Highly Local Model Calibration with a New GEDI LiDAR Asset on Google Earth Engine Reduces Landsat Forest Height Signal Saturation

While Landsat has proved to be effective for monitoring many elements of forest condition and change, the platform has well-documented limitations in measuring forest structure, the vertical distribution of the canopy. This is important because structure determines several key ecosystem functions, including: carbon storage; habitat suitability; and timber volume. Canopy structure is directly measured by LiDAR, and it should be possible to train Landsat structure models at a highly local scale with the dense, global sample of full waveform LiDAR observations collected by NASA’s Global Ecosystem Dynamics Investigation (GEDI). Local models are expected to perform better because: (a) such models may take advantage of localized correlations between structure and canopy surface reflectance; and (b) to the extent that models revert to the mean of the calibration data due to a lack of discrimination, local models will revert to a more representative mean. We tested Landsat-based relative height predictions using a new GEDI asset on Google Earth Engine, described here. Mean prediction error declined by 23% and important prediction biases at the extremes of the range of canopy height dropped as model calibration became more local, minimizing forest structure signal saturation commonly associated with Landsat and other passive optical sensors. Our results suggest that Landsat-based maps of structural variables such as height and biomass may substantially benefit from the kind of local calibration that GEDI’s dense sample of LiDAR data supports.

[1]  W. Cohen,et al.  Landsat's Role in Ecological Applications of Remote Sensing , 2004 .

[2]  W. Cohen,et al.  Estimating the age and structure of forests in a multi-ownership landscape of western Oregon, U.S.A. , 1995 .

[3]  R. Hall,et al.  Biomass mapping using forest type and structure derived from Landsat TM imagery , 2006 .

[4]  Simone R. Freitas,et al.  Relationships between forest structure and vegetation indices in Atlantic Rainforest , 2005 .

[5]  A. Baccini,et al.  Capabilities and limitations of Landsat and land cover data for aboveground woody biomass estimation of Uganda , 2012 .

[6]  David Saah,et al.  Aboveground Forest Biomass Estimation with Landsat and LiDAR Data and Uncertainty Analysis of the Estimates , 2012 .

[7]  Xiaoli Sun,et al.  The GEDI Simulator: A Large‐Footprint Waveform Lidar Simulator for Calibration and Validation of Spaceborne Missions , 2019, Earth and space science.

[8]  G. Foody,et al.  Predictive relations of tropical forest biomass from Landsat TM data and their transferability between regions , 2003 .

[9]  S. Goetz,et al.  Estimated carbon dioxide emissions from tropical deforestation improved by carbon-density maps , 2012 .

[10]  Göran Ståhl,et al.  Statistical properties of hybrid estimators proposed for GEDI—NASA’s global ecosystem dynamics investigation , 2019, Environmental Research Letters.

[11]  C. Woodcock,et al.  Continuous change detection and classification of land cover using all available Landsat data , 2014 .

[12]  Zhiqiang Yang,et al.  Continuous monitoring of land disturbance based on Landsat time series , 2020, Remote Sensing of Environment.

[13]  N. Laporte,et al.  Carbon stock corridors to mitigate climate change and promote biodiversity in the tropics , 2014 .

[14]  Hong Chi,et al.  Estimation of Forest Aboveground Biomass in Changbai Mountain Region Using ICESat/GLAS and Landsat/TM Data , 2017, Remote. Sens..

[15]  Kenneth B. Pierce,et al.  Quantification of live aboveground forest biomass dynamics with Landsat time-series and field inventory data: A comparison of empirical modeling approaches , 2010 .

[16]  A. Baccini,et al.  Mapping forest canopy height globally with spaceborne lidar , 2011 .

[17]  J. Carreiras,et al.  Mapping major land cover types and retrieving the age of secondary forests in the Brazilian Amazon by combining single-date optical and radar remote sensing data , 2017 .

[18]  Narayani Barve,et al.  Assessing Biodiversity from Space: an Example from the Western Ghats, India , 2002 .

[19]  S. Goetz,et al.  Aboveground carbon loss in natural and managed tropical forests from 2000 to 2012 , 2015 .

[20]  B. Markham,et al.  Summary of Current Radiometric Calibration Coefficients for Landsat MSS, TM, ETM+, and EO-1 ALI Sensors , 2009 .

[21]  Göran Ståhl,et al.  Use of models in large-area forest surveys: comparing model-assisted, model-based and hybrid estimation , 2016, Forest Ecosystems.

[22]  Scott J. Goetz,et al.  The Global Ecosystem Dynamics Investigation: High-resolution laser ranging of the Earth’s forests and topography , 2020, Science of Remote Sensing.

[23]  Guangxing Wang,et al.  Examining Spectral Reflectance Saturation in Landsat Imagery and Corresponding Solutions to Improve Forest Aboveground Biomass Estimation , 2016, Remote. Sens..

[24]  Evan B. Brooks,et al.  How Similar Are Forest Disturbance Maps Derived from Different Landsat Time Series Algorithms , 2017 .

[25]  Zhiqiang Yang,et al.  Detecting trends in forest disturbance and recovery using yearly Landsat time series: 1. LandTrendr — Temporal segmentation algorithms , 2010 .

[26]  Nandin-Erdene Tsendbazar,et al.  Copernicus Global Land Cover Layers - Collection 2 , 2020, Remote. Sens..

[27]  M. Steininger Satellite estimation of tropical secondary forest above-ground biomass: Data from Brazil and Bolivia , 2000 .

[28]  Sean P. Healey,et al.  Application of two regression-based methods to estimate the effects of partial harvest on forest structure using Landsat data , 2006 .

[29]  Michael Dixon,et al.  Google Earth Engine: Planetary-scale geospatial analysis for everyone , 2017 .

[30]  Leo Breiman,et al.  Random Forests , 2001, Machine Learning.

[31]  Göran Ståhl,et al.  Generalized Hierarchical Model-Based Estimation for Aboveground Biomass Assessment Using GEDI and Landsat Data , 2018, Remote. Sens..

[32]  M. Hansen,et al.  Global humid tropics forest structural condition and forest structural integrity maps , 2019, Scientific Data.

[33]  S. Díaz,et al.  Plant functional types and ecosystem function in relation to global change , 1997 .

[34]  R. McRoberts A model-based approach to estimating forest area , 2006 .

[35]  Jan Dirk Wegner,et al.  Country-wide high-resolution vegetation height mapping with Sentinel-2 , 2019, Remote Sensing of Environment.

[36]  J. Townshend,et al.  Characterizing the magnitude, timing and duration of urban growth from time series of Landsat-based estimates of impervious cover , 2016 .

[37]  M. Hansen,et al.  Annual continuous fields of woody vegetation structure in the Lower Mekong region from 2000‐2017 Landsat time-series , 2019, Remote Sensing of Environment.

[38]  K. Moffett,et al.  Remote Sens , 2015 .