5G Wireless – A Comprehensive Technical Overview Training

5G Wireless - A Comprehensive Technical Overview Training

Introduction:

5G Wireless - A Comprehensive Technical Overview Training - Hands-on

5G Wireless - A Comprehensive Technical Overview Training, (5th generation wireless systems or mobile networks) covers next major phase of wireless and mobile telecommunications standards beyond the current 4G/IMT-Advanced standards. 5G Wireless Training introduces most dominant technologies and architectures in near future which make 5G technology. 5G networks are expected to roll out broadly after 2020.

5G Wireless Training course also covers the fundamental 5G wireless communications including, channels, RF circuits, antennas, propagation, and issues surrounding emerging 5G wireless LAN and cellular/backhaul applications. Compared with 4G/LTE cellular systems, 5G wireless communication systems (5G) are expected to provide higher spectral and energy efficiency and area throughput growth. Learn the key 5G wireless communication networks cellular architecture and key technologies for 5G communication networks.

Learn how 5G networks could provide more data bandwidth and less latency using built-in computing intelligence to handle more data more efficiently than today’s 4G networks. 5G networks will leverage more benefits of Moore’s Law due to the convergence of communications and computing technologies and platforms. 5G wireless training covers concepts, services, technologies and network components behind 5G wireless. Find out how 5G wireless networks will be much smarter and faster than 4G. New trends such as M2M, self driving cars, smart cities, connected society , Internet of Things (IoT), broadcast-like services, lifeline communications in times of natural disaster will be part of the new 5G wireless services.

Duration: 3 days

5G Wireless - A Comprehensive Technical Overview Training

5G Wireless - A Comprehensive Technical Overview TrainingRelated Courses:

Customize It:

» If you are familiar with some aspects of this 5G Wireless - A Comprehensive Technical Overview Training course, we can omit or shorten their discussion.
» We can adjust the emphasis placed on the various topics or build the 5G Wireless - A Comprehensive Technical Overview Training course around the mix of technologies of interest to you (including technologies other than those included in this outline).
» If your background is nontechnical, we can exclude the more technical topics, include the topics that may be of special interest to you (e.g., as a manager or policy-maker), and present the 5G Wireless - A Comprehensive Technical Overview Training course in manner understandable to lay audiences.

Audience / Target Group:

The target audience for this 5G Wireless - A Comprehensive Technical Overview Training course is defined here:

• Planners, strategists, and others interested in an advance look at the factors shaping the evolution of 4G LTE to 5G wireless and the technologies likely to be included in 5G.

Objectives:

Upon completing this 5G Wireless - A Comprehensive Technical Overview Training course, learners will be able to meet these objectives:

• Describe what 5G is
• List the 5G wireless features and their benefits (5G wireless communication networks)
• Describe key 5G technology drivers and enablers of 5G
• List 5G technology candidates in RAN/radio, transport, core networks, interoperability and services
• List 5G Wireless Use Cases
• List User-Driven 5G Requirements
• Describe ITU 5G standards (IMT2020) along with NGMN alliance and 3GPP
• Describe 3GPP LTE/LTE-A evolution towards 5G
• Walk through current and future deployment of 5G scenarios
• Co-Existence of LTE End-to-End Ecosystem with 5G
• List similarities and differences between 5G Radio Access and LTE
• Learn how 5G wireless networks could support up to 1,000-fold gains in capacity
• List requirements to connect 100 billion human and devices with a 10 Gb/s speed with zero-distance connectivity
• Describe new 5G Radio Access Technology Interworking with LTE
• List 3GPP Licensed-Assisted Access (LAA), Narrowband- Internet of Things (NB-IoT), and Enhanced Device to Device (DD) requirements
• Explain LTE-Advanced Pro and 3GPP roadmap to 5G
• New Radio (NR), Cloud RAN: Cloud- Radio Access Network (C-RAN) and Next Generation (NexGen) architecture
• Illustrate 5G wireless communication networks cellular architecture and key technologies
• Illustrate 5G network architecture and components
• Describe the operation scenarios of 5G
• Explain the key RF, PHY, MAC and air interface changes required to support 5G
• Describe features supporting 5G wireless deployments
• Discuss the rationale for 5G wireless and key deployment typologies
• Outline changes required to implement 5G
• Learn about features of Massive MIMO

5G Wireless - A Comprehensive Technical Overview Training - Course Syllabus:

What is 5G Wireless Communication?

5th Generation Wireless technology
5G as a technology vision
Why 5G?
End-to-End 5G Ecosystem
5G high level requirements and features
Basic concepts behind 5G technology of mobile communication
5G technologies
5G technical objectives
5G Activities and Interest Groups
5GPP
5G Forum
5GMF
3GPP
ITU-T’s IMT-2020, WRC-15
NGMN Alliance
5G Americas
ETSI
ARIB

5G Wireless Requirements, Applications, and Services

5G promises and challenges
Disruptive technology directions
Bandwidth
Power consumption
Infrastructure
Spectral efficiency
Resilience of the network
Adapting new topologies
Radio propagation and channel models
Pervasive networks
Internet of things (IoT) and M2M
Wireless sensor networks and ubiquitous computing
Wearable devices with AI capabilities

5G Vision

Typical usage scenarios of 5G New RAT
Phase I
eMBB for sub-6GHz
Non-standalone
5G New RAT
Phase II
eMBB for above 6GHz
Massive MTC
Critical MTC
Key technology drivers and innovations behind 5G wireless
Next Wave of digital society
Machine-type Communications
Smart homes and buildings
Smart grid
Smart meters
Intelligent Transportation Systems (ITS)
Ultrahigh definition video
Virtual reality applications
Fiber-like user experience: 10 Gb/s data rates
Mobile cloud service
“Full Immersive” services
Immersive experience
Zero latency and response times
Zero-second switching
Tactical Radio
Policy-based DSA systems
Cognitive radar
Exa-scale cloud data centers and Edge computing
Internet of Vehicles
Ultra-dense networks
Virtualized and cloud-based radio access infrastructure

5G Wireless Use Cases and Applications

Description of Use Cases and Scenarios
Internet of Things (IoT) and Machine to Machine (M2M)
Smart Grid, SCADA, EMS and Critical Infrastructure Monitoring
Smart Building and Smart Cities
m-Health/Telemedicine
eMBB: Enhanced Mobile Broadband
MTC: Machine Type Communications
Automotive and Self-Driving Vehicles
V2X
Sports and Fitness Management
3D/Virtual Reality (VR)
Augmented Reality (AR)
Gaming Applications
Public Safety and Citizen AnalyticLocation and Context-Aware Service

Key Capabilities in IMT-2020

Peak data rate
Latency
Mobility
Connection density
Energy efficiency
Energy efficiency has two aspects:
Spectrum efficiency
Area traffic capacity

Overview of current and Past 5G Wireless Standardization and Projects

IEEE
ITU-T
3GPP
ETSI
5G Americas
WWRF, the METIS Project and the DVB Project
METIS Project
Mobile and wireless communications Enablers for the Twenty-twenty Information Society
European Union Seventh Framework Programme (FP7)
IEEE 802.xx wireless mobile networks
Development of World Wide Wireless Web (WWWW)
11 Wireless Local Area Networks (WLAN)
16 Wireless Metropolitan Area Networks (WMAN)
Ad-hoc Wireless Personal Area Network (WPAN)
WiGig or IEEE 802.11ad
Millimeter Wave Mobile Communications for 5G Cellular
IEEE 802.22
DSA modes for WiFi and WiMAX
Whitespace and WhiteFi
Emerging field of mmWave communications.
Ultrawideband WLAN and PAN networks.
IEEE 802.15.3c 802.11ad/802.11ax/802.11az/802.11ay
ECMA
High rate 60 GHz PHY

5G Technology Enablers

System design concepts
Dynamic Spectrum Access (DSA)
Interference Management
Small Cells
Coordinated Multipoint
Mass-scale MIMO, Massive MIMO
Caching and Delivering Techniques
Personal Mobile Internet
Device-to-Device Communication
Software-Defined Radio (SDR)
Cognitive Radio
Smart-radio
Multi-hop networks
Direct device-to-device (D2D) communications
Dynamic Adhoc Wireless Networks (DAWN)
IPv6 and 6LowPAN
Centralized RAN vs. Cloud RAN
NFV, SDN, ICN, semantic and cloud networking
Direct Device-to-Device Communication (D2D)
Massive Machine Communication (MMC)
Massive Internet of Things (IoT)
SDN and NFV
Moving Networks (MN)
Ultra-Dense Networks (UDN)
Ultra-Reliable Communication (URC)
Mobile ad hoc network (MANET)
Wireless mesh network (WMN)
Vandermonde-subspace frequency division multiplexing (VFDM)
Millimeter-Wave
5G Cloud radio access network (C-RAN)
Ultra small cells based heterogeneous network (HetNet)
Heterogeneous cloud radio access network (H-CRAN)
Disruptive approaches for increasing network capacity
Programmable optical backbone networks with petabit throughput
Ultra Reliable and Low Latency Communication (URLLC)
5G management and orchestration
Full Dimension MIMO
Adaptive Coding and Modulation (AMC)
Filter-Bank Multi-Carrier (FBMC)
Frequency and Quadrature Amplitude Modulation (FQAM)

5G Challenges and Requirements

ITU and NMGN use cases for 5G
New radio access technologies (RAT)
Spectrum bands availability
Networks and devices
Air-interface and RAN systems
Virtualized architectures
Service delivery architecture
Single frequency full duplex radio technologies
Architecture and key technologies
Dynamic deployment of network functions
New wireless backhaul solutions
Adaptive resource management
Flexible spectrum usage
Safety and delay critical network of Cloudlets
Performance requirements
Latency
Always-on users per cell
Duty cycles
Signaling loads
Massive capacity
Energy consumption
Spectrum impact
New architecture for services and service delivery
Hyper connectivity to trillions of devices
Massive dense networks
Massive distributed MIMO
Advanced interference and mobility management
Cooperation of different transmission points with overlapped coverage
Efficient support of machine-type devices
Latency and enhanced reliability

5G Wireless Air Interface

New access protocols and procedures for collaborative communications
Software defined air interface
Spectral usage techniques
New multiple accesses (“no cell” concept)
New radio resource management techniques
Physical layer procedures, and coding New modulations schemes
Channel models for 2.3 GHz, 2.6 GHz, 5.25 GHz, 26.4 GHz, and 58.68 GHz.
Advanced MIMO technology with wider bandwidths
Propagation modeling of densely populated urban areas
Beamforming, network discovery, and relaying
Coding and modulation algorithms
Interference management
Non-Orthogonal, Asynchronous Waveforms
Millimeter-Wave Beamforming
Cooperative diversity and flexible modulation
C o-existence of macro-cells and cognitive radio small-cells
Systems for mmWave transceivers
Generalized frequency division multiplex (GFDM)
Filter bank multicarrier (FBMC)
Universal filtered multicarrier (UFMC)
Filtered OFDM (f-OFDM)
Sparse code multiple access (SCMA)
Non-orthogonal multiple access (NOMA)
Resource spread multiple access (RSMA)
3D Beamforming & Diversity
Hardwire connection replacement on chip
Information showers

3GPP Evolution to 5G: LTE-Advanced Pro

Major advances
Narrowband- Internet of Things (NB-IoT)
MTC enhancements
D2D, Enhanced Device to Device (D2D)
Public safety features : Proximity-based Services (Prose) for Public Safety
TDD/FDD Evolution
Small cell dual-connectivity and architecture
Carrier aggregation enhancements
Interworking with Wi-Fi
LTE-Unlicensed (LTE-U)
Licensed-Assisted Access (LAA) and Enhanced LAA (eLAA)
Indoor positioning
Single cell-point to multi-point
Impact on latency reduction
QAM-256
FD-MIMO or Full Dimension MIMO
MultiFire
Using Traditional licensed spectrum
Cloud RAN/C-RAN, SON, and Dual Connectivity

The 5G Operational Scenarios

Explanation of 5G scenarios
Examples of 5G technology components
Cognitive & energy-efficient wireless technologies
Enhancing LTE radio standards
Capacity and performance
System robustness
5G wireless implementation roadmaps
Spectrum metrics
Interference approaches
Reconfigurable radio hardware
5G evaluation tools and testbeds

3GPP Standardization and Enabling Technologies for 5G

3GPP 5G System Requirements
3GPP 5G System Architecture
Evolve Packet Core (EPC) Evolution
Next Generation EPC and Multi-RAT Support
Dedicated Core Network
eMBB, mMTC and URLLC
Network Slicing
RRC / NAS Status
Smalls Cells
Heterogeneous Networks (HetNet)
LTE and LTE-A Evolution to 5G Path
LTE Unlicensed
LTE License Assisted Access (LAA)
LTE-WiFi Radio Level Aggregation (LWA)
Cloud RAN (C-RAN), vEPC and vIMS
Discovery and Device to Device (D2D)
Vehicle to Vehicle (V2V)
LTE Machine Type Communication for Internet of Things (IoT)
Narrowband Internet of Things (NB-IoT)
Enhancements for eMTC and NB-IoT
Coordinated Multi-Point Transmission and Reception (CoMP)
Licensed Assisted Access for LTE (LAA-LTE)
LTE Wireless Local Area Network (WLAN) Aggregation (LWA)
Downlink (DL) Multi-User Superposition Transmission (MUST)
Network-Based IP Flow Mobility (NBIFOM)
Mission Critical Push-to-Talk (MCPTT) over LTE
Monitoring Enhancement (MONTE) for MTC services
Enhancements to MBMS, ProSe and group communications
Enhancements to User Plane Congestion Management (UPCON)

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Time Frame: 0-3 Months4-12 Months

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