Mitigation of range velocity ambiguities Phase coding at lower elevations Staggered PRT at higher elevations Demonstration of clutter filtering for both schemes Integration into volume coverage patterns Inclusion of oversampling Adaptive automatic choice of PRTs based on obscurations in immediately preceding scans

9 Reflectivity Long PRT EL = 0.5 deg 10/08/02 15:11 GMT Phase Coding

10 Doppler Velocity Phase coding, medium PRT EL = 0.5 deg 10/08/02 15:11 GMT Doppler Velocity Processing as on WSR-88D v a = 23.7 m s -1, r a = 175 km Phase Coding

11 Staggered PRT Reflectivity Staggered PRT EL = 2.5 deg 04/06/03 4:42 GMT

12 Staggered PRT v a = 25.4 m s -1 v a = 45.2 m s -1 148 km 184 km KTLX Doppler Velocity VCP 11 – Batch Mode KOUN Doppler Velocity Staggered PRT (184 km/276 km) EL = 2.5 deg 04/06/03 4:42 GMT

13 Dual Polarization at NSSL 1983: Upgrade of Cimarron radar to dual polarization; switching between horizontal and vertical polarization 1984: Collection of first (anywhere) dual polarization time series data 1985 to 1989: Definition of the complete set of polarimetric variables. Development of schemes to obtain these variables together with spectral moments 1992: First (anywhere) collection of polarimetric variables at all range locations 1992 to present: Development of schemes to classify hydrometeor type. Improvement of rainfall estimation. Design of a system functionally compatible with the WSR-88D; simultaneous transmission and reception of horizontally and vertically polarized waves 2002: Upgrade of KOUN radar to dual polarization 2002-2003: Joint POLarization Experiment (JPOLE)

14 Fields of polarimetric variables

15 Dual Polarization - Benefits Vastly superior data quality: calibration, mitigation of attenuation and beam blockage effects Discrimination between insects, birds, ground echoes, and precipitation Superior measurement of rainfall Detection of hail Classification of precipitation – rain vs freezing rain vs snow Determination of hail size Measurement of snowfall Icing detection

16 Stratiform Rain vs Snow

17 Imminent Goals Combining techniques to mitigate range and velocity ambiguities with optimum (pseudo whitening) procedure to increase speed of volume coverage and decrease errors of estimates Incorporating the above combined technique into dual polarization radar Developing adaptive scanning strategy for agile beam phased array radar

18 Three Challenges Direct estimation of wind transverse to the radar beam Determination of the alias interval of Doppler velocity from a single pulse Estimation of the forward propagation coefficient using returns from hydrometeors or biological scatterers

19 Major Endeavor Explaining bulk hydrometeor properties that cause distinct polarimetric signatures in convective storms

20 Major Endeavor Assimilation of radar data into local NWP (short term ~ 3 h, fine resolution ~ 1 km) model –coupled to distributed hydrological model for use over small watersheds (~ 1000s km 2 ) –capable of predicting tornadoes, strong winds, hail, and other hazards

21 END These are the news from the Prairie Town of Norman Were all meteorologists are No 1 And Engineers are second to none

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

Similar presentations

POLARIMETRIC RADAR IMPROVEMENTS

POLARIMETRIC RADAR IMPROVEMENTS
CLEAN-AP Update Cl utter E nvironment An alysis using A daptive P rocessing Sebastián Torres and David Warde CIMMS/The University of Oklahoma and National.

CLEAN-AP Update Cl utter E nvironment An alysis using A daptive P rocessing Sebastián Torres and David Warde CIMMS/The University of Oklahoma and National.
1 Sebastian Torres NEXRAD Range-Velocity Ambiguity Mitigation Staggered PRT and Phase Coding Algorithms on the KOUN Research Radar.

1 Sebastian Torres NEXRAD Range-Velocity Ambiguity Mitigation Staggered PRT and Phase Coding Algorithms on the KOUN Research Radar.
7. Radar Meteorology References Battan (1973) Atlas (1989)

7. Radar Meteorology References Battan (1973) Atlas (1989)
ATS 351 Lecture 9 Radar. Radio Waves Electromagnetic Waves Consist of an electric field and a magnetic field Polarization: describes the orientation.

ATS 351 Lecture 9 Radar. Radio Waves Electromagnetic Waves Consist of an electric field and a magnetic field Polarization: describes the orientation.
NEXRAD TAC Norman, OK March 21-22, 2006 Clutter Mitigation Decision (CMD) system Status and Demonstration Studies Mike Dixon, Cathy Kessinger, and John.

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 2007 4 th Southwest Hydrometeorology Symposium, Tucson, AZ Future QPE: Dual-Pol and Gap-Filler Radars Kevin Scharfenberg University of Oklahoma/CIMMS.

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

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.
Contributors to Measurement Errors (Chap. 7) *1) Widespread spatial distribution of scatterers (range ambiguities) *2) Large velocity distribution (velocity.

Contributors to Measurement Errors (Chap. 7) *1) Widespread spatial distribution of scatterers (range ambiguities) *2) Large velocity distribution (velocity.
DUAL-POLARIZATION OF WSR-88D NETWORK

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.

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 2002. KOUN transmits each EM pulse with an orientation.

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 Monitioring Using Dual-polarization Radars Alexander Ryzhkov National Severe Storms Laboratory / University of Oklahoma, USA.
 Definition of Spectrum Width (σ v ) › Spectrum width is a measure of the velocity dispersion within a sample volume or a measure of the variability.

 Definition of Spectrum Width (σ v ) › Spectrum width is a measure of the velocity dispersion within a sample volume or a measure of the variability.
Staggered PRT Update Part I Sebastián Torres and David Warde CIMMS/The University of Oklahoma and National Severe Storms Laboratory/NOAA NEXRAD TAC Norman,

Staggered PRT Update Part I Sebastián Torres and David Warde CIMMS/The University of Oklahoma and National Severe Storms Laboratory/NOAA NEXRAD TAC Norman,
VCPs for Staggered PRT Sebastián Torres and David Warde CIMMS/NSSL Data Quality MOU – Technical Interchange Meeting Fall 2008.

VCPs for Staggered PRT Sebastián Torres and David Warde CIMMS/NSSL Data Quality MOU – Technical Interchange Meeting Fall 2008.
Operational Weather Radar Featuring: WSR-88D Doppler Radar

Operational Weather Radar Featuring: WSR-88D Doppler Radar
New Concepts in Utilization of Polarimetric Weather Radars Alexander Ryzhkov (CIMMS) February 25–27, 2015 National Weather Center Norman, Oklahoma.

New Concepts in Utilization of Polarimetric Weather Radars Alexander Ryzhkov (CIMMS) February 25–27, 2015 National Weather Center Norman, Oklahoma.
© Crown copyright Met Office RAINGAIN Kick-Off Meeting Benefits of High Spatial and Temporal Resolution for Urban Catchments from existing Radars.

© Crown copyright Met Office RAINGAIN Kick-Off Meeting Benefits of High Spatial and Temporal Resolution for Urban Catchments from existing Radars.
Carlos A. Rodríguez Rivera Mentor: Dr. Robert Palmer Carlos A. Rodríguez Rivera Mentor: Dr. Robert Palmer Is Spectral Processing Important for Future WSR-88D.

Carlos A. Rodríguez Rivera Mentor: Dr. Robert Palmer Carlos A. Rodríguez Rivera Mentor: Dr. Robert Palmer Is Spectral Processing Important for Future WSR-88D.

Similar presentations

Ads by Google