Shaping Future 6G Networks. Группа авторов

Shaping Future 6G Networks - Группа авторов


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from sensors in physical space are accumulated in cyberspace and analyzed by artificial intelligence (AI) to provide intuitive and near‐real‐time feedback to humans in physical space. This vision first drawn by science fiction authors in the early 1980s is about to become a reality. “Cyberspace… Data abstracted from the banks of every computer in the human system. Unthinkable complexity.” wrote William Gibson (who coined the term of cyberspace) in his 1984 novel Neuromancer.

      The recent COVID‐19 misfortune might appear as a new step toward this Society 5.0, as we have re‐recognized the need for enhancing and upgrading information communication infrastructure to ensure the continuity of our social activities, as well as the growing blurring between virtual and real relationships. On this road, it is essential not only to promote research and development of technology but also to consider the global environmental impacts (such as carbon neutral and green recovery), the social inclusiveness so that no one will be left behind, and the ethics and social acceptability of these forthcoming technologies.

      This wish for a future better and enhanced society shall be and remain the underlying foundation for designing future 6G networks. It should bond all the stakeholders engaged in research and development of next‐generation cyber infrastructure, 6G mobile network systems, to globally unite forces to define new requirements, use cases, and fundamental theories and technologies that must be realized for the next decade. These researches are also a way to progress for accomplishing the 2030 Agenda for Sustainable Development adopted by the United Nations in 2015, where one of the sustainable development goals is about building resilient infrastructure, promote inclusive and sustainable industrialization, and foster innovation.

      Although it is just the very beginning of our journey for developing 6G mobile networking, we can assume that the next‐generation cyber infrastructure will bring us communications features very close to human capability, such as ultralow latency, ultra‐high capacity, ultra‐large number of connected devices, ultralow power communication, stringent security and privacy, autonomy enabled by machine learning and AI, and ultra‐coverage and extensibility including non‐terrestrial networks, underwater communication, etc.

      Along with the editors, I hope that this book serves as a navigating compass in our endeavor for developing 6G infrastructure for the next decade, by providing the insights from internationally known distinguished experts.

      Akihiro Nakao

      The University of Tokyo, Japan

      Acronyms

Abbreviation Explanation
3GPP2 3rd Generation Partnership Project 2
5G 5th Generation
5GAA 5G Automotive Association
5GC 5G Core
5G‐NTN 5G Non‐Terrestrial Network
6G 6th Generation
AD Anomaly Detection
AFL Agnostic Federated Learning
AI Artificial Intelligence
AIaaS AI‐as‐a‐Service
API Application Programming Interface
APS Angular Power Spectrum
APSM Adaptive Projected Subgradient Method
ARCEP Autorité de Régulation des Communications Électroniques et des Postes
ARIB Association of Radio Industries and Businesses
AS Autonomous System
ASIC Application‐Specific Integrated Circuit
ATIS Alliance for Telecommunications Industry Solutions
B2B Business‐to‐Business
B2C Business‐to‐Consumer
B5G Beyond 5G
BBUs Baseband Units
BGP Border Gateway Protocol
BN Boundary Nodes
BOM Business, Operation, and Management
Base Station
BSS Business Support System
BW Bandwidth
CAPEX Capital Expenses
CBRS Citizen Broadband Radio System
CCNx Content‐Centric Networking
CCSA China Communications Standards Association
CDMA Code Division Multiple Access
CeTI Centre for Tactile Internet with Human‐in‐the‐Loop
CFN Computer‐First Networking
C‐ITS Cooperative Intelligent Transport System

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