Kobiolka J, Habermann J, Yamakou M (2024)
Publication Type: Journal article
Publication year: 2024
DOI: 10.1007/s11071-024-10821-6
This paper addresses the reduced-order synchronization problem between two chaotic memristive Hindmarsh-Rose (HR) neurons of different orders using two distinct methods. The first method employs the Lyapunov active control technique. Through this technique, we develop appropriate control functions to synchronize a 4D chaotic HR neuron (response system) with the canonical projection of a 5D chaotic HR neuron (drive system). Numerical simulations are provided to demonstrate the effectiveness of this approach. The second method is data-driven and leverages a machine learning-based control technique. Our technique utilizes a heuristic combination of reservoir computing (RC) algorithms, incorporating reservoir observer, online control, and online predictive control algorithms. We anticipate our effective heuristic RC adaptive control algorithm to guide the development of more formally structured and systematic, data-driven RC control approaches to chaotic synchronization problems and to inspire more data-driven neuromorphic methods for controlling and achieving synchronization in chaotic neural networks in vivo.
APA:
Kobiolka, J., Habermann, J., & Yamakou, M. (2024). Reduced-order adaptive synchronization in a chaotic neural network with parameter mismatch: a dynamical system versus machine learning approach. Nonlinear Dynamics. https://doi.org/10.1007/s11071-024-10821-6
MLA:
Kobiolka, Jan, Jens Habermann, and Marius Yamakou. "Reduced-order adaptive synchronization in a chaotic neural network with parameter mismatch: a dynamical system versus machine learning approach." Nonlinear Dynamics (2024).
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