Presentation is loading. Please wait.

Presentation is loading. Please wait.

A review on different methodologies employed in current SWE products from spaceborne passive microwave observations Nastaran Saberi, Richard Kelly Interdisciplinary.

Published byAnnis Day Modified over 8 years ago

Similar presentations

Presentation on theme: "A review on different methodologies employed in current SWE products from spaceborne passive microwave observations Nastaran Saberi, Richard Kelly Interdisciplinary."— Presentation transcript:

1 A review on different methodologies employed in current SWE products from spaceborne passive microwave observations Nastaran Saberi, Richard Kelly Interdisciplinary Center on Climate Change (IC3) and Department of Geography and Environmental Management, University of Waterloo, ON, Canada

2 Outline Introduction –Snow physical properties retrieval using passive microwave observations Emission Modeling (HUT, MEMLS, DMRT) SWE Products & Validation Process Research questions and summary

3 Why measuring snowpack physical properties? How? Which properties?

4 Snow Properties Retrieval Using Passive Microwave RS Passive microwave observations Brightness temperature: T B –Appropriate frequency channels: 10 GHz-19GHz-37GHz X, Ku, Ka (IEEE) o Goal: Modeling microwave-medium interactions to retrieve snow physical properties AMSR2 instrument http://www.drroyspencer.com/2012/05/

5 Snow properties retrieval Empirical approaches SD & TB differences Emission modeling PhysicalDMRT-ML Semi- empirical MEMLSHUT (Matzler et al., 1982) (Wiesmann and Matzler, 1999) Snow Properties Retrieval Using Passive Microwave RS

6 Emission Modeling http://www.iup.uni-bremen.de/iuppage/psa/members/MariaHoerhold.php

7 HUT snowpack emission model Pulliainen et al. (1999) Semi-empirical model, adapted for remote sensing observations 1 2 3 d 4

8 MEMLS Snowpack emission model A. Wiesmann and C. Matzler (1999) A semi-empirical six-flux radiative transfer model For a multi layered snowpack MEMLS inputs (for each layer of snowpack) o Grain size (correlation length) o LWC o Temperature o Depth o Density For substratum, reflectivity and temperature is needed

9 DMRT-ML Leung Tsang et al. (2000), Picard et al. (2012)  QCA-CP  DMRT (k s, k e )  DISORT (RT) o Mono disperse, stickiness o Poly disperse, Rayleigh DMRT-ML inputs (for each layer of snowpack) o Grain size (Optical) o Temperature o Depth o Density o Substratum model

10 Emission Models Summary Differences HUT, MEMLS, DMRT-ML: –Radiative transfer solution –Wave propagation –Substratum –Representation of a snow grain EmpiricalPhysical Complexity Sensitivity Analysis SimplicityCalibration Parsimonious modeling: physics-based | semi-empirical | empirical

11 Snow Depth & Snow Water Equivalent Products

12 Snow Depth and Snow Water Equivalent Products SWE estimation using in-situ data =>sparse observing networks Data assimilation Reanalysis snow cover using land surface or snow models Problem: dependency on precipitation data Satellite passive microwave derived SWE datasets Challenge: complex topography Data assimilation Reanalysis snow cover using land surface or snow models Problem: dependency on precipitation data Satellite passive microwave derived SWE datasets Challenge: complex topography

13 GlobSnow - SWE

14 AMSR2 Snow Depth and Snow Water Equivalent Product by R. Kelly V1 & V2 :Predicated on the AMSR-E algorithm (2003/4) V1: Regression based, came in response to deficiencies in static algorithm (Kelly,2009). V2: Physical modeling based (kelly, 2003) V2 Grain size & Density are dynamic Forest correction is model-based Atmospheric correction Lake ice addressed RFI determination (10 Ghz) AMSR2 - SWE V2 Snow Detection based on history of snow Snow Depth/SWE Retrieval using DMRT-ML

15 Methods that Use Machine Learning Techniques Neural network Emission model: HUT/MEMLS/DMRT Training Process TB SD/SWE Training Process TB SD/SWE Passive microwave observation (TB) Inversion by NN SD/SWE Inversion by NN SD/SWE Training dataset TB 19V TB 37V SWE/SD

16 MicroWave Radiation Imager (MWRI) on Feng-Yun 3 Grass LandBare Soil Farm Land Forest SD=fgrass×SDgrass+ fbarren×Sdbaren+fforest×Sdforest + ffarmland×Sdfarmland SDfarmland=  4.235+0.432×d18h36h+1.074×d89v89h;

17 Validation Process

18 Validation Process General overview of SWE dataset assessment by SnowPEx

19 Statistical Assessment Tools

20 Summary & Research Questions! Challenges in gathering In-situ data High spatial variability in snow physical properties and limitation in accessibility => Quantifying errors In electromagnetic modeling Adaptation of physical model to metamorphic processes and a layered snowpack structure, also adapting to spaceborne scale => Key emission controllers of seasonal snow evolution

21 Thank you Aknowledgements: Karem Chokmani

Download ppt "A review on different methodologies employed in current SWE products from spaceborne passive microwave observations Nastaran Saberi, Richard Kelly Interdisciplinary."

Similar presentations

Extension and application of an AMSR global land parameter data record for ecosystem studies Jinyang Du, John S. Kimball, Lucas A. Jones, Youngwook Kim,

Extension and application of an AMSR global land parameter data record for ecosystem studies Jinyang Du, John S. Kimball, Lucas A. Jones, Youngwook Kim,
A thermodynamic model for estimating sea and lake ice thickness with optical satellite data Student presentation for GGS656 Sanmei Li April 17, 2012.

A thermodynamic model for estimating sea and lake ice thickness with optical satellite data Student presentation for GGS656 Sanmei Li April 17, 2012.
Land Surface Microwave Emissivity Dynamics: Observations, Analysis and Modeling Yudong Tian, Christa Peters-Lidard, Ken Harrison, Sujay Kumar and Sarah.

Land Surface Microwave Emissivity Dynamics: Observations, Analysis and Modeling Yudong Tian, Christa Peters-Lidard, Ken Harrison, Sujay Kumar and Sarah.
Electromagnetic Models In Active And Passive Microwave Remote Sensing of Terrestrial Snow Leung Tsang 1, Xiaolan Xu 2 and Simon Yueh 2 1 Department of.

Electromagnetic Models In Active And Passive Microwave Remote Sensing of Terrestrial Snow Leung Tsang 1, Xiaolan Xu 2 and Simon Yueh 2 1 Department of.
SnowSAR in Canada: An evaluation of basin scale dual-frequency (17.2 and 9.6 GHz) snow property retrieval in a tundra environment Joshua King and Chris.

SnowSAR in Canada: An evaluation of basin scale dual-frequency (17.2 and 9.6 GHz) snow property retrieval in a tundra environment Joshua King and Chris.
1 CODATA 2006 October 23-25, 2006, Beijing Cryospheric Data Assimilation An Integrated Approach for Generating Consistent Cryosphere Data Set Xin Li World.

1 CODATA 2006 October 23-25, 2006, Beijing Cryospheric Data Assimilation An Integrated Approach for Generating Consistent Cryosphere Data Set Xin Li World.
Multi-sensor and multi-scale data assimilation of remotely sensed snow observations Konstantinos Andreadis 1, Dennis Lettenmaier 1, and Dennis McLaughlin.

Multi-sensor and multi-scale data assimilation of remotely sensed snow observations Konstantinos Andreadis 1, Dennis Lettenmaier 1, and Dennis McLaughlin.
ElectroScience Lab Remote Sensing of Ice Sheet Subsurface Temperatures Mustafa Aksoy, Joel T. Johnson, and Kenneth C. Jezek* Department of Electrical and.

ElectroScience Lab Remote Sensing of Ice Sheet Subsurface Temperatures Mustafa Aksoy, Joel T. Johnson, and Kenneth C. Jezek* Department of Electrical and.
Near Surface Soil Moisture Estimating using Satellite Data Researcher: Dleen Al- Shrafany Supervisors : Dr.Dawei Han Dr.Miguel Rico-Ramirez.

Near Surface Soil Moisture Estimating using Satellite Data Researcher: Dleen Al- Shrafany Supervisors : Dr.Dawei Han Dr.Miguel Rico-Ramirez.
Remote Sensing of Hydrological Variables over the Red Arkansas Eric Wood Matthew McCabe Rafal Wojcik Hongbo Su Huilin Gao Justin Sheffield Princeton University.

Remote Sensing of Hydrological Variables over the Red Arkansas Eric Wood Matthew McCabe Rafal Wojcik Hongbo Su Huilin Gao Justin Sheffield Princeton University.
SMOS – The Science Perspective Matthias Drusch Hamburg, Germany 30/10/2009.

SMOS – The Science Perspective Matthias Drusch Hamburg, Germany 30/10/2009.
Detecting SWE peak time from passive microwave data Naoki Mizukami GEOG6130 Advanced Remote Sensing.

Detecting SWE peak time from passive microwave data Naoki Mizukami GEOG6130 Advanced Remote Sensing.
An artificial neural networks system is used as model to estimate precipitation at 0.25° x 0.25° resolution. Two different networks are being developed,

An artificial neural networks system is used as model to estimate precipitation at 0.25° x 0.25° resolution. Two different networks are being developed,
Single Column Experiments with a Microwave Radiative Transfer Model Henning Wilker, Meteorological Institute of the University of Bonn (MIUB) Gisela Seuffert,

Single Column Experiments with a Microwave Radiative Transfer Model Henning Wilker, Meteorological Institute of the University of Bonn (MIUB) Gisela Seuffert,
A Study on Vegetation OpticalDepth Parameterization and its Impact on Passive Microwave Soil Moisture Retrievals A Study on Vegetation Optical Depth Parameterization.

A Study on Vegetation OpticalDepth Parameterization and its Impact on Passive Microwave Soil Moisture Retrievals A Study on Vegetation Optical Depth Parameterization.
A new prototype AMSR-E SWE operational algorithm M. Tedesco The City College of New York, CUNY, NYC With contributions from : Chris Derksen, Jouni Pulliainen,

A new prototype AMSR-E SWE operational algorithm M. Tedesco The City College of New York, CUNY, NYC With contributions from : Chris Derksen, Jouni Pulliainen,
Retrieval of Snow Water Equivalent Using Passive Microwave Brightness Temperature Data By: Purushottam Raj Singh & Thian Yew Gan Dept. of Civil & Environmental.

Retrieval of Snow Water Equivalent Using Passive Microwave Brightness Temperature Data By: Purushottam Raj Singh & Thian Yew Gan Dept. of Civil & Environmental.
Improving the AMSR-E snow depth product: recent developments Richard Kelly University of Waterloo, Canada.

Improving the AMSR-E snow depth product: recent developments Richard Kelly University of Waterloo, Canada.
Introduction Knowledge of the snow microstructure (correct a priori parameterization of grain size) is relevant for successful retrieval of snow parameters.

Introduction Knowledge of the snow microstructure (correct a priori parameterization of grain size) is relevant for successful retrieval of snow parameters.
Snow Cover: Current Capabilities, Gaps and Issues (Canadian Perspective) Anne Walker Climate Research Branch, Meteorological Service of Canada IGOS-Cryosphere.

Snow Cover: Current Capabilities, Gaps and Issues (Canadian Perspective) Anne Walker Climate Research Branch, Meteorological Service of Canada IGOS-Cryosphere.

Similar presentations

Ads by Google