Introduction: Our goal is to provide maps of woody plant crown cover and canopy height in the arid southwest US using moderate resolution NASA Earth Observing.

Slides:

Advertisements

Similar presentations

DEPARTMENT OF LAND INFORMATION – SATELLITE REMOTE SENSING SERVICES CRCSI AC Workshop November 2005 Remote Sensing in Near-Real Time of Atmospheric.

Advertisements

SNPP VIIRS green vegetation fraction products and application in numerical weather prediction Zhangyan Jiang 1,2, Weizhong Zheng 3,4, Junchang Ju 1,2,

Evaluating Calibration of MODIS Thermal Emissive Bands Using Infrared Atmospheric Sounding Interferometer Measurements Yonghong Li a, Aisheng Wu a, Xiaoxiong.

Scaling Biomass Measurements for Examining MODIS Derived Vegetation Products Matthew C. Reeves and Maosheng Zhao Numerical Terradynamic Simulation Group.

Satellite based estimates of surface visibility for state haze rule implementation planning Air Quality Applied Sciences Team 6th Semi-Annual Meeting (Jan.

Goal: estimate sub-pixel woody shrub fractional cover at landscape scales Approach: evaluate the Simple Geometric Model (GM) against the 631 nm directional.

US Forest Disturbance Trends observed with Landsat Time Series Samuel N. Goward 1 (PI), Jeffrey Masek 2, Warren Cohen 3, Gretchen Moisen 4, Chengquan Huang.

Quantitative Interpretation of Satellite and Surface Measurements of Aerosols over North America Aaron van Donkelaar M.Sc. Defense December, 2005.

Carbon Benefits Project: Measurement of Carbon in Woody Biomass Mike Smalligan, Research Forester Global Observatory for Ecosystem Services Department.

Quantifying aerosol direct radiative effect with MISR observations Yang Chen, Qinbin Li, Ralph Kahn Jet Propulsion Laboratory California Institute of Technology,

The CHRIS/PROBA Jornada Experiment: Exploitation of Data from the CHRIS Mark J. Chopping Department of Earth and Environmental Studies Montclair State.

A Remote Sensing Model Estimating Water Body Evaporation Junming Wang, Ted Sammis, Vince Gutschick Department of Plant and Environmental Sciences New Mexico.

Questions How do different methods of calculating LAI compare? Does varying Leaf mass per area (LMA) with height affect LAI estimates? LAI can be calculated.

ESTEC July 2000 Estimation of Aerosol Properties from CHRIS-PROBA Data Jeff Settle Environmental Systems Science Centre University of Reading.

Important science questions addressed by the NASA Carbon Cycle and Ecosystems program include “How are the Earth’s carbon cycle and ecosystems changing.

October 28, 2004C Pools from EOS MISR & MODIS1 Carbon Pools in Desert Grasslands from EOS: First Meeting Jornada Experimental Range, Las Cruces, NM, October.

Update on MISR applications to Shrub Abundance Mapping in Desert Grasslands Mark Chopping, Lihong Su, Albert Rango, Debra P.C. Peters, John V. Martonchik,

What is RADAR? What is RADAR? Active detecting and ranging sensor operating in the microwave portion of the EM spectrum Active detecting and ranging sensor.

Landscape-scale forest carbon measurements for reference sites: The role of Remote Sensing Nicholas Skowronski USDA Forest Service Climate, Fire and Carbon.

Mapping Forest Vegetation Structure in the National Capital Region using LiDAR Data and Analysis Geoff Sanders, Data Manager Mark Lehman, GIS Specialist.

USDA Forest Service Remote Sensing Applications Center Forest Inventory and Analysis New Technology How is FIA integrating new technological developments.

Goal: To improve estimates of above- and belowground C pools in desert grasslands by providing more accurate maps of plant community type, canopy structural.

Satellite Imagery and Remote Sensing NC Climate Fellows June 2012 DeeDee Whitaker SW Guilford High Earth/Environmental Science & Chemistry.

MODIS: Moderate-resolution Imaging Spectroradiometer National-Scale Remote Sensing Imagery for Natural Resource Applications Mark Finco Remote Sensing.

July 14, 2004Alexander Marshak 3D Error Assessment and Cloud Climatology from MODIS R.F. Cahalan, A. Marshak (GSFC) K.F. Evans (University of Colorado)

Mapping Forest Canopy Height with MISR We previously demonstrated a capability to obtain physically meaningful canopy structural parameters using data.

Developing a High Spatial Resolution Aerosol Optical Depth Product Using MODIS Data to Evaluate Aerosol During Large Wildfire Events STI-5701 Jennifer.

Development of the Temperate Shrub Submodel for the Community Land Model-Dynamic Global Vegetation Model (CLM-DGVM) Xubin Zeng Xiaodong Zeng Mike Barlage.

Chuvieco and Huete (2009): Fundamentals of Satellite Remote Sensing, Taylor and Francis Emilio Chuvieco and Alfredo Huete Fundamentals of Satellite Remote.

Estimates of Biomass Burning Particulate Matter (PM2.5) Emissions from the GOES Imager Xiaoyang Zhang 1,2, Shobha Kondragunta 1, Chris Schmidt 3 1 NOAA/NESDIS/Center.

Slide #1 Emerging Remote Sensing Data, Systems, and Tools to Support PEM Applications for Resource Management Olaf Niemann Department of Geography University.

Karnieli: Introduction to Remote Sensing

Biomass Mapping The set of field biomass training data and the MODIS observations were used to develop a regression tree model (Random Forest). Biomass.

Abstract: Dryland river basins frequently support both irrigated agriculture and riparian vegetation and remote sensing methods are needed to monitor.

Generating fine resolution leaf area index maps for boreal forests of Finland Janne Heiskanen, Miina Rautiainen, Lauri Korhonen,

Maria Val Martin and J. Logan (Harvard Univ., USA) D. Nelson, C. Ichoku, R. Kahn and D. Diner (NASA, USA) S. Freitas (INPE, Brazil) F.-Y. Leung (Washington.

Support the spread of “good practice” in generating, managing, analysing and communicating spatial information Introduction to Remote Sensing Images By:

Daily Inventory of Biomass Burning Emissions using Satellite Observations and Using Satellite Observations of CO from MOPITT Colette Heald Advisor: Daniel.

Site Harvard Hemlock Site 305 Site Harvard EMS tower  The LAI estimates are impacted by changes in the occlusion effect at the different scales.  75.

BIOPHYS: A Physically-based Algorithm for Inferring Continuous Fields of Vegetative Biophysical and Structural Parameters Forrest Hall 1, Fred Huemmrich.

DEVELOPING HIGH RESOLUTION AOD IMAGING COMPATIBLE WITH WEATHER FORECAST MODEL OUTPUTS FOR PM2.5 ESTIMATION Daniel Vidal, Lina Cordero, Dr. Barry Gross.

Wildfire Plume Injection Heights Over North America: An Analysis of MISR Observations Maria Val Martin and Jennifer A. Logan (Harvard Univ., USA) Fok-Yan.

Spectral unmixing of vegetation, soil and dry carbon cover in arid regions: comparing multispectral and hyperspectral observations G.P.Asner and K.B.Heidebrecht.

14 ARM Science Team Meeting, Albuquerque, NM, March 21-26, 2004 Canada Centre for Remote Sensing - Centre canadien de télédétection Geomatics Canada Natural.

REASoN Multi-Resolution Snow Products for the Hydrologic Sciences University of California, Santa Barbara University of California, Merced Long term commitment.

Principal Investigators: Athol D. Abrahams (Geography), State University of New York, Buffalo, NY Dale Gillette, NOAA, Research.

Retrieval of Cloud Phase and Ice Crystal Habit From Satellite Data Sally McFarlane, Roger Marchand*, and Thomas Ackerman Pacific Northwest National Laboratory.

We show how moderate resolution data from the Multiangle Imaging SpectroRadiometer (MISR) on the NASA Earth Observing System Terra satellite can be interpreted.

Arizona Space Grant Consortium Statewide Symposium Arizona Space Grant Consortium Statewide Symposium Light Detection and Ranging (LiDAR) Survey of a Sky.

Objectives The Li-Sparse reciprocal kernel is based on the geometric optical modeling approach developed by Li and Strahler, in which the angular reflectance.

H51A-01 Evaluation of Global and National LAI Estimates over Canada METHODOLOGY LAI INTERCOMPARISONS LEAF AREA INDEX JUNE 1997 LEAF AREA INDEX 1993 Baseline.

Biomass and Carbon Residence Time Estimation by Remote Sensing and Direct Measurements at the Santa Rita Experimental Research Station 1 Theodore Jones.

Analysis of satellite imagery to map burned areas in Sub-Saharan Africa CARBOAFRICA conference “Africa and Carbon Cycle: the CarboAfrica project” Accra.

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu Assessment of Albedo Derived from MODIS at ChEAS - Park Falls ChEAS 2006 Meeting: June 5 - June.

DEFINITION LEAF AREA INDEX is defined as one half the total foliage

Aboveground Biomass, Mg ha -1 < 1.0 Red band bidirectional reflectance data from the NASA MODerate resolution Imaging Spectroradiometer (MODIS)

Evaluating simulated vegetation distributions and characteristics Andrew D. Friend, Tim Tito Rademacher, ISI-MIP2 biomes teams, etc. 1.

Integrating LiDAR Intensity and Elevation Data for Terrain Characterization in a Forested Area Cheng Wang and Nancy F. Glenn IEEE GEOSCIENCE AND REMOTE.

Use of Remote Sensing to Detect and Monitor Landscape Vulnerability to Wind Erosion and Dust Emission With Potential Connection to Climate Pat Chavez Adjunct.

Figure 10. Improvement in landscape resolution that the new 250-meter MODIS (Moderate Resolution Imaging Spectroradiometer) measurement of gross primary.

J. C. Stroeve, J. Box, F. Gao, S. Liang, A. Nolin, and C. Schaaf

Department of Atmospheric Sciences

Using MISR to Map Woody Plant Canopy Crown Cover, Height, and Biomass

Figure 1. Spatial distribution of pinyon-juniper and ponderosa pine forests is shown for the southwestern United States. Red dots indicate location of.

Satellite Sensors – Historical Perspectives

NASA alert as Russian and US satellites crash in space

National Forest Inventory for Great Britain

Using dynamic aerosol optical properties from a chemical transport model (CTM) to retrieve aerosol optical depths from MODIS reflectances over land Fall.

By: Paul A. Pellissier, Scott V. Ollinger, Lucie C. Lepine

Planning a Remote Sensing Project

Presentation transcript:

Introduction: Our goal is to provide maps of woody plant crown cover and canopy height in the arid southwest US using moderate resolution NASA Earth Observing System data with a multi-angle approach. These are important parameters in western forests that are increasingly vulnerable to fire and also in grasslands that have experienced increases in woody plant abundance since the late C19 th, resulting in changes in C pools and cycling. We show how data from the NASA Multiangle Imaging SpectroRadiometer (MISR) can be used to map woody plant canopies. Method: MISR Level 1B2 Terrain Data from June 2002 over SE Arizona and S New Mexico were atmospherically corrected and mapped to 250 m grids. The background (soil+understory) angular response in the MISR viewing plane was estimated a priori, using the isotropic, geometric, and volume scattering weights of a LiSparse-RossThin kernel- driven model (adjusted against the MISR red band data in nine views) plus nadir camera reflectance factors. Calibration of these relationships was effected using shrub cover estimates obtained from IKONOS 1 m panchromatic imagery in a grass-shrub transition zone in the USDA, ARS Jornada Experimental Range. A simple geometric-optical (GO) model was then adjusted against the MISR red band data in all 9 views (providing view zenith angles of up to 70.5°) to retrieve crown cover (by adjusting only mean crown radius; Fig. 1) or mean crown radius and mean canopy height (using the Praxis algorithm). NASA Carbon Cycle and Ecosystems Workshop, Adelphi, MD, August 21-25, Acknowledgments: This work was supported by NASA grant NNG04GK91G under the EOS/LCLUC program (program manager: Dr. Garik Gutman). Oblique aerial photo: Scott Bauer, USDA, ARS Photo Unit. Data credits: NASA/JPL/LARC; USDA, ARS, Jornada Experimental Range; The Global Land Cover Facility ( Further results are at Results: Woody plant cover shows a good if biased relationship to cover from QuickBird-derived shrub maps (Fig. 2) and MODIS Vegetation Continuous Fields % Tree Cover (Fig. 3); cover and height show a match with Forest Inventory Analysis Maps (Figs. 4 and 5). Regional-scale maps give very reasonable distributions (Figs. 6, 7, and 8). Inversions took ~1 hour. A Multi-Angle Approach to Mapping Forest and Shrub Canopy Structure in the Southwestern US Mark Chopping 1, Lihong Su 1, Andrea Laliberte 2, Albert Rango 2, Gretchen Moisen 3, and John V. Martonchik Earth & Environmental Studies, Montclair State University, Montclair, NJ 2. USDA, ARS Jornada Experimental Range, New Mexico State University, Las Cruces, NM 3. USDA, US Forest Service Rocky Mountain Research Station, Ogden, UT 4. NASA/JPL, Pasadena, CA Figure 1. L-R: ground and air photogrpahs showing typical backgrounds; flowchart showing the method used to enable GO model inversions. +shrub -volume scattering +u.story +volume scattering Fig. 4 MISR/GO Woody Plant Canopy Cover AZ NM TX Mexico MISR/GO Forest Inventory Analysis white=cloud cover and White Sands National Monument Fig. 5 MISR/GO Woody Plant Canopy Height MISR/GO Forest Inventory Analysis AZ NM TX Mexico Figure 3. Comparisons of Retrievals with MODIS VCF % Tree Cover Map Left: MISR/GO Woody Plant Cover Right: MODIS Vegetation Continuous Fields % Tree Cover for the USDA, ARS Jornada Experimental Range near Las Cruces, NM Summerford San Andres Mountain Mountains 10 km Rio Grande riparian zone Fractional Cover Fractional Cover tree shrub km-- 10 km Top: MISR/GO Woody Plant Cover Bottom: MODIS Vegetation Continuous Fields % Tree Cover for the Sevilleta National Wildlife Refuge near Socorro, NM San Andres Mountains Rio Grande riparian zone Fractional Cover tree shrub (a)(b)(c) shrub non-shrub 500 m (d) Figure 2. (a) QuickBird shrub map in the Jornada Experimental Range (b) aggregated to 250 m (c) retrieved using MISR and the SGM GO model (d) retrieved vs measured cover Regional Crown Cover and Canopy Height from MISR Figure 7. Retrieved mean canopy height for SE Arizona and S New Mexico Black: close to zero VIBGYOR: MISR/GO Regional Woody Plant Canopy Cover MISR/GO Regional Woody Plant Canopy Height MISR/GO Regional Crown Cover x Canopy Height Figure 8. Dot product of crown cover and mean canopy height (a surrogate of aboveground woody biomass). Grayscale: VIBGYOR: Conclusions: Multi-angle data are sensitive to canopy structure and can be exploited to provide maps of woody plant cover and canopy height over large areas. Further work is required to validate these retrievals. Figure 6. Retrieved woody plant crown cover for SE Arizona and S New Mexico Black: cover < 0.05 Grayscale: (shrubs) VIBGYOR: (trees) White: cloud cover and White Sands National Monument (gypsum dunes and alkali flats)