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.

Slides:

Advertisements

Similar presentations

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

Advertisements

Plant Canopy Analysis Gaylon S. Campbell, Ph.D. Decagon Devices and Washington State University.

Relationships among photosynthesis, foliar nitrogen and stomatal conductance in tropical rain forest vegetation Tomas Domingues; Joe Berry; Luiz Martinelli;

TRMM Tropical Rainfall Measurement (Mission). Why TRMM? n Tropical Rainfall Measuring Mission (TRMM) is a joint US-Japan study initiated in 1997 to study.

MODIS Collection 6 BRDF/Albedo: Status and Updates Zhuosen Wang 1, Crysal Schaaf 1, Miguel Román 2 1 University of Massachusetts-Boston 2 NASA Goddard.

Estimating forest structure in wetlands using multitemporal SAR by Philip A. Townsend Neal Simpson ES 5053 Final Project.

J.-F. Müller, J. Stavrakou, S. Wallens Belgian Institute for Space Aeronomy, Brussels, Belgium IUGG Symposium, July 2007 Interannual variability of biogenic.

FOR 474: Forest Inventory Plot Level Metrics from Lidar Heights Other Plot Measures Sources of Error Readings: See Website.

Globally distributed evapotranspiration using remote sensing and CEOP data Eric Wood, Matthew McCabe and Hongbo Su Princeton University.

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

Overview of Biomass Mapping The Woods Hole Research Center Alessandro Baccini, Wayne Walker and Ned Horning November 8 – 12, Samarinda, Indonesia.

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

Forrest G. Hall 1 Thomas Hilker 1 Compton J. Tucker 1 Nicholas C. Coops 2 T. Andrew Black 2 Caroline J. Nichol 3 Piers J. Sellers 1 1 NASA Goddard Space.

Aircraft spiral on July 20, 2011 at 14 UTC Validation of GOES-R ABI Surface PM2.5 Concentrations using AIRNOW and Aircraft Data Shobha Kondragunta (NOAA),

Introduction OBJECTIVES  To develop proxies for canopy cover and canopy closure based on discrete-return LiDAR data.  To determine whether there is a.

Examination of Tropical Forest Canopy Profiles Using Field Data and Remotely Sensed Imagery Michael Palace 1, Michael Keller 1,2, Bobby Braswell 1, Stephen.

Objectives  The objectives of the workshop are to stimulate discussions around the use of 3D (and probably 4D = 3D+time) realistic modeling of canopy.

Quantitative Estimates of Biomass and Forest Structure in Coastal Temperate Rainforests Derived from Multi-return Airborne Lidar Marc G. Kramer 1 and Michael.

Introduction To describe the dynamics of the global carbon cycle requires an accurate determination of the spatial and temporal distribution of photosynthetic.

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.

Translation to the New TCO Panel Beverly Law Prof. Global Change Forest Science Science Chair, AmeriFlux Network Oregon State University.

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

How Do Forests, Agriculture and Residential Neighborhoods Interact with Climate? Andrew Ouimette, Lucie Lepine, Mary Martin, Scott Ollinger Earth Systems.

Field Measurements of Leaf Mass Area (LMA) in Support of Remote Sensing Studies of a Pacific Northwest Old Growth Forest Canopy Katie Berger (UMASS-Amherst)

Remote Sensing of LAI Conghe Song Department of Geography University of North Carolina Chapel Hill, NC

Leaf Area Index for Fire Chronosequences in Siberian Boreal Forest PI: Don Deering, NASA GSFC CO-I: Slava Kharuk, Sukachev Institute of Forest Research.

Scaling and Evaluation of Ecosystem Carbon Uptake Through Multi-Scale Remote Sensing of Canopy Nitrogen Scott V. Ollinger, Mary.E. Martin, Julian.P. Jenkins,

VEGETATION Narrow- vs. Broad-Band Instruments Wavelength (nm) Reflectance TM Bands.

Remote Sensing of Evapotranspiration with MODIS

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

Investigating the Carbon Cycle in Terrestrial Ecosystems (ICCTE) Scott Ollinger * -PI, Jana Albrecktova †, Bobby Braswell *, Rita Freuder *, Mary Martin.

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

#9 #118 #11 #13 #14 SOC Camera Images & Tree Samples SOC camera 09/05 11:01 am, composited by R-G-B Tag #Family 9 Vochysiaceae 11 Leguminosae-

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

Assessing the Phenological Suitability of Global Landsat Data Sets for Forest Change Analysis The Global Land Cover Facility What does.

Scaling Up Above Ground Live Biomass From Plot Data to Amazon Landscape Sassan S. Saatchi NASA/Jet Propulsion Laboratory California Institute of Technology.

How Do Forests, Agriculture and Residential Neighborhoods Interact with Climate? Andrew Ouimette, Lucie Lepine, Mary Martin, Scott Ollinger Earth Systems.

Goal: to understand carbon dynamics in montane forest regions by developing new methods for estimating carbon exchange at local to regional scales. Activities:

Improving fine root sampling methods for landscape-level ecosystem studies using root anatomy and morphology Kirsten Lloyd M.S. Candidate Complex Systems.

Spectral Reflectance Features Related to Foliar Nitrogen in Forests and their Implications for Broad-Scale Nitrogen Mapping Lucie C. Lepine, Scott V. Ollinger,

Examination of Canopy Disturbance in Logged Forests in the Brazilian Amazon using IKONOS Imagery Michael Palace 1, Michael Keller 1,2, Bobby Braswell 1,

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

Land-Climate Interactions Across 4 Land Cover Types in New Hampshire Latent and sensible heat “Sweating” Greenhouse Gases Longwave Radiation Albedo “Breathing”“Reflectivity”

Citation: Richardson, J. J, L.M. Moskal, S. Kim, Estimating Urban Forest Leaf Area Index (LAI) from aerial LiDAR. Factsheet # 5. Remote Sensing and.

Figure 1. (A) Evapotranspiration (ET) in the equatorial Santarém forest: observed (mean ± SD across years of eddy fluxes, K67 site, blue shaded.

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

Determination of cloud immersion and biogeography of cloud forests using satellite data Udaysankar S. Nair 1, Salvi Asefi 3, Ron Welch 3, Robert O. Lawton.

Above and Below ground decomposition of leaf litter Sukhpreet Sandhu.

References: 1)Ganguly, S., Samanta, A., Schull, M. A., Shabanov, N. V., Milesi, C., Nemani, R. R., Knyazikhin, Y., and Myneni, R. B., Generating vegetation.

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

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

Assessing the climate impacts of land cover and land management using an eddy flux tower cluster in New England Earth Systems Research Center Institute.

PADMA ALEKHYA V V L, SURAJ REDDY R, RAJASHEKAR G & JHA C S

Term Project Presentation

Comparison of GPP from Terra-MODIS and AmeriFlux Network Towers

Canopy Structure Measurements with Ground-based High-Resolution Laser Range Sampling (LIDAR) Phil Radtke, Virginia Tech Britt Boucher, Foresters, Inc.

Contact: Tel.: Exploring the influence of canopy structure on the link between canopy nitrogen concentration.

E.V. Lukina, K.W. Freeman,K.J. Wynn, W.E. Thomason, G.V. Johnson,

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

Zaixing Zhou, Scott V. Ollinger, Lucie Lepine

A Comparison of Forest Biodiversity Metrics Using Field Measurements and Aircraft Remote Sensing Kaitlyn Baillargeon Scott Ollinger,

Sources of Variability in Canopy Spectra and the Convergent Properties of Plants Funding From: S.V. Ollinger, L. Lepine, H. Wicklein, F. Sullivan, M. Day.

Lucie C. Lepine, Scott V. Ollinger, Mary E. Martin

By: Paul Pellissier, Andrew Ouimette, Lucie Lepine

Funding From: Sources of Variability in Canopy Reflectance and the Convergent Properties of Plants: Integrating Remote Sensing and Ecological Theory toward.

Investigating land-climate interactions across land cover types

Evaluating the Ability to Derive Estimates of Biodiversity from Remote Sensing Kaitlyn Baillargeon Scott Ollinger, Andrew Ouimette,

VALIDATION OF FINE RESOLUTION LAND-SURFACE ENERGY FLUXES DERIVED WITH COMBINED SENTINEL-2 AND SENTINEL-3 OBSERVATIONS IGARSS 2018 – Radoslaw.

Presentation transcript:

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 from measurements of how quickly radiation attenuates as it passes through the canopy. LAI-2000 is a handheld device that takes 5 simultaneous measurements at different angles from the zenith (Figure 2) and compares it to measurements taken in the open sky. LAI estimates improve with increased sampling. LAI 2000 can be an effective method for small-scale LAI estimates. Estimates were obtained for 2004, 2007, and Leaf litter collection is one way to estimate foliar biomass. Leaf litter was collected in 96 litterfall baskets (Figure 4) (2 per subplot), each with an area of 0.24 m 2. To obtain an estimate of biomass for 2012 leaf litter was collected in October and November of 2012, and May of Foliar biomass was estimated to be 293 g/m 2. NASA’s Moderate-resolution Imaging Spectroradiometer (MODIS) composites global satellite estimates of LAI every 8 days at 1km resolution. MODIS can be an effective method for estimating LAI on large-scales. Mean LAI estimates were filtered with June, July, and August as quality control flags. We obtained LAI year values ( ) for the nine 1km pixels encompassing the experimental plots. Leaf area index (LAI) is generally defined as the total surface area of foliage in a canopy per unit of ground area. Leaf surface area is directly correlated to forest productivity. Obtaining accurate measurements of LAI is important for evaluating and understanding different forest ecosystem fluxes, including those of light, heat, moisture, carbon and nitrogen. Because measuring LAI is labor intensive and time consuming, there are many different techniques for estimating LAI, and each comes with its own advantages and disadvantages. Here, we compare optical LAI measurements from MODIS and LAI 2000, to those from a hybrid technique utilizing leaf litter biomass measurements and camera point foliage height profiles. Established in 1932 by the USDA Forest Service, BEF is a field laboratory for studying the ecology and management practices of northern forest ecosystems (Figure 3a). Camera point is a method for determining canopy composition by height. Using a 35mm telephoto lens as a range finder, the height of the lowest leaf covering each grid point (Figure 5) was measured. 15 observations were recorded at plot center and each of the four cardinal and off-cardinal directions. The result was a total of 135 measurements per plot used to construct a vertical profile of the canopy (Figure 6). LMA is the ratio of dry leaf mass per area (g/m 2 ). As seen in Figure 7, some tree species’ LMA have been found to vary with height through the canopy, with leaves at the top of the canopy tending to have the highest LMA. Often LAI estimates incorporating LMA tend to neglect foliar density distribution, using one LMA for the whole canopy. When data were available, we varied LMA across canopy height based on canopy species distribution, to accurately reflect LMA. Assessing Methods for Generating Estimates of Leaf Area Index in Bartlett Experimental Forest John Hastings 1, Andrew Ouimette 2, Lucie Lepine 2 1 Department of Natural Resources and the Environment, 2 Earth Systems Research Center Introduction Study Site: Bartlett Experimental Forest (BEF) Measurements were taken at 12 plots surrounding an eddy flux tower. Each plot consists of 4 subplots (Figure 3b). Leaf Litter Collection Camera Foliage Height Profiles Leaf Mass per Area MODIS LAI 2000 Optical Methods Abstract Hybridized Methods Figure 3a. BEF location within NH Figure 3b. 12 experimental plots (four subplots per plot) surrounding an eddy flux tower Figure 1. Example of MODIS large-scale LAI estimates for the contiguous United States Figure 2 Figure 4. Example of the leaf litter collection baskets, area = 0.24 m 2. Figure 5. Example of the view seen through the camera point range finder Figure 6. Example of the canopy profile constructed from camera point data. Results Figure 7. Example of how LMA can vary with height, as seen in American Beech (Fagus grandifolia). Figure 8. Comparison of LMA obtained from literature to LMA varied by height. LMA values derived from the literature (Smith and Martin, 2001) were compared to LMA varied by height (Figure 8). For Tsuga canadensis, Pinus strobus, and Populus grandidentata (Indicated by * in Figure 8) LMA values from several sources were averaged to create a proxy for variability by height. Further measurements are required to estimate LMA trends in these species. Varying LMA was found to affect LAI estimates, resulting in a ~13.5% increase in estimated LAI over LAI estimated utilizing Smith and Martin, 2001 LMA values (Figure 9). Figure 9. Comparison of LAI estimates between optical methods and hybridized method. Asner, G., Scurlock, J., & Hicke, J. (2003). Global synthesis of leaf area index observations: Implications for ecological and remote sensing studies. Global Ecology and Biogeography, 12, Smith, M., & Martin, M. (2001). A plot-based method for rapid estimation of forest canopy chemistry. Canadian Journal of Forest Research, 31, Yang, W., Tan, B., Huang, D., Rautiainen, M., Shabanov, N., Wang, Y.,... Myneni, R. (2006). MODIS leaf area index products: From validation to algorithm improvement. IEEE Transactions on Geoscience and Remote Sensing, 44(7), References Thank you to Lucie Lepine and Andrew Ouimette for help in preparation for the URC Figure 2. Examples of data captured with LAI 2000 optical sensor. LAI estimates using varied LMA have the potential to increase if Tsuga canadensis, Pinus strobus, and Populus grandidentata are found to vary with height in the canopy, as observed with other species. A study by Yang et al., 2006 found MODIS to overestimate LAI by about 12%. Correcting for overestimates, MODIS LAI is 4.84, comparable to LAI 2000 estimates. Among compared LAI estimation techniques, LAI 2000 appears to be the most cost- and time-efficient, and accurate method for estimating LAI at small scales. Summary The MODIS 2012 LAI estimate is 5.5; the 14 year average is 5.4. LAI 2000 average estimates in 2004 is 4.68; 2007, 4.81; 2008, 4.77; three year average, Hybrid estimate using Smith values is 3.75; estimate using varied LMA by height is 4.34