3PG-MT-LSTM: A Hybrid Model under Biomass Compatibility Constraints for the Prediction of Long-Term Forest Growth to Support Sustainable Management

Qin, Jushuang; Ma, Menglu; Zhu, Yanhui; Wu, Baoguo; Su, Xiaohui

doi:10.3390/f14071482

Cited by 3 publications

(1 citation statement)

References 74 publications

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“…Models of individual trees are required to describe the basic attributes of trees [35,[49][50][51][52][53][54][55] as well as entire forests [48]. These models are essential in forestry [56] because they can facilitate decision-making in sustainable forestry practice, as well as estimating forest biomass yields [57][58][59].…”

Section: Literature Reviewmentioning

confidence: 99%

Modeling the Geometry of Individual Tree Trunks Using LiDAR Data

Tarsha Kurdi,

Gharineiat,

Lewandowicz

et al. 2023

Preprint

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Effective development of digital twins of real-world objects requires sophisticated data collection techniques and algorithms for automated modeling of individual objects. In City Information Modeling (CIM) systems, individual buildings can be modeled automatically at the second Level Of Detail or LOD 2. Similarly, automated solutions for 3D modeling of individual trees at different levels of details are required for Tree Information Modeling (TIM) and building Forest Digital Twins (FDT). The existing algorithms support the automated modeling of trees by generating models of the canopy and the lower part of the trunk. Our work in this paper is based on the assumption that, similar to the canopy shape, the structure of tree trunk and branches is also an important consideration. An algorithm for automated modeling of tree trunks is proposed. Aiming to generate 3D models of tree trunks, the suggested approach starts by extracting the trunk point cloud, which is then segmented into single stems. Finally, the individual stems are modeled by dividing them into slices. The geometry of the developed tree models is represented in a matrix format. This solution enables automatic comparisons of tree elements over time, which is necessary for monitoring changes in forest stands and promoting sustainable forest management. Despite the huge variation of trunk geometric forms, the proposed modeling approach can gain an accuracy of better than 4 cm in the constructed tree trunk models.

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