Abstract
The expected huge amount of connected cars and applications with varying Quality of Service (QoS) demands still depend on agile/flexible networking infrastructure to deal with dynamic service requests to the control plane, which may become a bottleneck for 5G and Beyond Software-Defined Network (SDN) based Internet of Vehicles (IoV). At the heart of this issue is the need for an architecture and optimization mechanisms that benefit from cutting edge technologies while granting latency bounds in order to control and manage the dynamic nature of IoV. To this end, this article proposes an autonomic software-defined vehicular architecture grounded on the synergy of Multi-access Edge Computing (MEC) and Network Functions Virtualization (NFV) along with a heuristic approach and an exact model based on linear programming to efficiently optimize the dynamic resource allocation of SDN controllers, ensuring load balancing between controllers and employing reserve resources for tolerance in case of demand variation. The analyses carried out in this article consider: (a) to avoid waste of limited MEC resources, (b) to devise load balancing among controllers, (c) management complexity, and (d) to support scalability in dense IoV scenarios. The results show that the heuristic efficiently manages the environment even in highly dynamic and dense scenarios.
Highlights
The automotive industry has been evolved in a rapid pace and has become an important player for the future hyper-connected (IoT) Internet of Things and (IoV)Vehicles [1]
This approach aims to solve the problem of dynamic allocation of SoftwareDefined Network (SDN) controllers, which is modeled as a problem of multiple backpacks, in the context of Software Defined Mobile Network (SDMN)
Multi-access Edge Computing (MEC) applications correspond to SDN controllers along with their applications provisioned by means of Virtualized Network Functions (VNFs)
Summary
The automotive industry has been evolved in a rapid pace and has become an important player for the future hyper-connected (IoT) Internet of Things and (IoV). To the best of our knowledge, there is no work on dynamic resource allocation of SDN controllers for the Internet of Vehicles leveraging on an NFV-based MEC infrastructure This way, Dynamic Software Defined Vehicular Multi-access Edge Computing – DSDVMEC is propose as an autonomic extension to the ETSI MEC reference architecture along with. DSDVMEC aims at being flexible and scalable through dynamically reducing the wasting of MEC resources due to previous allocations of SDN controllers that either became idle or not fully utilized by current demand, but without compromising the quality of service of ongoing flows coming from access points In this way, DSDVMEC provides the IoV context with the ability to scale the infrastructure of controllers as VNFs according to the variability of vehicle’s flow on the roads, without compromising latency due to the proximity of SDN controllers located at the MEC.
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