5G Training Course Online, Onsite and Live Online
According to Heavy Reading’s Mobile Operator 5G Capex, total global spending on 5G is set to reach $88 billion by 2023. Once it becomes truly viable, certain device segments will be connected in entirely new ways, particularly vehicles, appliances, robots and city infrastructure.
The 5G network is expensive, and carriers are raising the money by increasing customer revenue. Much like LTE plans incurred a higher initial cost, 5G is following the same course.
But the major carriers remind us, it’s not just building a layer on top of an existing network as was the case in previous networking generations. With 5G it’s a matter of laying the groundwork for something new altogether.
Despite launching the 5G network in April 2019, the major U.S. carriers still have a long way to go before covering the U.S. in 5G architecture. If you call up this map of 5G’s current availability, you will probably be surprised at the sparsity of coverage.
The slow going has largely been due to the cost as well as the legal challenges (i.e., local zoning approval) of setting up the infrastructure to support 5G in the U.S.
The problem is that small cell base stations in a 5G infrastructure require a considerable amount of construction. These antennas take up less real estate and are designed for device-dense areas, such as urban settings, and to blend in with the existing landscape.
Small cell antennas transmit and receive the higher band radio frequency spectrum with millimeter wave (mmWave) frequencies. High-band frequencies can carry more information faster but over shorter distances. As such, they do not cover much area and must be densely arranged.
Beamforming is used to help expand the mmWave signal’s reach. Radio signals are made into focused beams directed at the target. The goal is to maximize signal quality while avoiding interference from other radio waves.
The RAN is a key element of cellular communications and plays a role in covering medium and large geographic areas in 5G networks. 5G RAN focuses on mid- and lower-band radio frequencies like sub-6 GHz frequencies that can cover a larger area but carry less data. That is why this part of 5G infrastructure will be more often used for less populated areas where there is less network congestion allowing for higher speeds with a more dispersed infrastructure.
5G Training Course Online, Onsite and Live Online by Tonex
5G Wireless Training, A Comprehensive 5G Technical Overview Training. 5G Training, A Comprehensive 5G Technical Overview Training with Workshops, Hands-on Exercises (can be done Online, Onsite and Live online). 5G Wireless Training, (5th generation wireless systems, 5G mobile networks) is the innovative course covers 5G Wireless revolution.
5G Wireless Training course also covers the fundamental 5G wireless communications including, 5G services, 5G frequency spectrum, 5G RAN, 5G core, Service Based Architecture (SBA), cloud technology applied in 5G, SDN/NFV, AI.ML, 5G security, innovations in 5G backhaul technologies and more.
For successful deployment of 5G, mobile network operators (MNOs) need transport technologies that can meet stringent throughput, latency and reliability requirements.
Participants will learn about 5G wireless communications framework and technical attributes defined by 3GPP and International Mobile Telecommunications – 2020 (IMT-2020) by the ITU-Radiocommunication Sector. 5G requirements and the primary 5G use cases are discussed.
An overview for the 5G network and system architecture gives the attendees a foundation of the 5G System. 5G core and access networks including cloud architecture, Service Based Architecture (SBA) and 5G reference points/interfaces are discussed. Service Based Architecture (SBA) provides a modular framework from which common applications related to 5G control plane and interconnected Network Functions (NFs). An overview of network slicing, Software Defined Networks (SDN)) and Network Function Virtualization (NFV) is provided.
Participants will learn more about 5G radio interface including: 5G NR, mmWave, Massive MIMO, duplexing modes, frequency bands, Dual-Connectivity (DC) operation, Device-to-Device (D2D) communications, implementation of the CPRI and eCPRI standards, OpenRAN architecture, Backhaul, Midhaul, and Fronthaul.
An overview of 5G networks security is provided including: 5G security threats and vulnerabilities, risk management and mitigation, 5G Authentication and Key Agreement (AKA) process, encryption and integrity processes and keys.
Learning Objectives
Upon the completion of 5G Fundamentals training, the attendees will:
- Learn the fundamental concepts of 5G wireless system
- List and discuss various 5G services and use cases
- Discuss end-to-end 5G network architecture
- Learn about 5G NR, 5GC: 5G core functions, network slicing, architecture, structure, and components
- Discuss 5G Security, D2D, Proximity Services, IoT, and advanced features
Course Topics
The 5G Evolution
- Global 5G
- 5G Spectrum Vision
- 5G Service Innovation
- 5G Ultra-Reliable Low Latency Communications (ULLC)
- 5G Enhanced Mobile broadband (eMBB)
- IoT/M2M, Machine Type Communication (MTC)
Overview of Key 5G Wireless Communication
- 5G Wireless Requirements, Applications, and Services
- Overview of 5G Vision
- 5G Wireless Use Cases and Applications
- Key Capabilities in IMT-2020
- Overview of current and Past 5G Wireless Standardization and Projects
- 5G Technology Enablers
- 5G Challenges and Requirements
- 5G Wireless Air Interface Options
- 3GPP Evolution to 5G: LTE-Advanced Pro
- The 5G Operational Scenarios
- 3GPP Standardization and Enabling Technologies for 5G
- 3GPP 5G System Survey
- 3GPP 5G Identifiers
- 3GPP 5G Core Architecture Overview
Mobile Wireless Technology Evolution: Transition from 4G to 5G
- 5G and the Cloud
- Cloud, Core, Edge, and 5G Radio Access Networks
- Small Cells and mmWave
- NFV and SDN: Management Orchestration (MANO) & Automation
- Planning for 5G Networks
- New Radio (NR)
- Cloud RAN: Cloud-Radio Access Network (C-RAN)
- Next Generation (NexGen) Architecture
- Massive MIMO
- Antenna Systems (AASs) for 5G
- The Evolution of Security in 5G
- 5G: The Future of IoT
- Open Source for 5G
- 5G Vertical Domains
- New Services & Applications
- 5G Communications for Automation
- 3GPP Licensed-Assisted Access (LAA)
- Narrowband- Internet of Things (NB-IoT)
- Enhanced Device to Device (D2D)
- Public Warning Systems (PWS)
- Cellular V2X Communications Towards 5G
Details of 5G Reference Points and Interfaces
- Overview of REST API applied to Service-Based Architecture (SBA)
- NG1: Between UE and AMF (Access and Mobility Management Function)
- NG2: Between gNB (i.e. 5G base station) and AMF
- NG3: Between gNB and UPF (User Plane Function)
- NG4: Between SMF (Session Management Function) and UPF
- NG5: Between PCF (Policy Control Function) and AF (Application Function).
- NG6: Between UPF and DN (Data Network)
- NG7: Between SMF and PCF
- NG8: Between Unified Data Management (UDM) and AMF
- NG9: Between core UPFs
- NG10: Reference point between UDM and SMF
- NG11: Between SMF and SMF
- NG12: Between AMF and AUSF (Authentication Server Function)
- NG13: Between UDM and AUSF
- NG14: Between two AMFs
- NG15: Between PCF and AMF (Non-roaming scenario)
5G Training