Presentation is loading. Please wait.

Presentation is loading. Please wait.

October 02, 20031 st IHOP_2002 Water Vapor Intercomparison Workshop Status of intercomparisons and the next steps  Characterize moisture measuring techniques.

Published byEaster Wilkerson Modified over 8 years ago

Similar presentations

Presentation on theme: "October 02, 20031 st IHOP_2002 Water Vapor Intercomparison Workshop Status of intercomparisons and the next steps  Characterize moisture measuring techniques."— Presentation transcript:

1 October 02, 20031 st IHOP_2002 Water Vapor Intercomparison Workshop Status of intercomparisons and the next steps  Characterize moisture measuring techniques  Identify missing specifications  Suggest additional efforts such as further intercomparisons to close knowledge with respect to instrument performance

2 October 02, 20031 st IHOP_2002 Water Vapor Intercomparison Workshop Instruments considered 1)DIAL and Raman lidar 2)S-Pol refractivity 3)GPS and microwave radiometer 4)In-situ sensors (reference radiosondes, dropsondes, standard radiosondes, aircraft sensors) 5)AERI? 6)NAST? 7)Satellites? 8)Complete?

3 October 02, 20031 st IHOP_2002 Water Vapor Intercomparison Workshop Suggestion for providing information about instrument performance  Performance analysis web page (status, intercomparisons, etc.)  Specific web page for each instrument: - Methodology (references) - Retrieval technique (flow chart), expected errors (references) - Approaches applied for error analysis (analytical, ACOV, intercomparisons including lessons learned, …) - Most important errors sources, critical components (important for future campaigns) - Spec table (continuously updated), goals? - Future efforts and suggestions to close remaining gaps

4 October 02, 20031 st IHOP_2002 Water Vapor Intercomparison Workshop DIAL principle Example: DIAL

5 October 02, 20031 st IHOP_2002 Water Vapor Intercomparison Workshop Shotland equation 1st guess estimate Doppler broadening terms Retrieval

6 October 02, 20031 st IHOP_2002 Water Vapor Intercomparison Workshop Flow chart of retrieval module TIME AVERAGE Single-shot signals QUALITY CONTROL - - VERTICAL AVERAGE BACKGROUND DETERMINATION CONDITIONAL SAMPLING BACKGROUND SUBTRACTION RATIO LOGARITHM DIFFERENTIATION

7 October 02, 20031 st IHOP_2002 Water Vapor Intercomparison Workshop Error analysis  Systematic errors: - Analytical error propagation - Forward performance model - Intercomparisons (LASE validation campaigns: 6%) - Rms error or mean difference?  Noise errors: - Poisson statistics - Autocovariance technique - Spectral technique  Representativeness error: IHOP data

8 October 02, 20031 st IHOP_2002 Water Vapor Intercomparison Workshop 1) DIAL and Raman lidar specifications  Horizontal or time resolution (weighting function)  Vertical resolution (weighting function)  Systematic error profile (bias)  Noise error profile (precision) in dependence of resolutions  Errors at boundaries (special attention, e.g. Rayleigh Doppler)  Representativeness error  Overall accuracy including covariance matrix for each profile, if required, for all missions  Suggestions: Cross section at 930 nm, investigate spectral purity, ….

9 October 02, 20031 st IHOP_2002 Water Vapor Intercomparison Workshop 2) S-Pol refractivity specifications  Height above ground including weighting function  Horizontal and range resolution (weighting function)  Time resolution  Systematic error map (bias)  Noise error map (precision)  Errors at boundaries?  Representativeness error?  Overall accuracy matrix Suggestions: further comparisons: radiosondes, lidar data, …

10 October 02, 20031 st IHOP_2002 Water Vapor Intercomparison Workshop 3) GPS and microwave  Pointing direction  GPS: ZPD, slant path, tomography  Time resolution, spatial resolution (tomography)  Systematic error (bias)  Noise error (precision)  Representativeness error?  Further comparisons: lidar, radiosondes

11 October 02, 20031 st IHOP_2002 Water Vapor Intercomparison Workshop 4) In-situ sensors specifications  Vertical resolution (weighting function)  Systematic error profile (bias)  Noise error profile (precision)  Errors at boundaries (special attention, e.g. drop sondes)  Representativeness error  Overall accuracy including covariance matrix for each profile, if required

12 October 02, 20031 st IHOP_2002 Water Vapor Intercomparison Workshop 5) AERI and others  Vertical resolution (weighting function)  Systematic error profile (bias)  Noise error profile (precision)  Errors at boundaries  Representativeness error  Overall accuracy including covariance matrix for each profile, if required

13 October 02, 20031 st IHOP_2002 Water Vapor Intercomparison Workshop 6. Expectations  Coordination of intercomparison efforts  Identify missing, important comparisons  Access to results (Web page?)  REPRODUCIBLE PROCEDURES: - Flow chart of data analysis (DIAL and others) - Clear definition and characterization of all errors  Representativeness error  Blind test

Download ppt "October 02, 20031 st IHOP_2002 Water Vapor Intercomparison Workshop Status of intercomparisons and the next steps  Characterize moisture measuring techniques."

Similar presentations

Institut für Physik der Atmosphäre Institut für Physik der Atmosphäre High Resolution Airborne DIAL Measurements of Water Vapor and Vertical Humidity Fluxes.

Institut für Physik der Atmosphäre Institut für Physik der Atmosphäre High Resolution Airborne DIAL Measurements of Water Vapor and Vertical Humidity Fluxes.
Institut für Physik der Atmosphäre Institut für Physik der Atmosphäre High Resolution Airborne DIAL Measurements of Water Vapour and Vertical Humidity.

Institut für Physik der Atmosphäre Institut für Physik der Atmosphäre High Resolution Airborne DIAL Measurements of Water Vapour and Vertical Humidity.
Institut für Physik der Atmosphäre Institut für Physik der Atmosphäre High Resolution Airborne DIAL Measurements of Water Vapour and Vertical Humidity.

Institut für Physik der Atmosphäre Institut für Physik der Atmosphäre High Resolution Airborne DIAL Measurements of Water Vapour and Vertical Humidity.
Integrated Profiling at the AMF

Integrated Profiling at the AMF
Upper Tropospheric Humidity: A Comparison of Satellite, Radiosonde, Lidar and Aircraft Measurements Satellite Lidar Aircraft Radiosonde.

Upper Tropospheric Humidity: A Comparison of Satellite, Radiosonde, Lidar and Aircraft Measurements Satellite Lidar Aircraft Radiosonde.
Water vapor estimates using simultaneous S and Ka band radar measurements Scott Ellis, Jothiram Vivekanandan NCAR, Boulder CO, USA.

Water vapor estimates using simultaneous S and Ka band radar measurements Scott Ellis, Jothiram Vivekanandan NCAR, Boulder CO, USA.
US Calibration/Validation Activities for the ADM/Aeolus Mission Mike Hardesty and Lars-Peter Riishojgaard.

US Calibration/Validation Activities for the ADM/Aeolus Mission Mike Hardesty and Lars-Peter Riishojgaard.
Inter-comparison of retrieved CO 2 from TCCON, combining TCCON and TES to the overpass flight data Le Kuai 1, John Worden 1, Susan Kulawik 1, Kevin Bowman.

Inter-comparison of retrieved CO 2 from TCCON, combining TCCON and TES to the overpass flight data Le Kuai 1, John Worden 1, Susan Kulawik 1, Kevin Bowman.
CPI International UV/Vis Limb Workshop Bremen, April 14-16 2003 Development of Generalized Limb Scattering Retrieval Algorithms Jerry Lumpe & Ed Cólon.

CPI International UV/Vis Limb Workshop Bremen, April Development of Generalized Limb Scattering Retrieval Algorithms Jerry Lumpe & Ed Cólon.
NDACC Working Group on Water Vapor NDACC Working Group on Water Vapor Bern, July 5 -7, 2006 Raman Lidar activities at Rome - Tor Vergata F.Congeduti, F.Cardillo,

NDACC Working Group on Water Vapor NDACC Working Group on Water Vapor Bern, July 5 -7, 2006 Raman Lidar activities at Rome - Tor Vergata F.Congeduti, F.Cardillo,
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.
Water vapour intercomparison effort in the frame of the Convective and Orographically-induced Precipitation Study 6th COPS Workshop 27 – 29 February 2008.

Water vapour intercomparison effort in the frame of the Convective and Orographically-induced Precipitation Study 6th COPS Workshop 27 – 29 February 2008.
On average TES exhibits a small positive bias in the middle and lower troposphere of less than 15% and a larger negative bias of up to 30% in the upper.

On average TES exhibits a small positive bias in the middle and lower troposphere of less than 15% and a larger negative bias of up to 30% in the upper.
Unstable Science Question 2 John Hanesiak CEOS, U. Manitoba Unstable Workshop, Edmonton, AB April 18-19, 2007.

Unstable Science Question 2 John Hanesiak CEOS, U. Manitoba Unstable Workshop, Edmonton, AB April 18-19, 2007.
6 July 2006First NDACC Water Vapor Working Group Workshop, Bern, Switzerland. 1 NDACC and Water Vapor Raman Lidars Thierry Leblanc JPL - Table Mountain.

6 July 2006First NDACC Water Vapor Working Group Workshop, Bern, Switzerland. 1 NDACC and Water Vapor Raman Lidars Thierry Leblanc JPL - Table Mountain.
Scanning Raman Lidar Error Characteristics and Calibration For IHOP David N. Whiteman/NASA-GSFC, Belay Demoz/UMBC Paolo Di Girolamo/Univ. of Basilicata,

Scanning Raman Lidar Error Characteristics and Calibration For IHOP David N. Whiteman/NASA-GSFC, Belay Demoz/UMBC Paolo Di Girolamo/Univ. of Basilicata,
Cirrus Cloud Boundaries from the Moisture Profile Q-6: HS Sounder Constituent Profiling Capabilities W. Smith 1,2, B. Pierce 3, and Z. Chen 2 1 University.

Cirrus Cloud Boundaries from the Moisture Profile Q-6: HS Sounder Constituent Profiling Capabilities W. Smith 1,2, B. Pierce 3, and Z. Chen 2 1 University.
2010 CEOS Field Reflectance Intercomparisons Lessons Learned K. Thome 1, N. Fox 2 1 NASA/GSFC, 2 National Physical Laboratory.

2010 CEOS Field Reflectance Intercomparisons Lessons Learned K. Thome 1, N. Fox 2 1 NASA/GSFC, 2 National Physical Laboratory.
SCIENTIST WORK STATIONS Advanced display tools will build on current software to allow for integrated displays of data from onboard instrumentation (e.g.,

SCIENTIST WORK STATIONS Advanced display tools will build on current software to allow for integrated displays of data from onboard instrumentation (e.g.,
Science Objectives for the ATHENA-OAWL Venture Tech Airborne Mission M. Hardesty CIRES University of Colorado/NOAA S. Tucker and C. Weimer Ball Aerospace.

Science Objectives for the ATHENA-OAWL Venture Tech Airborne Mission M. Hardesty CIRES University of Colorado/NOAA S. Tucker and C. Weimer Ball Aerospace.

Similar presentations

Ads by Google