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Dr. Dragan Maksimovic

This course can also be taken for academic credit as ECEA 5709, part of CU Boulder’s Master of Science in Electrical Engineering degree.

This is Course #5 in the Modeling and Control of Power Electronics Specialization. The course is focused on modeling and control of grid-tied power electronics. Upon completion of the course, you will be able to understand, analyze, model, and design low-harmonic rectifiers and inverters interfacing dc loads or dc power sources, such as photovoltaic arrays, to the single-phase ac power grid.

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This course can also be taken for academic credit as ECEA 5709, part of CU Boulder’s Master of Science in Electrical Engineering degree.

This is Course #5 in the Modeling and Control of Power Electronics Specialization. The course is focused on modeling and control of grid-tied power electronics. Upon completion of the course, you will be able to understand, analyze, model, and design low-harmonic rectifiers and inverters interfacing dc loads or dc power sources, such as photovoltaic arrays, to the single-phase ac power grid.

We strongly recommend students complete the CU Boulder Power Electronics Specialization as well as Courses #1 (Averaged-Switch Modeling and Simulation) and #4 (Current-Mode Control) before enrolling in this course (the course numbers provided below are for students in the CU Boulder's MS-EE program):

● Introduction to Power Electronics (ECEA 5700)

● Converter Circuits (ECEA 5701)

● Converter Control (ECEA 5702)

● Averaged-Switch Modeling and Simulation (ECEA 5705)

● Current-Mode Control (ECEA 5708)

After completing this course, you will be able to:

● Understand the operating principles of low-harmonic, high power factor rectifier and inverters

● Model and design current shaping and voltage control loops in power factor correction (PFC) rectifiers

● Model and design control loops in single-phase dc-to-ac inverters

● Design photovoltaic power systems tied to the single-phase ac power grid

● Use computer-aided tools and simulations to verify the design of rectifiers and inverters

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What's inside

Syllabus

Grid-Tied Power Electronics
Introduction to power factor and harmonics, operating principles, and modeling of low-harmonic power factor correction (PFC) rectifiers.
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Control of Power Factor Correction Rectifiers
Modeling of low-harmonic rectifiers, the need for energy storage in single-phase systems, and design of current and voltage control loops.
Modeling and Control of Single-Phase Inverters
Introduction to photovoltaic (PV) systems, modeling and control of single-phase PV inverters.

Good to know

Know what's good
, what to watch for
, and possible dealbreakers
Develops knowledge of control loops in power factor correction (PFC) rectifiers, inverters, and photovoltaic (PV) systems
Taught by Dr. Dragan Maksimovic, who is known for his research in power electronics and control systems
Part of the Modeling and Control of Power Electronics Specialization, which provides a comprehensive foundation in the field
Explores the modeling and control of grid-tied power electronics, which is a highly relevant topic for industry and academia
Requires students to have completed previous courses in the specialization, which may hinder accessibility for some learners
Assumes prior knowledge of averaged-switch modeling and simulation and current-mode control, which may not be suitable for all students

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Reviews summary

Well-received rectifier & inverter course

Learners say this modeling and control course is good with clear explanations and practical applications. They found the course engaging and enjoyed the MATLAB and LTspice simulations. Several learners praised the instructor's teaching style and expertise. However, one learner mentioned having concerns which a free Q&A session could address.
Includes engaging assignments and simulations
"Good practical course with lots of modern applications."
"I enjoyed the final peer graded assignment."
"Access to Matlab, use of LTspice. You will practice transfer functions a lot."
Instructor is knowledgeable and provides clear explanations
"Professor gives clear explanations and proofs. Better teaching than usual professors."
"Thank you very much Dr. Maksimovic for the techniques and skills taught."
One learner mentioned having some concerns
"As a recommendation, I would add a free Q&A meeting for possible concerns about the course."

Activities

Be better prepared before your course. Deepen your understanding during and after it. Supplement your coursework and achieve mastery of the topics covered in Modeling and Control of Single-Phase Rectifiers and Inverters with these activities:
Review the basics of circuit analysis.
Refreshing the basics of circuit analysis will provide a strong foundation for understanding the concepts of the course.
Browse courses on Circuit Analysis
Show steps
Review the concepts of power electronics.
Refreshing the concepts of power electronics will help to ensure that students have a strong understanding of the prerequisites for this course.
Browse courses on Power Electronics
Show steps
Fundamentals of Power Electronics by Robert W. Erickson
Reviewing this book will provide a deeper understanding of the fundamentals of power electronics.
Show steps
Three other activities
Expand to see all activities and additional details
Show all six activities
Power Electronics by Muhammad H. Rashid
Reviewing this book will provide a comprehensive overview of power electronics.
Show steps
Practice solving problems related to modeling power factor correction rectifiers
Solving practice problems will reinforce the concepts of modeling power factor correction rectifiers.
Show steps
  • Identify the key concepts and formulas for modeling power factor correction rectifiers.
  • Find and solve practice problems related to modeling power factor correction rectifiers.
  • Check your solutions and identify areas for improvement.
Follow tutorials on designing current shaping and voltage control loops in PFC rectifiers
Following tutorials will provide practical guidance on designing current shaping and voltage control loops in PFC rectifiers.
Show steps
  • Find tutorials on designing current shaping and voltage control loops in PFC rectifiers.
  • Follow the steps outlined in the tutorials and apply the concepts to practice problems.
  • Review the outcomes and identify areas for further exploration.

Career center

Learners who complete Modeling and Control of Single-Phase Rectifiers and Inverters will develop knowledge and skills that may be useful to these careers:
Power Electronics Engineer
Power Electronics Engineers design, develop, and test power electronic systems. To succeed in this role, one could enroll in a course on modeling and control of single-phase rectifiers and inverters to gain specialized knowledge in the modeling, design, and control of power electronic systems. This course is especially relevant because it covers topics such as Grid-Tied Power Electronics, Control of Power Factor Correction Rectifiers, Modeling and Control of Single-Phase Inverters, which are fundamental concepts in power electronics engineering.
Power Systems Engineer
Power Systems Engineers design, develop, and maintain power systems. To succeed in this role, one might consider studying modeling and control of single-phase rectifiers and inverters to gain specialized knowledge in the modeling, design, and control of power electronic systems. This course is particularly relevant because it covers topics such as Grid-Tied Power Electronics, Control of Power Factor Correction Rectifiers, Modeling and Control of Single-Phase Inverters, which are essential for designing and maintaining power systems.
Electrical Engineer
Electrical Engineers design, develop, and maintain electrical systems. To excel in this role, one could consider taking a course on modeling and control of single-phase rectifiers and inverters to build a strong foundation in power electronics. This course is particularly relevant because it covers topics such as Grid-Tied Power Electronics, Control of Power Factor Correction Rectifiers, Modeling and Control of Single-Phase Inverters, which are essential for designing and maintaining electrical systems.
Electronics Engineer
Electronics Engineers design, develop, and test electronic devices and systems. To be successful in this role, one might consider studying modeling and control of single-phase rectifiers and inverters to gain specialized knowledge in the modeling and control of power electronic systems. This course is especially relevant because it covers topics such as Grid-Tied Power Electronics, Control of Power Factor Correction Rectifiers, Modeling and Control of Single-Phase Inverters, which are essential for designing and testing electronic devices and systems.
Mechatronics Engineer
Mechatronics Engineers design, develop, and maintain mechatronic systems. To excel in this role, one could consider taking a course on modeling and control of single-phase rectifiers and inverters to build a foundation in power electronics. This course is particularly relevant because it covers topics such as Grid-Tied Power Electronics, Control of Power Factor Correction Rectifiers, Modeling and Control of Single-Phase Inverters, which are fundamental concepts in mechatronics engineering.
Industrial Automation Engineer
Industrial Automation Engineers design, develop, and maintain automated systems in industrial settings. To excel in this role, one could study modeling and control of single-phase rectifiers and inverters to build a foundation in the fundamentals of power electronics. This course is particularly relevant because it covers topics such as control of Power Factor Correction Rectifiers, Modeling and Control of Single-Phase Inverters, and Introduction to photovoltaic (PV) systems, all of which are essential for designing and maintaining automated systems in industrial settings.
Controls Engineer
Controls Engineers design, develop, and maintain control systems. To be successful in this role, one could consider taking a course on modeling and control of single-phase rectifiers and inverters to gain specialized knowledge in the modeling and control of power electronic systems. This course is especially relevant because it covers topics such as Control of Power Factor Correction Rectifiers, Modeling and Control of Single-Phase Inverters, which are essential for designing and maintaining control systems.
Renewable Energy Engineer
Renewable Energy Engineers design, develop, and maintain renewable energy systems. To excel in this role, one could consider taking a course on modeling and control of single-phase rectifiers and inverters to build a foundation in power electronics. This course is especially relevant because it covers topics such as Grid-Tied Power Electronics, Modeling and Control of Single-Phase Inverters, Introduction to photovoltaic (PV) systems, which are fundamental concepts in renewable energy engineering.
Product Development Engineer
Product Development Engineers design, develop, and test new products. To excel in this role, one could consider taking a course on modeling and control of single-phase rectifiers and inverters to build a foundation in power electronics. This course is particularly relevant because it covers topics such as Grid-Tied Power Electronics, Control of Power Factor Correction Rectifiers, Modeling and Control of Single-Phase Inverters, which are fundamental concepts in product development engineering.
Robotics Engineer
Robotics Engineers design, develop, and maintain robots. To be successful in this role, one might consider studying modeling and control of single-phase rectifiers and inverters to gain specialized knowledge in the modeling and control of power electronic systems. This course is especially relevant because it covers topics such as Control of Power Factor Correction Rectifiers, Modeling and Control of Single-Phase Inverters, which are essential for designing and maintaining robots.
Test Engineer
Test Engineers design and conduct tests to ensure that products meet specifications. To succeed in this role, one might consider studying modeling and control of single-phase rectifiers and inverters to gain specialized knowledge in the testing of power electronic systems. This course is especially relevant because it covers topics such as Grid-Tied Power Electronics, Control of Power Factor Correction Rectifiers, Modeling and Control of Single-Phase Inverters, which are essential for designing and conducting tests on power electronic systems.
Technical Writer
Technical Writers create technical documentation, such as user manuals and white papers. To be successful in this role, one could consider taking a course on modeling and control of single-phase rectifiers and inverters to gain specialized knowledge in the field of power electronics. This course is especially relevant because it covers topics such as Grid-Tied Power Electronics, Control of Power Factor Correction Rectifiers, Modeling and Control of Single-Phase Inverters, which are essential for writing technical documentation on power electronic systems.
Sales Engineer
Sales Engineers sell technical products and services. To excel in this role, one could consider taking a course on modeling and control of single-phase rectifiers and inverters to build a foundation in power electronics. This course is particularly relevant because it covers topics such as Grid-Tied Power Electronics, Control of Power Factor Correction Rectifiers, Modeling and Control of Single-Phase Inverters, which are fundamental concepts in the sales of power electronic products and services.
Business Development Manager
Business Development Managers develop and execute business strategies. To succeed in this role, one might consider studying modeling and control of single-phase rectifiers and inverters to gain specialized knowledge in the field of power electronics. This course is especially relevant because it covers topics such as Grid-Tied Power Electronics, Control of Power Factor Correction Rectifiers, Modeling and Control of Single-Phase Inverters, which are essential for developing and executing business strategies in the field of power electronics.
Project Manager
Project Managers plan, execute, and close projects. To be successful in this role, one could consider taking a course on modeling and control of single-phase rectifiers and inverters to gain specialized knowledge in the field of power electronics. This course is especially relevant because it covers topics such as Grid-Tied Power Electronics, Control of Power Factor Correction Rectifiers, Modeling and Control of Single-Phase Inverters, which are essential for planning, executing, and closing projects in the field of power electronics.

Reading list

We've selected six books that we think will supplement your learning. Use these to develop background knowledge, enrich your coursework, and gain a deeper understanding of the topics covered in Modeling and Control of Single-Phase Rectifiers and Inverters.
Comprehensive reference on power electronics, covering topics such as converter circuits, control techniques, and applications. It would be a useful reference for students and professionals in the field.
Provides a comprehensive introduction to power electronics, covering topics such as power semiconductor devices, converters, and applications. It would be a good textbook for an undergraduate or graduate course on power electronics.
Provides a comprehensive treatment of power semiconductor switches, covering topics such as device physics, modeling, and applications. It would be a useful reference for students and professionals in the field.
This handbook provides a comprehensive overview of power electronics, including topics such as power semiconductor devices, converters, and applications. It would be a useful reference for students and professionals in the field.
Provides a comprehensive treatment of power electronics, covering topics such as power semiconductor devices, converters, and applications. It would be a useful reference for students and professionals in the field.
Provides a concise introduction to power electronics, covering topics such as power semiconductor devices, converters, and applications. It would be a good textbook for an undergraduate or graduate course on power electronics.

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