Abstract
The popularisation of aerial remote sensing using unmanned aerial vehicles (UAV), has boosted the capacities of agronomists and researchers to offer farmers valuable data regarding the status of their crops. This paper describes a methodology for the automated detection and individual delineation of tree crowns in aerial representations of crop fields by means of image processing and analysis techniques, providing accurate information about plant population and canopy coverage in intensive-farming orchards with a row-based plant arrangement. To that end, after pre-processing initial aerial captures by means of photogrammetry and morphological image analysis, a resulting binary representation of the land plot surveyed is treated at connected component-level in order to separate overlapping tree crown projections. Then, those components are morphologically transformed into a set of seeds with which tree crowns are finally delineated, establishing the boundaries between them when they appear overlapped. This solution was tested on images from three different orchards, achieving semantic segmentations in which more than 94% of tree canopy-belonging pixels were correctly classified, and more than 98% of trees were successfully detected when assessing the methodology capacities for estimating the overall plant population. According to these results, the methodology represents a promising tool for automating the inventorying of plants and estimating individual tree-canopy coverage in intensive tree-based orchards.
Highlights
Modern agricultural practices developed around the precision agriculture (PA) paradigm, demand data-collecting systems for assembling information regarding the spatial and temporal variability of those factors of influence in agricultural production [1]
This paper presents a novel methodology for identifying crop trees in low-altitude unmanned aerial vehicles (UAV)-based aerial images by means of image analysis techniques, with the ability to automatically delineate those tree crowns detected, enabling the estimation of features related to the size and morphology of each individual canopy
Notwithstanding, the differences are so insignificant for the three crops that they are hardly attributable to the developed methodology, and they may be related to the ground-truth images
Summary
Modern agricultural practices developed around the precision agriculture (PA) paradigm, demand data-collecting systems for assembling information regarding the spatial and temporal variability of those factors of influence in agricultural production [1] This datadriven approach is aimed at developing decision-making frameworks to help farmers with their daily tasks [2], supporting the eventual optimisation of the farming-inputs management and favouring the improvement of the overall agricultural activity in terms of crop productivity, sustainability, and profitability [3]. Extensive related research has been carried out on the development of solutions aimed at improving farming processes, by developing decision support models by means of remotely sensed data [6,7,8,9,10,11] In this sense, aerial remote sensing has had a pivotal role in agriculture over time. Initial applications, which focused mainly on the land cover classification [13,14] distinguishing between types of crops and vegetation present in the surveyed fields, soon became more complex as technology advances allowed higher spatial resolution and increased computational power, necessary for processing and analysing the collected data
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