Spatial Queues with Nearest Neighbour Shifts

In this work we study multi-server queues on a Euclidean space. Consider $N$ servers that are distributed uniformly in $[0,1]^d$. Customers (users) arrive at the servers according to independent Poisson processes of intensity $\lambda$. However, they probabilistically decide whether to join the queue they arrived at, or move to one of the nearest neighbours. The strategy followed by the customers affects the load on the servers in the long run. In this paper, we are interested in characterizing the fraction of servers that bear a larger load as compared to when the users do not follow any strategy, i.e., they join the queue they arrive at. These are called overloaded servers. In the one-dimensional case ($d=1$), we evaluate the expected fraction of overloaded servers for any finite $N$ when the users follow probabilistic nearest neighbour shift strategies. Additionally, for servers distributed in a $d$-dimensional space we provide expressions for the fraction of overloaded servers in the system as the total number of servers $N\rightarrow \infty$. Numerical experiments are provided to support our claims. Typical applications of our results include electric vehicles queueing at charging stations, and queues in airports or supermarkets.