Abstract
With the development of various vehicle applications, such as vehicle social networking, pattern recognition, and augmented reality, diverse and complex tasks have to be executed by the vehicle terminals. To extend the computing capability, the nearest roadside-unit (RSU) is used to offload the tasks. Nevertheless, for intensive tasks, excessive load not only leads to poor communication links but also results to ultrahigh latency and computational delay. To overcome these problems, this paper proposes a joint optimization approach on offloading and resource allocation for Internet of Vehicles (IoV). Specifically, assuming particle tasks assigned for vehicles in the system model are offloaded to RSUs and executed in parallel. Moreover, the software-defined networking (SDN) assisted routing and controlling protocol is introduced to divide the IoV system into two independent layers: data transmission layer and control layer. A joint approach optimized offloading decision, offloading ratio, and resource allocation (ODRR) is proposed to minimize system average delay, on the premise of satisfying the demand of the quality of service (QoS). By comparing with conventional offloading strategies, the proposed approach is proved to be optimal and effective for SDN-enabled IoV.
Highlights
The Internet of Vehicles (IoV) is one of the most promising application for Internet of Things (IoT) technology
We propose a multiuser and multi-RSU system architecture based on software-defined networking (SDN)-enabled IoV
In order to reduce the delay of task offloading in IoV, a joint approach is proposed to optimize the offloading ratio, offloading decision-making, and resource allocation
Summary
The Internet of Vehicles (IoV) is one of the most promising application for Internet of Things (IoT) technology. The selected part of the in-vehicle task can be Wireless Communications and Mobile Computing offloaded to the appropriate MEC for parallel processing and feedback the execution result to the vehicle-mounted terminal through the neighboring BSs or APs. the MEC server has richer resources than local equipment, excessive load has a great impact on the transmission link. (i) A tasks-divisible system model with a softwaredefined network is proposed based on two-layer transmission (ii) A Particle Swarm Optimization- (PSO-) based heuristic approach for the overall optimization is proposed, which can effectively solve the offloading strategy problem of multiuser and multiobjective nodes This approach works by decomposing the problem into three subproblems: (1) offloading decision of vehicles; (2) resource allocation by RSUs; and (3) offload ratio of vehicles. By comparing with the conventional offloading strategies, simulation results show the proposed ODRR approach achieves the best performance
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