English

Reentrant value fields as delayed coupled reaction-diffusion systems on finite graphs

Dynamical Systems 2026-05-21 v3

Abstract

This article develops a field theory of synthetic cognition in which a symbolic field HLH_L and a geometric field XRX_R, each a section of a vertex bundle over a finite graph, are coupled through a bipartite Hilbert-Schmidt operator with propagation delays. The central object is a retarded functional differential equation (RFDE) on the history space: the reaction-diffusion equation is the operative equation of the theory. Nine synthetic design blueprints specify admissibility conditions for each architectural component; each condition carries a dynamical consequence. The main formal results are: (1) well-posedness of the full deterministic RFDE under constant input uu^*, (2) existence of a compact global attractor from compact viability and eventual compactness of solution segments, (3) delay-independent global stability of the principal components (HL,XR,P)(H_L,X_R,P) in the closed stability regime with fixed interfield coupling operators satisfying CK2<μLμRC_{\mathcal{K}}^2<\mu_L\mu_R, (4) SE(d)\mathrm{SE}(d)-invariance of the scalar geometric feature dynamics, and (5) an O(1/κY)O(1/\kappa_Y) fast relaxation estimate for the valuative variable. The well-posedness and attractor results allow Lipschitz state-dependent attention operators. The stability theorem is stated for the fixed-coupling principal subsystem, with the extra small-gain terms for state-dependent coupling identified explicitly.

Keywords

Cite

@article{arxiv.2605.03940,
  title  = {Reentrant value fields as delayed coupled reaction-diffusion systems on finite graphs},
  author = {Karsten Bohlen},
  journal= {arXiv preprint arXiv:2605.03940},
  year   = {2026}
}
R2 v1 2026-07-01T12:51:09.585Z