LTE RF Engineering Training

LTE RF Engineering Training


LTE RF Engineering Training Course Powered by ENO

LTE RF Engineering Training Course Program, a strong understanding of RF engineering fundamentals is required to optimize the performance of LTE networks.

LTE RF engineering training program provides the engineering and non-engineering professional with the LTE technological advances in both the commercial and military arenas. You will learn the fundamental principles of LTE, MIMO, RF systems, the design of practical and cost effective LTE RF subsystems, and integrated circuits or full LTE RF systems. Learn the key concepts of planning, analyzing, modeling, simulating, design, implementation, integration testing, verification and validating RF systems related to LTE and LTE-Advanced.

Customize It:

With onsite Training, courses can be scheduled on a date that is convenient for you, and because they can be scheduled at your location, you don’t incur travel costs and students won’t be away from home. Onsite classes can also be tailored to meet your needs. You might shorten a 5-day class into a 3-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.

LTE RF Engineering TrainingRelated Courses:

Duration: 3 days


◾LTE Systems Engineering Principles
◾LTE RF Principles and Applications
◾Principles of OFDMA, SC-FDMA and MIMO
◾LTE Design and Applications
◾LTE Cell Planning Principles
◾LTE Link Budget Calculation
◾LTE Transmission and Backhauling Engineering
◾Antenna Theory and Design
◾LTE M2M, IoT and Remote Sensors
◾LTE Test & Measurement
◾RF System Design for LTE and LTE-A Communications
◾LTE RF Circuit Design
◾LTE RFIC Design
◾Software Defined Radios (SDR) Applied to LTE

Course Content:

LTE Systems Engineering Principles
◾Foundations of System Engineering
◾LTE standards, architectures, and processes
◾LTE system requirements
◾LTE systems management
◾LTE system functional analysis
◾LTE system analysis of alternatives
◾LTE decision making and support
◾LTE operational analysis
◾Engineering principles of complex LTE systems
◾LTE system development process
◾LTE system engineering management
◾LTE system engineering development stages
◾LTE system Integration and evaluation
◾LTE operation and support

LTE RF Principles and Applications
◾LTE RF environment
◾LTE frequency bands
◾Propagation principles of LTE
◾LTE antennas
◾Scattering parameters in LTE radio
◾LTE system active and passive components
◾Analysis of low noise high power amplifiers for LTE
◾LTE modulation and demodulation techniques
◾LTE circuits
◾LTE receiver/transmitter characteristics
◾Transmission lines

Principles of OFDMA, SC-FDMA and MIMO
◾LTE air interface
◾LTE Multiple Access principles
◾OFDMA basics
◾SC-FDMA basics
◾MIMO basics
◾MU-MIMO principles

LTE Design and Applications
◾Implementation of LTE RF circuits
◾LTE Integrated Circuit (IC) configurations
◾LTE passive components
◾LTE low noise amplifiers and mixers
◾LTE IC packaging and testing
◾LTE transceiver architectures

LTE Cell Planning Principles
◾LTE radio propagation fundamentals
◾LTE frequency planning and management
◾LTE cell planning tools and procedures
◾Uplink vs. downlink coverage analysis
◾LTE traffic engineering
◾LTE capacity planning and management
◾LTE RF optimization principals
◾LTE cell planning KPIs

LTE Link Budget Calculation
◾What is link budget?
◾Typical link budget elements
◾LTE link losses and gains from the transmitter
◾Channel losses, Path loss
◾Transmitter output power
◾How much sensitivity do we need?
◾Transmit antenna gain
◾Receive antenna gain
◾Receiver noise power
◾Link margin
◾Variations on the basic link budget
◾LTE Sample Link Budget

LTE Transmission and Backhauling Engineering
◾LTE transmission network design, planning and implementation
◾LTE link engineering
◾LTE network performance and reliability issues
◾LTE link protection
◾Project management and logistics
◾LTE deployment challenges

LTE Antenna Theory and Design
◾Principles of electromagnetic radiation fields
◾Antenna fundamentals
◾Various antennas in LTE deployment
◾Application of antennas in communication links

LTE M2M, IoT and Remote Sensors
◾M2M basics
◾IoT basics
◾Remote Sensors applications
◾Surveillance, tracking and target detection systems
◾Commercial and military grade
◾Passive and active sensors
◾Sensor system technologies and LTE
◾Comparison to microwave/millimeter-wave Radar
◾Electro-optical and Thermal imaging systems

LTE Test & Measurement
◾Introduction to RF/LTE parameters
◾Measurement principles and test techniques
◾LTE test and measurement methods and equipment specifications
◾LTE simulations software based tools
◾LTE network and spectrum analysis

RF System Design for LTE and LTE-A
◾Characteristics and benefits RF systems in LTE applications
◾LTE system blocks and functions
◾LTE system architecture requirements
◾Calculation of critical system characteristics
◾LTE sensitivity requirements
◾System response
◾Effect of temperature changes
◾LTE system measurements
◾LTE RF circuit design
◾LTE passive and active components
◾Basic impedance matching; S-parameters
◾Stability prediction
◾LTE amplifier design
◾Coupling structures
◾Filters and mixers
◾Non-linearity and its effects
◾LTE transceiver architectures
◾Design tradeoffs between various blocks in a system

Software Defined Radios (SDR) in LTE
◾What is SDR?
◾Software aspects of SDRs
◾LTE SDR applications
◾SDR current developments and implementations
◾Benefits and challenges of LTE SDR development and deployment

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    Time Frame: 0-3 Months4-12 Months

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