Abstract
We propose a novel strategy for energy-efficient dynamic computation offloading, in the context of edge-computing-aided beyond 5G networks. The goal is to minimize the energy consumption of the overall system, comprising multiple User Equipment (UE), an access point (AP), and an edge server (ES), under constraints on the end-to-end service delay and the packet error rate performance over the wireless interface. To reduce the energy consumption, we exploit low-power sleep operation modes for the users, the AP and the ES, shifting the edge computing paradigm from an always on to an always available architecture, capable of guaranteeing an on-demand target service quality with the minimum energy consumption. To this aim, we propose an online algorithm for dynamic and optimal orchestration of radio and computational resources called Discontinuous Computation Offloading (DisCO). In such a framework, end-to-end delay constraints translate into constraints on overall queueing delays, including both the communication and the computation phases of the offloading service. DisCO hinges on Lyapunov stochastic optimization, does not require any prior knowledge on the statistics of the offloading traffic or the radio channels, and satisfies the long-term performance constraints imposed by the users. Several numerical results illustrate the advantages of the proposed method.
Highlights
With the advent of beyond 5G networks [1], [2], mobile communication systems are evolving from a pure communication framework to service enablers, building on the tight integration of communication, computation, caching, and control functionalities [3], [4]
We focus on computation offloading services, in which the execution of applications is transferred from mobile devices to a nearby edge server (ES) [10]
We proposed a dynamic resource allocation algorithm for computation offloading that jointly exploits lowpower sleep modes of User Equipment (UE), Access Point (AP), and ES to reduce the system energy consumption with guaranteed E2E average delay and reliability
Summary
With the advent of beyond 5G networks [1], [2], mobile communication systems are evolving from a pure communication framework to service enablers, building on the tight integration of communication, computation, caching, and control functionalities [3], [4]. Future networks will serve a plethora of new applications, addressed to mobile end users, and for whole different sectors (verticals), such as Industry 4.0, Internet of Things (IoT), autonomous driving, remote surgery, Artificial Intelligence (AI) etc. These new services have very different requirements and they generally involve massive data processing within low end-to-end (E2E) delays (in the order of ms). Among several technology enablers at different layers (e.g., AI, network function virtualization, millimeter-wave communications), a prominent role will be played by Edge Computing, whose aim is to move cloud functionalities (e.g., computing and storage resources) at the edge of the network, to avoid the relatively long delays necessary to reach central clouds. Recent surveys on MEC are available in [9], [10]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
