872 research outputs found
Joint Service Caching and Task Offloading for Mobile Edge Computing in Dense Networks
Mobile Edge Computing (MEC) pushes computing functionalities away from the
centralized cloud to the network edge, thereby meeting the latency requirements
of many emerging mobile applications and saving backhaul network bandwidth.
Although many existing works have studied computation offloading policies,
service caching is an equally, if not more important, design topic of MEC, yet
receives much less attention. Service caching refers to caching application
services and their related databases/libraries in the edge server (e.g.
MEC-enabled BS), thereby enabling corresponding computation tasks to be
executed. Because only a small number of application services can be cached in
resource-limited edge server at the same time, which services to cache has to
be judiciously decided to maximize the edge computing performance. In this
paper, we investigate the extremely compelling but much less studied problem of
dynamic service caching in MEC-enabled dense cellular networks. We propose an
efficient online algorithm, called OREO, which jointly optimizes dynamic
service caching and task offloading to address a number of key challenges in
MEC systems, including service heterogeneity, unknown system dynamics, spatial
demand coupling and decentralized coordination. Our algorithm is developed
based on Lyapunov optimization and Gibbs sampling, works online without
requiring future information, and achieves provable close-to-optimal
performance. Simulation results show that our algorithm can effectively reduce
computation latency for end users while keeping energy consumption low
Satellite-MEC Integration for 6G Internet of Things: Minimal Structures, Advances, and Prospects
The sixth-generation (6G) network is envisioned to shift its focus from the
service requirements of human beings' to those of Internet-of-Things (IoT)
devices'. Satellite communications are indispensable in 6G to support IoT
devices operating in rural or disastrous areas. However, satellite networks
face the inherent challenges of low data rate and large latency, which may not
support computation-intensive and delay-sensitive IoT applications. Mobile Edge
Computing (MEC) is a burgeoning paradigm by extending cloud computing
capabilities to the network edge. By utilizing MEC technologies, the
resource-limited IoT devices can access abundant computation resources with low
latency, which enables the highly demanding applications while meeting strict
delay requirements. Therefore, an integration of satellite communications and
MEC technologies is necessary to better enable 6G IoT. In this survey, we
provide a holistic overview of satellite-MEC integration. We first discuss the
main challenges of the integrated satellite-MEC network and propose three
minimal integrating structures. For each minimal structure, we summarize the
current advances in terms of their research topics, after which we discuss the
lessons learned and future directions of the minimal structure. Finally, we
outline potential research issues to envision a more intelligent, more secure,
and greener integrated satellite-MEC network
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