Shuai Nie

TL;DR: This article proposes a radically different approach, enabling deterministic, programmable control over the behavior of wireless environments, using the so-called HyperSurface tile, a novel class of planar meta-materials that can interact with impinging electromagnetic waves in a controlled manner.

TL;DR: A case is made for using mmWave for a fifth generation (5G) wireless system for ultradense networks by presenting an overview of enhanced local area (eLA) technology at mmWave with emphasis on 5G requirements, spectrum considerations, propagation and channel modeling, air-interface and multiantenna design, and network architecture solutions.

TL;DR: Significant technological breakthroughs to achieve connectivity goals within 6G include: a network operating at the THz band with much wider spectrum resources, intelligent communication environments that enable a wireless propagation environment with active signal transmission and reception, and pervasive artificial intelligence.

TL;DR: The state-of-the-art and the potentials of these ten enabling technologies are extensively surveyed, and the challenges and limitations for each technology are treated in depth, while the possible solutions are highlighted.

TL;DR: This paper presents path loss models suitable for the development of fifth generation (5G) standards that show the distance dependency of received power, and shows that coverage is actually better than first suggested by work in [1], [7] and [8].