Course 9008: RF Engineering Training Boot Camp - TONEX.com

TONEX Radio Frequency (RF) Engineering Training Boot Camp is the answer to your RF planning, design and engineering in any wireless networks needs.

RF Engineering, also known as Radio Frequency Engineering, is a subset of electrical engineering that deals with devices which are designed to operate in the Radio Frequency spectrum:  range of about 3 kHz up to 300 GHz.

RF Engineering is a highly specialized field. To produce quality results in RF Engineeing Training bootcamp, the program covers an in-depth knowledge of Mathematics, Physics, general electronics theory as well as specialized modules in propagation and microstrip design may be required.

RF Engineering Boot Camp provides participants with a solid understanding of RF surveys and planning, electromagnetic modeling and simulation, interference analysis and resolution, coverage analysis, propagation models, RF engineering, system specifications and performance, modulation, antenna theory, link design, traffic engineering, optimization, benchmarking, safety, RF testing and system integration and measurements. Design and production engineers and technicians interested in improving RF engineering skills through a practical approach will benefit from this course.

Topics Covered: 

• RF Theory
• RF Engineering Principles
• Modulation
• Antenna Theory
• Interference Analysis
• Link Design
• Principles of Noise and Interference
• Principles of Jamming
• Communications Control and Jamming Theory of Operation
• RF System Specifications
• RF Surveys and Planning
• Radio Wave Propagation and Modeling
• FrequencyPlanning and
• Traffic Dimensioning
• Cell Planning Principals
• Coverage Analysis
• RF Optimization
• RF Benchmarking
• RF Performance
• RF Safety
• RF Simulation
• RF Testing
• RF System Integration and Measurements
• Planning of GSM, GRS, EDGE, CDMA, W-CDMA Radio Networks
• Advanced Topics in GSM, GPRS and EDGE Cell Planning
• Advanced Topics in CDMA and CDMA2000 Cell Planning
• Advanced Topics in W-CDMA (R-99), HSDPA, HSUPA and LTE Cell Planning
• Advanced Topics in WiMAX (802.16e) Planning and Architecture
• Voice and Data Traffic Engineering
• RAN Optimization

RF Engineering priciples

• Fundamentals of RF Systems 
• RF 101
• History of RF
• Basic Building Blocks in Radio and Microwave Planning and Design
• RF Principles, Design, and Deployment
• RF Propagation, Fading, and Link Budget Analysis
• Intro to Radio Planning for Mobile and Fixed Networks
• RF Planning and Design for GSM, CDMA, UMTS, HSPA/HSPA+, LTE and WiMAX Networks
• RF Planning and Design for Satallite Communications and VSAT
• RF Planning and Design for 2-way Radio Communications
• RF Planning and Design for Radar and Jammers Path Survey
• RF Impairments
• Noise and Distortion
• Antennas and Propagation for Wireless Systems
• Filters
• Amplifiers
• Mixers
• Transistor Oscillators and Frequency Synthesizers
• Modulation Techniques
• Receiver Design
• Eb/No vs. SNR, BER vs. noise, Bandwidth Limitations
• Modulation Schemes and Bandwidth
• RF Technology Fundamentals
• Types of Modulation: AM, FM, FSK, QAM, PSK & QPSK
• RF Engineering Principals applied
• Cellular and Mobile RF (WiMAX, CDMA/CDMA2000, GSM, GPRS, EDGE, UMTS/W-CDMA, HSPA/HSPA+ , and LTE)
• Fixed Wireless RF (802.11, 802.16, HF, UHF, Microwave, Satellite, VSAT, Radar and GPS)

RF System Design Considerations

• RF System Design
• Multiple Access Methods and Comparative Capacities
• Modulation, Bandwidth, Interference, Performance
• BER vs. Noise
• Bandwidth Limitations
• Noise Figure
• Eb/No vs. SNR
• Receiver Sensitivity
• Desensitization and Blocking
• Dynamic Range
• Intermodulation Distortion
• Power Output
• Spectral Efficiency and System Limitations
• Sample Link Budget Calculations
• Link Structure
• Design Engineering
• Performance Engineering
• Traffic Engineering
• System Noise Management
• Propagation Modes
• Scattering Parameter Analysis
• RF Regulatory Considerations

RF Propagation Principles

• Estimating Path Loss
• VHF/UHF/Microwave Radio Propagation
• Physics and Propagation Mechanisms
• Propagation Models and Link Budgets
• Practical System Design Considerations
• The Physics of Propagation: Free Space, Reflection, Diffraction
• Local Variability: Rayleigh fading and multipath cancellation
• Free Space Path Loss
• Area Propagation Models: Okumura, HATA, Cost 231 and others
• Point-to-Point Models: techniques and commercial software
• Analyzing measured data to produce models
• Reliability of Service
• Macro-cell Indoor Penetration
• Micro-cellular systems and techniques
• Propagation Prediction Tools and Measurement Tools
• Propagation Losses
• Refraction and Fresnel Zones
• Reflection and Scattering Loss
• Multipath
• Rayleigh Fading Models
• Noise and interference
• Polarization distortion
• Diversity implementation
• Link Budgets and High-Level System Design
• Link Budget Basics and Application Principles
• Traffic Considerations

Details Of Propagation Models And Their Uses

• Free space, Okamura/HATA, Okamura with Knife Edge Diffraction, Longley-Rice, and the proprietary BIBY-C
• Simple Analytical models
• General Area models
• Point-to-Point models
• Local Variability models
• The Okumura Model
• The Hata Model
• The EURO COST-231 Model
• Walfisch-Betroni/Walfisch-Ikegami Models
• Morphological Zones
• Commercial Propagation Prediction Software

RF Modulation

• Fundamentals of analog transmission
• Quantization
• Pulse-code modulation
• Geometrical representations of waveforms
• Modulation techniques (QAM, PSK, QPSK, DPSK, FSK)
• The additive Gaussian noise channel
• Optimal detectors
• Performance analysis of digital receivers.

Antenna Theory & Design Principles

• Principle of Antennas and Wave Propagation
• Antenna properties
• Impedance, directivity, radiation patterns, polarization
• Types of Antennas, Radiation Mechanism (Single Wire, Two-Wires, Dipole)
• Current Distribution on Thin Wire Antenna
• Radiation Pattern
• Gain Antenna types, composition and operational principles
• ERP and EIRP
• Antenna gains, patterns, and selection principles
• Antenna system testing
• Fundamental Parameters of Antennas
• Radiation Pattern and types
• Radiation Intensity and Power Density
• Directivity, Gain, Half Power Beamwidth
• Beam Efficiency, Antenna Efficiency
• Bandwidth, Polarization (Linear, Circular and Elliptical)
• Polarization Loss Factor
• Input Impedance
• Antenna Radiation Efficiency
• Effective Length, Friis Transmission Equation
• Antenna Temperature
• Infinitesimal Dipole
• Small Dipole
• Region Separation
• Finite Length Dipole
• Half Wavelength Dipole
• Ground Effects
• Loop Antennas
• Small Circular Loop
• Circular Loop of Constant Current
• Circular Loop with Non-uniform Current
• Ground and Earth Curvature Effects
• Mobile Communication Systems Application
• Types of Antennas
  • Resonant antennas
  • Traveling wave antennas
  • Frequency Independent antennas
  • Aperture antennas
  • Phased arrays
  • Electrically small antennas
  • Circularly polarized antennas
  • Elementary Antenna Elements
  • Omnidirectional Antennas
  • Microstrip Antennas
  • Achieving circular polarization
  • The helix antenna
  • Electrically Small Antennas
  • Fractal Antennas
  • Ultra Wideband (UWB) Antennas
  • Low Profile Antennas
  • Linear Wire Antennas
• Monopole configurations
• Feed considerations
• Dipole configurations
• Ground plane considerations
• Bandwidth improvement techniques
• Antenna Arrays

VHF/UHF/Microwave Radio Propagation

• Estimating Path Loss
• Free Space Propagation
• Path Loss on Line of Sight Links
• Diffraction and Fresnel Zones
• Ground Reflections
• Effects of Rain, Snow and Fog
• Path Loss on Non-Line of Sight Paths
• Diffraction Losses
• Attenuation from Trees and Forests
• General Non-LOS Propagation Models

RF Optimization Principles

• Site Acquisition
• Design, analysis and optimization of wireless networks
• Verification of network deployments for wireless networks
• RF engineering principals
• Good quality network and services
• Network planning resources
• Link budgets, scheduling and resource allocation
• Preparation and Report generation
• Real-time coverage maps
• True-up RF modeling software

RF System Optimization

• RF coverage and service performance measurements
• System Setting
• Initial optimization testing of installed networks
• Antenna and Transmission Line Considerations
• System field-testing and parameter optimization
• Functional testing and optimization for implemented sites
• Test plan development
• System drive test and data analysis
• System parameter settings and interference control

Key RF Performance Indicators

• FER, Mobile Receive Power, Ec/Io, Mobile Transmit Power
• System accessibility analysis
• Available radio resources and network trunking issues
• System parameter optimization
• Regression analysis to measure benefits
• Frequency/PN offset planning
• Self-generated system interference
• Cell site integration
• Construction coordination
• Equipment installation/antenna system verification
• RF parameter datafills
• Radio testing
• Initial drive testing
• Performance monitoring
• Site migration planning and testing
• ERP changes
• Orientation changes

RF Troubleshooting

• Safety
• Basic troubleshooting steps
• Signal tracing
• Signal injection
• Lead dress
• Heat sinks

Labs and Calcualations

• Wireless Network Link Analysis
• System Operating Margin (SOM)
• Free Space Loss
• Freznel Clearance Zone
• Latitude/Longitude Bearing
• Microwave Radio Path Analysis
• Line-of-Sight Path Analysis
• Longley-Rice Path Loss Analysis
• United States Elevation Analysis
• Parabolic Reflector Gain and Focal Point Calculator
• Urban Area Path Loss
• Antenna Up/Down Tilt Calculator
• Distance & Bearing Calculator
• Omnidirectional Antenna Beamwidth Analysis
• Return Loss Calculator
• Knife Edge Diffraction Loss Calculator
• Scattering: gamma in/out from s-parameters
• Lumped Component Wilkinson Splitter / Combiner Designer
• Pi & Tee Network Resistive Attenuation Calculator
• RF Safety Compliance Calculation
• Microstripline Analysis & Design
• Calculating Phase Line Length
• 3-Pole Butterworth Characteristic Bandpass Filter Calculation
• RF Pi Network Design
• PLL 3rd Order Passive Loop Filter Calculation
• Antenna Isolation Calculator

• Experienced instructors including senior executives, managers, authors, educators, consultants, course developers, and CTOs.
• Real life examples and practices
• Small class size
• Personalized instructor mentoring
• Ongoing post-training support via e-mail and phone

On-Site Classes 

On-site classes can also be tailored to meet your needs. You might shorten a 20-day class into a 5-day class, or combine portions of several related courses into a single course, or have the instructor vary the emphasis of topics depending on your staff's and site's requirements. We require a minimum of five employees and above. The CISSP (Certified Information Systems Security Professionals) exam is a six-hour, monitored paper-based exam covering 10 domains of information system security knowledge, each representing a specific area of expertise.

Customize your Boot Camp
TONEX Boot camps can be tailored to meet your specific needs. At TONEX, we gain an in-depth understanding of your organization and your training requirements. We can then customize the Boot Camp to match your project and the attendees' experience and requirements.

• Courses can be delivered to your office, providing content and focus integrated with the immediate needs of your organization.
• TONEX extracts the key elements of the course topics and packages them into an efficient and cost effective Boot Camp by eliminating the overlap and introductory redundancy.
• A customized Boot Camp gives provides immersion into a subject in a comparatively short period of time. For those requiring more detailed views, we offer Advanced courses.

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