Course

RF Power Amplifier Design Deep Dive

課程
23 項目

Join Keysight EDA engineers for a skill-building deep dive into the best practices for designing RF power amplifiers. This boot camp guides you through a basic grounding in the different RF amplifier categories. Building upon this foundation, subsequent lessons will examine specialty topics you will encounter, with guidance on solving those challenges. Each lesson includes demonstrations and step-by-step guidance you can apply in your ADS simulations today to shorten your path to first-pass success.

Learn:

How to design an RF power amplifier and simulate the design robustness with 5G modulation.
How to optimize your design to withstand RF coupling and non-linearity effects.
How to simulate and measure the effects of a power amplifier’s change in active impedance from the dynamic changes in the load pull from a phased array antenna.

This course is ideal for RF design engineers, and anyone looking to gain a deeper understanding of RF power amplifier design for 5G circuits and systems.

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Webinars

Lesson 1 - Why is RF Simulation Important?

Keysight’s Matt Ozalas examines highly accurate RF design simulation tools, critical in today's high-tech workflows.

學習

Lesson 2 - How to Design a RF Power Amplifier

Explore the basics of simulating an RF power amplifier design, and design approaches to the different classes.

學習

Lesson 3 - Designing an Amplifier for Stability

Review design approaches of linear and nonlinear stability analysis in high-frequency circuits.

應用說明

Designing for Stability in High-Frequency Circuits

Learn how instabilities fundamentally arise and see how to resolve these challenges in the design process.

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Validate Stability Under Load Pull Conditions

Validate your power amplifier (PA) stability over all external passive loading conditions without needing to simulate every load point.

Case Studies

RF Driver Amplifiers with Better Engineered Tradeoffs

Marki Microwave leveraged circuit / EM co-simulation and stability analysis to increase first-pass success.

Webinars

Lesson 4 - Designing for 5G Modulation

Learn eight pro tips using Keysight EDA software for designing with 5G modulation.

應用說明

Designing Robust 5G Power Amplifiers

Simulating 5G power amplifier (PA) designs at the component and system levels increases predictability, lowers risk, and shrinks schedules.

Case Studies

Creating Highly Efficient mmWave Power Amplifiers

mmTron uses Keysight ADS and Keysight RFPro to identify power amplifier subtleties that only appear under modulated signals.

學習

Lesson 5 - Measuring Amplifier Distortion

This course explains the importance of characterizing nonlinear amplifier behavior.

Webinars

Lesson 6 - Designing for Digital Pre-Distortion

Learn how to unlock power amplifier (PA) design with predictive digital predistortion (DPD) transforms and linearize PA performance.

應用說明

How to Simulate a Dynamic Gain Model

Generate a dynamic gain model from a circuit envelope simulation of a power amplifier schematic in ADS.

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Optimizing Power Amplifier Designs for Predistortion

Learn how to optimize your power amplifier for digital predistortion with Keysight ADS.

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Lesson 7 - MMIC Power Amplifier Electrothermal Analysis

Perform electrothermal analysis of a monolithic microwave integrated circuit (MMIC) power amplifier to gain insights into the performance and reliability.

Case Studies

Multivariable Design Optimization via Simulation

Broadcom uses a science-based approach for complex multivariable design optimization via simulation.

學習

Lesson 8 - Load Pull Design Techniques

See practical examples of using load-pull data in a power amplifier design to optimize PAE, EVM, and ACLR.

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Automate Load-Pull Simulations with Python

Integrate test instruments, import and design with load-pull data, and turn data into an executable simulation model.

解決方案簡介

Phased Array Models for Amplifier Load Pull

Behavioral simulation captures power amplifier load pull and array active impedance effects on beamforming.

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Phased Array Beamforming Optimization

Streamline design capture, predict accurate beam performance with active impedance and load pull, and visualize beam key performance indicators (KPIs).