A Bachelor of Electrical Engineering (BEE) is one of the most versatile and in-demand engineering degrees available today. This guide covers everything you need to know about the degree, from core coursework and specialization tracks to the career opportunities that await graduates.
A Bachelor of Electrical Engineering (BEE) is a four-year undergraduate degree that prepares students to design, develop, and maintain electrical systems and electronic devices. The degree covers circuits, power systems, signal processing, electromagnetics, and embedded systems, giving graduates the technical foundation to work across industries from energy and telecommunications to aerospace and robotics.
The Bachelor of Electrical Engineering is a professional engineering degree focused on the study of electricity, electronics, and electromagnetism. Unlike a general electrical engineering technology degree, the BEE is accredited by ABET and qualifies graduates to pursue a Professional Engineer (PE) license after gaining work experience.
BEE programs combine heavy mathematics and physics coursework with hands-on laboratory sessions. Students typically spend the first two years completing foundational courses in calculus, differential equations, linear algebra, and university physics before moving into upper-division engineering courses.
The degree is offered at nearly every major university in the United States and remains one of the top-earning bachelor's degrees across all fields. Graduates are qualified for roles in hardware design, power distribution, telecommunications infrastructure, and control systems engineering.
If you are considering this degree path, test your foundational knowledge with our Signals & Systems practice questions to see where you stand on key concepts.
A standard BEE curriculum is built around several pillars of electrical engineering knowledge. Understanding these core areas is essential for passing coursework and succeeding in the field.
Every BEE program begins with a rigorous math and science foundation. Students complete Calculus I through III, differential equations, linear algebra, probability and statistics, and two semesters of calculus-based physics. These courses provide the mathematical tools needed for circuit analysis, signal processing, and electromagnetic theory.
Circuit analysis is the backbone of electrical engineering. Students learn Kirchhoff’s laws, Thevenin and Norton equivalents, AC/DC circuit behavior, and transient response. This coursework builds the analytical skills needed for virtually every specialization within electrical engineering. You can practice these fundamentals with our Fundamental Circuit Analysis quiz.
Upper-division courses cover semiconductor physics, diode and transistor operation, amplifier design, and integrated circuit fundamentals. Students learn to analyze and design both analog and digital electronic circuits, from simple amplifiers to complex mixed-signal systems.
This core area covers continuous-time and discrete-time signal analysis, Fourier transforms, Laplace transforms, Z-transforms, and system frequency response. Understanding signal processing theory is critical for careers in telecommunications, audio engineering, and control systems. Our Signals & Systems practice test covers the essential concepts from this coursework.
Electromagnetic theory courses cover Maxwell’s equations, wave propagation, transmission lines, and antenna design. This coursework connects theoretical physics with practical applications in wireless communications, radar, and microwave engineering.
Nearly all ABET-accredited programs require a two-semester capstone project where students design, build, and test a complete engineering system. These projects often involve collaboration with industry sponsors and provide portfolio-worthy work for job applications.
Most BEE programs allow students to concentrate their electives in a specific area. Choosing the right specialization can significantly impact your career trajectory and earning potential.
Power systems engineers design and maintain the electrical grid, including generation facilities, transmission lines, substations, and distribution networks. With the growth of renewable energy, this specialization has seen surging demand. Power engineers work for utilities, energy companies, and government agencies. Starting salaries typically range from $70,000 to $85,000.
This track focuses on integrated circuit design, from individual transistors to complete system-on-chip architectures. Graduates work for semiconductor companies designing processors, memory chips, and application-specific integrated circuits. This is one of the highest-paying specializations, with experienced engineers earning well above $130,000 annually.
Telecom engineers design the infrastructure that carries voice, data, and video across wired and wireless networks. Coursework covers RF engineering, fiber optics, network protocols, and wireless system design. The rollout of 5G networks and satellite internet has created strong job prospects in this area.
Embedded systems engineers design the microcontroller-based systems found in everything from automobiles and medical devices to smart home products. This specialization blends hardware design with firmware programming and is one of the fastest-growing areas within electrical engineering.
Control engineers design feedback systems that regulate processes in manufacturing, aerospace, and autonomous vehicles. Coursework covers classical and modern control theory, state-space analysis, and digital control. Robotics applications have expanded this field significantly.
A Bachelor of Electrical Engineering opens doors to a wide range of career paths. Here are the primary roles available to BEE graduates, along with typical salary ranges based on Bureau of Labor Statistics and industry data.
The most direct career path, electrical engineers design and test electrical equipment and systems. The median annual salary is $104,610, with experienced engineers in high-demand specializations earning $130,000 or more. Industries include manufacturing, utilities, telecommunications, and defense.
Electronics engineers focus on smaller-scale electronic components and systems, including consumer electronics, medical devices, and navigation equipment. Median salary is approximately $110,000, with semiconductor industry positions often paying significantly more.
Power engineers manage electrical generation and distribution systems. With the energy transition driving demand for grid modernization and renewable integration, starting salaries are competitive at $75,000–$90,000, rising to $120,000 or more with experience and PE licensure.
These engineers write the low-level software that runs on microcontrollers and embedded processors. Salaries range from $85,000 to $140,000 depending on industry, with automotive and medical device sectors offering premium compensation.
RF engineers design wireless communication systems, antennas, and radar equipment. This niche specialization commands salaries of $95,000–$135,000, with defense contractors and wireless carriers being the primary employers.
To strengthen your preparation for any of these career paths, work through our Fundamental Circuit Analysis and Signals & Systems practice quizzes.
A Bachelor of Electrical Engineering typically takes four years of full-time study to complete. The program requires 120–130 credit hours, including general education, mathematics, science, and engineering courses. Some students take five years if they add a co-op or internship semester, which provides valuable industry experience before graduation.
Electrical engineering (EE) programs focus on theory, design, and research, preparing graduates to create new systems and technologies. Electrical engineering technology (EET) programs emphasize the practical application and implementation of existing designs. EE degrees typically require more advanced mathematics and qualify graduates to pursue a Professional Engineer (PE) license, which is not available through most EET programs.
A bachelor's degree is sufficient for most electrical engineering positions. However, a master's degree can open doors to specialized roles in research, advanced design, and leadership positions. It is also beneficial for careers in semiconductor design, signal processing research, and academia. Many employers offer tuition assistance for part-time graduate study.
BEE programs require Calculus I, II, and III, differential equations, linear algebra, and probability/statistics at minimum. Some programs also require complex analysis or numerical methods. Strong mathematical skills are essential because circuit analysis, signal processing, and electromagnetic theory all rely heavily on advanced mathematics.
Electrical engineering remains an excellent career choice. The Bureau of Labor Statistics projects steady job growth driven by demand in renewable energy, electric vehicles, semiconductor manufacturing, and telecommunications infrastructure. The median salary of over $104,000 makes it one of the highest-paying bachelor's degree paths, and the skills are transferable across many industries.
ABET (Accreditation Board for Engineering and Technology) is the recognized accreditor for college and university programs in engineering. Graduating from an ABET-accredited program is required to take the Fundamentals of Engineering (FE) exam and eventually earn a Professional Engineer (PE) license. Most employers prefer or require candidates from ABET-accredited programs.