Multiangle cloud remote sensing from

Similar documents

Remote Sensing of Clouds from Polarization

Cloud Oxygen Pressure Algorithm for POLDER-2

Studying cloud properties from space using sounder data: A preparatory study for INSAT-3D

Electromagnetic Radiation (EMR) and Remote Sensing

Passive Remote Sensing of Clouds from Airborne Platforms

Retrieval of cloud spherical albedo from top-of-atmosphere reflectance measurements performed at a single observation angle

Comparison of NOAA's Operational AVHRR Derived Cloud Amount to other Satellite Derived Cloud Climatologies.

Evaluation of the Effect of Upper-Level Cirrus Clouds on Satellite Retrievals of Low-Level Cloud Droplet Effective Radius

MOD09 (Surface Reflectance) User s Guide

Measurement of the effect of biomass burning aerosol on inhibition of cloud formation over the Amazon

GOES-R AWG Cloud Team: ABI Cloud Height

Cloud Climatology for New Zealand and Implications for Radiation Fields

16 th IOCCG Committee annual meeting. Plymouth, UK February mission: Present status and near future

ARM SWS to study cloud drop size within the clear-cloud transition zone

Sky Monitoring Techniques using Thermal Infrared Sensors. sabino piazzolla Optical Communications Group JPL

FRESCO. Product Specification Document FRESCO. Authors : P. Wang, R.J. van der A (KNMI) REF : TEM/PSD2/003 ISSUE : 3.0 DATE :

Advances in Cloud Imager Remote Sensing

CALIPSO, CloudSat, CERES, and MODIS Merged Data Product

SATELLITE OBSERVATION OF THE DAILY VARIATION OF THIN CIRRUS

Retrieval of vertical cloud properties of deepconvective clouds by spectral radiance measurements

Comparison of Cloud and Radiation Variability Reported by Surface Observers, ISCCP, and ERBS

Best practices for RGB compositing of multi-spectral imagery

'Developments and benefits of hydrographic surveying using multispectral imagery in the coastal zone

A climatology of cirrus clouds from ground-based lidar measurements over Lille

VIIRS-CrIS mapping. NWP SAF AAPP VIIRS-CrIS Mapping

Validation of SEVIRI cloud-top height retrievals from A-Train data

Cloud Masking and Cloud Products

Remote sensing of precipitable water vapour and cloud cover for site selection of the European Extremely Large Telescope (E-ELT) using MERIS

Volcanic Ash Monitoring: Product Guide

MSG-SEVIRI cloud physical properties for model evaluations

Evaluations of the CALIPSO Cloud Optical Depth Algorithm Through Comparisons with a GOES Derived Cloud Analysis

An Airborne A-Band Spectrometer for Remote Sensing Of Aerosol and Cloud Optical Properties

Total radiative heating/cooling rates.

Obtaining and Processing MODIS Data

Clouds and the Energy Cycle

Saharan Dust Aerosols Detection Over the Region of Puerto Rico

Assessing Cloud Spatial and Vertical Distribution with Infrared Cloud Analyzer

Towards assimilating IASI satellite observations over cold surfaces - the cloud detection aspect

Physical properties of mesoscale high-level cloud systems in relation to their atmospheric environment deduced from Sounders

CERES Edition 2 & Edition 3 Cloud Cover, Cloud Altitude and Temperature

SAMPLE MIDTERM QUESTIONS

Data processing (3) Cloud and Aerosol Imager (CAI)

Microwave observations in the presence of cloud and precipitation

A review of cloud top height and optical depth histograms from MISR, ISCCP, and MODIS

Climatology of aerosol and cloud properties at the ARM sites:

DISCRIMINATING CLEAR-SKY FROM CLOUD WITH MODIS ALGORITHM THEORETICAL BASIS DOCUMENT (MOD35) MODIS Cloud Mask Team

Realization of a UV fisheye hyperspectral camera

Satellite Remote Sensing of Volcanic Ash

Night Microphysics RGB Nephanalysis in night time

CBERS Program Update Jacie Frederico dos Santos Liporace AMS Kepler

Labs in Bologna & Potenza Menzel. Lab 3 Interrogating AIRS Data and Exploring Spectral Properties of Clouds and Moisture

ESCI 107/109 The Atmosphere Lesson 2 Solar and Terrestrial Radiation

Hyperspectral Satellite Imaging Planning a Mission

3.4 Cryosphere-related Algorithms

Global Moderate Resolution Imaging Spectroradiometer (MODIS) cloud detection and height evaluation using CALIOP

Data Processing Flow Chart

China Earth Observation

2.3 Spatial Resolution, Pixel Size, and Scale

Cloud detection and clearing for the MOPITT instrument

Technical note on MISR Cloud-Top-Height Optical-depth (CTH-OD) joint histogram product

Examination Space Missions and Applications I (AE2103) Faculty of Aerospace Engineering Delft University of Technology SAMPLE EXAM

Blackbody radiation. Main Laws. Brightness temperature. 1. Concepts of a blackbody and thermodynamical equilibrium.

Evaluating GCM clouds using instrument simulators

The Effect of Droplet Size Distribution on the Determination of Cloud Droplet Effective Radius

REMOTE SENSING OF CLOUD-AEROSOL RADIATIVE EFFECTS FROM SATELLITE DATA: A CASE STUDY OVER THE SOUTH OF PORTUGAL

Reprojecting MODIS Images

The APOLLO cloud product statistics Web service The APOLLO cloud product statistics Web service

Level 3 Cloud Fraction by Altitude Algorithm Theoretical Basis

LANDSAT 8 Level 1 Product Performance

Overview. What is EMR? Electromagnetic Radiation (EMR) LA502 Special Studies Remote Sensing

Fourth Cloud Retrieval Evaluation Workshop 4-7 March 2014, Grainau, Germany

The study of cloud and aerosol properties during CalNex using newly developed spectral methods

Spectral Response for DigitalGlobe Earth Imaging Instruments

Lake Monitoring in Wisconsin using Satellite Remote Sensing

The APOLLO cloud product statistics Web service

Fig.1. The DAWN spacecraft

Lectures Remote Sensing

Generation of Cloud-free Imagery Using Landsat-8

WATER BODY EXTRACTION FROM MULTI SPECTRAL IMAGE BY SPECTRAL PATTERN ANALYSIS

A remote sensing instrument collects information about an object or phenomenon within the

Radiative effects of clouds, ice sheet and sea ice in the Antarctic

RESULTS FROM A SIMPLE INFRARED CLOUD DETECTOR

SPOT Satellite Earth Observation System Presentation to the JACIE Civil Commercial Imagery Evaluation Workshop March 2007

Sentinel-1 Mission Overview

Computer Vision: Machine Vision Filters. Computer Vision. Optical Filters. 25 August 2014

The Sentinel-4/UVN instrument on-board MTG-S

RPG MWR PRO TN Page 1 / 12 physics.de Radiometer Physics GmbH

Surface Atmosphere Radia3on Budget (SARB) working group update

Near Real Time Blended Surface Winds

Transcription:

Multiangle cloud remote sensing from POLDER3/PARASOL Cloud phase, optical thickness and albedo F. Parol, J. Riedi, S. Zeng, C. Vanbauce, N. Ferlay, F. Thieuleux, L.C. Labonnote and C. Cornet Laboratoire d'optique Atmosphérique, Université des Sciences et Technologies de Lille 1/27

Instrumental Background CNES/LOA instrument, Parasol launched Dec. 2004 ~ 705 km polar orbits, ascending (13:30 a.m.) Data available from March 2005 to Jan 2010 within A-TRAIN and more Sensor Characteristics 10 spectral bands ranging from 0.443 to 1.020 µm 3 polarised channels Wide FOV CCD Camera with 1800 km swath width +/- 43 degrees cross track +/- 51degrees along track Multidirectionnal observations (up to 16 directions) Spatial resolution : 6x7 km No onboard calibration system - Inflight vicarious calibration : 2-3% absolute calibration accuracy 1% interband 0.1% interpixel over clouds 2/27

ERB, WV and Clouds Level 2 processing scheme Level 1 georeferenced data Int. Sinusoidal grid 6km x 6km Gazeous absorption correction Clear sky only Cloud detection Water vapor content Cloud phase Ice only Cloud Optical Thickness and spectral albedo SW albedo integration Microphysical index from polarisation Rayleigh and Oxygen cloud pressure Level 2 gridded product Int. Sinusoidal 20km x 20km Apparent pressure determination 3/27

Multiangle polarisation measurements and Cloud Phase Liquid Ice 4/27

MODIS/Aqua and PARASOL Observation of Clouds and Aerosols Properties MODIS Sci. Team Meeting Oct. 2006 Multiangle polarisation measurements and Cloud Phase Cloud phase at 20x20 km resolution Liquid, Ice, Mixed, Unknow with individual quality index within each. 5/30

MODIS/Aqua and PARASOL Observation of Clouds and Aerosols Properties MODIS Sci. Team Meeting Oct. 2006 Multiangle multispectral measurements Cloud optical thickness is retrieved under up to 16 directions Directional product provided at = 670nm (land) and 865 nm (ocean) 6/30

MODIS/Aqua and PARASOL Observation of Clouds and Aerosols Properties MODIS Sci. Team Meeting Oct. 2006 Multiangle multispectral measurements Cloud spherical albedo is retrieved under up to 16 directions Directional product provided at = 670nm (land) and 865 nm (ocean) 7/30

Multiangle multispectral measurements λ = 443 nm 200 550 nm 3 Spectral λ = 670 nm 550 700 nm Cloud Albedo λ = 865 nm 700 4000 nm SW CLOUD ALBEDO 8/27

Analysis of cloud phase against MODIS and CALIOP 9/27

Cloud phase as seen by POLDER, MODIS & CALIOP Level 2 official data POLDER MODIS CALIOP PM dataset: (Level 2 of MODIS & POLDER data ) resolution : 20 x 20km2 sinusoidal grid MODIS averaged over POLDER pixel CALTRACK dataset: (Level 2 of MODIS, POLDER & CALIOP data ) resolution : 5km available through ICARE Data & Services Center http://www.icare.univ lille1.fr Period: From 12/2007 to 11/2008 10/27

MODIS / POLDER global match & mismatch Data: PM dataset, 12/2007 11/2008, [90 S 90 N] 11/27

Geographical Distributions of Phase Frequency 4/10 Data: PM dataset, 12/2007 11/2008, [90 S 90 N] 12/27

5/10 View zenith angle analysis of Phase detection Data: PM dataset, 12/2007 11/2008, [90 S 90 N] CALIOP SAMPLING LOCATION 13/27

POLDER/MODIS phase in CALIOP space Data: CALTRACK dataset, 12/2007 11/2008, [90 S 90 N] 14/27

POLDER/MODIS vs CALIOP phase product Data: CALTRACK dataset, 12/2007 11/2008, [90 S 90 N] 15/27

Sensitivity to thin cirrus 16/27

Analysis of cloud optical thickness/albedo POLDER / MODIS 17/27

Measured reflectance 0.8 0.8 (a1) SZA = 30-40 deg (b1) SZA = 60-70 deg 0.7 Measured Reflectance Measured Reflectance 0.7 0.6 0.5 0.4 0.3 0.2 0.1 Retrieved albedo should be independant of viewing geometry. 0.6 0.5 0.4 0.3 0.2 0.1 0 0 0 10 20 30 40 50 60 0 10 Viewing Zenith Angle (deg) 20 30 40 50 60 Viewing Zenith Angle (deg) Retrieved «directionnal» albedo 0.8 0.8 (a2) SZA = 30-40 deg (b2) SZA = 60-70 deg 0.7 "Directional" Albedo 0.7 "Directional" Albedo 0.6 0.5 0.4 0.3 0.6 0.5 0.4 0.3 0.2 0.2 0.1 0.1 0 0 0 10 20 30 40 50 60 0 10 Viewing Zenith Angle (deg) 20 30 40 50 60 Retrieved «average» albedo Albedo RMS of : 0.8 (a3) SZA = 30-40 deg (b3) SZA = 60-70 deg 0.7 Averaged Albedo 0.6 Averaged Albedo Red : clouds Green : clear sky land Blue : clear sky ocean Viewing Zenith Angle (deg) 0.8 0.7 Plots here for 2 sun elevations, as a function of view zenith angle. 0.5 0.4 0.3 0.5 0.4 0.012 0.016 for clouds 0.3 0.2 0.2 0.1 0.1 0 0.006 in clear sky 0.6 0 0 10 20 30 40 Viewing Zenith Angle (deg) 50 60 0 10 20 30 40 50 60 Viewing Zenith Angle (deg) 18/27

Testing cloud models from multiangle observation 19/27

Testing cloud models from multiangle observation Baran & Labonnote (2001) 20/27

From Zhang et al, 2009 (ACP) 21/27

From Zhang et al, 2009 (ACP) 22/27

POLDER vs MODIS Optical thickness for different phase categories 23/27

POLDER vs MODIS Scaled Optical thickness for different phase categories 24/27

Optical thickness and scaled optical thickness zonal variation 25/27

View zenith angle analysis MODIS POLDER 26/27

Summary POLDER phase product provides a reliable information on thermodynamic phase independant of cloud temperature and particle size In conjunction, POLDER and MODIS can be used to create a reference cloud phase dataset for benchmark studies of models or other sensors POLDER multiangle observations provide a unique way to constrain cloud models (micro and macro physics) and get «less biased» optical thickness/albedo Comparing scaled optical thickness (or albedo) can make our life easier in a first stage for this GEWEX exercise 27/27