Summary

Based on SM Technologies famous RF course material, this program has been reworked and updated to meet the needs of today’s engineers looking for online self-paced study. Video lectures are followed by our exclusive online workbooks featuring interactive problem sets and quizzes along with optional supplemental reading for those who wish to explore topics in more depth. A bonus guest tutorial from a SM Technologies instructor offers a different perspective on one of the topics covered in the course (guest tutorials vary by course offering). This course is the first part of an RF Engineering Certificate program currently under development by SM Technologies.

Even when working with “off the shelf” integrated radio products, engineers still need a basic understanding of circuit operation and design considerations to assure a successful product implementation and avoid unexpected pitfalls. Switching from traditional circuit definitions based on voltages and currents, to power-flow concepts and scattering parameters, this course offers engineers a smooth transition into understanding circuit operation in the RF and wireless domain. We review S-parameter measurements and applications for both single-ended (unbalanced) and balanced circuits. Impedance matching is vitally important in RF systems and we use both graphical (Smith Chart ) and analytical techniques throughout the course. We also examine discrete and monolithic component models in their physical forms, discussing parasitic effects and losses, revealing reasons why circuit elements behave in surprising manners at RF.

Since wires and printed circuit conductors may behave as transmission line elements, we also cover microstrip and stripline realizations. Another important consideration is circuit layout, therefore we look at problems caused by coupling, grounding and parasitic resistance.

Learning objectives

Upon completing the course you will be able to:

• design impedance matching networks analytically
• use S-parameters to predict basic performance of components
• use the Smith Chart for matching network design and to visualize circuit performance
• predict the effect of parasitics on capacitor and inductor performance at higher frequencies
• convert series circuits to parallel equivalents and vice versa
• decide when to treat interconnects as transmission lines
• use transmission lines for matching networks
• understand some basic principles of PC board behavior at high frequencies

Target Audience

This course is intended for students with an engineering background or equivalent practical experience. The material covered is similar to the RF Technology Certification program (part 1), but with with more in-depth numerical design examples and exercises.

The course follows the proven format of the RF Technology Certification program, with video lectures followed by online workbooks. The exercises in the workbooks are expanded with more custom calculators and design work. A free open-source RF circuit simulator is employed for working on simple design exampels.

Outline

Course Overview

• Frequency spectrum • Power levels at RF

Basic Analytical Tools

• dB, dBm • Complex number review • wave parameters

Complex Impedance, Resonance

• Series RC, RL networks • Parallel RC, RL networks • Resonance • Q factor • conversion between series and parallel circuits

Transmission Lines

• transmission line types • characteristic impedance • the 5% rule • lumped vs. distributed networks • short and open terminated transmission lines

Reflections

• mismatch and reflections • reflection coefficient • return loss • mismatch loss • SWR

Basic Derivation

• derivation of impedance curves – resistance – reactance • admittance chart

Component Manipulations

• Series Capacitor, Inductor, Resistor • Parallel Capacitor, Inductor, Resistor • Transmission lines

Definition

• what the S-parameters refer to • comparison with Z, Y, ABCD parameters

Measurement

• basic network analyzer block diagram

Cascaded Calculations

• Cascaded S-parameters • T-parameters

Differential Circuits

• Mixed mode S-parameters • Description of X-parameters

Analytical Techniques

• Using Q to Match Impedances • absorbing reactances • resonating reactances • Smith Chart • visualizing matching networks on the Smith Chart

Lumped Elements at RF

• resistor component models • capacitor component models • inductor component models • behavior at high frequencies • package effects • ferrite behavior

• Via hole inductance • multi-layer PC-board parasitics • via stub effects • PC board materials, dielectric constants

Transmission Lines

• transmission line realizations • discontinuities • converting a circuit schematic to physical form

Summary

Power amplifiers are crucially important in determining a communications system cost, efficiency, size, and weight. Designing high power / high efficiency amplifiers that satisfy the system requirements (bandwidth, linearity, spectral mask, etc.) is challenging. It involves difficult trade-offs, proper understanding of the theory, and careful attention to details. Additionally, designing, building, and testing power amplifiers usually pushes test equipment and lab components to their limits and frequently results in damage to the circuit or lab equipment. This course will examine the different aspects of this challenge with emphasis on hand-on exercises and practical tips to build power amplifiers successfully. This course will give special attention to GaN power amplifiers. Differences between GaN pHEMT, Si LDMOS,GaAs MESFETs, and SiGe will be discussed.

Learning objectives

Upon completing the course you will be able to:

• Learn the advantages and limitations of various technologies.
• Gain an understanding of the pros and cons of various classes operations.
• Learn how to characterize device for power amplifier design.
• Acquire design know-how of high efficiency amplifiers.
• Attain practical knowledge on the design of linear amplifiers.
• Calculate the lifetime of power amplifiers in packaged and unpackaged assemblies.

Target Audience

Microwave engineers who want to design, fabricate, and test power amplifiers, in the 1-50 GHz frequency range, will benefit from this comprehensive design course. Basic knowledge of microwave measurements and transmission line (Smith Chart) theory is assumed.

Outline

Power amplifier Fundamentals

 • Device technologies: GaAs, LDMOS, GaN, Si, SiGe • Small signal model generation, transistor speed (ft, and fmax) calculation. • Power Amplifier Stability: even mode, odd mode. • Optimum power load estimation, calculation, and simulation. • Load-pull characterization of devices. • Device characteristics and non-idealities. • Dependence of transistor parameters on drive level. • Large signal models. • Power Amplifier biasing. • Exercise: GaN pHEMT small signal model generation.

Conventional and High Efficiency Amplifier Design

 • Power amplifier classes A, B, AB, C, and D; concepts, designs, and examples. • Waveform engineering for maximum efficiency. • Class E Switching mode power amplifiers: Concept, Design, Limitations, Maximum Frequency, Exercises, and Examples. • Class F (and F-1) power amplifiers: Concept, Design, Limitations, and Examples. • Comparison of various classes: efficiency, output power, and frequency limitations. • Doherty power amplifiers • Effects of knee voltage, harmonic terminations, and nonlinearities. • GaN pHEMT power amplifiers

Linearization Techniques, Power Combing, Packaging, and Reliability

 • Distortions in power amplifiers. • Harmonic balance and time domain simulations. • Linear/Non-linear Memory effects; electrical and thermal memory effects • Measures of Distortion: Third order intermodulation, ACPR, NPR, M-IMR • Linearization techniques: Feed Forward, Predistortion, LINC, Cartesian Feedback, Envelope Elimination and Restoration, Cross Cancellation. • Comparison of Linearization Techniques •  Real world design examples, challenges, and solutions. • Push-pull, Balanced amplifiers, and Traveling Wave Combiners. • Power combining techniques. • Exercise: Design of a power combiner. • Package design • Power Combing, Packaging, and Reliability • Thermal management and reliability calculations. • Biasing and transient considerations. • Exercise: calculating required biasing for 20+ year lifetime.

Summary

The successful design of mm-Wave (Millimeter Wave) monolithic microwave integrated circuits (MMICs) and RFICs is the result of a disciplined design approach. This course covers, in detail, the theory, and practical strategies required to achieve first-pass design success. Specifically, the course covers the implementation of mm-Wave circuits on SiGe, GaAs, InP, and GaN substrates including instruction on processing, masks, simulation, layout, design rule checking, packaging, and testing. Numerous design examples are provided with emphasis on increasing yield, and reliability.

Learning objectives

Upon completing the course you will be able to:

• Learn the advantages and limitations of MMIC Designs
• Take advantage of the inherent benefits of MMICs over hybrid circuits.
• Account for the parasitics of the active device.
• Design biasing networks for active circuits.
• Design broadband amplifier.
• Design MMIC power amplifiers at mm-Wave.
• Test and detect odd and even-mode instabilities.
• Improve the yield of MMIC chips.
• Calculate the lifetime of MMIC chips in packaged and unpackaged assemblies.

Target Audience

Microwave engineers who want to design, fabricate, and test robust RF/Wireless MMICs, in the 30-100 GHz frequency range, will benefit from this comprehensive design course. Basic knowledge of microwave measurements and transmission line (Smith Chart) theory is assumed.

Outline

Introduction to MMIC Design

 • Advantages and tradeoffs: true cost, performance, reliability, size • Unique mm-Wave applications: Satellite communications, automotive radar, 5G, 60 GHz communications, beamforming •  Choosing among device technologies: GaAs FET/pHEMT, GaAs HBT, InP, SiGe, GaN HEMT • RFIC/MMIC Design cycle – process selection, device characterization, circuit topology decision, design, taping-out, testing

Passive MMIC Elements

 • mm-Wave element modeling – capacitors, inductors, transformers, via holes • Transmission line modeling – microstrip, coplanar. • mm-Wave combiners and dividers – Wilkinson, Lange, Pi-wave • Baluns, coupled lines, couplers. • mm-Wave impedance matching – Ruthroff transformer, Trifilar structure, and Coupled transmission line transformer

Odd / Even-mode Instability Detection

 • Gain definitions: Gmax, MSG, Unilateral gain • Conjugate matching • Stability analysis – odd mode, even mode analysis, bias-induced instabilities. Instability tests

Active Devices

 • De-embedding, Characterization, modeling. • GaAs MESFET, pHEMT, HBT, SiGe, InP and GaN HEMT • Device parameters: ft, fmax, gm, RON, parasitics • Equivalent circuit—physical basis • Intrinsic equivalent circuit • Illustrative example: equivalent circuit extraction • Thermal resistance and lifetime estimation • Design example: choosing FET gate-pitch and bias for 10+ years lifetime

mm-Wave Amplifiers

 • Biasing network selection

Single stage design: lumped vs. distributed matching

 • Design example: 30 GHz 4W GaN feedback amplifier • Multi-stage design

Sample Case Studies

 • Designing a 20 – 40 GHz 10 W GaN amplifier • Designing a 75 – 100 GHz 2W amplifier • Designing a 80 GHz SiGe amplifier • Designing a 45 GHz CMOS amplifier • Design a 28 GHz CMOS amplifier

Layout

 • Layout design rules • Process control and monitoring • Reverse engineering • Yield and sensitivity analysis

Testing and Packaging

 • Rapid testing: on-wafer, dc-screening • Package design • Package parasitics – cavity effects, stabilization • Thermal management – epoxy, eutectic

Summary

This online program has been designed for applications, production, manufacturing engineers and technicians as well as other professionals who need to have a solid background in the fundamentals of working with RF and wireless products. This four part program provides a thorough understanding of RF analytical tools, communications signals, RF devices and test instruments. Starting with basic analytical tools such as the decibel scale, S-parameters and the Smith Chart, this program covers test instrumentation, RF components, and modulation. A basic block diagram of a transmitter/receiver chain forms the backbone of the course outline. Each component is described, and the relative performance parameters defined. Key impairments are introduced as they become relevant to the operation of the system. Basic system calculations are covered, as well as modulation formats and multiple access techniques.

The self-paced program is divided into four parts, each consisting of pre-recorded self-paced lectures followed by custom online “workbooks” that contain a summary of formulas learned and practice exercise questions or measurement procedures. A bonus on-demand tutorial webcast in each part offers an additional perspective on a related topic of interest. Each part has a brief test as well. The program is equivalent to approximately 40 hours of training and students are given six months to complete the material. After finishing the program students will receive a signed certificate of completion.

Learning objectives

Upon completing the course you will be able to:

• work natively with dB values (without using a calculator)
• understand basic wave parameters and propagation
• appreciate the effects of parasitics on component behavior
• understand the effects of mismatches at RF
• create basic matching networks using the Smith Chart
• describe basic transmission line structures and input impedance
• interpret S-parameters from measurements and datasheets
• describe the basic function of spectrum analyzers, vector network analyzers, and power meters
• know the limitations on accuracy/uncertainty that affect all RF and high frequency measurements
• describe the operation of the main components of an RF transceiver system
• interpret key performance parameters such as P1dB, IP3, noise figure, etc.
• describe the modulation formats used to impress information onto the RF carrier
• understand the basic principles of multiple access techniques such as TDMA, CDMA, OFDMA

Target Audience

This program is ideally suited for applications, manufacturing and production engineers or technicians who are new to the RF/wireless field. It is also suitable for those who have been working in the field but who have not had a formal introduction to the key concepts that form the basis of understanding and troubleshooting wireless systems. A knowledge of basic circuit theory/operation (resistors, inductors, capacitors) is assumed.

Outline

Analytical tools

 • wave parameters • dB & dBm • mismatches and reflection • impedance matching and the Smith Chart • transmission lines • device parasitics and their effects • S-parameters

Modulation

 • Analog – AM, FM • IQ Modulation – PSK – QAM

Multiple Access Techniques

 • FDMA • TDMA • CDMA • OFDMA

Performance of RF Components with Digital Signals

 • digital modulation fundamentals • adjacent channel power ACP • error vector magnitude EVM • EVM due to power amplifier compression and AM to PM • EVM due to group delay • EVM due to phase noise • IQ modulator troubleshooting with the VSA

Description of Bit Error Rate

Cables and Connectors

 • cable and connector care • connector types

Vector Network Analyzer

 • directional couplers • basic block diagram • calibration • basic measurement setup

Spectrum Analyzer

 • time domain vs. frequency domain • basic block diagram • typical measurements

Signal Generator

 • basic block diagram

Power Meters

 • power detection

Noise Figure Meter

Vector Signal Analyzer

 • basic introduction

Measurement Uncertainties

 • mismatch uncertainty • systematic errors in VNA measurements • VNA calibration • instrument-generated distortion products

Measurements of Non-connectorized devices

 • de-embedding • alternate calibration types: TRL • fixturing

Phase Locked Oscillator

 • principles of operation • phase noise – measurement techniques – impacts of phase noise on sytem performance

Upconverter

 • modulation basics • principles of operation • 1 dB compression point for active devices • output spectrum of upconverter

Power Amplifier

 • principles of operation • 1 dB compression point, saturation • AM to PM distortion • harmonics

Antennas

 • description of antenna types • dBi, dBd gain parameters

Filters

 • common filter types – Butterworth, Chebychev, Gaussian • transfer function • inband loss • match • bandwidth • group delay

Noise and Noise Figure

 • definition of thermal noise • definition of noise figure • techniques for measuring noise figure – Y-factor technique – cold-source

Low Noise Amplifiers

 • principles of operation • noise figure • intermodulation products • S-parameters – input vs. output match • 1 dB compression point

Mixer

 • principles of operation • image noise from LNA

Intermodulation products

 • how intermodulation products are produced • definition of IP3 • definition of IP2

Overall Receiver Performance

 • typical overall receiver performance • cascaded noise figure, IP3 • SFDR Spur Free Dynamic Range

Summary

This two-day course provides participants with coverage of antenna element, phased array, link budget, propagation, integration and test topics associated with millimeter Wave (mm-Wave) and 5G applications. The course provides an understanding of antenna property definitions, antenna fundamentals and considerations, antenna types and mm-Wave propagation. The course provides information on how antenna properties and propagation characteristics affect communication systems. Topics also covered include how to test and measure mm-Wave antenna performance.

Learning objectives

Upon completing the course you will be able to:

• Understand the concepts associated with antenna performance, operation and classification.
• Describe and understand mm-Wave antenna types.
• Implement antenna arrays using basic principles.
• Account for antenna performance and the mm-Wave propagation environment when predicting communication system performance.
• Measure and test mm-Wave antenna performance.

Target Audience

The course is well suited for those who require an understanding of antenna principles and concepts related to mm-Wave applications. Basic mathematical and computing skills are a prerequisite for this course. An electrical engineering background or equivalent practical experience is recommended but not required.

Outline

Basic RF Concepts

 • Basic design and performance requirements of a wireless communication system

Basic Antenna Concepts

 • Definitions of basic antenna properties – impedance, VSWR, bandwidth, directivity, gain, radiation patterns, polarization, etc.

Fundamental Antenna Elements

 • The Monopole • The Dipole • The Loop • The Slot • Microstrip Antennas

Waveguides

 • Basic Concepts • Size versus Frequency • Common Waveguides • Connection Tips

Aperture Antennas

 • Aperture design concepts • The horn antenna • The reflector antenna

Antenna Arrays

 • Fundamental array theory • Types of antenna arrays • Feed network design considerations • Beam steering and shaping concepts • Performance trade-offs

mm-Wave Propagation

 • Friis Equation • The communication link • Understanding and calculating path loss • Receiver Sensitivity and antenna noise figure • Link budget calculations • Atmospheric Loss • Rain Attenuation • Sky Noise • Other Topics

Common mm-Wave Antennas

 • Overview of Common mm-Wave Antennas

mm-Wave Antenna Testing

 • Antenna Ranges • Far-field Testing • Near-Field Testing • How to test and measure antenna performance