Optimal Traffic Splitting Policy in LTE-based Heterogeneous Network

TL;DR

This paper proposes an optimal traffic splitting policy in LTE-based heterogeneous networks with dual connectivity, aiming to minimize average delay while managing blocking probabilities for users.

Contribution

It introduces a threshold-based optimal policy for traffic splitting in dual connectivity LTE networks, balancing delay minimization and user blocking constraints.

Findings

Optimal policy has a threshold structure.

Average delay varies with system parameters.

Trade-offs between delay and blocking probability are analyzed.

Abstract

Dual Connectivity (DC) is a technique proposed to address the problem of increased handovers in heterogeneous networks. In DC, a foreground User Equipment (UE) with multiple transceivers has a possibility to connect to a Macro eNodeB (MeNB) and a Small cell eNodeB (SeNB) simultaneously. In downlink split bearer architecture of DC, a data radio bearer at MeNB gets divided into two; one part is forwarded to the SeNB through a non-ideal backhaul link to the UE, and the other part is forwarded by the MeNB. This may lead to an increase in the total delay at the UE since different packets corresponding to a single transmission may incur varying amounts of delays in the two different paths. Since the resources in the MeNB are shared by background legacy users and foreground users, DC may increase the blocking probability of background users. Moreover, single connectivity to the small cell may increase the blocking probability of foreground users. Therefore, we target to minimize the average delay of the system subject to a constraint on the blocking probability of background and foreground users. The optimal policy is computed and observed to contain a threshold structure. The variation of average system delay is studied for changes in different system parameters.