Abstract
AbstractWe study an open discrete-time queueing network. We assume data is generated at nodes of the network as a discrete-time Bernoulli process. All nodes in the network maintain a queue and relay data, which is to be finally collected by a designated sink. We prove that the resulting multidimensional Markov chain representing the queue size of nodes has two behavior regimes depending on the value of the rate of data generation. In particular, we show that there is a nontrivial critical value of the data rate below which the chain is ergodic and converges to a stationary distribution and above which it is non-ergodic, i.e., the queues at the nodes grow in an unbounded manner. We show that the rate of convergence to stationarity is geometric in the subcritical regime.
Publisher
Cambridge University Press (CUP)
Subject
Applied Mathematics,Statistics and Probability
Reference33 articles.
1. Packet routing and job-shop scheduling inO(congestion+dilation) steps
2. [30] Szpankowski, W. (1990). Towards computable stability criteria for some multidimensional stochastic processes. In Stochastic Analysis of Computer and Communication Systems, ed. Takagi, H. , Elsevier, Amsterdam , pp. 131–172.
3. A Queueing Network-Based Distributed Laplacian Solver
4. Maximum hitting time for random walks on graphs
5. Randomized Routing and Sorting on Fixed-Connection Networks