Hypergraph Minority Game with Local Hyperedge Payoffs
Abstract
We provide a theoretical derivation of the Hypergraph Minority Game with Local Hyperedge Payoffs (HMG-L), in which N adaptive agents compete simultaneously in multiple overlapping groups modeled as hyperedges of a static hypergraph =(,). Each hyperedge constitutes an independent local minority game, and agents accumulate payoffs across all groups to which they belong. We derive the continuum-time limit of the score dynamics, from which we obtain a set of coupled nonlinear stochastic differential equations for the agents' strategy polarization variables. The deterministic drift is shown to derive from a global cost function that generalizes the standard Minority Game Hamiltonian to hypergraph-structured interactions. We perform a sparse-annealed replica analysis of the stationary state for the case of a k-uniform, d-regular random hypergraph, obtaining the saddle-point equations within the replica-symmetric ansatz, an explicit replicon stability criterion, and Bethe/cavity equations for sparse corrections. The leading sparse-regime transition occurs on a critical surface αcrit(k,d), while the globally coupled MG value αcrit0.3374 is recovered only in the separate single-hyperedge limit. We derive expressions for the order parameters -- global volatility σ2, predictability θ, hyperedge frustration Fe, and frozen fraction ϕ -- and discuss their scaling behavior near criticality. The Fokker-Planck equation governing finite-N fluctuations is presented, and the noise covariance matrix is computed from the hypergraph structure. Limiting cases (k N, k2, d∞) are analyzed in detail, establishing connections to the standard MG, networked MG, and parallel MG models.
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