Presentation is loading. Please wait.

Presentation is loading. Please wait.

National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California Evaluation of the SMAP.

Published byRoss Booth Modified over 8 years ago

Similar presentations

Presentation on theme: "National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California Evaluation of the SMAP."— Presentation transcript:

1 National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California Evaluation of the SMAP Combined Radar-Radiometer Soil Moisture Algorithm 1 Jet Propulsion Laboratory, California Institute of Technology, Pasadena, California 91109, USA 2 Massachusetts Institute of Technology, Cambridge, MA 02139, USA 3 University of California, Santa Barbara, CA 93106, USA IGARSS 2011 Paper #3398 N. N. Das 1 D. Entekhabi 2 S. K. Chan 1 R. S. Dunbar 1 S. Kim 1 E. G. Njoku 1 J. C. Shi 3

2 National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California SMAP Measurements Approach Radar Frequency: 1.26 GHz Polarizations: VV, HH, HV Resolution: 3 km Relative Accuracy: 1.0 dB (HH,VV), 1.5 dB (HV) Radiometer Frequency: 1.41 GHz Polarizations: H, V, 3 rd & 4 th Stokes Resolution: 40 km Relative Accuracy: 1.3 K Shared Antenna Constant Incidence Angle: 40º Wide Swath: 1000 km Orbit Sun-Synchronous, 6 am/pm Orbit, 680 km Overview of the SMAP Mission

3 National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California L-band Active/Passive Assessment  Soil Moisture Retrieval Algorithms Build on Heritage of Microwave Modeling and Field Experiments MacHydro’90, Monsoon’91, Washita92, Washita94, SGP97, SGP99, SMEX02, SMEX03, SMEX04, SMEX05, CLASIC, SMAPVEX08, CanEx10  Radiometer - High Accuracy (Less Influenced by Roughness and Vegetation) but Coarser Resolution (40 km)  Radar - High Spatial Resolution (1-3 km) but More Sensitive to Surface Roughness and Vegetation Combined Radar-Radiometer Product Provides Blend of Measurements for Intermediate Resolution and Intermediate Accuracy

4 National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California RequirementSoil Moisture Freeze/ Thaw Resolution 10 km3 km Refresh Rate 3 days2 days (1) Accuracy 0.04 [cm 3 cm -3 ] (2) 80% (2) Duration 36 months (1) North of 45°N Latitude (2) % volumetric water content, 1-sigma (3) % classification accuracy (binary: Freeze or Thaw) SMAP Level 1 Science Requirements Product Short Name Description Data Resolution L2_SM_PRadiometer Soil Moisture36 km L2_SM_ARadar Soil Moisture3 km L2_SM_A/PActive-Passive Soil Moisture9 km L2_F/T_HiResDaily Global Composite Freeze/Thaw State1-3 km L3_SM_PDaily Global Composite Radiometer Soil Moisture36 km L3_SM_A/PDaily Global Composite Active-Passive Soil Moisture9 km L4_SMSurface & Root Zone Soil Moisture9 km L4_CCarbon Net Ecosystem Exchange1 km

5 National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California Definitions and Data Products Flow L1_S0_HiRes σ Merge Algorithms C M nm nc = 1 nf = 144 nm = 16 C = Coarse (~36 km Radiometer) M nm = Medium (~9 km Merged Product) F nf = Fine (~3 km Radar) L1C_TB T B L2_SM_AP T B disaggregation (Das et al., Preliminary ATBD) (TGARS, submitted) F nf

6 National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California L2_SM_AP Radar-Radiometer T B Disaggregation Algorithm Same evaluated at scale M j : Temporal Changes in T B and σ pp are Related. Relationship Parameter β is Estimated Statistically at Radiometer C- Scale Using Successive Overpasses: Subtract Two Equations to Write: DOY, 2002T Bh ~4 kmσ vv ~800 m 176 178 182 183 186 187 188 189 R 2 (Low: 0.65, High: 0.93) values between T Bh and σ vv dBK SMEX02

7 National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California L2_SM_AP Radar-Radiometer Algorithm Heterogeneity in Vegetation and Roughness Conditions Estimated by Sensitivities Γ in Radar HV Cross-Pol: T B ( M j ) is Used to Retrieve Soil Moisture at 9 km T B -Disaggregation Algorithm is: Based on PALS Observations From: SGP99, SMEX02, CLASIC and SMAPVEX08

8 National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California Combined Airborne Data From: SGP99, SMEX02, CLASIC and SMAPVEX08 Active-Passive Algorithm Performance Minimum Performance Algorithm RMSE: 0.055 [cm 3 cm -3 ] Active-Passive Algorithm RMSE: 0.033 [cm 3 cm -3 ]

9 National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California The Role of Cross-Pol in Capturing Heterogeneity Active-Passive Algorithm RMSE: 0.033 [cm 3 cm -3 ] Active-Passive Algorithm Without Cross-Pol RMSE: 0.043 [cm 3 cm -3 ] Minimum Performance Algorithm RMSE: 0.055 [cm 3 cm -3 ]

10 National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California ParameterAdded Uncertainty (1 std.) Brightness Temperature T B 1.5 [K] Vegetation Opacity (τ)10% Soil Temprature2 [K] Single-Scattering Albedo (ω)5% Roughness (h)10% Sand fraction (sf)10% Clay fraction (cf)10% Study region selected from the CONUS domain. Assessment of L2_SM_AP Algorithm Using SMAP Algorithm Testbed

11 National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California Sample of L3_SM_AP Output from SMAP Algorithm Testbed V/V Global Composite Map of Soil Moisture for April 02

12 National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California Summary  PALS data verifies that the assumption (linear TB-log[σ] relationship) holds well as the basis for the L2_SM_A/P algorithm  With current baseline approach, the algorithm meets the SMAP Level-1 requirements  Algorithm relies on radar co-pols and cross-pols  L2_SM_AP processor developed in SMAP Testbed

13 National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California  Optimize length of temporal window (balance between phenology and statistical robustness)  Develop and mature algorithm prior parameters database for Bayesian estimation  Develop and mature L2_SM_A/P error budget table Work in Progress

14 National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California Acknowledgements Andreas Colliander Jet Propulsion Laboratory Joel Johnson Ohio State University NASA SMAP Project

Download ppt "National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California Evaluation of the SMAP."

Similar presentations

Environmental Application of Remote Sensing: CE 6900 Tennessee Technological University Department of Civil and Environmental Engineering Course Instructor:

Environmental Application of Remote Sensing: CE 6900 Tennessee Technological University Department of Civil and Environmental Engineering Course Instructor:
Evaluation and Improvement of the AQUA/AMSR-E Soil Moisture Algorithm AMSR-E Science Team Meeting 28-29 June, 2011, Asheville, NC I. E. Mladenova, T. J.

Evaluation and Improvement of the AQUA/AMSR-E Soil Moisture Algorithm AMSR-E Science Team Meeting June, 2011, Asheville, NC I. E. Mladenova, T. J.
MoistureMap: Multi-sensor Retrieval of Soil Moisture Mahdi Allahmoradi PhD Candidate Supervisor: Jeffrey Walker Contributors: Dongryeol Ryu, Chris Rudiger.

MoistureMap: Multi-sensor Retrieval of Soil Moisture Mahdi Allahmoradi PhD Candidate Supervisor: Jeffrey Walker Contributors: Dongryeol Ryu, Chris Rudiger.
AMS’04, Seattle, WA. January 12, 2004Slide 1 HYDROS Radiometer and Radar Combined Soil Moisture Retrieval Using Kalman Filter Data Assimilation X. Zhan,

AMS’04, Seattle, WA. January 12, 2004Slide 1 HYDROS Radiometer and Radar Combined Soil Moisture Retrieval Using Kalman Filter Data Assimilation X. Zhan,
SNPP VIIRS green vegetation fraction products and application in numerical weather prediction Zhangyan Jiang 1,2, Weizhong Zheng 3,4, Junchang Ju 1,2,

SNPP VIIRS green vegetation fraction products and application in numerical weather prediction Zhangyan Jiang 1,2, Weizhong Zheng 3,4, Junchang Ju 1,2,
On Estimation of Soil Moisture & Snow Properties with SAR Jiancheng Shi Institute for Computational Earth System Science University of California, Santa.

On Estimation of Soil Moisture & Snow Properties with SAR Jiancheng Shi Institute for Computational Earth System Science University of California, Santa.
Jet Propulsion Laboratory California Institute of Technology The NASA/JPL Airborne Synthetic Aperture Radar System (AIRSAR) Yunling Lou Jet Propulsion.

Jet Propulsion Laboratory California Institute of Technology The NASA/JPL Airborne Synthetic Aperture Radar System (AIRSAR) Yunling Lou Jet Propulsion.
National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California 3/3/2011 National Aeronautics.

National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Pasadena, California 3/3/2011 National Aeronautics.
SMAP and Agricultural Productivity Applications

SMAP and Agricultural Productivity Applications
7/27/11 Peggy O’Neill, NASA GSFC IGARSS’11, Vancouver, BC, Canada National Aeronautics and Space Administration Utilization of.

7/27/11 Peggy O’Neill, NASA GSFC IGARSS’11, Vancouver, BC, Canada National Aeronautics and Space Administration Utilization of.
AGU 2004 Fall Meeting, May 19, 2015Slide 1 Jointly Retrieving Surface Soil Moisture from Active and Passive Microwave Observations using Cubist Data-Mining.

AGU 2004 Fall Meeting, May 19, 2015Slide 1 Jointly Retrieving Surface Soil Moisture from Active and Passive Microwave Observations using Cubist Data-Mining.
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.
Soil moisture retrieval over bare surfaces using time-series radar observations and a lookup table representation of forward scattering Seung-bum Kim,

Soil moisture retrieval over bare surfaces using time-series radar observations and a lookup table representation of forward scattering Seung-bum Kim,
1 Microwave Vegetation Indices and VWC in NAFE’06 T. J. Jackson 1, J. Shi 2, and J. Tao 3 1 USDA ARS Hydrology and Remote Sensing Lab, Maryland, USA 2.

1 Microwave Vegetation Indices and VWC in NAFE’06 T. J. Jackson 1, J. Shi 2, and J. Tao 3 1 USDA ARS Hydrology and Remote Sensing Lab, Maryland, USA 2.
Identifying Soil Types using Soil moisture data CVEN 689 BY Uday Sant April 26, 2004.

Identifying Soil Types using Soil moisture data CVEN 689 BY Uday Sant April 26, 2004.
SMOS – The Science Perspective Matthias Drusch Hamburg, Germany 30/10/2009.

SMOS – The Science Perspective Matthias Drusch Hamburg, Germany 30/10/2009.
Globally distributed evapotranspiration using remote sensing and CEOP data Eric Wood, Matthew McCabe and Hongbo Su Princeton University.

Globally distributed evapotranspiration using remote sensing and CEOP data Eric Wood, Matthew McCabe and Hongbo Su Princeton University.
The Soil Moisture Active/Passive (SMAP) Mission: Monitoring Soil Moisture and Freeze/Thaw State John Kimball, Global Vegetation Workshop, June 16-19 2009.

The Soil Moisture Active/Passive (SMAP) Mission: Monitoring Soil Moisture and Freeze/Thaw State John Kimball, Global Vegetation Workshop, June
Remote Sensing of Soil Moisture Lecture 7. What is soil moisture? Soil moisture is the water that is held in the spaces between soil particles. Surface.

Remote Sensing of Soil Moisture Lecture 7. What is soil moisture? Soil moisture is the water that is held in the spaces between soil particles. Surface.
Synergy of L-band and optical data for soil moisture monitoring O. Merlin, J. Walker and R. Panciera 3 rd NAFE workshop 17-18 sept. 2007.

Synergy of L-band and optical data for soil moisture monitoring O. Merlin, J. Walker and R. Panciera 3 rd NAFE workshop sept

Similar presentations

Ads by Google