Abstract
With the development of electrification, automation, and interconnection of the automobile industry, the demand for vehicular computing has entered an explosive growth era. Massive low time-constrained and computation-intensive vehicular computing operations bring new challenges to vehicles, such as excessive computing power and energy consumption. Computation offloading technology provides a sustainable and low-cost solution to these problems. In this article, we study an adaptive wireless resource allocation strategy of computation offloading service under a three-layered vehicular edge cloud computing framework. We model the computation offloading process at the minimum assignable wireless resource block level, which can better adapt to vehicular computation offloading scenarios and can also rapidly evolve to the 5G network. Subsequently, we propose a method to measure the cost-effectiveness of allocated resources and energy savings, named value density function. Interestingly, with respect to the amount of allocation resource, it can obtain the maximum value density when offloading energy consumption equals to half of local energy consumption. Finally, we propose a low-complexity heuristic resource allocation algorithm based on this novel theoretical discovery. Numerical results corroborate that our designed algorithm can gain above 80% execution time conservation and 62% conservation on energy consumption, and it exhibits fast convergence and superior performance compared to benchmark solutions.
Highlights
Along with the rapid research and development of Internet of Things (IoT) in the field of transportation, vehicles are undergoing tremendous changes
SYSTEM MODEL we introduce the resource block (RB)-based model of the computation offloading service (COS) under the vehicular edge cloud computing (VECC) framework
When the controller allocates at least a∗i RBs to user i, user i will benefit from VECC by costing less energy consumption than the local computing
Summary
Along with the rapid research and development of Internet of Things (IoT) in the field of transportation, vehicles are undergoing tremendous changes. We expand VEC to a three-layered system framework, i.e., vehicular edge cloud computing (VECC) It has more system resources than traditional VEC to provide abundant vehicular services for CAVs, such as perception, computing, storage, and communication. Zhou et al [24] studied the vehicular workload offloading problem and proposed a low-complexity distributed solution to determine the optimal portion of workload to be offloaded based on the dynamic states of energy consumption and latency in local computing, data transmission, workload execution and handover. Based on the VECC framework, we first model the vehicular computation offloading process at the minimum assignable resource block level This model supports stricter resource management requirements for vehicles and more efficient energy consumption management. Some of the VFCC applications can be implemented in the VECC, such as the driver behavior detection system based on fog computing proposed by Aazam et al in [30]
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