High-dimensional limits for reflected Brownian motion in the orthant

Abstract

We study interacting Brownian particles on the half-line whose interaction occurs through boundary local times at the origin. The particle system is given by \[ Xin(t)=Xn0,i+Win(t)+Lin(t) +1n-1Σj inijLjn(t), i∈[n],\ t0, \] where the initial conditions are exchangeable, the driving Brownian motions Win are i.i.d., and Lin denotes the boundary local time of Xin at zero. For each fixed coefficient array \nij\, the system can be viewed as a semimartingale reflected Brownian motion in the orthant. We first consider the homogeneous case nij=a. In this case, global well-posedness holds under the completely- S condition a>-1. We prove propagation of chaos under this condition; the subregime a∈(-1,0], in the homogeneous setting, was previously covered as part of the results of baker2025particle. The limiting process is the nonlinear reflected Brownian motion \[ X(t)= X0+ W(t)+ L(t)+a E[ L(t)], t0. \] We also treat heterogeneous random coefficients nij, assumed to have mean a, support in a compact subset of (-1,1), and to be independent across j for each i. In both the quenched and annealed settings, the particle system converges to the same McKean--Vlasov limit as in the homogeneous case. The model is motivated by large Jackson networks in heavy traffic.