Abstract
Shadows exist universally in sunlight-source remotely sensed images, and can interfere with the spectral morphological features of green vegetations, resulting in imprecise mathematical algorithms for vegetation monitoring and physiological diagnoses; therefore, research on shadows resulting from forest canopy internal composition is very important. Red edge is an ideal indicator for green vegetation’s photosynthesis and biomass because of its strong connection with physicochemical parameters. In this study, red edge parameters (curve slope and reflectance) and the normalized difference vegetation index (NDVI) of two species of coniferous trees in Inner Mongolia, China, were studied using an unmanned aerial vehicle’s hyperspectral visible-to-near-infrared images. Positive correlations between vegetation red edge slope and reflectance with different illuminated/shaded canopy proportions were obtained, with all R2s beyond 0.850 (p < 0.01). NDVI values performed steadily under changes of canopy shadow proportions. Therefore, we devised a new vegetation index named normalized difference canopy shadow index (NDCSI) using red edge’s reflectance and the NDVI. Positive correlations (R2 = 0.886, p < 0.01) between measured brightness values and NDCSI of validation samples indicated that NDCSI could differentiate illumination/shadow circumstances of a vegetation canopy quantitatively. Combined with the bare soil index (BSI), NDCSI was applied for linear spectral mixture analysis (LSMA) using Sentinel-2 multispectral imaging. Positive correlations (R2 = 0.827, p < 0.01) between measured brightness values and fractional illuminated vegetation cover (FIVC) demonstrate the capacity of NDCSI to accurately calculate the fractional cover of illuminated/shaded vegetation, which can be utilized to calculate and extract the illuminated vegetation canopy from satellite images.
Highlights
Vegetation is an important component of the global ecosystem that can ameliorate climate change and maintain the global carbon cycle [1]
We proposed a new vegetation index named the normalized difference canopy shadow index (NDCSI) to represent the proportion of shadows in forest canopies quantitatively
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Summary
Vegetation is an important component of the global ecosystem that can ameliorate climate change and maintain the global carbon cycle [1]. Coniferous forests have complex canopy structures through which sunlight can be refracted and reflected repeatedly, causing shadows in remote sensing images [3,4]. Vegetation shadows are caused generally by sunlight being blocked by topographic relief or canopy obscuration, causing energy loss and the darkening of vision in remotely sensed images [5,6]. The ability for images to display the details of the target has been improved, while the shadow details have been enhanced as well. For this reason, the interference of shadows on image pixels is increasing with finer spatial resolutions [17]. How to effectively detect and quantify the shadow proportion in satellite imagery has become a subject of much research
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