Accelerated Smoke Simulation by Super-Resolution With Deep Learning on Downscaled and Binarized Space
- Authors
- Hong, Byeong-Sun; Zhang, Qimeng; Kim, Chang-Hun; Lee, Jung; Kim, Jong-Hyun
- Issue Date
- 2021
- Publisher
- IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
- Keywords
- Octrees; Mathematical model; Adaptation models; Three-dimensional displays; Computational modeling; Data models; Numerical models; Fluid simulations; deep learning; super-resolution; adaptive synthesizing; octree; physics-based simulations
- Citation
- IEEE ACCESS, v.9, pp.98615 - 98629
- Indexed
- SCIE
SCOPUS
- Journal Title
- IEEE ACCESS
- Volume
- 9
- Start Page
- 98615
- End Page
- 98629
- URI
- https://scholar.korea.ac.kr/handle/2021.sw.korea/130017
- DOI
- 10.1109/ACCESS.2021.3095904
- ISSN
- 2169-3536
- Abstract
- In this paper, we propose a highly efficient method for synthesizing high-resolution(HR) smoke simulations based on deep learning. A major issue for physics-based HR fluid simulations is that they require large amounts of physical memory and long execution times. In recent years, this issue has been addressed by developing deep-learning-based super-resolution(SR) methods that convert low-resolution(LR) fluid simulation results to HR(High-resolution) versions. However, these methods were not very efficient because they performed operations even in areas with low density or no density. In this paper, we propose a method that can maximize its efficiency by introducing a downscaled and binarized adaptive octree. However, even if it is divided by octree, because the number of nodes increases when the resolution of the simulation space is large, we reduce the size of the space by multiscaling and at the same time perform binarization to preserve the density that may be lost in this process. The octree calculated in this process has a structure similar to that of a multigrid solver, and the octree calculated at coarse resolution is restored to its original size and used for HR expression. Finally, we apply the SR process only to those areas having significant density values. Using the proposed method, the SR process is significantly faster and the memory efficiency is improved. The performance of our method is compared with that of an existing SR method to demonstrate its efficiency.
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Collections - Graduate School > Department of Computer Science and Engineering > 1. Journal Articles
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