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Adaptive Temporal Dynamics for Personalized Emotion Recognition: A Liquid Neural Network Approach

Signal Processing 2026-02-10 v1 Artificial Intelligence Machine Learning Neural and Evolutionary Computing

Abstract

Emotion recognition from physiological signals remains challenging due to their non-stationary, noisy, and subject-dependent characteristics. This work presents, to the best of our knowledge, the first comprehensive application of liquid neural networks for EEG-based emotion recognition. The proposed multimodal framework combines convolutional feature extraction, liquid neural networks with learnable time constants, and attention-guided fusion to model temporal EEG dynamics with complementary peripheral physiological and personality features. Dedicated subnetworks are used to process EEG features and auxiliary modalities, and a shared autoencoder-based fusion module is used to learn discriminative latent representations before classification. Subject-dependent experiments conducted on the PhyMER dataset across seven emotional classes achieve an accuracy of 95.45%, surpassing previously reported results. Furthermore, temporal attention analysis provides interpretable insights into emotion-specific temporal relevance, and t-SNE visualizations demonstrate enhanced class separability, highlighting the effectiveness of the proposed approach. Finally, statistical analysis of temporal dynamics confirms that the network self-organizes into distinct functional groups with specialized fast and slow neurons, proving it independently tunes learnable time constants and memory dominance to effectively capture complex emotion artifacts.

Keywords

Cite

@article{arxiv.2602.06997,
  title  = {Adaptive Temporal Dynamics for Personalized Emotion Recognition: A Liquid Neural Network Approach},
  author = {Anindya Bhattacharjee and Nittya Ananda Biswas and K. A. Shahriar and Adib Rahman},
  journal= {arXiv preprint arXiv:2602.06997},
  year   = {2026}
}
R2 v1 2026-07-01T10:24:56.764Z