A Data Driven Characteristically Filtering Method for 3D Flow Field

doi:10.13190/j.jbupt.2019-152

JOURNAL OF BEIJING UNIVERSITY OF POSTS AND TELECOM ›› 2019, Vol. 42 ›› Issue (6): 91-97.doi: 10.13190/j.jbupt.2019-152

• Papers • Previous Articles Next Articles

A Data Driven Characteristically Filtering Method for 3D Flow Field

XIONG Guang-zheng¹, HUANG Zhi-bin¹, DAI Zhi-tao¹, YANG Wu-bing²

1. Beijing Key Laboratory of Intelligent Telecommunication Software and Multimedia, Beijing 100876, China;
2. China Academy of Aerospace Aerodynamics, Beijing 100074, China

Received:2019-07-10 Online:2019-12-28 Published:2019-11-15

Abstract

Abstract: With the wide application of fluid mechanics, more and more large-scale fine flow fields have emerged. Overlapping streamlines and dense fields make it hard to use the traditional streamline visualization methods to characterizes the flow fields or process with large-scale fine flow fields. Based on the idea of data-driven, this paper presents an algorithm to implement the characterization of large-scale fine flow fields. The algorithm characterizes streamlines obtained by widely spreading seed points, calculates the features of each point, segments the streamlines based on the features, and then constructs a set of feature vectors and a set of word vectors. Then, the algorithm calculates the geometric feature similarity between streamlines to evaluate streamline similarity and achieves streamlines filtering. Two typical application scenarios, streamline query and flow field compression, verify the proposed method.

Key words: data driven, streamline segmentation, flow field visualization, bag-of-word, large-scale fine flow field

CLC Number:

TP391.41

XIONG Guang-zheng, HUANG Zhi-bin, DAI Zhi-tao, YANG Wu-bing. A Data Driven Characteristically Filtering Method for 3D Flow Field[J]. JOURNAL OF BEIJING UNIVERSITY OF POSTS AND TELECOM, 2019, 42(6): 91-97.

References

[1] McLoughlin T, Laramee R S, Peikert R, et al. Over two decades of integration-based, geometric flow visualization[J]. Computer Graphics Forum, 2010, 29(6):1807-1829.
[2] Ye Xiangong, Kao David, Pang Alex. Strategy for seeding 3D streamlines[C]//IEEE Visualization. Minneapolis:[s.n.], 2005:471-478.
[3] Edmunds M, Laramee R S, Malki R, et al. Automatic stream surface seeding:a feature centered approach[J]. Computer Graphics Forum, 2012, 31(3pt2):1095-1104.
[4] 郭雨蒙, 王文珂, 李思昆. 基于相似度引导的流线种子点并行分布方法[J]. 系统仿真学报, 2014, 26(9):2155-2159. Guo Yumeng, Wang Wenke, Li Sikun. Parallel strategy of streamline seeding with similarity-guiding[J]. Journal of System Simulation, 2014, 26(9):2155-2159.
[5] Marchesin S, Chen C K, Ho C, et al. View-dependent streamlines for 3D vector fields[J]. IEEE Transactions on Visualization and Computer Graphics, 2010, 16(6):1578-1586.
[6] 李春鑫, 彭认灿, 高占胜, 等. 一种改进的三维流场数据可视化方法[J]. 武汉大学学报(信息科学版), 2017, 42(6):744-748. Li Chunxin, Peng Rencan, Gao Zhansheng, et al. An improved legible method for visualizing 3D flow field[J]. Geomatics and Information Science of Wuhan University, 2017, 42(6):744-748.
[7] Li Yifei, Wang Chaoli, Shene C K. Extracting flow features via supervised streamline segmentation[J]. Computers & Graphics, 2015(52):79-92.
[8] Yu H, Wang C, Shene C K, et al. Hierarchical streamline bundles for visualizing 2D flow fields[C]//IEEE VisWeek 2010 Posters. Salt Lake City:[s.n.], 2010.
[9] Rossl C, Theisel H. Streamline embedding for 3D vector field exploration[J]. IEEE Transactions on Visualization and Computer Graphics, 2012, 18(3):407-420.
[10] Liu Shiguang, Song Hange. Streamline querying based on finite substructures[J]. Journal of Visualization, 2019, 22(3):571-585.
[11] Li Yifei. Extracting flow features using bag-of-features and supervised learning techniques[D]. Michigan:Open Access Dissertation, Michigan Technological University, 2015.
[12] Han Jun, Tao Jun, Zheng Hao, et al. Flow field reduction via reconstructing vector data from 3D streamlines using deep learning[J]. IEEE Computer Graphics and Applications, 2019, 39(4):54-67.
[13] Wang Zhongjie, Martinez Esturo J, Seidel H P, et al. Pattern search in flows based on similarity of stream line segments[C]//Proc Vision, Modeling and Visualization. Darmstadt, Germany:[s.n.], 2014:23-30.
[14] Li Yifei, Wang Chaoli, Shene C K. Streamline similarity analysis using bag-of-features[C]//Proc SPIE 9017, Visualization and Data Analysis 2014. San Francisco, California:[s.n.], 2014:90170N.
[15] Tang Bin. Parallel visualization of flow field based on streamline similarity[J]. International Journal of Performability Engineering, 2018, 14(4):717-728.
[16] Han Jun, Tao Jun, Zheng Hao, et al. Flow field reduction via reconstructing vector data from 3D streamlines using deep learning[J]. IEEE Computer Graphics and Applications, 2019, 39(4):54-67.
[17] Han Jun, Tao Jun, Wang Chaoli. FlowNet:a deep learning framework for clustering and selection of streamlines and stream surfaces[EB/OL]. 2018(2018-11-12)[2019-05-23]. https://doi.org/10.1109/TVCG.2018.2880207.

A Data Driven Characteristically Filtering Method for 3D Flow Field

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 1

Recommended Articles

Metrics

Comments