Power Electronics

This course covers modeling, analysis, and design of power electronic circuits used for efficient energy conversion and control, including rectifiers, DC-DC converters, inverters, magnetics, loss/thermal design, control, EMI, and advanced soft-switching/resonant techniques.

No Certificate / Course on Audit Track

About Course

This course offers a structured and in-depth study of power electronics, focusing on the principles, analysis, and practical design of power conversion systems. Beginning with core fundamentals, learners develop a strong understanding of rectifiers, AC systems, and non-isolated DC–DC converters. The course then covers magnetics, isolation techniques, losses, and thermal considerations essential for efficient and reliable converter design.

Advanced topics include inverters, switched-mode rectifiers, and three-phase systems, enabling learners to work with industrial and high-power applications. The course also emphasizes control strategies for power converters, addressing stability, performance, and dynamic response. In the final modules, students explore EMI mitigation, advanced conversion techniques, and practical implementation aspects, preparing them to design, analyze, and deploy real-world power electronic systems.

Authorship and Attribution

This course has been curated by Riphah International University faculty and staff using publicly available third-party content and Open Educational Resources (OER) for self-paced learning. Learners will engage with curated open-access materials to achieve the course learning outcomes. All third-party content is used under open-access or fair-use policies, while any original materials are developed specifically for this learning experience.

Source and Credits :

Instructor: Dr. Justin Johnson
Provider: MIT OpenCourseWare YouTube (@mitocw)
License: Standard YouTube license

What You'll Learn

By completing this course, you will be able to:

Explain the role of power electronics in energy conversion and identify application domains across power levels (consumer → industrial).
Analyze basic power conversion stages (rectification, DC-DC conversion, inversion) using switching models and periodic steady-state concepts.
Design DC-DC converters to meet voltage regulation, ripple, efficiency, and device stress constraints.
Evaluate magnetics and isolation design considerations (inductors/transformers), including losses and practical constraints.
Apply converter control concepts (small-signal thinking, loop shaping concepts, current-mode control basics) for stable regulation.
Assess switching losses, snubbers, thermal design, and EMI mitigation techniques for reliable hardware implementation.
Integrate advanced conversion methods (soft switching, resonant conversion, gate drive/layout) into practical design decisions.

Prerequisites

To be successful in this course, learners should have:

Circuit analysis (RLC, phasors), basic electronics (diodes/MOSFET/IGBT concepts)
Signals/control basics helpful (transfer functions, feedback fundamentals)
Comfort with algebra/calculus at engineering level

Who Can Take This Course?

This course is designed for:

Senior undergraduate / graduate students in Electrical Engineering
Engineers who need practical understanding of converters, regulation, and power stage design
Students working in renewable energy, drives, UPS, EV powertrains, and power supplies

Course Outline

Module 1: Introduction and Fundamentals

Course intro and overview

Introduction to Power Electronics (Video)

Module 2: Rectifiers and AC

Rectifiers and Analysis Method

Analysis Methods and Rectifiers (Video)

Regulation & Power actor

Load Regulation (Video)

Power Factor (Video)

Module 3: DC-DC Conversion (Non-Isolated)

Intro to DC-DC (Part 1–4)

DC/DC, Part 1 (Video)

DC/DC, Part 2 (Video)

DC/DC, Part 3 (Video)

DC/DC, Part 4 (Video)

Module 4: Magnetics, Isolation, Losses, Thermal

Magnetics (Part 1–4)

Magnetics, Part 1 (Video)

Magnetics, Part 2 (Video)

Magnetics, Part 3 (Video)

Magnetics, Part 4 (Video)

Isolated DC-DC (Part 1–2)

Isolated DC/DC Converters, Part 1 (Video)

Isolated DC/DC Converters, Part 2 (Video)

Losses, Snubbers, Thermal

Switching Losses and Snubbers (Video)

Thermal Modeling and Heat Sinking (Video)

Module 5: Inverters and Switched-Mode Rectifiers

Inverters (Part 1–3)

Inverters, Part 1 (Video)

Inverters, Part 2 (Video)

Inverters, Part 3 (Video)

Switched-mode rectifiers

Switched-Mode Rectifiers (Video)

Module 6: Three-Phase Systems and Three-Phase Inverters

Three-Phase Systems (Part 1-2)

Three-Phase Systems, Part 1 (Video)

Three-Phase Systems, Part 2 (Video)

Three-Phase Inverters

Three-Phase Inverters (Video)

Module 7: Control of Power Converters

Basic concepts of dynamic control (part 1-3)

Control, Part 1 (Video)

Control, Part 2 (Video)

Control, Part 3 (Video)

Current mode control

Current-Mode Control (Video)

Module 8: EMI + Advanced Conversion + Practical Implementation

EMI filters (Part 1–3)

EMI Filters, Part 1 (Video)

EMI Filters, Part 2 (Video)

EMI Filters, Part 3 (Video)

Switched-capacitor converters (Part 1–2)

Switched-Capacitor Convertors, Part 1 (Video)

Switched-Capacitor Convertors, Part 2 (Video)

Soft switching + resonant conversion + gate drive/layout

Soft Switching, Part 1 (Video)

Soft Switching, Part 2 (Video)

Resonant Power Conversion, Part 1 (Video)

Resonant Power Conversion, Part 2 (Video)

Resonant Converters: Matching Networks (Video)

Gate Drive, Level Shift, Layout (Video)

Skills You Will Gain

Converter Design Rectifier Analysis DC-DC Conversion Inverter Systems Converter Control EMI Mitigation

Course Information

Duration

Approximately 32 Hours

Course Information

Category: Engineering & Applied Sciences
Type: Self-paced
Start Date: Feb 16, 2026

Difficulty Level

Intermediate

Learning Mode

Fully Online (Asynchronous)

Learning Type

Self Paced

Language

English Only

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