Abstract
High-resolution UAV imagery paired with a convolutional neural network approach offers significant advantages in accurately measuring forestry ecosystems. Despite numerous studies existing for individual tree crown delineation, species classification, and quantity detection, the comprehensive situation in performing the above tasks simultaneously has rarely been explored, especially in mixed forests. In this study, we propose a new method for individual tree segmentation and identification based on the improved Mask R-CNN. For the optimized network, the fusion type in the feature pyramid network is modified from down-top to top-down to shorten the feature acquisition path among the different levels. Meanwhile, a boundary-weighted loss module is introduced to the cross-entropy loss function Lmask to refine the target loss. All geometric parameters (contour, the center of gravity and area) associated with canopies ultimately are extracted from the mask by a boundary segmentation algorithm. The results showed that F1-score and mAP for coniferous species were higher than 90%, and that of broadleaf species were located between 75–85.44%. The producer’s accuracy of coniferous forests was distributed between 0.8–0.95 and that of broadleaf ranged in 0.87–0.93; user’s accuracy of coniferous was distributed between 0.81–0.84 and that of broadleaf ranged in 0.71–0.76. The total number of trees predicted was 50,041 for the entire study area, with an overall error of 5.11%. The method under study is compared with other networks including U-net and YOLOv3. Results in this study show that the improved Mask R-CNN has more advantages in broadleaf canopy segmentation and number detection.
Highlights
Forests play a key role in maintaining the natural environment, such as carbon storage, water cycle, soil conservation, and timber production [1,2]
The precision and recall ratio of Sophora japonica, Salix matsudana, Ailanthus altissima, Amygdalus davidiana ranged between 80.02% and 85.44%, and the F1-score and mean average precision (mAP) between 80% and 84%, slightly lower than those of coniferous species
Theresults resultsshow showthat thatthe theaccuracy accuracyof ofindividual individual tree of of thethe brightness variation tree prediction is higher than 90% when the brightness varies over the range of [0.6, 1.25]
Summary
Forests play a key role in maintaining the natural environment, such as carbon storage, water cycle, soil conservation, and timber production [1,2]. Since forests have a great influence upon the human environment in many ways, it becomes critical to obtain accurate value at the single tree aspect—with key characteristics such as tree species, canopy size and the number of trees. The accuracy of tree count determines biomass assessment in the whole forest area. The numbers of all tree species measured by field survey and prediction approach are shown, which shows that the average error of coniferous species (3.7%) is smaller than that of broad-leaved species (7.9%). 4.3 Accuracy Evaluation of Tree Count Detection (3.7%) is smaller than that of broad-leaved species (7.9%). Pinus armandii had the smallest mean error of 2.1%, andand
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