Self-organization maps (SOM) in the definition of a “transfer function” for a diatoms-based climate proxy

Juan David Acevedo-Acosta; Aída Martínez-López; Tomás Morales-Acoltzi; Mirtha Albáñez-Lucero; Gerardo Verdugo-Díaz

doi:10.1007/s00382-020-05482-1

Self-organization maps (SOM) in the definition of a “transfer function” for a diatoms-based climate proxy

Juan David Acevedo-Acosta, Aída Martínez-López, Tomás Morales-Acoltzi, Mirtha Albáñez-Lucero, Gerardo Verdugo-Díaz

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

2 Scopus citations

Abstract

This study utilizes self-organizing maps (SOM) —a particular type of artificial neural network (ANN) — as a nonlinear analysis tool for identifying species that can be used as proxies for climate variables. Instrumental, environmental, and biological time-series data from the Alfonso Basin (Gulf of California) were analyzed. The analysis comprised three stages: (1) standardization and selection of biological databases; (2) elimination of noise in the time series data; (3) definition of an ANN architecture and assessment of differences between models built using either noisy or noiseless time series. Noise reduction improved the SOM outputs. A global structuring index was estimated to define the associative linkage between diatoms and climate variables. The results showed that diatoms identified are the most suitable proxies for reconstructing the main climate variables including precipitation, atmospheric temperature, and sea surface temperature. The method developed has the potential to improve the hierarchization and selection of variables that can be potentially reconstructed without a significant loss of climate information.

Original language	English
Pages (from-to)	423-437
Number of pages	15
Journal	Climate Dynamics
Volume	56
Issue number	1-2
DOIs	https://doi.org/10.1007/s00382-020-05482-1
State	Published - Jan 2021
Externally published	Yes

Keywords

Artificial neural networks
Climate proxy
Nonlinear parameters for noise reduction
Parameters for optimal architecture network
Planktonic diatoms

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1007/s00382-020-05482-1

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abstract = "This study utilizes self-organizing maps (SOM) —a particular type of artificial neural network (ANN) — as a nonlinear analysis tool for identifying species that can be used as proxies for climate variables. Instrumental, environmental, and biological time-series data from the Alfonso Basin (Gulf of California) were analyzed. The analysis comprised three stages: (1) standardization and selection of biological databases; (2) elimination of noise in the time series data; (3) definition of an ANN architecture and assessment of differences between models built using either noisy or noiseless time series. Noise reduction improved the SOM outputs. A global structuring index was estimated to define the associative linkage between diatoms and climate variables. The results showed that diatoms identified are the most suitable proxies for reconstructing the main climate variables including precipitation, atmospheric temperature, and sea surface temperature. The method developed has the potential to improve the hierarchization and selection of variables that can be potentially reconstructed without a significant loss of climate information.",

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AU - Acevedo-Acosta, Juan David

AU - Martínez-López, Aída

AU - Morales-Acoltzi, Tomás

AU - Albáñez-Lucero, Mirtha

AU - Verdugo-Díaz, Gerardo

PY - 2021/1

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N2 - This study utilizes self-organizing maps (SOM) —a particular type of artificial neural network (ANN) — as a nonlinear analysis tool for identifying species that can be used as proxies for climate variables. Instrumental, environmental, and biological time-series data from the Alfonso Basin (Gulf of California) were analyzed. The analysis comprised three stages: (1) standardization and selection of biological databases; (2) elimination of noise in the time series data; (3) definition of an ANN architecture and assessment of differences between models built using either noisy or noiseless time series. Noise reduction improved the SOM outputs. A global structuring index was estimated to define the associative linkage between diatoms and climate variables. The results showed that diatoms identified are the most suitable proxies for reconstructing the main climate variables including precipitation, atmospheric temperature, and sea surface temperature. The method developed has the potential to improve the hierarchization and selection of variables that can be potentially reconstructed without a significant loss of climate information.

AB - This study utilizes self-organizing maps (SOM) —a particular type of artificial neural network (ANN) — as a nonlinear analysis tool for identifying species that can be used as proxies for climate variables. Instrumental, environmental, and biological time-series data from the Alfonso Basin (Gulf of California) were analyzed. The analysis comprised three stages: (1) standardization and selection of biological databases; (2) elimination of noise in the time series data; (3) definition of an ANN architecture and assessment of differences between models built using either noisy or noiseless time series. Noise reduction improved the SOM outputs. A global structuring index was estimated to define the associative linkage between diatoms and climate variables. The results showed that diatoms identified are the most suitable proxies for reconstructing the main climate variables including precipitation, atmospheric temperature, and sea surface temperature. The method developed has the potential to improve the hierarchization and selection of variables that can be potentially reconstructed without a significant loss of climate information.

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KW - Climate proxy

KW - Nonlinear parameters for noise reduction

KW - Parameters for optimal architecture network

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Self-organization maps (SOM) in the definition of a “transfer function” for a diatoms-based climate proxy

Abstract

Keywords

UN SDGs

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