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Main Authors: Ammar, Wiem Haj, Boujnah, Aicha, Baron, Antoine, Boubaker, Aimen, Kalboussi, Adel, Lmimouni, Kamal, Pecqueur, Sebastien
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2401.00684
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author Ammar, Wiem Haj
Boujnah, Aicha
Baron, Antoine
Boubaker, Aimen
Kalboussi, Adel
Lmimouni, Kamal
Pecqueur, Sebastien
author_facet Ammar, Wiem Haj
Boujnah, Aicha
Baron, Antoine
Boubaker, Aimen
Kalboussi, Adel
Lmimouni, Kamal
Pecqueur, Sebastien
contents Identifying relevant machine-learning features for multi-sensing platforms is both an applicative limitation to recognize environments and a necessity to interpret the physical relevance of transducers' complementarity in their information processing. Particularly for long acquisitions, feature extraction must be fully automatized without human intervention and resilient to perturbations without increasing significantly the computational cost of a classifier. In this study, we investigate on the relative resistance and current modulation of a 24-dimensional conductimetric electronic nose, which uses the exponential moving average as a floating reference in a low-cost information descriptor for environment recognition. In particular, we identified that depending on the structure of a linear classifier, the 'modema' descriptor is optimized for different material sensing elements' contributions to classify information patterns. The low-pass filtering optimization leads to opposite behaviors between unsupervised and supervised learning: the latter one favors longer integration of the reference, allowing to recognize five different classes over 90%, while the first one prefers using the latest events as its reference to clusterize patterns by environment nature. Its electronic implementation shall greatly diminish the computational requirements of conductimetric electronic noses for on-board environment recognition without human supervision.
format Preprint
id arxiv_https___arxiv_org_abs_2401_00684
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A Temporal Filter to Extract Doped Conducting Polymer Information Features from an Electronic Nose
Ammar, Wiem Haj
Boujnah, Aicha
Baron, Antoine
Boubaker, Aimen
Kalboussi, Adel
Lmimouni, Kamal
Pecqueur, Sebastien
Materials Science
Machine Learning
Identifying relevant machine-learning features for multi-sensing platforms is both an applicative limitation to recognize environments and a necessity to interpret the physical relevance of transducers' complementarity in their information processing. Particularly for long acquisitions, feature extraction must be fully automatized without human intervention and resilient to perturbations without increasing significantly the computational cost of a classifier. In this study, we investigate on the relative resistance and current modulation of a 24-dimensional conductimetric electronic nose, which uses the exponential moving average as a floating reference in a low-cost information descriptor for environment recognition. In particular, we identified that depending on the structure of a linear classifier, the 'modema' descriptor is optimized for different material sensing elements' contributions to classify information patterns. The low-pass filtering optimization leads to opposite behaviors between unsupervised and supervised learning: the latter one favors longer integration of the reference, allowing to recognize five different classes over 90%, while the first one prefers using the latest events as its reference to clusterize patterns by environment nature. Its electronic implementation shall greatly diminish the computational requirements of conductimetric electronic noses for on-board environment recognition without human supervision.
title A Temporal Filter to Extract Doped Conducting Polymer Information Features from an Electronic Nose
topic Materials Science
Machine Learning
url https://arxiv.org/abs/2401.00684