Your search keyword '"Quemy, Alexandre"' showing total 2 results

1. First steps towards quantum machine learning applied to the classification of event-related potentials

Author

Cattan, Grégoire, Quemy, Alexandre, and Andreev, Anton

Subjects

Computer Science - Human-Computer Interaction, Statistics - Machine Learning

Abstract

Low information transfer rate is a major bottleneck for brain-computer interfaces based on non-invasive electroencephalography (EEG) for clinical applications. This led to the development of more robust and accurate classifiers. In this study, we investigate the performance of quantum-enhanced support vector classifier (QSVC). Training (predicting) balanced accuracy of QSVC was 83.17 (50.25) %. This result shows that the classifier was able to learn from EEG data, but that more research is required to obtain higher predicting accuracy. This could be achieved by a better configuration of the classifier, such as increasing the number of shots., Comment: in French language

Published

2023

2. Hypergraph Case-based Reasoning applied to Brain-Computer Interfaces: A Pilot Study

Author

Cattan, Grégoire, Quemy, Alexandre, CATTAN, Grégoire, IBM - Cloud and Cognitive Software, and Poznan University of Technology (PUT)

Subjects

Interface Cerveau-Ordinateur (ICO), [INFO.INFO-AI] Computer Science [cs]/Artificial Intelligence [cs.AI], ACM: K.: Computing Milieux/K.8: PERSONAL COMPUTING/K.8.0: General, Human-Computer Interaction (HCI), Classification Non Structurée, [SCCO.COMP]Cognitive science/Computer science, ACM: G.: Mathematics of Computing, [INFO.INFO-AI]Computer Science [cs]/Artificial Intelligence [cs.AI], Électroencéphalographie (EEG), [SCCO.COMP] Cognitive science/Computer science, [INFO.INFO-HC]Computer Science [cs]/Human-Computer Interaction [cs.HC], Electroencephalography (EEG), P300, Hypergraph Case-based Reasoning (HCBR), Unstructured Classification, [SCCO.NEUR]Cognitive science/Neuroscience, [SCCO.NEUR] Cognitive science/Neuroscience, Interaction Homme-Machine (IHM), Interface Cerveau-Machine (ICM), Event-Related Potential (ERP), Potentiels Evoqués Cognitifs (PEC), Apprentissage de Métrique, Raisonnement par Cas basé sur un Hypergraphe (RCH), Supervised Learning, [INFO.INFO-HC] Computer Science [cs]/Human-Computer Interaction [cs.HC], Brain-Computer Interface (BCI), Metric Learning, Apprentissage Supervisé

Abstract

Signal analysis of brain-computer interface (BCI) based on electroencephalography (EEG) is complex and, therefore constitutes a practical impediment for application developers and content providers. In this study, we evaluate the use of the hypergraph case-based reasoning (HCBR) classifier to simplify EEG analysis, by reducing the number of pre-processing steps. Direct and preprocessed data were given as input to HCBR. Maximal performance was achieved with preprocessed data, thereby invalidating our initial hypothesis. Best testing (predicting) accuracy was 71.10 (52.04) %. This shows that the classifier was able to learn from the data, but that more research is required to obtain better predicting accuracy. This could be achieved by enlarging the number of trials through transfer learning., L’analyse du signal des interfaces cerveau-machines (ICM) basée sur l’électroencéphalographie (EEG) est complexe et constitue un obstacle pour les développeurs d’applications et les créateurs de contenus. Dans cette étude, nous évaluons l’utilisation du classifieur HCBR, qui évolue dans un espace non-structuré (raisonnement par cas) afin de simplifier l’analyse EEG en réduisant le nombre d’étapes de prétraitement. Des données directes et prétraitées ont été fournies en entrée du classifieur. La performance du classifieur était meilleur avec les donnes prétraitées, invalidant par conséquent notre hypothèse initiale. La précision maximale obtenue par le classifieur était respectivement de 71.10 % et 52.04 % lors de la phase de test et de prédiction (sur des données prétraitées). Ceci indique que HCBR est capable d'apprendre à partir des données, mais que davantage d’efforts restent nécessaires pour obtenir une meilleure précision lors de la prédiction - par exemple en augmentant le nombre d’essais grâce au transfert d’apprentissage.

Published

2021