Physics-based algorithm to simulate tree dynamics under wind load

Rapid development in the different computer science fields during the recent decades has facilitated the creation of new applications in the area of dynamic simulation of plant development. Among these new applications, simulation of trees swaying in the wind is of great importance, as those compute...

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Veröffentlicht in:International journal of agricultural and biological engineering Jg. 13; H. 2; S. 26 - 32
Hauptverfasser: Xu, Lifeng, Yang, Zhongzhu, Ding, Weilong, Buck-Sorlin, Gerhard
Format: Journal Article
Sprache:Englisch
Veröffentlicht: Beijing International Journal of Agricultural and Biological Engineering (IJABE) 2020
Schlagworte:
Algorithms
Bioinformatics
Cantilever beams
Computer & video games
Computer applications
Computer graphics
Computer Science
Computer simulation
Cultivation
Data Structures and Algorithms
Environmental Sciences
Forest management
Global Changes
Leaves
Load
Loads (forces)
Modeling and Simulation
Morphology
Noise
Physics
Realism
Simulation
Trees
Wind
Wind loads
physics-based algorithm
tree model
Cantilever beam
L-system
ISSN:1934-6344, 1934-6352
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Zusammenfassung:Rapid development in the different computer science fields during the recent decades has facilitated the creation of new applications in the area of dynamic simulation of plant development. Among these new applications, simulation of trees swaying in the wind is of great importance, as those computer graphics related areas, e.g., computer games, tree cultivation and forest management simulations, help a lot in revealing the mechanisms of tree dynamics under wind load. However, it is a big challenge to balance the effect of visualization in real time and calculation efficiency for any simulation algorithm. A physics-based algorithm to simulate tree dynamics under wind load was proposed in this study. A mechanistic model simulating the bending of a cantilever beam was used within the algorithm to simulate deformation of stems, and the algorithm was integrated with a landscape model in which different types of trees were constructed with an L-system-based formalism. Simulation results show that realistic dynamic effects can be achieved with reasonably high computational efficiency.
Bibliographie:ObjectType-Article-1
SourceType-Scholarly Journals-1
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content type line 14
ISSN:1934-6344
1934-6352
DOI:10.25165/j.ijabe.20201302.4967