Learning the Brain's Dynamics as a Port-Hamiltonian System
Abstract
We model human motor cortex during a wrist-extension BCI task as a port-Hamiltonian system (pHS): a conservative interconnection (gyroscopic coupling between neural phasors) plus a dissipative port (power-law energy decay driven by a GNN surrogate). A metriplectic integrator evolves the phasor state; a Fluctuation--Dissipation-consistent noise channel produces stochastic trajectories at body temperature. Training on \ real EEG cycles (PhysioNet EEGMMIDB, 3 held-out subjects) reaches a test MSE of \ and passes three scale-free criticality rungs: near-critical branching ratio (σ≈1), 1/f power-law spectrum, and long-range DFA correlations. The model generates closed-loop neuromodulation signals that restore phase-locking in silico when applied to de-synchronised inputs, suggesting a path toward structure-preserving BCI decoders.
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