Exploring the Relationship between Forest Canopy Height and Canopy Density from Spaceborne LiDAR Observations

Heather Kay,Richard Lucas,Oliver Cartus,Pete Bunting,Maurizio Santoro

doi:10.3390/rs13244961

Heather Kay, Richard Lucas + Show 3 more

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https://doi.org/10.3390/rs13244961

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Abstract

Forest structure is a useful proxy for carbon stocks, ecosystem function and species diversity, but it is not well characterised globally. However, Earth observing sensors, operating in various modes, can provide information on different components of forests enabling improved understanding of their structure and variations thereof. The Ice, Cloud and Elevation Satellite (ICESat) Geoscience Laser Altimeter System (GLAS), providing LiDAR footprints from 2003 to 2009 with close to global coverage, can be used to capture elements of forest structure. Here, we evaluate a simple allometric model that relates global forest canopy height (RH100) and canopy density measurements to explain spatial patterns of forest structural properties. The GLA14 data product (version 34) was applied across subdivisions of the World Wildlife Federation ecoregions and their statistical properties were investigated. The allometric model was found to correspond to the ICESat GLAS metrics (median mean squared error, MSE: 0.028; inter-quartile range of MSE: 0.022–0.035). The relationship between canopy height and density was found to vary across biomes, realms and ecoregions, with denser forest regions displaying a greater increase in canopy density values with canopy height, compared to sparser or temperate forests. Furthermore, the single parameter of the allometric model corresponded with the maximum canopy density and maximum height values across the globe. The combination of the single parameter of the allometric model, maximum canopy density and maximum canopy height values have potential application in frameworks that target the retrieval of above-ground biomass and can inform on both species and niche diversity, highlighting areas for conservation, and potentially enabling the characterisation of biophysical drivers of forest structure.

Highlights

Forest structure can be defined as the three-dimensional arrangement of tree components, covering land areas of varying dimension
This was the threshold adopted for exclusion of the polygons generated by the union of World Wildlife Federation (WWF) ecoregions and the 1◦ × 1◦ grid
The model described in Equation (1) corresponded with the ICESat Geoscience Laser Altimeter System (GLAS) metrics, despite varying patterns of the canopy density to canopy height relationship (Figure 2)

Summary

Introduction

Forest structure can be defined as the three-dimensional arrangement of tree components (leaves, branches and stems), covering land areas of varying dimension. It provides crucial information on how forest ecosystems function, advancing studies of carbon stocks and fluxes [1]. Large footprint LiDAR data have been used successfully to estimate elements of forest structure, e.g., canopy height, above-ground biomass, stand volume, canopy density and basal area, across various biomes (e.g., [5,6,7]). The Ice, Cloud and Elevation Satellite (ICESat) Geoscience Laser Altimeter System (GLAS) was a full-waveform LiDAR mission, with the main focus being to measure ice sheet elevation. The mission was able to develop vegetation products which have been used to study forest height and Remote Sens.

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