Abstract
Relating ground photographs to UAV orthomosaics is a key linkage required for accurate multi-scaled lichen mapping. Conventional methods of multi-scaled lichen mapping, such as random forest models and convolutional neural networks, heavily rely on pixel DN values for classification. However, the limited spectral range of ground photos requires additional characteristics to differentiate lichen from spectrally similar objects, such as bright logs. By applying a neural network to tiles of a UAV orthomosaics, additional characteristics, such as surface texture and spatial patterns, can be used for inferences. Our methodology used a neural network (UAV LiCNN) trained on ground photo mosaics to predict lichen in UAV orthomosaic tiles. The UAV LiCNN achieved mean user and producer accuracies of 85.84% and 92.93%, respectively, in the high lichen class across eight different orthomosaics. We compared the known lichen percentages found in 77 vegetation microplots with the predicted lichen percentage calculated from the UAV LiCNN, resulting in a R2 relationship of 0.6910. This research shows that AI models trained on ground photographs effectively classify lichen in UAV orthomosaics. Limiting factors include the misclassification of spectrally similar objects to lichen in the RGB bands and dark shadows cast by vegetation.
Highlights
Recent studies have indicated that the mapping of caribou lichen is vital for sustainable land management and caribou recovery plans [1,2,3,4,5]
Prediction mosaics using the Unmanned Aerial Vehicles (UAVs) Lichen Convolutional Neural Network (LiCNN) were created from the orthomosaics of the eight sites
This study demonstrated that a neural network trained on ground photos could classify lichen cover percentages in UAV orthomosaics with high accuracy
Summary
Recent studies have indicated that the mapping of caribou lichen is vital for sustainable land management and caribou recovery plans [1,2,3,4,5]. Digital ground photographs of vegetation microplots can be used to infer localized knowledge across broader landscapes, such as large-scale vegetation patterns and plant classifications [7]. These photographs have ultra-high spatial resolution (mm) by nature, and allow scientists or artificial intelligence to classify plant species in the survey location with high accuracy [7]. This information can be used to inform classification models operating at lower resolution over the same area, such as aerial or satellite imagery
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