A Delaunay diagram-based Min-Max CP-Tree algorithm for Spatial Data Analysis

Co‐location patterns are the subsets of Boolean spatial features whose instances are often located in close geographic proximity. Neighborhood is a major challenge and a key part of spatial co‐location pattern mining. In existing conventional models, the neighborhood was defined by the user which is...

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Veröffentlicht in:	Wiley interdisciplinary reviews. Data mining and knowledge discovery 2015-05, Vol.5 (3), p.142-154
Hauptverfasser:	Sundaram, Venkatesan Meenakshi, Thangavelu, Arunkumar
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Sprache:	eng
Schlagworte:	Algorithms Boolean algebra Data analysis Data mining Landslides Neighborhoods Pattern analysis Performance enhancement Set theory Software development tools Spatial data
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creator	Sundaram, Venkatesan Meenakshi Thangavelu, Arunkumar
description	Co‐location patterns are the subsets of Boolean spatial features whose instances are often located in close geographic proximity. Neighborhood is a major challenge and a key part of spatial co‐location pattern mining. In existing conventional models, the neighborhood was defined by the user which is not suitable for massive data set. The idea of this paper is to improve the performance of co‐location mining by proposing novel neighborhood model and effective co‐location algorithm for spatial data analysis. The first methodology is to model the neighborhood of spatial data by using Delaunay diagram geometry approach. Delaunay‐based neighborhood model finds the neighborhoods dynamically and avoids user‐based neighborhood. The second methodology is to present novel efficient Min–Max CP‐Tree algorithm to discover precise co‐location patterns from spatial data. The proposed co‐location mining algorithm is effective and efficient for complex landslide spatial data. WIREs Data Mining Knowl Discov 2015, 5:142–154. doi: 10.1002/widm.1151 This article is categorized under: Algorithmic Development > Spatial and Temporal Data Mining Application Areas > Data Mining Software Tools Technologies > Association Rules
doi_str_mv	10.1002/widm.1151
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subjects	Algorithms Boolean algebra Data analysis Data mining Landslides Neighborhoods Pattern analysis Performance enhancement Set theory Software development tools Spatial data
title	A Delaunay diagram-based Min-Max CP-Tree algorithm for Spatial Data Analysis
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