5G mmWave Transmission Planning Workshop
3 DAYS
INSTRUCTOR LED WORKSHOP
“OUR COURSES CAN BE SPECIALLY TAILORED TO ADDRESS YOUR REQUIREMENT – TELECONTRAN”
COURSE OBJECTIVES
The Millimeter Wave (mmWave) frequency band has been seen as a serious candidate to host very high data rate wireless communications, firstly used for high capacity radio links, then for broadband indoor wireless networks. The interest in this frequency band has boosted, as it is proposed to accommodate 5G and future 6G mobile communication systems. mmWave radio has attracted a great deal of interest from academic, industrial and global standardization bodies due to a number of attractive features of mmWave to provide multi-gigabit transmission rate.
Telecontran’s 3-day Workshop on 5G mmWave Transmission Planning is designed to cover fundamental communications, design guidelines, channel modelling, circuits, antennas and propagation issues surrounding emerging mmWave cellular/backhaul applications. This workshop also emphasizes on different modeling approaches in characterizing the 60 GHz propagation channel along with 60GHz indoor propagation channel model and its comparison with other frequency bands that also can be used to implement mmWave.
After successful completion of this workshop participants will be able to
- Understand a concise and accessible explanation of the 5G networking technology and millimeter Wave frequency bands.
- Enhance knowledge and skills by gaining a greater understanding of mmWave Link Budget and RF Network Design
- Illustrate potential mmWave deployment scenarios as well as system architecture and design of mmWave.
- Understand the mmWave propagation mechanisms and principles.
- Relate mmWave and 5G radio network architecture and system implementation and antenna deployments
COURSE CURRICULUM
This course is specially designed for Radio Network Planners, Transmission Engineers, Core Network Engineers, Project Managers, RF Engineers & Technicians and frequency spectrum and policy makers from Operators, Regulators, in a word, any technical person engaged in 5G Rollout, mmWave or NR implementation and willing to learn about mmWave and its deployment.
3GPP 5G System Overview and Network Architecture
- 5G Drivers
- Evolution of LTE / 4G to beyond 4G
- 5G System Architecture
- 5G Access Network
- NG-RAN and 5G NR
- The new service-based architecture (SBA)
- 5G Core Network Architecture
- C-RAN, V-RAN Architecture
- 5G Radio Frequency
- mmWave
Introduction to mmWave
- MmWave Implementation Challenges
- Emerging Applications of MmWave Communications
- mmWave Roadmap
- mmWave Regulation and Standards
- mmWave Spectrum and Frequency Range
- V-Band, E-Band and W-Band
- 5G Beamforming
- WiGiG
Ultra Wideband Digital Communications
- Ultra Wideband Signaling
- Digital Modulation
- Equalization in Time and Frequency Domain
- Error Control Coding
- Estimation and Synchronization
- MIMO Communication
- Radiance ecosystems in mmwave bands
- Mmwave spectrum rights fees in many countries
- Examples of use cases for some of the mmwave bands
Millimeter-Wave Propagation Characteristics
- Large Scale Propagation Channel Effects
- Free-Space Loss
- Atmospheric Attenutations
- Rain-Induced Fading
- Foliage Attenuation
- Material Penetration
- Small Scale Channel Effects
- Propagation Mechanisms
- Other Propagation Factors
The mmWave Channel Model
- mmWave Channel Modeling Efforts
- Modeling Challenges
- General Structure of The mmWave Channel
- Outdoor and Indoor Channel Models
- 3GPP-Style Outdoor Propagation Models
- Vehicle-to-Vehicle Models
- Ray-Tracing Models for Indoor Channels
- Rayleigh, Rician, and Multiwave Fading Models
- Path-Loss and Shadowing
- Narrow-Band Channel Model
- Wideband Channel Model
- Spatio-Temporal Characteristics
mmWave Design Guidelines
- Channel Model Considerations
- System Design Considerations
- Antenna Design Considerations
- Antenna Polarization
- Fundamentals of Antenna Arrays
- On-Chip Antenna Environment
- Link Budget Analysis
mmWave Analog and Digital Device and Circuits
- MmWave Transistors and Devices
- S-Parameters, Z-Parameters, Y-Parameters, and ABCD-Parameters
- CMOS Production of MmWave Circuits
- RF Integrated Circuits (RFICs)
- Monolithic Microwave Integrated Circuits (MMICs)
- BSIM Model
- EKV Model
- Sampling and Conversion for ADCs and DACs
- Basic A/D Conversion Circuitry
60-GHz Millimeter-Wave Radio
- Principle and Technology
- 60 GHz mmWave Wireless LAN Standards
- 60 GHz Indoor Propagation Studies
- Channel Characteristics and Transmission Performance for Various Channel Configurations at 60 GHz
- Rain Attenuation at 58 GHz
- Rain-Induced Bistatic Scattering at 60 GHz
- Comparison of OQPSK and CPM for Communications at 60 GHz
Case Studies
- Contribution to the Channel Path Loss and Time-Dispersion Characterization in an Office Environment at 26 GHz
- Wideband Performance Comparison between the 40 GHz and 60 GHz Frequency Bands for Indoor Radio Channels
- 3D Printing Using a 60 GHz Millimeter Wave Segmented Parabolic Reflective Curved Antenna
- LNAs, PAs and switch MMICs for 40.5 to 43.5 GHz microwave point to point links
TRAINING/WORKSHOP | DURATION | TRAINING DATE | LOCATION |
5G mmWave Transmission Planning Workshop | 3 Days | 26th Feb. - 28th Feb 2024 | Dubai, UAE |
OUR HAPPY CLIENTS
WHAT OUR CLIENTS SAY ABOUT TELECONTRAN !!
I have learnt new methods of how to calculate link planning, link budget and losses using Pathloss 5
Well explanation about RF & Transmission planning, Radio Propagation model, Link budget, Interference, noise and transmission optimization.
The Training Material is well prepared with excellent technical depth and after the workshop I have a very clear understanding about Pathloss software.
This course has given me more insight on 5G network as a whole, from introduction to Smart Cities. The presentation was well outlined and learning objectives were successfully completed.
It was a fantastic workshop done by the instructor where I learnt a lot about 5G Technology.
