Significant spatial co-distribution pattern discovery

Jiannan Cai; Yiqun Xie; Min Deng; Xun Tang; Yan Li; Shashi Shekhar

doi:10.1016/j.compenvurbsys.2020.101543

Significant spatial co-distribution pattern discovery

Jiannan Cai, Yiqun Xie, Min Deng, Xun Tang, Yan Li, Shashi Shekhar

Computer Science and Engineering

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

Given instances (spatial points) of different spatial features (categories), significant spatial co-distribution pattern discovery aims to find subsets of spatial features whose spatial distributions are statistically significantly similar to each other. Discovering significant spatial co-distribution patterns is important for many application domains such as identifying spatial associations between diseases and risk factors in spatial epidemiology. Previous methods mostly associated spatial features whose instances are frequently located together; however, this does not necessarily indicate a similarity in the spatial distributions between different features. Thus, this paper defines the significant spatial co-distribution pattern discovery problem and subsequently develops a novel method to solve it effectively. First, we propose a new measure, dissimilarity index, to quantify the difference between spatial distributions of different features under the spatial neighbor relation and then employ it in a distribution clustering method to detect candidate spatial co-distribution patterns. To further remove spurious patterns that occur accidentally, the validity of each candidate spatial co-distribution pattern is verified through a significance test under the null hypothesis that spatial distributions of different features are independent of each other. To model the null hypothesis, a distribution shift-correction method is presented by randomizing the relationships between different features and maintaining spatial structure of each feature (e.g., spatial auto-correlation). Comparisons with baseline methods using synthetic datasets demonstrate the effectiveness of the proposed method. A case study identifying co-morbidities in central Colorado is also presented to illustrate the real-world applicability of the proposed method.

Original language	English (US)
Article number	101543
Journal	Computers, Environment and Urban Systems
Volume	84
DOIs	https://doi.org/10.1016/j.compenvurbsys.2020.101543
State	Published - Nov 2020

Bibliographical note

Funding Information:
This study was funded through support from the National Natural Science Foundation of China (NSFC) [ 41730105 , 41471385 ]; National Key Research and Development Foundation of China [ 2017YFB0503503 ]; U.S. National Science Foundation (NSF) [ 1737633 , 0940818 , 1029711 , 1541876 , IIS-1218168 , IIS-1320580 ]; Advanced Research Projects Agency - Energy, U.S. Department of Energy [ DE-AR0000795 ]; U.S. Department of Defense [ HM0210-13-1-0005 , HM1582-08-1-0017 ]; U.S. Department of Agriculture [ 2017-51181-27222 ]; U.S. National Institute of Health [ KL2 TR002492 , TL1 TR002493 , UL1 TR002494 ]; OVPR Infrastructure Investment Initiative, University of Minnesota; Minnesota Supercomputing Institute (MSI), University of Minnesota. We would like to thank the reviewers and the members of the spatial computing research group at the University of Minnesota for their helpful comments. We also thank Kim Koffolt for improving the readability of this article.

Funding Information:
This study was funded through support from the National Natural Science Foundation of China (NSFC) [41730105, 41471385]; National Key Research and Development Foundation of China [2017YFB0503503]; U.S. National Science Foundation (NSF) [1737633, 0940818, 1029711, 1541876, IIS-1218168, IIS-1320580]; Advanced Research Projects Agency - Energy, U.S. Department of Energy [DE-AR0000795]; U.S. Department of Defense [HM0210-13-1-0005, HM1582-08-1-0017]; U.S. Department of Agriculture [2017-51181-27222]; U.S. National Institute of Health [KL2 TR002492, TL1 TR002493, UL1 TR002494]; OVPR Infrastructure Investment Initiative, University of Minnesota; Minnesota Supercomputing Institute (MSI), University of Minnesota. We would like to thank the reviewers and the members of the spatial computing research group at the University of Minnesota for their helpful comments. We also thank Kim Koffolt for improving the readability of this article.

Publisher Copyright:
© 2020 Elsevier Ltd

Keywords

Co-distribution patterns
Significance test
Spatial association
Spatial clustering
Spatial data mining

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title = "Significant spatial co-distribution pattern discovery",

abstract = "Given instances (spatial points) of different spatial features (categories), significant spatial co-distribution pattern discovery aims to find subsets of spatial features whose spatial distributions are statistically significantly similar to each other. Discovering significant spatial co-distribution patterns is important for many application domains such as identifying spatial associations between diseases and risk factors in spatial epidemiology. Previous methods mostly associated spatial features whose instances are frequently located together; however, this does not necessarily indicate a similarity in the spatial distributions between different features. Thus, this paper defines the significant spatial co-distribution pattern discovery problem and subsequently develops a novel method to solve it effectively. First, we propose a new measure, dissimilarity index, to quantify the difference between spatial distributions of different features under the spatial neighbor relation and then employ it in a distribution clustering method to detect candidate spatial co-distribution patterns. To further remove spurious patterns that occur accidentally, the validity of each candidate spatial co-distribution pattern is verified through a significance test under the null hypothesis that spatial distributions of different features are independent of each other. To model the null hypothesis, a distribution shift-correction method is presented by randomizing the relationships between different features and maintaining spatial structure of each feature (e.g., spatial auto-correlation). Comparisons with baseline methods using synthetic datasets demonstrate the effectiveness of the proposed method. A case study identifying co-morbidities in central Colorado is also presented to illustrate the real-world applicability of the proposed method.",

keywords = "Co-distribution patterns, Significance test, Spatial association, Spatial clustering, Spatial data mining",

author = "Jiannan Cai and Yiqun Xie and Min Deng and Xun Tang and Yan Li and Shashi Shekhar",

note = "Funding Information: This study was funded through support from the National Natural Science Foundation of China (NSFC) [ 41730105 , 41471385 ]; National Key Research and Development Foundation of China [ 2017YFB0503503 ]; U.S. National Science Foundation (NSF) [ 1737633 , 0940818 , 1029711 , 1541876 , IIS-1218168 , IIS-1320580 ]; Advanced Research Projects Agency - Energy, U.S. Department of Energy [ DE-AR0000795 ]; U.S. Department of Defense [ HM0210-13-1-0005 , HM1582-08-1-0017 ]; U.S. Department of Agriculture [ 2017-51181-27222 ]; U.S. National Institute of Health [ KL2 TR002492 , TL1 TR002493 , UL1 TR002494 ]; OVPR Infrastructure Investment Initiative, University of Minnesota; Minnesota Supercomputing Institute (MSI), University of Minnesota. We would like to thank the reviewers and the members of the spatial computing research group at the University of Minnesota for their helpful comments. We also thank Kim Koffolt for improving the readability of this article. Funding Information: This study was funded through support from the National Natural Science Foundation of China (NSFC) [41730105, 41471385]; National Key Research and Development Foundation of China [2017YFB0503503]; U.S. National Science Foundation (NSF) [1737633, 0940818, 1029711, 1541876, IIS-1218168, IIS-1320580]; Advanced Research Projects Agency - Energy, U.S. Department of Energy [DE-AR0000795]; U.S. Department of Defense [HM0210-13-1-0005, HM1582-08-1-0017]; U.S. Department of Agriculture [2017-51181-27222]; U.S. National Institute of Health [KL2 TR002492, TL1 TR002493, UL1 TR002494]; OVPR Infrastructure Investment Initiative, University of Minnesota; Minnesota Supercomputing Institute (MSI), University of Minnesota. We would like to thank the reviewers and the members of the spatial computing research group at the University of Minnesota for their helpful comments. We also thank Kim Koffolt for improving the readability of this article. Publisher Copyright: {\textcopyright} 2020 Elsevier Ltd",

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AU - Xie, Yiqun

AU - Deng, Min

AU - Tang, Xun

AU - Li, Yan

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N2 - Given instances (spatial points) of different spatial features (categories), significant spatial co-distribution pattern discovery aims to find subsets of spatial features whose spatial distributions are statistically significantly similar to each other. Discovering significant spatial co-distribution patterns is important for many application domains such as identifying spatial associations between diseases and risk factors in spatial epidemiology. Previous methods mostly associated spatial features whose instances are frequently located together; however, this does not necessarily indicate a similarity in the spatial distributions between different features. Thus, this paper defines the significant spatial co-distribution pattern discovery problem and subsequently develops a novel method to solve it effectively. First, we propose a new measure, dissimilarity index, to quantify the difference between spatial distributions of different features under the spatial neighbor relation and then employ it in a distribution clustering method to detect candidate spatial co-distribution patterns. To further remove spurious patterns that occur accidentally, the validity of each candidate spatial co-distribution pattern is verified through a significance test under the null hypothesis that spatial distributions of different features are independent of each other. To model the null hypothesis, a distribution shift-correction method is presented by randomizing the relationships between different features and maintaining spatial structure of each feature (e.g., spatial auto-correlation). Comparisons with baseline methods using synthetic datasets demonstrate the effectiveness of the proposed method. A case study identifying co-morbidities in central Colorado is also presented to illustrate the real-world applicability of the proposed method.

AB - Given instances (spatial points) of different spatial features (categories), significant spatial co-distribution pattern discovery aims to find subsets of spatial features whose spatial distributions are statistically significantly similar to each other. Discovering significant spatial co-distribution patterns is important for many application domains such as identifying spatial associations between diseases and risk factors in spatial epidemiology. Previous methods mostly associated spatial features whose instances are frequently located together; however, this does not necessarily indicate a similarity in the spatial distributions between different features. Thus, this paper defines the significant spatial co-distribution pattern discovery problem and subsequently develops a novel method to solve it effectively. First, we propose a new measure, dissimilarity index, to quantify the difference between spatial distributions of different features under the spatial neighbor relation and then employ it in a distribution clustering method to detect candidate spatial co-distribution patterns. To further remove spurious patterns that occur accidentally, the validity of each candidate spatial co-distribution pattern is verified through a significance test under the null hypothesis that spatial distributions of different features are independent of each other. To model the null hypothesis, a distribution shift-correction method is presented by randomizing the relationships between different features and maintaining spatial structure of each feature (e.g., spatial auto-correlation). Comparisons with baseline methods using synthetic datasets demonstrate the effectiveness of the proposed method. A case study identifying co-morbidities in central Colorado is also presented to illustrate the real-world applicability of the proposed method.

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Significant spatial co-distribution pattern discovery

Abstract

Bibliographical note

Keywords

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