Abstract
Massive content delivery is in the spotlight of the research community as both data traffic and the number of connected mobile devices are increasing at an incredibly fast pace. The enhanced mobile broadband (eMBB) is one of the main use cases for the fifth generation of mobile networks (5G), which focuses on transmitting greater amounts of data at higher data rates than in the previous generations, but also on increasing the area capacity (given in bits per second per square meter) and reliability. However, the broadcast and multicast implementation in 5G and presents several drawbacks such as unexpected disconnections and the lack of device-specific QoS guarantees. As a result, whenever the exact same content is to be delivered to numerous mobile devices simultaneously, this content must be replicated. Hence, the same number of parallel unicast sessions as users are needed. Therefore, novel systems that provide efficient massive content delivery and reduced energy consumption are needed. In this paper, we present a network-coded cooperation (NCC) protocol for efficient massive content delivery and the analytical model that describes its behavior. The NCC protocol combines the benefits of cooperative architectures known as mobile clouds (MCs) with Random Linear Network Coding (RLNC). Our results show the benefits of our NCC protocol when compared to the establishment of numerous parallel unicast sessions are threefold: offload data traffic from the cellular link, reduce the energy consumption at the cooperating users, and provide throughput gains when the cellular bandwidth is insufficient.
Highlights
This section presents relevant results regarding the accuracy of our analytical models with respect to simulations and the achievable gains with our network-coded cooperation (NCC) protocol
We first compare the results obtained by our model with those obtained by Monte Carlo simulations
Afterwards, we present the optimal number of coded transmissions s∗ as a function of the cloud size n, the generation size g, and the packet error ratio (PER)
Summary
Since the UEs within a MC are closely located, the use of multicast short-range links for content delivery is possible and much more efficient than the use of independent unicast sessions It is in multicast wireless networks where Network Coding (NC) schemes have proven to be highly valuable to ensure a high data rate and a low error ratio [11]. The content is distributed among the UEs in the MC and the packets received at each node are not present at the remaining UEs. As a reference, single-source multicast scenarios under RLNC schemes have been studied in the literature and the formulation of the exact probability of delivering the content to every destination is not trivial [18].
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