Abstract
Ultra-dense networks (UDNs) are considered as key 5G technologies. They provide mobile users a high transmission rate and efficient radio resource management. However, UDNs lead to the dense deployment of small base stations (BSs) that can cause stronger interference and subsequently increase the handover management complexity. At present, the conventional handover triggering mechanism of user equipment (UE) is only designed for macro mobility and thus could result in negative effects such as frequent handovers, ping-pong handovers, and handover failures on the handover process of UE at UDNs. These effects degrade the overall network performance. In addition, a massive number of BSs significantly increase the network maintenance system workload. To address these issues, this paper proposes an intelligent handover triggering mechanism for UE based on Q-learning frameworks and subtractive clustering techniques. The input metrics are first converted to state vectors by subtractive clustering, which can improve the efficiency and effectiveness of the training process. Afterward, the Q-learning framework learns the optimal handover triggering policy from the environment. The trained Q table is deployed to UE to trigger the handover process. The simulation results demonstrate that the proposed method can ensure the stronger mobility robustness of UE that is improved by 60%–90% compared to the conventional approach with respect to the number of handovers, ping-ping handover rate, and handover failure rate while maintaining other key performance indicators (KPIs), that is, a relatively high level of throughput and network latency. In addition, through integration with subtractive clustering, the proposed mechanism is further improved by an average of 20% in terms of all the evaluated KPIs.
Highlights
To manage increasing demand for mobile data traffic and efficient data delivery, ultra-dense networks (UDNs) have been introduced in the fifth-generation mobile communications system (5G)
A3 event occur when the difference between the reference signal receiving power (RSRP) from user equipment (UE) serving cells and neighbouring cells is higher than a pre-determined condition, the handover hysteresis margin (HHM)
We introduce a more systematic subtractive clustering technique to categorise the handover metrics into corresponding states based on the data distribution
Summary
To manage increasing demand for mobile data traffic and efficient data delivery, ultra-dense networks (UDNs) have been introduced in the fifth-generation mobile communications system (5G). The A3 event may face the following three challenges within 5G-UDNs. First, because the coverage area of small BSs is much lower than macro BSs, UE will meet the edge of the cell more frequently. The decision-making process is affected by interference and frequent handovers continually occurring among serving and target cells (known as the ping-pong effect). The A3 event needs to adjust the handover parameters, that is, HHM and TTT, to avoid frequent handovers, ping-pong effects, and handover failure rates. To achieve this target, the network operator needs to frequently conduct extensive measuring activities and data analysis to determine the suitable handover parameters [6]. The main contributions of this study are summarised as follows:
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