Abstract
The future 5G New Radio (NR) systems are expected to support both multicast and unicast traffic. However, these traffic types require principally different NR system parameters. Particularly, the area covered by a single antenna configuration needs to be maximized when serving multicast traffic to efficiently use system resources. This prevents the system from using the maximum allowed number of antenna elements decreasing the inter-site distance between NR base stations. In this paper, we formulate a model of NR system with multi-connectivity capability serving a mixture of unicast and multicast traffic types. We show that multi-connectivity enables a trade-off between new and ongoing session drop probabilities for both unicast and multicast traffic types. Furthermore, supporting just two simultaneously active links allows to exploit most of the gains and the value of adding additional links is negligible. We also show that the service specifics implicitly prioritize multicast sessions over unicast ones. If one needs to achieve a balance between unicast and multicast session drop probabilities, explicit prioritization mechanism is needed at NR base stations.
Highlights
The Third Generation Partnership Project (3GPP) is currently in the process of specifying a new 5th generation (5G) radio interface widely known as 5G New Radio (NR) [1]
We investigate the effect of recently standardized 3GPP multiconnectivity operation on performance metrics of a mixture of unicast and multicast traffic in the cellular deployment of NR systems
We numerically assess the performance gains provided by multiconnectivity operation at base station (BS) serving mixtures of unicast and multicast traffic
Summary
The Third Generation Partnership Project (3GPP) is currently in the process of specifying a new 5th generation (5G) radio interface widely known as 5G NR [1]. One of the consequences of increased ISD in NR deployment is potential session drops caused by human-body blockage phenomenon or insufficient resources available at the NR BS to support a session changing its state from non-blocked to blocked [15, 21] To alleviate these effects, 3GPP has recently proposed socalled multi-connectivity operation ( known as macro-diversity), where UE is allowed to simultaneously support connections to multiple NR BSs and switch between them in case of outage events [22]. We investigate the effect of recently standardized 3GPP multiconnectivity operation on performance metrics of a mixture of unicast and multicast traffic in the cellular deployment of NR systems. System level modeling framework we analyze user- and system-centric performance metrics provided to multicast and unicast sessions in the presence of multi-connectivity capabilities.
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