Abstract
Abstract. An accurate characterisation of the complex and heterogeneous forest architecture is necessary to parameterise physically-based hydrologic models that simulate precipitation interception, energy fluxes and water dynamics. While hemispherical photography has become a popular method to obtain a number of forest canopy structure metrics relevant to these processes, image acquisition is field-intensive and, therefore, difficult to apply across the landscape. In contrast, airborne laser scanning (ALS) is a remote-sensing technique increasingly used to acquire detailed information on the spatial structure of forest canopies over large, continuous areas. This study presents a novel methodology to calibrate ALS data with in situ optical hemispherical camera images to obtain traditional forest structure and solar radiation metrics. The approach minimises geometrical differences between these two techniques by transforming the Cartesian coordinates of ALS data to generate synthetic images with a polar projection directly comparable to optical photography. We demonstrate how these new coordinate-transformed ALS metrics, along with additional standard ALS variables, can be used as predictors in multiple linear regression approaches to estimate forest structure and solar radiation indices at any individual location within the extent of an ALS transect. We expect this approach to substantially reduce fieldwork costs, broaden sampling design possibilities, and improve the spatial representation of forest structure metrics directly relevant to parameterising fully-distributed hydrologic models.
Highlights
Forested environments create unique microclimatic conditions that modulate a wide array of biophysical processes tightly linked to components of the hydrologic cycle
Our results suggest that reprojection of the airborne laser scanning (ALS) point cloud is necessary if accurate Hemispherical photography (HP)-derived estimates of canopy gap fraction, leaf area index (LAI), sky-view factor (SVF) and solar radiation transmission are required at the point level
The goal of this study was not to provide prediction models with universal application across all forest types and ALS datasets, but to reveal the importance of coordinate transformation for the estimation of gap fraction (GF) and other bulk-canopy metrics, and to demonstrate that these variables can be predicted from discrete ALS calibrated with HP
Summary
Forested environments create unique microclimatic conditions that modulate a wide array of biophysical processes tightly linked to components of the hydrologic cycle. The attenuation of solar radiation as it passes through forest structural elements is of particular importance as it controls the rate and timing of snow melt, and strongly determines flooding risk levels and seasonal water availability (Varhola et al, 2010a). Radiation attenuation and other biophysical processes requires a detailed characterisation of vegetation structure. While the capacity of forests to intercept snow is primarily affected by snow density, stand architecture and branch flexibility (Parviainen and Pomeroy, 2000), spatiotemporal patterns of light transmission through the canopies are created by the interaction between local solar paths, the anisotropy of diffuse sky brightness, cloud cover and the three-dimensional distribution of all canopy
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