Exploring Non-Linear Dependencies in Atmospheric Data with Mutual Information

Petri Laarne; Emil Amnell; Martha Arbayani Zaidan; Santtu Mikkonen; Tuomo Nieminen

doi:10.3390/atmos13071046

Exploring Non-Linear Dependencies in Atmospheric Data with Mutual Information

Petri Laarne, Emil Amnell, Martha Arbayani Zaidan, Santtu Mikkonen, Tuomo Nieminen

Forskningsoutput: Tidskriftsbidrag › Artikel › Vetenskaplig › Peer review

Sammanfattning

Relations between atmospheric variables are often non-linear, which complicates research efforts to explore and understand multivariable datasets. We describe a mutual information approach to screen for the most significant associations in this setting. This method robustly detects linear and non-linear dependencies after minor data quality checking. Confounding factors and seasonal cycles can be taken into account without predefined models. We present two case studies of this method. The first one illustrates deseasonalization of a simple time series, with results identical to the classical method. The second one explores associations in a larger dataset of many variables, some of them lognormal (trace gas concentrations) or circular (wind direction). The examples use our Python package 'ennemi'.

Originalspråk	engelska
Artikelnummer	1046
Tidskrift	Atmosphere
Volym	13
Nummer	7
Antal sidor	13
ISSN	2073-4433
DOI	https://doi.org/10.3390/atmos13071046
Status	Publicerad - juli 2022
MoE-publikationstyp	A1 Tidskriftsartikel-refererad

Vetenskapsgrenar

1172 Miljövetenskap
114 Fysik
1171 Geovetenskaper
112 Statistik

Åtkomst av dokument

10.3390/atmos13071046Licens: CC BY

Supplementary materialSlutlig publicerad version, 4,88 MBLicens: !!Unspecified

http://hdl.handle.net/10138/346021Licens: CC BY

Citera det här

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title = "Exploring Non-Linear Dependencies in Atmospheric Data with Mutual Information",

abstract = "Relations between atmospheric variables are often non-linear, which complicates research efforts to explore and understand multivariable datasets. We describe a mutual information approach to screen for the most significant associations in this setting. This method robustly detects linear and non-linear dependencies after minor data quality checking. Confounding factors and seasonal cycles can be taken into account without predefined models. We present two case studies of this method. The first one illustrates deseasonalization of a simple time series, with results identical to the classical method. The second one explores associations in a larger dataset of many variables, some of them lognormal (trace gas concentrations) or circular (wind direction). The examples use our Python package 'ennemi'.",

keywords = "1172 Environmental sciences, 114 Physical sciences, 1171 Geosciences, 112 Statistics and probability, correlation detection, variable selection, mutual information, exploratory data analysis, PARTICLE FORMATION, STATION, SINK",

author = "Petri Laarne and Emil Amnell and Zaidan, {Martha Arbayani} and Santtu Mikkonen and Tuomo Nieminen",

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AU - Nieminen, Tuomo

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