Result Details

Multi-Objective Evolutionary Design of Explainable EEG Classifier

HURTA, M.; OVESNÁ, A.; MRÁZEK, V.; SEKANINA, L. Multi-Objective Evolutionary Design of Explainable EEG Classifier. Genetic Programming, 28th European Conference, EuroGP 2025. Lecture Notes in Computer Science. Terst: Springer Nature Switzerland AG, 2025. p. 52-67. ISBN: 978-3-031-89990-4.

Type

conference paper

Language

English

Authors

Hurta Martin, Ing., DCSY (FIT)
Ovesná Anna, Ing.
Mrázek Vojtěch, Ing., Ph.D., DCSY (FIT)
Sekanina Lukáš, prof. Ing., Ph.D., DCSY (FIT)

Abstract

Deep neural networks (DNNs) have achieved impressive results in many fields.
However, the use of black-box solutions based on DNNs in medical applications
poses challenges, as understanding the rationale behind decisions is crucial for
application in healthcare. For those reasons, we propose a new method for the
evolutionary multi-objective design (MOD) of small and potentially explainable
EEG (Electroencephalography) signal classifiers. We evaluate a combination of
genetic algorithm (GA) for feature selection with multiple algorithms for the
automated design of the classifier, including Support Vector Machine, k-Nearest
Neighbors, and Naive Bayes. To further improve the classification quality and
obtain less complex solutions, we compare three different MOD scenarios targeting
the accuracy, specificity, sensitivity, and the number of used features. In
addition, we evaluate the use of Cartesian Genetic Programming (CGP) as a way to
achieve smaller and more interpretable solutions and combine it with the
compositional co-evolution of selected features to improve computational
requirements and find solutions in a reasonable time. The proposed methods are
experimentally evaluated on tasks of alcohol use disorder and major depressive
disorder classification. Experimental results show that newly proposed MOD
scenarios lead to significantly better trade-offs between the accuracy and the
number of features compared to the state-of-the-art method employing the NSGA-II
algorithm. The proposed co-evolution of features (evolved by GA) and classifier
(evolved by CGP) allowed the design of small and potentially explainable
solutions and led to 20-100 times faster convergence than the baseline CGP-based
approach.

Keywords

Multi-objective design, Classification, Explainability, Co-evolution, Genetic
algorithm, Cartesian genetic programming, EEG

URL

https://link.springer.com/chapter/10.1007/978-3-031-89991-1_4

Published

2025

Pages

52–67

Proceedings

Genetic Programming, 28th European Conference, EuroGP 2025

Series

Lecture Notes in Computer Science

Volume

15609

Conference

28th European Conference on Genetic Programming

ISBN

978-3-031-89990-4

Publisher

Springer Nature Switzerland AG

Place

Terst

DOI

10.1007/978-3-031-89991-1_4

EID Scopus

2-s2.0-105003908688

BibTeX

@inproceedings{BUT193309,
  author="Martin {Hurta} and Anna {Ovesná} and Vojtěch {Mrázek} and Lukáš {Sekanina}",
  title="Multi-Objective Evolutionary Design of Explainable EEG Classifier",
  booktitle="Genetic Programming, 28th European Conference, EuroGP 2025",
  year="2025",
  series="Lecture Notes in Computer Science",
  volume="15609",
  pages="52--67",
  publisher="Springer Nature Switzerland AG",
  address="Terst",
  doi="10.1007/978-3-031-89991-1\{_}4",
  isbn="978-3-031-89990-4",
  url="https://link.springer.com/chapter/10.1007/978-3-031-89991-1_4"
}

Projects

Hardware-Aware Machine Learning: From Automated Design to Innovative and Explainable Solutions, GACR, Standardní projekty, GA24-10990S, start: 2024-01-01, end: 2026-12-31, running

Research groups

Evolvable Hardware Research Group (RG EHW)

Departments

Department of Computer Systems (DCSY)