Presentation is loading. Please wait.

Presentation is loading. Please wait.

Lidar algorithms to retrieve cloud distribution, phase and optical depth Y. Morille, M. Haeffelin, B. Cadet, V. Noel Institut Pierre Simon Laplace SYMPOSIUM.

Published byGervais Reed Modified over 9 years ago

Similar presentations

Presentation on theme: "Lidar algorithms to retrieve cloud distribution, phase and optical depth Y. Morille, M. Haeffelin, B. Cadet, V. Noel Institut Pierre Simon Laplace SYMPOSIUM."— Presentation transcript:

1 Lidar algorithms to retrieve cloud distribution, phase and optical depth Y. Morille, M. Haeffelin, B. Cadet, V. Noel Institut Pierre Simon Laplace SYMPOSIUM This work is supported by the French Space Agency

2 Lidar Data processing: L1 Pr2 L2 classification flag L2 Thermo Phase Opt Depth Extinction STRAT CAPRO 2 algorithms: -STRAT : STRucture of the Atmosphere -CAPRO : Cloud Aerosol Properties

3 STRAT: Occurrence and distribution * Morille et al, JAOT 2005 (submitted) Pr 2 paral. polarization STRAT flag STRAT detects: - cloud layers (wavelet method) - aerosol layers (wavelet method) - boundary layer (wavelet method) - molecular layers (slope method) - noise (SNR threshold)

4 Palaiseau 10/2002-09/2004 Lidar Cloud and Aerosol Statistics Seasonal variations of cloud occurrence

5 Cloud and Aerosol Statistics Seasonal variations of aerosol occurrence

6 CAPRO - Cloud thermodynamic phase Cloud thermodynamic phase Based on lidar depolarization ratio + temperature Requires normalization in particle-free zone (2.74%)

7 Cloud Phase retrieval algorithm Cloud Distribution : Lidar Depolarization vs Temperature 3 years dataset - SIRTA # data points

8 Cloud Distribution : Lidar Depolarization vs Temperature 3 years dataset - SIRTA # data points Temp > 0 C, Depol < 0.2 : Liquid water Depol > 0.2 Temp < -42°C Ice Mixed-phase clouds Cloud Phase retrieval algorithm

9 Depolarization - 2004-09-02 Temperature profile (RS) Phase IC E LIQUID WATER MIXED PHASE 0.6 0.0 0.2 0.4 100 % 0 % 50 % Ice Figures Y. Morille (LMD) Cloud Phase Results

10 Cloud Phase Statistics Vertical distribution of Cloud thermodynamic phase (seasonal variations) Mixed phase Liquid water Ice water

11 CAPRO - Optical thickness Optical thickness Based on lidar backscattered power Pr 2 data Requires normalization in particle-free zone Optimal estimation algorithm

12 STRAT Classification 2 optical depth retrieval methods PIMI Information outside the cloud Information inside the cloud Requires molecular zones beneath and above the cloud Requires an a priori Lr eff Comparison (Cadet et al. 2004) Particle Integration method:  = k eff ∫ (R(z)-1)  m (z)dz where R(z)=(  m (z)+  c (z))/  m (z) k eff prescribed: 18 sr k eff opt derived from MI method

13

14 Optimal estimation technique using: PR2 profile Optical depth Uncertainties For the retrieval of: Extinction profile Lidar ratio Extinction Profile

15 Optimal estimation technique using: PR2 profile Optical depth Uncertainties For the retrieval of: Extinction profile Lidar ratio

16 Optical thickness - Statistics

17 Conclusions Develop algorithms to interpret lidar profiles in terms of cloud and aerosol macrophysical and microphysical properties Objective: Process long-term data sets Derive regional statistics of cloud properties Conduct process studies STRAT applied to multiple lidar systems. Has been distributed to several research groups Available on demand Phase and optical depth retrievals validation under way Interested in collaborations with other lidar groups

18 Statistics - Lidar Ratio

Download ppt "Lidar algorithms to retrieve cloud distribution, phase and optical depth Y. Morille, M. Haeffelin, B. Cadet, V. Noel Institut Pierre Simon Laplace SYMPOSIUM."

Similar presentations

Lidar observations of mixed-phase clouds Robin Hogan, Anthony Illingworth, Ewan OConnor & Mukunda Dev Behera University of Reading UK Overview Enhanced.

Lidar observations of mixed-phase clouds Robin Hogan, Anthony Illingworth, Ewan OConnor & Mukunda Dev Behera University of Reading UK Overview Enhanced.
Proposed new uses for the Ceilometer Network

Proposed new uses for the Ceilometer Network
Radar/lidar observations of boundary layer clouds

Radar/lidar observations of boundary layer clouds
Robin Hogan & Julien Delanoe

Robin Hogan & Julien Delanoe
Robin Hogan Department of Meteorology University of Reading Cloud and Climate Studies using the Chilbolton Observatory.

Robin Hogan Department of Meteorology University of Reading Cloud and Climate Studies using the Chilbolton Observatory.
Robin Hogan, Richard Allan, Nicky Chalmers, Thorwald Stein, Julien Delanoë University of Reading How accurate are the radiative properties of ice clouds.

Robin Hogan, Richard Allan, Nicky Chalmers, Thorwald Stein, Julien Delanoë University of Reading How accurate are the radiative properties of ice clouds.
Integrated lidar backscatter: Quantifying the occurrence of supercooled water and specular reflection Robin Hogan and Anthony Illingworth Enhanced algorithm.

Integrated lidar backscatter: Quantifying the occurrence of supercooled water and specular reflection Robin Hogan and Anthony Illingworth Enhanced algorithm.
A Methodology for Simultaneous Retrieval of Ice and Liquid Water Cloud Properties O. Sourdeval 1, L. C.-Labonnote 2, A. J. Baran 3, G. Brogniez 2 1 – Institute.

A Methodology for Simultaneous Retrieval of Ice and Liquid Water Cloud Properties O. Sourdeval 1, L. C.-Labonnote 2, A. J. Baran 3, G. Brogniez 2 1 – Institute.
Exploiting multiple scattering in CALIPSO measurements to retrieve liquid cloud properties Nicola Pounder, Robin Hogan, Lee Hawkness-Smith, Andrew Barrett.

Exploiting multiple scattering in CALIPSO measurements to retrieve liquid cloud properties Nicola Pounder, Robin Hogan, Lee Hawkness-Smith, Andrew Barrett.
Calibration Scenarios for PICASSO-CENA J. A. REAGAN, X. WANG, H. FANG University of Arizona, ECE Dept., Bldg. 104, Tucson, AZ 85721 MARY T. OSBORN SAIC,

Calibration Scenarios for PICASSO-CENA J. A. REAGAN, X. WANG, H. FANG University of Arizona, ECE Dept., Bldg. 104, Tucson, AZ MARY T. OSBORN SAIC,
Earth System Science Teachers of the Deaf Workshop, August 2004 S.O.A.R. High Earth Observing Satellites.

Earth System Science Teachers of the Deaf Workshop, August 2004 S.O.A.R. High Earth Observing Satellites.
Mars’ North and South Polar Hood Clouds Jennifer L. Benson Jet Propulsion Laboratory, California Institute of Technology July 22, 2010 Copyright 2010 California.

Mars’ North and South Polar Hood Clouds Jennifer L. Benson Jet Propulsion Laboratory, California Institute of Technology July 22, 2010 Copyright 2010 California.
1 An initial CALIPSO cloud climatology ISCCP Anniversary, 23-25 July 2008, New York Dave Winker NASA LaRC.

1 An initial CALIPSO cloud climatology ISCCP Anniversary, July 2008, New York Dave Winker NASA LaRC.
1. The problem of mixed-phase clouds All models except DWD underestimate mid-level cloud –Some have separate “radiatively inactive” snow (ECMWF, DWD) –Met.

1. The problem of mixed-phase clouds All models except DWD underestimate mid-level cloud –Some have separate “radiatively inactive” snow (ECMWF, DWD) –Met.
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.
TReSS (Transportable Remote Sensing Station) in Tamanrasset Overview of TReSS Status of implementation on April 1 st 2006 Operations in the framework of.

TReSS (Transportable Remote Sensing Station) in Tamanrasset Overview of TReSS Status of implementation on April 1 st 2006 Operations in the framework of.
IRCTR - International Research Centre for Telecommunication and Radar ATMOS Ice crystals properties retrieval within ice and mixed-phase clouds using the.

IRCTR - International Research Centre for Telecommunication and Radar ATMOS Ice crystals properties retrieval within ice and mixed-phase clouds using the.
Observed and modelled long-term water cloud statistics for the Murg Valley Kerstin Ebell, Susanne Crewell, Ulrich Löhnert Institute for Geophysics and.

Observed and modelled long-term water cloud statistics for the Murg Valley Kerstin Ebell, Susanne Crewell, Ulrich Löhnert Institute for Geophysics and.
Ben Kravitz November 5, 2009 LIDAR. What is LIDAR? Stands for LIght Detection And Ranging Micropulse LASERs Measurements of (usually) backscatter from.

Ben Kravitz November 5, 2009 LIDAR. What is LIDAR? Stands for LIght Detection And Ranging Micropulse LASERs Measurements of (usually) backscatter from.
1 Satellite Remote Sensing of Particulate Matter Air Quality ARSET Applied Remote Sensing Education and Training A project of NASA Applied Sciences Pawan.

1 Satellite Remote Sensing of Particulate Matter Air Quality ARSET Applied Remote Sensing Education and Training A project of NASA Applied Sciences Pawan.

Similar presentations

Ads by Google