Community Detection in Very High-Resolution Meteorological Networks

Community Detection in Very High-Resolution Meteorological Networks

Several complex dynamical systems are embedded in geographical space. Geographical data have proven its importance in several domains. For instance, the formation and scrutiny of climate networks have emerged as a new research topic in environmental literature. However, there is still a lack of inve...

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Bibliographic Details
Published in:IEEE geoscience and remote sensing letters Vol. 17; no. 11; pp. 2007 - 2010
Main Authors: Ceron, Wilson, Santos, Leonardo B. L., Neto, Giovanni Dolif, Quiles, Marcos G., Candido, Onofre A.
Format: Journal Article
Language:English
Published: Piscataway IEEE 01-11-2020
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Clustering methods
Community structure
complex networks
Correlation
Disaster management
Ecological studies
Embedding
Emergency preparedness
Geographic information systems
Geographical distribution
Geographical locations
Graphs
High resolution
Information systems
Land cover
Land surface
Land use
Meteorological data
Meteorological networks
meteorological radar
Meteorology
Networks
Nodes
Properties
Radar
Radar data
Radar remote sensing
Rain
Rainfall
Rainfall data
Resolution
Risk management
Risk reduction
Spatial discrimination
Spatial resolution
Surface topography
Surface treatment
Sustainable development
Topology
Urban planning
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Summary:Several complex dynamical systems are embedded in geographical space. Geographical data have proven its importance in several domains. For instance, the formation and scrutiny of climate networks have emerged as a new research topic in environmental literature. However, there is still a lack of investigations of scenarios with very high spatial resolution, such as those considering meteorological data. Recently, a new concept, named (geo)graphs, was proposed. (Geo)graphs are graphs, or networks, in which the nodes have an assigned geographical location. Besides embedding nodes into space, these graphs are readily manipulated with a geographical information system, and, thus, represent a suitable tool for dealing with very high-resolution scenarios, such as meteorological data. In this context, here, we apply a (geo)graph approach to model a radar-derived rainfall data set. We represent the nodes as a point-type shapefile and the edges as a line-type shapefile, which are standard file types in geoinformatics. After, we analyze the topological properties of a family of (geo)graphs considering distinct thresholds. The analysis of these networks reveals a spatially well-defined community structure, which, interestingly, is consistent with topographical/altimetric and land use/land cover data. These results show the relation between geographical properties and the topological structure of the network might be applied to different ecological studies, from sustainable development to urban planning and disaster risk reduction.
ISSN:1545-598X
1558-0571
DOI:10.1109/LGRS.2019.2955508