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Magnetics for Power Electronic Converters

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Magnetics for Power Electronic Converters

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Gain insight into a topic and learn the fundamentals.
4.8

167 reviews

Intermediate level

Recommended experience

Flexible schedule
2 weeks at 10 hours a week
Learn at your own pace

Gain insight into a topic and learn the fundamentals.
4.8

167 reviews

Intermediate level

Recommended experience

Flexible schedule
2 weeks at 10 hours a week
Learn at your own pace

What you'll learn

  • Understand the fundamentals of magnetic components, including inductors and transformers

  • Analyze and model losses in magnetic components, and understand design trade-offs 

  • Design and optimize inductors and transformers for switched-mode power converters

Details to know

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Assessments

4 assignments

Taught in English
Build toward a degree

There are 4 modules in this course

This course can also be taken for academic credit as ECEA 5703, part of CU Boulder’s Master of Science in Electrical Engineering degree.

This course covers the analysis and design of magnetic components, including inductors and transformers, used in power electronic converters. The course starts with an introduction to physical principles behind inductors and transformers, including the concepts of inductance, core material saturation, airgap and energy storage in inductors, reluctance and magnetic circuit modeling, transformer equivalent circuits, magnetizing and leakage inductance. Multi-winding transformer models are also developed, including inductance matrix representation, for series and parallel structures. Modeling of losses in magnetic components covers core and winding losses, including skin and proximity effects. Finally, a complete procedure is developed for design optimization of inductors in switched-mode power converters.   After completing this course, you will: - Understand the fundamentals of magnetic components, including inductors and transformers - Be able to analyze and model losses in magnetic components, and understand design trade-offs  - Know how to design and optimize inductors and transformers for switched-mode power converters This course assumes prior completion of courses 1 and 2: Introduction to Power Electronics, and Converter Circuits.

Magnetics are an integral part of every switching converter. Often, the design of the magnetic devices cannot be isolated from the converter design. The power electronics engineer must not only model and design the converter, but must model and design the magnetics as well. Modeling and design of magnetics for switching converters is the topic of this course. In this module, basic magnetics theory is reviewed, including magnetic circuits, inductor modeling, and transformer modeling. This provides the technical tools needed in the remainder of the course to understand operation of magnetic devices, model their losses, and design magnetic devices for switching converters.

What's included

5 videos6 readings1 assignment

5 videosβ€’Total 87 minutes
  • A Brief Introduction to the Courseβ€’3 minutes
  • 10.1.1 Basic Relationshipsβ€’27 minutes
  • Lecture 10.1.2: Magnetic Circuitsβ€’14 minutes
  • Lecture 10.2: Transformer Modelingβ€’16 minutes
  • 10.3 Loss Mechanisms in Magnetic Devicesβ€’26 minutes
6 readingsβ€’Total 51 minutes
  • Course Updates and Accessibility Supportβ€’1 minute
  • Non-Credit Students: Welcome and Where to Find Helpβ€’10 minutes
  • Course Syllabusβ€’10 minutes
  • Study Problems on Basic Magneticsβ€’10 minutes
  • Magnetics Design Tablesβ€’10 minutes
  • Homework Assignmentβ€’10 minutes
1 assignmentβ€’Total 180 minutes
  • Homework Assignment 1: Basic Magneticsβ€’180 minutes

Eddy currents also cause power losses in winding conductors. This can lead to copper losses significantly in excess of the value predicted by the dc winding resistance. The specific conductor eddy current mechanisms are called the "skin effect" and the "proximity effect". These effects are most pronounced in high-current conductors of multilayer windings, particularly in high-frequency converters. This module explains these physical mechanisms and provides practical methods to compute these losses.

What's included

7 videos2 readings1 assignment

7 videosβ€’Total 89 minutes
  • 10.4.1 Introduction to the Skin and Proximity Effectsβ€’24 minutes
  • 10.4.2: Leakage Flux in Windingsβ€’18 minutes
  • 10.4.3: Foil Windings and Layersβ€’8 minutes
  • 10.4.4 Power Loss in a Layerβ€’12 minutes
  • 10.4.5 Example: Power Loss in a Transformer Windingβ€’4 minutes
  • 10.4.6 Interleaving the Windingsβ€’15 minutes
  • 10.4.7 PWM Waveform Harmonicsβ€’9 minutes
2 readingsβ€’Total 20 minutes
  • Study Problemsβ€’10 minutes
  • Homework Assignment 2: AC Winding Lossesβ€’10 minutes
1 assignmentβ€’Total 150 minutes
  • Homework Assignment 2: AC Winding Lossesβ€’150 minutes

The goal of this chapter is to design inductors for switching converters. Specifically, magnetic elements such as filter inductors are designed using the Geometric Constant (Kg) method. The maximum flux density Bmax is specified in advance, and the element is designed to attain a given copper loss. Both single-winding inductors and multiple-winding elements such as coupled inductors and flyback transformers are considered.

What's included

8 videos1 reading1 assignment

8 videosβ€’Total 93 minutes
  • 10.5 Several Types of Magnetic Devices, their B-H Loops, and Core vs. Copper Lossβ€’11 minutes
  • 11.1 Filter Inductor Design Constraintsβ€’19 minutes
  • 11.2 A First-Pass Designβ€’18 minutes
  • 11.3.1 Window Area Allocationβ€’12 minutes
  • 11.3.2 Coupled Inductor Design Constraintsβ€’6 minutes
  • 11.3.3 First-Pass Design Procedure: Coupled Inductorβ€’3 minutes
  • 11.4.1 Example: Coupled Inductor for a Two-Output Forward Converterβ€’13 minutes
  • 11.4.2 Example: CCM Flyback Transformerβ€’11 minutes
1 readingβ€’Total 10 minutes
  • Homework Assignment 3: Inductor Designβ€’10 minutes
1 assignmentβ€’Total 150 minutes
  • HW3: Inductor Designβ€’150 minutes

In a substantial class of magnetic applications, the operating flux density is limited by core loss rather than saturation. For example, in a conventional high-frequency transformer, usually it is necessary to limit the core loss by operating at a reduced value of the peak ac flux density. Hence, design of core-loss-limited magnetic devices is characterized by finding the ac flux density that minimizes total core plus copper loss.This module considers the design of transformers and ac inductors for switching converters, including minimization of total loss. Design examples include the isolation transformers of a full bridge two-output converter and of an isolated Cuk converter.

What's included

5 videos1 reading1 assignment

5 videosβ€’Total 45 minutes
  • 12.1 Transformer Design: Basic Constraintsβ€’10 minutes
  • 12.2 First-Pass Transformer Design Procedureβ€’5 minutes
  • 12.3.1 Example: Single-Output Isolated Cuk Converterβ€’13 minutes
  • 12.3.2 Example 2: Multiple-Output Full Bridge Buck Converterβ€’14 minutes
  • 12.4 AC Inductor Designβ€’3 minutes
1 readingβ€’Total 10 minutes
  • Homework Assignment 4: Transformer Designβ€’10 minutes
1 assignmentβ€’Total 150 minutes
  • HW4: Transformer Designβ€’150 minutes

Build toward a degree

This course is part of the following degree program(s) offered by University of Colorado Boulder. If you are admitted and enroll, your completed coursework may count toward your degree learning and your progress can transfer with you.ΒΉ

Instructor

Instructor ratings
4.9 (66 ratings)
University of Colorado Boulder
11 Coursesβ€’165,538 learners

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Showing 3 of 167

SR
Β·

Reviewed on May 2, 2021

this course is especially for power electronics designer

CJ
Β·

Reviewed on Dec 17, 2020

Straightforward presentation of magnetic concepts and development of a systematic approach that can be iterated to produce any manner of magnetic devices used in dc switching converters.

SN
Β·

Reviewed on Oct 23, 2020

Good course on fundamentals of Magnetics for Power Electronics

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