What Is Power Electronics? (+ How to Start a Career in It)

Key takeaways

Power electronics is a branch of electrical engineering focused on how power is converted, delivered, and managed for electronic devices.

• By 2030, the global power electronics market is projected to reach $53.66 billion [1]. 

• Power electronic systems convert electrical energy from one form to another, ensuring the flow of electricity is suitable for user loads.

• You can enter careers in power electronics through relevant areas of study, including electrical engineering and computer engineering.

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What is power electronics?

Power electronics is a multidisciplinary branch of electrical engineering. It focuses on processing, controlling, and converting electric power. Power electronics utilize high voltages and currents to deliver power to electrical equipment and devices. These devices range from air conditioning systems in homes to cell phones to industrial machinery.

Why is it important?

By 2030, it’s anticipated that the global power electronics market is projected to reach $53.66 billion, up from $38.12 billion in 2023 [1]. The efficiency of these power conversion systems plays a key role in reducing energy waste and increasing power quality. Additionally, research and development (R&D) for the creation of spacecraft power systems relies on power electronic technology. Pursuing a career in power electronics can be rewarding because you may be able to build expertise in areas that are crucial to our planet, like renewable energy and space exploration.

Fundamentals of power electronics

Power electronic systems convert electrical energy from one form to another. This process may involve modifying the voltage, current, or frequency. It ensures the flow of electricity is suitable for user loads. Power electronics aim to achieve maximum efficiency and reliability at the lowest possible cost, weight, and size. Here are a few power electronics components:

• Power diodes. A power diode is a semiconductor device. It enables the flow of electric current in one direction by having low resistance to current in one direction and extremely high resistance in the other. Diodes are used as voltage regulators, signal modulators, and to convert alternating current (AC) to direct current (DC). 

• Transistors. Transistors are also semiconductor devices. These are used to amplify and switch electronic signals and electrical power. 

• GTO. A Gate Turn-Off Thyristor, or GTO, is a high-powered semiconductor switching device. It is characterized by its gate turn-off capability. GTOs can also turn on the main current with a gate drive circuit. 

Where is power electronics used?

Applications of power electronics are prevalent in daily life. You've likely used a device that relies on power electronics engineering today. The chart below outlines a few industries that use power electronics with examples.

Power electronics careers and outlook 

Power electronics engineers belong to the occupational field of architecture and engineering. According to the US Bureau of Labor Statistics (BLS), the number of architecture and engineering jobs will expand at a rate higher than the average for all occupations between 2024 and 2034 [2]. This statistic translates into about 186,500 new jobs, most of which can be attributed to engineering. Factors contributing to job growth in engineering include growing interest in areas like robotics, power management, and renewable energy. 

Power electronics engineering

If you’re interested in starting a career in power electronics, you may consider becoming a power electronics engineer. Power electronics engineer is a broad title that encompasses several specializations. Specific job duties vary depending on the industry, but the responsibilities below apply to most power electronics engineering roles:

• Design and test circuits for use in power electronic systems.

• Enhance existing mechanical designs.

• Perform research to develop solutions for known issues like power loss and overall inefficiency.

• Maintain documentation of designs and specifications.

• Collaborate with other engineers and departments for testing and development.

Related roles and job titles

• Test engineer, power electronics

• Power electronics design release engineer

• Electrical engineer, power electronics

• Research and development (R&D) engineer, power electronics

• Power electronics manufacturing engineer

• Electrical design engineer, power electronics

Power electronics engineer salary

The median total pay for a power electronics engineer in the US is $132,000 per year, which includes base salary and additional pay, which may represent profit-sharing, commissions, bonuses, or other compensation [3]. 

Read more: Electrical Engineer Salary: Your Guide 

How to get a job in power electronics

Seventy-six percent of electrical engineers hold a bachelor's degree, 12 percent hold a master's degree, and 8 percent hold an associate degree [4]. Relevant areas of study include electrical engineering and computer engineering.

Ready to take the next step in your power electronics career? On Coursera, you can pursue a Master of Science in Electrical Engineering online with the University of Colorado Boulder.

Gain the essential skills.

Below, we’ve compiled a list of technical and workplace skills for power electronics engineers. Consider using it to identify areas of focus for building your expertise. 

• Strong knowledge of power electronics systems and principles like AC/DC conversion, AC converters, DC-DC converters, and grid-connected converters

• Experience with power electronics equipment such as variacs, power analyzers, and oscilloscopes

• Understanding of safety procedures for working with hazardous voltage and current levels

• Excellent written and verbal communication skills

• High-level analytical skills

• Ability to work independently as well as in a team environment

• Experience with design and real-time simulation (RTS) tools such as MATLAB

• Capability to translate operational specifications into hardware requirements

Enhance your resume. 

There are many methods for ensuring recruiters notice your resume. For example, consider matching the words you use to describe your skill set to the language employers use in job postings. Employers often use applicant tracking systems (ATS). These systems enable recruiters to filter resumes and applications via keywords to process candidates quickly. You have a higher chance of selection when your terms match the terms employers have input in their ATS. Read nine additional ways to enhance your resume below.

Stay current with power electronics company and industry trends. 

You can demonstrate your expertise to employers while staying up-to-date with industry trends by engaging with the power electronics community. Following industry leaders on social media and subscribing to relevant YouTube channels and blogs are excellent ways to get started. For more information regarding experts in the power electronics field, you might check the Institute of Electrical and Electronics Engineers' (IEEE) website. 

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• Hear from experts: Leadership for engineers: How one manager is investing in himself and his team

• Watch on YouTube:Master of Science in Software Engineering Program Information Session

• Explore career paths:Becoming an AI Engineer: 7 Questions with an IBMer

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