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Graph induced complex on point data

Authors:

Tamal Krishna Dey,

Yusu WangAuthors Info & Claims

SoCG '13: Proceedings of the twenty-ninth annual symposium on Computational geometry

Pages 107 - 116

https://doi.org/10.1145/2462356.2462387

Published: 17 June 2013 Publication History

Abstract

The efficiency of extracting topological information from point data depends largely on the complex that is built on top of the data points. From a computational viewpoint, the most favored complexes for this purpose have so far been Vietoris-Rips and witness complexes. While the ietoris-Rips complex is simple to compute and is a good vehicle for extracting topology of sampled spaces, its size is huge--particularly in high dimensions. The witness complex on the other hand enjoys a smaller size because of a subsampling, but fails to capture the topology in high dimensions unless imposed with extra structures. We investigate a complex called the graph induced complex that, to some extent, enjoys the advantages of both. It works on a subsample but still retains the power of capturing the topology as the Vietoris-Rips complex. It only needs a graph connecting the original sample points from which it builds a complex on the subsample thus taming the size considerably. We show that, using the graph induced complex one can (i) infer the one-dimensional homology of a manifold from a very lean subsample, (ii) reconstruct a surface in three dimension from a sparse subsample without computing Delaunay triangulations, (iii) infer the persistent homology groups of compact sets from a sufficiently dense sample. We provide experimental evidences in support of our theory.

References

[1]

H. Adams and G. Carlsson. On the nonlinear statistics of range image patches. SIAM J. Img. Sci., 2(1):110--117, January 2009.

Digital Library

[2]

N. Amenta, S. Choi, T. K. Dey, and N. Leekha. A simple algorithm for homeomorphic surface reconstruction. Int. J. Comput. Geom. Appl., 12:125--141, 2002.

[3]

D. Attali, A. Lieutier, and D. Salinas. Vietoris-rips complexes also provide topologically correct reconstruction of sampled shapes. In Proc. 27th Annu. Sympos. Comput. Geom., pages 491--500, 2011.

Digital Library

[4]

J.-D. Boissonnat, L. J. Guibas, and S. Y. Oudot. Manifold reconstruction in arbitrary dimensions using witness complexes. Discrete Comput. Geom., 42:37--70, 2009.

Digital Library

[5]

J.-D. Boissonnat and C. Maria. The simplex tree : An efficient data structure for general simplicial complexes. In Proc. ESA, Lecture Notes in Computer Science, pages 731--742, 2012.

Digital Library

[6]

G. Carlsson and V. de Silva. Topological approximation by small simplicial complexes. preprint, 2003.

[7]

F. Chazal, L. J. Guibas, S. Y. Oudot, and P. Skraba. Analysis of scalar fields over point cloud data. Discrete Comput. Geom., 46:743--775, 2011.

Digital Library

[8]

F. Chazal and A. Lieutier. The lambda-medial axis. Graph. Models, 67:304--331, 2005.

Digital Library

[9]

F. Chazal and S. Oudot. Towards persistence-based reconstruction in euclidean spaces. In Proc. 24th Ann. Sympos. Comput. Geom., pages 232--241, 2008.

Digital Library

[10]

S.-W. Cheng, T. K. Dey, and E. A. Ramos. Manifold reconstruction from point samples. In Proc. 16th Sympos. Discrete Algorithms, pages 1018--1027, 2005.

Digital Library

[11]

D. Cohen-Steiner, H. Edelsbrunner, and J. L. Harer. Stability of persistence diagrams. Discrete Comput. Geom., 37:103--120, 2007.

Digital Library

[12]

V. de Silva and G. Carlsson. Topological estimation using witness complexes. In Proc. Sympos. Point Based Graphics, pages 157--166, 2004.

Digital Library

[13]

T. K. Dey. Curve and Surface Reconstruction : Algorithms with Mathematical Analysis. Cambridge University Press, New York, 2007.

Digital Library

[14]

T. K. Dey, F. Fan, and Y. Wang. Computing topological persistence for simplicial maps. arXiv:1208.5018v3 {cs.CG}, 2013.

[15]

T. K. Dey and Y. Wang. Reeb graphs: approximation and persistence. In Proc. 27th Annu. Sympos. Comput. Geom., pages 226--235, 2011. Extended version available from authors' web-pages.

Digital Library

[16]

H. Edelsbrunner and J. Harer. Computational Topology. American Mathematical Society, 2009.

[17]

Q. Fang, J. Gao, L. Guibas, V. de Silva, and L. Zhang. Glider: gradient landmark-based distributed routing for sensor networks. In Proc. INFOCOM 2005, pages 339--350, 2005.

[18]

J. Gao, L. Guibas, S. Oudot, and Y. Wang. Geodesic delaunay triangulation and witness complex in the plane. Trans. Algorithms (TALG), 6(4):1--47, August 2010.

Digital Library

[19]

R. Ghrist. Barcodes: The persistent topology of data. Bull. Amer. Math. Soc., 45:61--75, 2008.

[20]

T. Gonzalez. Clustering to minimize the maximum inter-cluster distance. Theoretical Computer Science, 38:293--306, 1985.

[21]

J.-C. Hausmann. On the vietoris-rips complexes and a cohomology theory for metric spaces. In Prospects in topology: Proc. Conf., pages 175--188, 1994.

[22]

J. R. Munkres. Elements of Algebraic Topology. Addison-Wesley Publishing Company, Menlo Park, 1984.

[23]

D. Sheehy. Linear-size approximations to the vietoris-rips filtration. In Proc. 28th. Annu. Sympos. Comput. Geom., pages 239--247, 2012.

Digital Library

Cited By

Choi JChen YFrías JCastillo JGel Y(2024)Revisiting Link Prediction with the Dowker ComplexAdvances in Knowledge Discovery and Data Mining10.1007/978-981-97-2253-2_33(418-430)Online publication date: 25-Apr-2024
https://doi.org/10.1007/978-981-97-2253-2_33
Singh RWilsey P(2022)Polytopal Complex Construction and Use in Persistent Homology2022 IEEE International Conference on Data Mining Workshops (ICDMW)10.1109/ICDMW58026.2022.00087(634-641)Online publication date: Nov-2022
https://doi.org/10.1109/ICDMW58026.2022.00087
Singh RWilsey P(2022)Persistence Homology of Proximity Hyper-Graphs for Higher Dimensional Big Data2022 IEEE International Conference on Big Data (Big Data)10.1109/BigData55660.2022.10020926(65-74)Online publication date: 17-Dec-2022
https://doi.org/10.1109/BigData55660.2022.10020926
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Index Terms

Graph induced complex on point data
1. Theory of computation
  1. Randomness, geometry and discrete structures
    1. Computational geometry

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Published In

cover image ACM Conferences

SoCG '13: Proceedings of the twenty-ninth annual symposium on Computational geometry

June 2013

472 pages

ISBN:9781450320313

DOI:10.1145/2462356

General Chairs:
Guilherme D. da Fonseca
UNIRIO
,
Thomas Lewiner
PUC-Rio
,
Luis Peñaranda
IMPA
,
Program Chairs:
Timothy Chan
University of Waterloo
,
Rolf Klein
University of Bonn

Copyright © 2013 ACM.

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Published: 17 June 2013

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SoCG '13

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SoCG '13: Symposium on Computational Geometry 2013

June 17 - 20, 2013

Rio de Janeiro, Brazil

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SoCG '13 Paper Acceptance Rate 48 of 137 submissions, 35%;

Overall Acceptance Rate 625 of 1,685 submissions, 37%

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Cited By

Choi JChen YFrías JCastillo JGel Y(2024)Revisiting Link Prediction with the Dowker ComplexAdvances in Knowledge Discovery and Data Mining10.1007/978-981-97-2253-2_33(418-430)Online publication date: 25-Apr-2024
https://doi.org/10.1007/978-981-97-2253-2_33
Singh RWilsey P(2022)Polytopal Complex Construction and Use in Persistent Homology2022 IEEE International Conference on Data Mining Workshops (ICDMW)10.1109/ICDMW58026.2022.00087(634-641)Online publication date: Nov-2022
https://doi.org/10.1109/ICDMW58026.2022.00087
Singh RWilsey P(2022)Persistence Homology of Proximity Hyper-Graphs for Higher Dimensional Big Data2022 IEEE International Conference on Big Data (Big Data)10.1109/BigData55660.2022.10020926(65-74)Online publication date: 17-Dec-2022
https://doi.org/10.1109/BigData55660.2022.10020926
Upadhyay AGoldfarb BWang WEkenna C(2022)A New Application of Discrete Morse Theory to Optimizing Safe Motion Planning PathsAlgorithmic Foundations of Robotics XV10.1007/978-3-031-21090-7_2(18-35)Online publication date: 15-Dec-2022
https://doi.org/10.1007/978-3-031-21090-7_2
Yan YIvanov KMumini Omisore OIgbe TLiu QNie ZWang L(2020)Gait Rhythm Dynamics for Neuro-Degenerative Disease Classification via Persistence Landscape- Based Topological RepresentationSensors10.3390/s2007200620:7(2006)Online publication date: 3-Apr-2020
https://doi.org/10.3390/s20072006
Yan YOmisore OXue YLi HLiu QNie ZFan JWang L(2020)Classification of Neurodegenerative Diseases via Topological Motion Analysis—A Comparison Study for Multiple Gait FluctuationsIEEE Access10.1109/ACCESS.2020.29966678(96363-96377)Online publication date: 2020
https://doi.org/10.1109/ACCESS.2020.2996667
Bendich PBubenik PWagner A(2019)Stabilizing the unstable output of persistent homology computationsJournal of Applied and Computational Topology10.1007/s41468-019-00044-9Online publication date: 9-Nov-2019
https://doi.org/10.1007/s41468-019-00044-9
Harker SKramár MLevanger RMischaikow K(2019)A comparison framework for interleaved persistence modulesJournal of Applied and Computational Topology10.1007/s41468-019-00026-xOnline publication date: 16-May-2019
https://doi.org/10.1007/s41468-019-00026-x
Carrière MOudot S(2018)Structure and Stability of the One-Dimensional MapperFoundations of Computational Mathematics10.1007/s10208-017-9370-z18:6(1333-1396)Online publication date: 1-Dec-2018
https://dl.acm.org/doi/10.1007/s10208-017-9370-z
Dey TMandal SVarcho WHullin MKlein RSchultz TYao A(2017)Improved image classification using topological persistenceProceedings of the conference on Vision, Modeling and Visualization10.2312/vmv.20171272(161-168)Online publication date: 25-Sep-2017
https://dl.acm.org/doi/10.2312/vmv.20171272
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