Self-organizing maps as an approach to exploring spatiotemporal diffusion patterns

Abstract Background Self-organizing maps (SOMs) have now been applied for a number of years to identify patterns in large datasets; yet, their application in the spatiotemporal domain has been lagging. Here, we demonstrate how spatialtemporal disease diffusion patterns can be analysed using SOMs and...

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Main Authors: Augustijn, Ellen-Wien, Zurita-Milla, Raul
Format: Other/Unknown Material
Language:English
Published: BioMed Central Ltd. 2013
Subjects:
Online Access:http://www.ij-healthgeographics.com/content/12/1/60
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spelling ftbiomed:oai:biomedcentral.com:1476-072X-12-60 2023-05-15T16:51:10+02:00 Self-organizing maps as an approach to exploring spatiotemporal diffusion patterns Augustijn, Ellen-Wien Zurita-Milla, Raul 2013-12-23 http://www.ij-healthgeographics.com/content/12/1/60 en eng BioMed Central Ltd. http://www.ij-healthgeographics.com/content/12/1/60 Copyright 2013 Augustijn and Zurita-Milla; licensee BioMed Central Ltd. Methodology 2013 ftbiomed 2014-01-12T01:26:04Z Abstract Background Self-organizing maps (SOMs) have now been applied for a number of years to identify patterns in large datasets; yet, their application in the spatiotemporal domain has been lagging. Here, we demonstrate how spatialtemporal disease diffusion patterns can be analysed using SOMs and Sammon’s projection. Methods SOMs were applied to identify synchrony between spatial locations, to group epidemic waves based on similarity of diffusion pattern and to construct sequence of maps of synoptic states. The Sammon’s projection was used to created diffusion trajectories from the SOM output. These methods were demonstrated with a dataset that reports Measles outbreaks that took place in Iceland in the period 1946–1970. The dataset reports the number of Measles cases per month in 50 medical districts. Results Both stable and incidental synchronisation between medical districts were identified as well as two distinct groups of epidemic waves, a uniformly structured fast developing group and a multiform slow developing group. Diffusion trajectories for the fast developing group indicate a typical diffusion pattern from Reykjavik to the northern and eastern parts of the island. For the other group, diffusion trajectories are heterogeneous, deviating from the Reykjavik pattern. Conclusions This study demonstrates the applicability of SOMs (combined with Sammon’s Projection and GIS) in spatiotemporal diffusion analyses. It shows how to visualise diffusion patterns to identify (dis)similarity between individual waves and between individual waves and an overall time-series performing integrated analysis of synchrony and diffusion trajectories. Other/Unknown Material Iceland BioMed Central
institution Open Polar
collection BioMed Central
op_collection_id ftbiomed
language English
description Abstract Background Self-organizing maps (SOMs) have now been applied for a number of years to identify patterns in large datasets; yet, their application in the spatiotemporal domain has been lagging. Here, we demonstrate how spatialtemporal disease diffusion patterns can be analysed using SOMs and Sammon’s projection. Methods SOMs were applied to identify synchrony between spatial locations, to group epidemic waves based on similarity of diffusion pattern and to construct sequence of maps of synoptic states. The Sammon’s projection was used to created diffusion trajectories from the SOM output. These methods were demonstrated with a dataset that reports Measles outbreaks that took place in Iceland in the period 1946–1970. The dataset reports the number of Measles cases per month in 50 medical districts. Results Both stable and incidental synchronisation between medical districts were identified as well as two distinct groups of epidemic waves, a uniformly structured fast developing group and a multiform slow developing group. Diffusion trajectories for the fast developing group indicate a typical diffusion pattern from Reykjavik to the northern and eastern parts of the island. For the other group, diffusion trajectories are heterogeneous, deviating from the Reykjavik pattern. Conclusions This study demonstrates the applicability of SOMs (combined with Sammon’s Projection and GIS) in spatiotemporal diffusion analyses. It shows how to visualise diffusion patterns to identify (dis)similarity between individual waves and between individual waves and an overall time-series performing integrated analysis of synchrony and diffusion trajectories.
format Other/Unknown Material
author Augustijn, Ellen-Wien
Zurita-Milla, Raul
spellingShingle Augustijn, Ellen-Wien
Zurita-Milla, Raul
Self-organizing maps as an approach to exploring spatiotemporal diffusion patterns
author_facet Augustijn, Ellen-Wien
Zurita-Milla, Raul
author_sort Augustijn, Ellen-Wien
title Self-organizing maps as an approach to exploring spatiotemporal diffusion patterns
title_short Self-organizing maps as an approach to exploring spatiotemporal diffusion patterns
title_full Self-organizing maps as an approach to exploring spatiotemporal diffusion patterns
title_fullStr Self-organizing maps as an approach to exploring spatiotemporal diffusion patterns
title_full_unstemmed Self-organizing maps as an approach to exploring spatiotemporal diffusion patterns
title_sort self-organizing maps as an approach to exploring spatiotemporal diffusion patterns
publisher BioMed Central Ltd.
publishDate 2013
url http://www.ij-healthgeographics.com/content/12/1/60
genre Iceland
genre_facet Iceland
op_relation http://www.ij-healthgeographics.com/content/12/1/60
op_rights Copyright 2013 Augustijn and Zurita-Milla; licensee BioMed Central Ltd.
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