Dynamic cluster recognition with multiple self-organising maps

Cosimo Distante; Pietro Siciliano; Krishna C. Persaud

doi:10.1007/s100440200027

Dynamic cluster recognition with multiple self-organising maps

Cosimo Distante, Pietro Siciliano, Krishna C. Persaud

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

Abstract

A neural architecture, based on several self-organising maps, is presented which counteracts the parameter drift problem for an array of conducting polymer gas sensors when used for odour sensing. The neural architecture is named mSom, where m is the number of odours to be recognised, and is mainly constituted of m maps; each one approximates the statistical distribution of a given odour. Competition occurs both within each map and between maps for the selection of the minimum map distance in the Euclidean space. The network (mSom) is able to adapt itself to new changes of the input probability distribution by repetitive self-training processes bused on its experience. This architecture has been tested and compared with other neural architectures, such as RBF and Fuzzy ARTMAP. The network shows long term stable behaviour, and is completely autonomous during the testing phase, where re adaptation of the neurons is needed due to the changes of the input probability distribution of the given data set.

Original language	English
Pages (from-to)	306-315
Number of pages	9
Journal	Pattern Analysis and Applications
Volume	5
Issue number	3
DOIs	https://doi.org/10.1007/s100440200027
Publication status	Published - 2002

Keywords

Drift counteraction
Electronic nose
mSom
Odour recognition
Polymer gas sensors
Self-organising map

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10.1007/s100440200027

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title = "Dynamic cluster recognition with multiple self-organising maps",

abstract = "A neural architecture, based on several self-organising maps, is presented which counteracts the parameter drift problem for an array of conducting polymer gas sensors when used for odour sensing. The neural architecture is named mSom, where m is the number of odours to be recognised, and is mainly constituted of m maps; each one approximates the statistical distribution of a given odour. Competition occurs both within each map and between maps for the selection of the minimum map distance in the Euclidean space. The network (mSom) is able to adapt itself to new changes of the input probability distribution by repetitive self-training processes bused on its experience. This architecture has been tested and compared with other neural architectures, such as RBF and Fuzzy ARTMAP. The network shows long term stable behaviour, and is completely autonomous during the testing phase, where re adaptation of the neurons is needed due to the changes of the input probability distribution of the given data set.",

keywords = "Drift counteraction, Electronic nose, mSom, Odour recognition, Polymer gas sensors, Self-organising map",

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T1 - Dynamic cluster recognition with multiple self-organising maps

AU - Distante, Cosimo

AU - Siciliano, Pietro

AU - Persaud, Krishna C.

PY - 2002

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N2 - A neural architecture, based on several self-organising maps, is presented which counteracts the parameter drift problem for an array of conducting polymer gas sensors when used for odour sensing. The neural architecture is named mSom, where m is the number of odours to be recognised, and is mainly constituted of m maps; each one approximates the statistical distribution of a given odour. Competition occurs both within each map and between maps for the selection of the minimum map distance in the Euclidean space. The network (mSom) is able to adapt itself to new changes of the input probability distribution by repetitive self-training processes bused on its experience. This architecture has been tested and compared with other neural architectures, such as RBF and Fuzzy ARTMAP. The network shows long term stable behaviour, and is completely autonomous during the testing phase, where re adaptation of the neurons is needed due to the changes of the input probability distribution of the given data set.

AB - A neural architecture, based on several self-organising maps, is presented which counteracts the parameter drift problem for an array of conducting polymer gas sensors when used for odour sensing. The neural architecture is named mSom, where m is the number of odours to be recognised, and is mainly constituted of m maps; each one approximates the statistical distribution of a given odour. Competition occurs both within each map and between maps for the selection of the minimum map distance in the Euclidean space. The network (mSom) is able to adapt itself to new changes of the input probability distribution by repetitive self-training processes bused on its experience. This architecture has been tested and compared with other neural architectures, such as RBF and Fuzzy ARTMAP. The network shows long term stable behaviour, and is completely autonomous during the testing phase, where re adaptation of the neurons is needed due to the changes of the input probability distribution of the given data set.

KW - Drift counteraction

KW - Electronic nose

KW - mSom

KW - Odour recognition

KW - Polymer gas sensors

KW - Self-organising map

U2 - 10.1007/s100440200027

DO - 10.1007/s100440200027

M3 - Article

SN - 1433-7541

VL - 5

SP - 306

EP - 315

JO - Pattern Analysis and Applications

JF - Pattern Analysis and Applications

IS - 3

ER -

Dynamic cluster recognition with multiple self-organising maps

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Keywords

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