Presentation is loading. Please wait.

Presentation is loading. Please wait.

International Research Centre for Telecommunications and Radar High resolution atmospheric profiling with the S-band Doppler polarimetric radar TARA Christine.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "International Research Centre for Telecommunications and Radar High resolution atmospheric profiling with the S-band Doppler polarimetric radar TARA Christine."— Presentation transcript:

1 International Research Centre for Telecommunications and Radar High resolution atmospheric profiling with the S-band Doppler polarimetric radar TARA Christine Unal, Marta Girame Ibanez, Yann Dufournet and Herman Russchenberg Delft University of Technology, The Netherlands  TARA type of measurement  Near vertical wind profiling mode  First comparisons of TARA wind profiling with radiosondes

2 International Research Centre for Telecommunications and Radar Hornisgrinde (site H) TARA (Transportable Atmospheric Radar) wavelength = 9.1 cm 1 s < time resolution < 10 s 3 m< height resolution< 30 m can simultaneously measure  dynamics (wind profiling with 3 beams)  microphysics (polarimetry) of precipitation, ice clouds, mixed-phased clouds and clear air scattering 4.5 Tb of raw data

3 International Research Centre for Telecommunications and Radar Measurement configuration 3 beams  3 mean Doppler velocities  horizontal wind + vertical wind MB VV HV HH OB1 OB2 measurement sequence time

4 International Research Centre for Telecommunications and Radar Radiosondes comparison Sites H and M About 30 mn time difference 2.5 m/s 1.3 m/s 6.5 deg. 17.6 deg.

5 International Research Centre for Telecommunications and Radar IOP-5a: reflectivity and horizontal wind

6 International Research Centre for Telecommunications and Radar Comparison of TARA horizontal wind with radiosonde H Standard deviation (radar measurement of 3 mn) Wind speed: from 1 m/s (cloud) to 2 m/s (rain) Wind direction: from 2 deg. (cloud) to 5 deg. (rain) Differences of the order of 5 m/s and 25 deg. between TARA and radiosonde H

7 International Research Centre for Telecommunications and Radar IOP-5a: horizontal wind and vertical velocity (zoom on 6 mn) heterogeneity

8 International Research Centre for Telecommunications and Radar IOP-8b: reflectivity and 3D wind

9 International Research Centre for Telecommunications and Radar Comparison of TARA horizontal wind with radiosondes Compared to precipitation, clear air scattering has a low signal-to-noise ratio and less data for the averaging period Differences of the order of 5 m/s and 90 deg. between TARA and radiosonde H

10 International Research Centre for Telecommunications and Radar IOP-8b: 3D wind (zoom on 30 mn) turbulence

11 International Research Centre for Telecommunications and Radar Status  atmosphere dynamics  evaluation of TARA wind estimates - different meteorological conditions - accuracy - COPS user needs  atmosphere microphysics  research on mixed-phased clouds (Yann Dufournet)  problems with TARA during COPS  data quality ok (raw data) but a part of the processing is thus not automatic  study cases will be selected

12 International Research Centre for Telecommunications and Radar IOP-5a: 3 time series of mean Doppler velocities

13 International Research Centre for Telecommunications and Radar IOP-8b: 3 time series of mean Doppler velocities

Download ppt "International Research Centre for Telecommunications and Radar High resolution atmospheric profiling with the S-band Doppler polarimetric radar TARA Christine."

Similar presentations

Convection Initiative discussion points What info do parametrizations & 1.5-km forecasts need? –Initiation mechanism, time-resolved cell size & updraft.

Convection Initiative discussion points What info do parametrizations & 1.5-km forecasts need? –Initiation mechanism, time-resolved cell size & updraft.
DYMECS: Dynamical and Microphysical Evolution of Convective Storms (NERC Standard Grant) University of Reading: Robin Hogan, Bob Plant, Thorwald Stein,

DYMECS: Dynamical and Microphysical Evolution of Convective Storms (NERC Standard Grant) University of Reading: Robin Hogan, Bob Plant, Thorwald Stein,
KIT – die Kooperation von Forschungszentrum Karlsruhe GmbH und Universität Karlsruhe (TH) 5.3 Advantages of a coordinated scanning Doppler lidar and cloud.

KIT – die Kooperation von Forschungszentrum Karlsruhe GmbH und Universität Karlsruhe (TH) 5.3 Advantages of a coordinated scanning Doppler lidar and cloud.
POLARIMETRIC RADAR IMPROVEMENTS

POLARIMETRIC RADAR IMPROVEMENTS
How do meteorologists make weather observations? Measuring the Weather.

How do meteorologists make weather observations? Measuring the Weather.
Specular reflectorquasi-specular reflector quasi-Lambert reflector Lambert reflector Limiting Forms of Reflection and Scatter from a Surface.

Specular reflectorquasi-specular reflector quasi-Lambert reflector Lambert reflector Limiting Forms of Reflection and Scatter from a Surface.
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.
Radio Acoustic Sounding Techniques for Temperature Profiling Mrs Jyoti Chande Head Atmospheric Remote Sensing Division SAMEER, IIT Campus, Powai, Mumbai.

Radio Acoustic Sounding Techniques for Temperature Profiling Mrs Jyoti Chande Head Atmospheric Remote Sensing Division SAMEER, IIT Campus, Powai, Mumbai.
Thermometer Variable: temperature Units: Degrees Celsius ( o C) Accuracy: marked to 0.5 o C Cost: £10 Site: in the shade (e.g. a Stevenson Screen) Mercury.

Thermometer Variable: temperature Units: Degrees Celsius ( o C) Accuracy: marked to 0.5 o C Cost: £10 Site: in the shade (e.g. a Stevenson Screen) Mercury.
CEREA – Group « Meteorological Measurements » 15 September 2006 1 METEOROLOGICAL MEASUREMENTS IN THE ATMOSPHERIC BOUNDARY LAYER E. Dupont – D. Demengel.

CEREA – Group « Meteorological Measurements » 15 September METEOROLOGICAL MEASUREMENTS IN THE ATMOSPHERIC BOUNDARY LAYER E. Dupont – D. Demengel.
Specular reflectorquasi-specular reflector quasi-Lambert reflector Lambert reflector Limiting Forms of Reflection and Scatter from a Surface.

Specular reflectorquasi-specular reflector quasi-Lambert reflector Lambert reflector Limiting Forms of Reflection and Scatter from a Surface.
Remote-sensing of the environment (RSE) ATMOS Design of a radar control and signal processor unit for the TARA radar BAP afstudeerproject Yann Dufournet.

Remote-sensing of the environment (RSE) ATMOS Design of a radar control and signal processor unit for the TARA radar BAP afstudeerproject Yann Dufournet.
Radar signatures in complex terrain during the passage of mid-latitude cyclones Socorro Medina Department of Atmospheric Sciences University of Washington.

Radar signatures in complex terrain during the passage of mid-latitude cyclones Socorro Medina Department of Atmospheric Sciences University of Washington.
Aerosol and Cloud Microphysics Working Group Dietrich Althausen, Andrea Riede, Herman Russchenberg, Aldo Amodeo, Susanne Crewell, Paolo Di Girolamo, Stephen.

Aerosol and Cloud Microphysics Working Group Dietrich Althausen, Andrea Riede, Herman Russchenberg, Aldo Amodeo, Susanne Crewell, Paolo Di Girolamo, Stephen.
Atmospheric structure from lidar and radar Jens Bösenberg 1.Motivation 2.Layer structure 3.Water vapour profiling 4.Turbulence structure 5.Cloud profiling.

Atmospheric structure from lidar and radar Jens Bösenberg 1.Motivation 2.Layer structure 3.Water vapour profiling 4.Turbulence structure 5.Cloud profiling.
Anomalous Propagation Greater density slows the waves more. Less dense air does not slow the waves as much. Since density normally decreases with height,

Anomalous Propagation Greater density slows the waves more. Less dense air does not slow the waves as much. Since density normally decreases with height,
IRCTR: International Research Centre for Telecommunications and Radar Evaluation of particle shape and orientation within ice clouds using the S-band Doppler.

IRCTR: International Research Centre for Telecommunications and Radar Evaluation of particle shape and orientation within ice clouds using the S-band Doppler.
COPS-GOP-WS3 Hohenheim 2006_04_10 Micro- Rain- Radar Local Area Weather Radar Cloud Radar Meteorological Institute University Hamburg Gerhard Peters.

COPS-GOP-WS3 Hohenheim 2006_04_10 Micro- Rain- Radar Local Area Weather Radar Cloud Radar Meteorological Institute University Hamburg Gerhard Peters.
Radar Operations during AMMA SOP Alain Protat  Benin mesosite : Scanning Polarimetric Doppler X-band radar (X-Port) + Scanning Polarimetric Doppler C-band.

Radar Operations during AMMA SOP Alain Protat  Benin mesosite : Scanning Polarimetric Doppler X-band radar (X-Port) + Scanning Polarimetric Doppler C-band.

Similar presentations

Ads by Google