Best Electrical Engineering Degree Programs of 2022
Learn more about the top Electrical Engineering programs, what to expect, job prospects, and how to choose the program that’s right for you.
Learn more about the top Electrical Engineering programs, what to expect, job prospects, and how to choose the program that’s right for you.
Electrical engineering is the study of the design, development, and implementation of electrical systems. Electrical engineering degrees can prepare students for a variety of careers in electrical engineering, including electrical design, electrical testing, and electrical research.
Electrical engineering degrees offer a broad overview of electrical engineering, covering topics such as electrical theory, circuit design, and electronics. Students in electrical engineering degree programs learn about the different aspects of designing and developing electrical systems, and how to apply those concepts to real-world problems.
When it comes to choosing the right electrical engineering program, there are many factors to consider. Cost, location, and time to degree are all important factors, but students should also research the curriculum and available specializations.
Many electrical engineering programs offer specializations, so students should research the options available at each school. For example, some programs offer specializations in power systems or telecommunications. Students should also research the graduation requirements to learn how many general engineering classes they must take versus the specialized courses in their track.
In addition to these factors, prospective electrical engineering students also need to consider the school’s accreditation status. Accreditation ensures that the program meets the standards set by the profession. Finally, students should research the job placement rate for graduates of the program.
The best programs for Electrical Engineering ranking is based on key statistics and student reviews using data from the U.S. Department of Education. Some of the metrics influencing how the rankings are determined include graduation rate, average salary for graduates, accreditation, retention rate, and cost.
The Bachelor of Science in Electrical Engineering from Embry-Riddle Aeronautical University provides students with a broad background in circuit theory, communication systems, computers, control systems, electromagnetic fields, energy sources and systems, and electronic devices. The emphasis on design places Embry-Riddle Electrical Engineering students in a unique position to increase employment opportunities after graduation.
Throughout Electrical Engineering studies, students are educated in the discipline’s theory and receive practical hands-on experience, culminating with the highly regarded senior capstone course that follows the development cycle of an actual engineering project. The Electrical Engineering program is accredited by the Engineering Accreditation Commission of ABET.
The Bachelor of Science in Electrical Engineering from New York University is a 128-credit program that trains students to become electrical engineers. The curriculum builds on foundational mathematics and science courses with studies of analysis and design in electrical engineering. These studies often include hands-on coursework in state-of-the-art laboratories. In addition, the variety of specialized subjects students can investigate through elective coursework. The BS in Electrical Engineering is accredited by the Engineering Accreditation Commission of ABET.
The Bachelor of Science in Electrical Engineering (BSEE) at Oregon Tech is a unique, innovative program that is designed to prepare professionals for the growing and changing Electrical Engineering industry. The program offers a hands-on, applied education that provides students with the skills and knowledge they need to be successful in their career. The program is flexible and allows students to customize their degree to match their interests and goals. The program also offers a variety of dual degrees, concurrent degrees, and minors that allow students to specialize in their area of interest.
The University of Wisconsin offers a Bachelor of Science in Electrical Engineering that provides a solid foundation in the principles of electrical engineering, with a focus on the design, development, analysis, research, and manufacture of systems and devices. Students learn to apply engineering principles to real-world problems and to communicate effectively with a range of audiences. The program also emphasizes ethical and professional responsibility, teamwork, and critical thinking.
The Bachelor of Science in Electrical Engineering from Lewis University provides students with the practical skills needed to begin their careers as electrical engineers. Through their coursework, students gain the deep technical knowledge necessary to stay up-to-date with the rapid changes in the industry throughout their career. With internship and project opportunities, students acquire job-ready skills that will enable them to work productively from the outset.
The Bachelor of Electrical Engineering degree from Auburn University is a 124-hour program that provides a solid foundation in the principles of electricity and electrical engineering, with courses in digital logic circuits, electric circuit analysis, computer systems, and applied electromagnetics. Students also have the opportunity to choose from a variety of technical electives to tailor the degree to their specific interests. The program culminates in a capstone design project, giving students the chance to apply their knowledge and skills to a real-world problem.
The University of South Carolina offers a Bachelor of Science in Electrical Engineering that prepares students for careers in a variety of industries. The curriculum provides a strong foundation in the core areas of electrical engineering, with courses in circuits and analog electronics, semiconductor materials and devices, digital electronics, signals/systems, and control systems. A series of vertically integrated laboratory courses provide hands-on experience in electrical and electronics engineering. Career plan electives allow students to concentrate in a specific area of interest. The capstone design project gives students the opportunity to work on a real-world engineering problem.
Rochester Institute of Technology’s Bachelor of Science in Electrical Engineering degree program prepares students for exciting careers in the electrical engineering field. The program provides students with a solid foundation in mathematics and the physical sciences, which is essential for the study of electrical engineering. In addition, students take courses in circuits, electronics, linear systems, electromagnetic fields, semiconductor devices, communication systems, control systems, and microelectromechanical systems. The program also includes a cooperative education experience, which gives students the opportunity to apply their knowledge in a professional setting.
The University of West Florida’s Bachelor of Science in Electrical Engineering program focuses on a solid foundation of core courses, with electives that allow students to explore selected subject matter in depth. In the last two semesters, students work on a senior design project (capstone) as the culmination of their engineering education. After developing objectives and analysis, students create design concepts, research implementation methods, and perform a feasibility study.
The Bachelor of Science in Electrical Engineering (BSEE) program at Minnesota State University is designed to prepare students for careers in the electrical engineering field. The curriculum includes coursework in the physical sciences, mathematics, and engineering sciences, as well as hands-on laboratory instruction. Students also have the opportunity to choose from a number of specialized areas of study, including power, digital systems, controls, signal processing, communications, and microelectronics. The program culminates with a capstone design project.
The Bachelor of Science in Electrical Engineering from Virginia Commonwealth University is a comprehensive program that covers all aspects of electrical engineering. Students will learn how to identify, formulate and solve complex engineering problems, as well as how to apply engineering design principles to produce solutions that meet specified needs. They will also gain communication and team-building skills, and learn how to conduct appropriate experimentation and analyze data.
The Bachelor of Science in Electrical Engineering from San Francisco State University is a four-year program that prepares students for careers in electrical engineering or related fields. The program provides students with a broad and basic understanding of the main fields in electrical engineering, and students can choose an area of specialization during their senior year in communications, computers, electronics, control, and robotics, or power engineering.
The Bachelor of Science in Electrical Engineering degree from Florida Institute of Technology is a great choice for students interested in a career in electrical engineering. The program provides a strong background in engineering with hands-on experience in software simulation and analysis. Students in the program have access to state-of-the-art research lab space and the opportunity to work closely with faculty on a variety of research projects. The program also provides the opportunity to complete a design project in collaboration with a team of peers.
The Bachelor of Science in Electrical Engineering degree from University of Nevada-Reno is a four-year program that prepares students for careers in electrical engineering. The program includes coursework in mathematics, physics, and engineering, as well as a senior capstone project. Students in the program will learn to apply principles of engineering, science, and mathematics to solve complex engineering problems. They will also learn to communicate effectively with a range of audiences and to work ethically and professionally in teams.
The Bachelor of Science in Electrical Engineering from University of Nevada-Las Vegas is a four-year program that prepares students for a career in the electrical engineering field.
Students in a bachelor’s in electrical engineering program can expect to take classes in physics, mathematics, and computer science, in addition to electrical engineering coursework. The degree typically takes four years to complete and may require an internship or practicum.
Most programs offer specializations in areas like power systems, telecommunications, or electronics. Students should choose a specialization that aligns with their career goals. For example, students interested in working in the automotive industry might choose a specialization in automotive engineering.
In addition to coursework, students in a bachelor’s in electrical engineering program should expect to complete an internship or practicum. This hands-on experience gives students the opportunity to apply what they’ve learned in the classroom to a real-world setting.
Overall, students in a bachelor’s in electrical engineering program should expect to develop strong analytical and problem-solving skills. They should also be prepared to work in teams and be comfortable with using various computer programs.
A bachelor’s degree in electrical engineering typically requires four years of study and 120 credit hours. The curriculum is designed to give students a broad foundation in the field, as well as in-depth knowledge in a chosen specialization. The courses below are representative of what students might take during their four years of study.
This course covers the analysis and design of linear time-invariant (LTI) systems. Topics include the time and frequency domain representation of signals and systems, Fourier series and transforms, the convolution integral, the z-transform, filter design, and an introduction to the Laplace transform. Emphasis is placed on the application of these concepts to the solution of engineering problems. Upon completion, students should be able to analyze and design LTI systems in both the time and frequency domains.
This course covers the analysis and design of linear feedback control systems. Topics include mathematical modeling of physical systems, time and frequency domain analysis of linear systems, transfer function representation, stability analysis, design of compensators, and frequency response methods. Upon completion, students should be able to analyze and design simple linear feedback control systems.
This course covers the operation, performance, and applications of rotating electrical machines. Topics include the physics of rotating machines, DC motors, DC generators, AC induction motors, synchronous machines, and transformer operation. Emphasis is placed on developing an understanding of the basic operating principles of rotating electrical machines and their relationship to real-world applications. Upon completion, students should be able to apply the principles of rotating machines to the analysis and design of electrical engineering systems.
This course covers the analysis of power systems, including power flow, short-circuit, and protective device coordination. Topics include power system components, per-unit calculations, transformer connections and tap changes, power flow solution methods, symmetrical components, sequence networks, unbalanced faults, and voltage drop. Upon completion, students should be able to apply power flow analysis methods to solve for voltage, current, and power in both balanced and unbalanced three-phase power systems.
This course covers the theory and application of digital signal processing. Topics include discrete-time signals and systems, the z-transform, the discrete Fourier transform, fast Fourier transform algorithms, filter design techniques, multirate signal processing, adaptive filters, and noise reduction. Upon completion, students should be able to apply the principles of digital signal processing to the solution of problems in such areas as communications, control systems, radar, and sonar.
Graduates of electrical engineering programs work in a variety of industries, including energy, transportation, telecommunications, and manufacturing. They may also work in fields such as research and development, consulting, and project management.
Electronics engineers develop, design, test, and oversee the production of electronic equipment, such as broadcast and communications systems, global positioning systems (GPS), and medical monitoring devices. They work in a variety of industries, including telecommunications, automotive, aerospace, and manufacturing. Electronics engineers typically have a bachelor’s degree in engineering, but some jobs may require a master’s degree or higher.
Power systems engineers work on the design, development, testing, and operation of electric power systems. They may work on the electrical grid, on individual components of the grid such as transformers or circuit breakers, or on power generation systems such as solar, wind, or nuclear. Power systems engineers often specialize in one particular area, such as transmission, distribution, or generation.
Robotics engineers design, build, and test robots. They work in a variety of settings, including factories, research laboratories, and hospitals. Robotics engineers typically have a bachelor’s degree in engineering, although some jobs may require a master’s degree or higher. Robotics engineers often specialize in a particular type of robot, such as industrial robots, service robots, or medical robots.
Design engineers use their technical expertise to develop products, systems, and components. In many cases, they are responsible for the entire design process, from initial research to final production. Design engineers often specialize in a particular type of product, such as medical devices, automobiles, or aircraft. They use computer-aided design (CAD) software to create models and prototypes and often work closely with other engineers, such as mechanical engineers, electrical engineers, and industrial engineers, to bring their designs to life.
Systems engineers are responsible for developing and maintaining complex systems. This can include anything from the electrical grid to computer systems to aircraft. Systems engineers often work with other engineers and technicians to design, develop, and test these systems. They also work with managers to ensure that the systems meet the needs of the people who will be using them. Systems engineers typically have a bachelor’s degree in engineering, but the specific field of study will vary depending on the type of system they’re working on.
Lamar Burns is a Senior Electrical Engineer at Tesla. He has a bachelor’s degree in electrical engineering from Stanford University. Lamar has over 20 years of experience in the electrical engineering field.
ClimbtheLadder: What would you recommend that students do in addition to their degree program, in order to stand out to employers?
Lamar Burns: I would recommend that students get involved in extracurricular activities, such as clubs or competitions related to their field of study. This will not only make them more well-rounded, but also give them the opportunity to apply what they’ve learned in the classroom to real-world scenarios. Employers are always looking for candidates who are not only knowledgeable, but also have the ability to put that knowledge into practice.
ClimbtheLadder: What should students interested in Electrical Engineering be good at?
Lamar Burns: In order to be successful in electrical engineering, students should be good at math and science. They should also be able to think logically and solve problems. Additionally, it is important to be able to work well in a team and communicate effectively.
ClimbtheLadder: What was the most challenging course you took? What advice would you give to students who are about to start this course?
Lamar Burns: The most challenging course I took was my senior design course. This course required us to design and build an electrical system from scratch. We had to do everything from designing the circuit boards to programming the microcontrollers.
My advice to students who are about to start this course is to be prepared to work hard. This course is very challenging, but it is also very rewarding. If you put in the effort, you will be able to learn a lot and build something that you can be proud of.