The need for faster and higher-capacity networks that can sustain modern, high-demanding
applications has driven the development of 5G technology. Moreover, support for low …

The development of the 5G technology has been driven by the need for faster and higher-
capacity networks that would be able to sustain modern, high-demanding applications and …

Abstract Mobile Edge Computing (MEC) will play a key role in next‐generation mobile
networks to extend the range of supported delay‐sensitive applications. Furthermore, an …

Edge computing capabilities in 5G wireless networks promise to benefit mobile users:
computing tasks can be offloaded from user devices to nearby edge servers, reducing users' …

5G systems are envisioned to support numerous delay-sensitive applications such as the
tactile Internet, mobile gaming, and augmented reality. Such applications impose new …

Mobile edge computing (MEC) provides a promising approach to significantly reduce
network operational cost and improve quality of service (QoS) of mobile users by pushing …

Recently, mobile edge computing (MEC) has attracted considerable research effort,
because mobile users can offload some tasks to edge servers that are closer to users than …

Abstract Mobile Edge Computing (MEC) is emerging as one of the key technologies to
process massive amount of data at the edge of the network for upcoming 6G networks. In the …

Extending cloud infrastructure to the Network Edge represents a breakthrough to support
delay-sensitive applications in next 5G cellular systems. In this context, to enable ultrashort …

Envisioned low-latency services in 5G, like automated driving, will rely mainly on Multi-
access Edge Computing (MEC) to reduce the distance, and hence latency, between users …