Heterogeneous Mean Field Game Framework for LEO Satellite-Assisted V2X Networks

Abstract

Coordinating mixed fleets of massive vehicles under stringent delay constraints is a central scalability bottleneck in next-generation mobile computing networks, especially when passenger cars, freight trucks, and autonomous vehicles share the same radio and multi-access edge computing (MEC) infrastructure. Heterogeneous mean field games (HMFG) are a principled framework for this setting, but a fundamental design question remains open: how many agent types should be used for a fleet of size N? The difficulty is a two-sided trade-off that existing theory does not resolve: using more types improves heterogeneity representation, but it reduces per-class sample size and weakens the mean-field approximation accuracy. This paper resolves that trade-off through an explicit -Nash error decomposition, a closed-form type-selection law, a heterogeneity-aware equilibrium solver, and a robust extension to time-varying LEO backhaul dynamics. For the 1D queue state space, the optimal type count satisfies K*(N)=(N1/3); for the joint queue-channel model (d=2), the scaling becomes K*(N)=(N1/5) with logarithmic correction. The unified formula K*(N)=(Nα/(α+β)) provides dimension-dependent design guidance, reducing type granularity to a principled, set-once system parameter rather than a per-deployment tuning burden. Experiments validate the 1D scaling law with empirical slope 0.334 0.004, achieve 2.3× faster PDHG convergence at K=5, and deliver up to 29.5\% lower delay and 60\% higher throughput than homogeneous baselines. Unlike model-free DRL methods whose training complexity scales with the state-action space, the proposed HMFG solver has per-iteration complexity O(K2 Nq Nt) independent of fleet size N, making it suitable for large-scale mobile edge computing deployment.