Most Popular Concentrations in Electrical Engineering Degrees for 2026

Rising workforce demands and rapid technological changes are driving increased interest in specialized electrical engineering fields. Students today seek concentrations that align with evolving industry needs and offer clear career advancement opportunities.

The most popular electrical engineering concentrations reflect this trend:

• Power systems and energy: This concentration is fueled by the global push toward renewable energy integration and modernized grid infrastructure. Utilities' need to upgrade aging power systems and incorporate distributed generation technologies keeps this track in high demand.
• Communications and signal processing: Foundational to wireless networks and 5G deployment, this specialization continues thriving due to the persistent growth in telecommunications and data transmission. The focus on efficient, reliable communications networks sustains strong enrollment, fitting naturally into the communications signals and systems specialization.
• Control systems: Automation's rise across manufacturing, robotics, and autonomous vehicles drives demand for experts in system stability and feedback mechanisms. Control systems engineers are critical to advancing intelligent, automated operations.
• Microelectronics and circuit design: Offering some of the highest compensation in the field, with average salaries near $133,364 annually, this concentration attracts those interested in semiconductor manufacturing and innovative electronics development. It closely links to electronics and optics concentration programs contributing to cutting-edge device design.
• Computer engineering: Bridging hardware and software, this track focuses on embedded systems, Internet of Things (IoT) devices, and computational architecture. It appeals to students wanting to work at the intersection of electrical engineering and computer science disciplines.

Students aiming for specialized study paths can explore programs designed to accelerate degree completion and better fit working schedules, such as the best accelerated online degree completion programs for working adults.

Developing specialized skills is essential for success in electrical engineering study paths, as evolving industry expectations continuously shape the competencies students must acquire. Mastery of foundational and advanced skills ensures graduates remain competitive in a dynamic workforce.

• Circuit analysis and electromagnetics fundamentals: These core skills underpin various concentrations, from electronics to power systems, enabling students to understand and design complex electrical components crucial in modern technology.
• Signal processing and digital logic design: Vital for electronics and communications, these skills support the creation of efficient communication infrastructure and consumer electronics in high demand sectors.
• Power electronics and renewable energy technologies: With the modernization of grids and emphasis on sustainability, expertise in these areas prepares students for careers focused on energy innovation and management.
• Programming skills for embedded systems design: Essential for embedded systems, robotics, and VLSI fields, programming ability allows engineers to develop responsive and integrated device controls critical to today's interconnected systems.
• Hands-on design experience and teamwork: Practical, team-based design projects reinforce theoretical knowledge and hone problem-solving skills, which employers highly value in an industry producing roughly 25,951 electrical engineering degrees annually in the US.

Students seeking the easiest online degree programs may find electrical engineering demanding but rewarding due to its blend of theory and practical application across diverse concentrations.

Different electrical engineering concentrations generally do not have radically different admission requirements, but variations do arise based on specialization complexity and specific prerequisite skills. Most universities set baseline electrical engineering program admission standards by school that apply across all concentrations. Graduate programs, especially those focused on niches like electrical and computer engineering, tend to enforce stricter prerequisites such as ABET-accredited degrees and advanced coursework in mathematics, physics, and circuits.

These differentiated expectations ensure students have the technical foundation needed for specialized study. In some cases, students who lack certain prerequisites may be admitted provisionally, with mandatory completion of required courses before full admission is granted.

Common differences in admission criteria often include concentration specific GPA and test score requirements as well as prerequisites that align with the discipline's demands. For example, Arizona State University requires first-year electrical engineering applicants to meet a minimum SAT, ACT, or high school GPA threshold, uniform across concentrations, while University of California San Diego sets varied GPA maintenance standards depending on the chosen track, which affect students after enrollment rather than admission.

Similarly, professional experience or portfolio submissions might be requested in highly specialized or research-oriented graduate programs. These criteria help programs maintain academic rigor and ensure students are well-prepared for the challenges ahead. Students interested in highest return fields can refer to majors that make money for guidance on choosing a lucrative path.

Accreditation is vital for specialized electrical engineering concentrations as it verifies a program's compliance with industry and academic standards. Holding an accredited degree can influence a student's eligibility for professional certifications and career opportunities in competitive fields.

• Licensure Requirements: Graduates of accredited programs meet the education criteria for professional engineering licenses across all U.S. states, a necessity for pursuing a PE designation.
• Employer Preferences: Many companies, especially in regulated industries like aerospace and telecommunications, prioritize candidates from accredited programs to ensure workforce reliability and compliance.
• Curriculum Standards: Accredited concentrations mandate at least 45 credit hours of engineering coursework and a capstone design project, ensuring comprehensive and practical training.
• Transferability of Credits: Credits earned in ABET-accredited programs are widely transferable, facilitating smoother transitions between institutions without loss of progress.

As more students weigh the benefits of online versus on-campus study options, the quality of electrical engineering concentration tracks has become a central consideration. Comparing these formats closely helps learners choose programs that truly prepare them for their careers.

• Curriculum Consistency: Accredited programs maintain identical course content and assessment standards regardless of delivery method, ensuring students cover core topics like circuits and signal processing equally.
• Accreditation: Recognition by ABET guarantees that both online and campus-based programs meet rigorous educational benchmarks valued by employers.
• Faculty Expertise: The same seasoned instructors often teach both online and in-person classes, preserving instructional quality across formats.
• Hands-On Training: Online programs address lab work challenges through virtual labs, remote equipment access, or occasional on-site sessions, bridging the gap with physical facilities.
• Technology Integration: Robust digital platforms enable real-time experiments and collaboration, enhancing learning experiences for remote students.
• Student Support: Comprehensive advising and resources are increasingly available to online learners, helping replicate the engagement found on campus.

A graduate from a popular concentration in electrical engineering who completed a hybrid program shared her reflections. "Balancing online lectures with on-campus labs was challenging, but it really deepened my understanding," she explained. She found virtual simulations effective for theory, yet valued the hands-on feel when working with actual equipment during intensive lab visits. According to her, "The instructors were accessible no matter the format, which made the experience seamless." She appreciated that neither part felt like a compromise, but rather complementary elements that together strengthened her skills and confidence in the field.

Electrical engineering concentrations vary in difficulty because of differences in coursework intensity, required skills, and program design. Some tracks demand a deeper understanding of abstract mathematics and complex theories, alongside heavy workloads and advanced technical knowledge.

• Advanced Mathematical Modeling: This involves mastering partial differential equations and Maxwell's equations, necessitating strong skills in calculus and linear algebra.
• Theoretical Complexity: Electromagnetic systems are less intuitive due to their abstract nature, posing challenges in connecting theory to practical applications.
• High Attrition Rates: Programs focusing on electromagnetics exhibit some of the highest dropout percentages among electrical engineering students, reflecting the concentration's difficulty.
• Hardware and Software Integration: Microelectronics requires simultaneous expertise in transistor physics, circuit design, and programming, along with adapting to fast-paced technological advancements.

Various concentrations within electrical engineering equip students with targeted expertise, opening pathways to distinct career opportunities. Recognizing how each specialization aligns with job roles helps students focus their education toward fields that match their ambitions.

• Computer Engineering: Graduates often enter roles designing computer hardware, smart devices, and digital systems. Common positions include hardware design engineers, network architects, and programmers, primarily in tech firms, semiconductor industries, and software companies.
• Communications and Signal Processing: This area centers on high-speed data transmission for wired and wireless networks. Careers typically involve telecommunications providers, government agencies, and equipment manufacturers, with work spanning satellite technologies, broadband infrastructure, and radio frequency design.
• Power Systems and Energy: Specialists focus on improving energy efficiency and integrating sustainable technologies. They work as power system engineers, renewable energy experts, and energy engineers in utilities, energy corporations, and infrastructure sectors.
• Controls and Robotics: Concentration here leads to roles in developing automated systems for manufacturing and autonomous technologies. Employers include automotive, aerospace, and transportation industries, with jobs like controls engineer, automation specialist, and systems designer.
• Biomedical Engineering: This field applies electrical engineering to healthcare innovations. Professionals find positions in medical device firms, hospitals, and pharmaceutical companies, engaging in R&D, validation, and service engineering for medical equipment.

A professional from the computer engineering track shared that choosing this specialization felt both exciting and daunting due to its vast potential. He recalled spending countless hours evaluating various industries before settling on semiconductor design, where problem-solving and innovation fueled his daily work. Reflecting on his journey, he noted how exploring diverse projects helped clarify what suited his skills and passions. "I never expected the breadth of career options would require such a deliberate approach to find the right fit," he said, emphasizing that early exposure to different roles was crucial in shaping a fulfilling career path.

Keeping up with industry trends helps students select electrical engineering concentrations that align with job prospects, salary potential, and sought-after skills. As technology and societal needs evolve, so do the demands for specialized expertise, making it vital to pursue fields with strong future growth and relevance.

• Renewable Energy and Power Systems: Growing emphasis on sustainable infrastructure fuels demand for engineers skilled in power generation, smart grids, and energy management. Job outlooks predict an 8-12% increase in this area over the next decade, reflecting a shift to cleaner energy technologies.
• Communications and Signal Processing: This specialization supports critical telecommunications networks, including 5G, requiring knowledge in wireless technology, digital signal processing, and information theory. These skills remain essential as data communication systems expand.
• Computer Engineering and Cybersecurity: Combining computing with electrical engineering opens extensive career options, especially in developing secure hardware and embedded systems. With nearly 18,000 degrees awarded annually, this concentration stands as a major segment addressing digital infrastructure protection.

Salary prospects in electrical engineering vary widely depending on the chosen concentration, with certain specializations offering significantly higher compensation due to industry demand and technical complexity. For students selecting a specialization, understanding these variations is critical to maximizing long-term earning potential and aligning career paths with market trends.

• Power Systems and Electrical Power Generation: Professionals in power systems roles command some of the highest salaries, with research and development positions averaging $130,840 annually. Electrical power generation specialists earn around $114,720 per year, while electrical power systems engineers typically make about $98,329. The essential role of power systems in critical infrastructure and the ongoing push for grid modernization contribute to sustained demand and competitive pay.
• Microelectronics Engineering: This specialization centers on semiconductor design and manufacturing, pivotal in the rapidly evolving tech industry. Microelectronics engineers earned an average of $77,747 as of March 2022, with a salary range between $72,396 and $84,221.
• Controls and Instrumentation: Focused on automation, robotics, and precision measurement, engineers in this concentration earn about $115,700 annually. Industry growth in these areas supports steady investment and competitive compensation packages.
• Engineering Services and Consulting: Electrical engineers working in services and consulting average $103,450 per year, reflecting the broad applicability of their skills across multiple industries and projects.

Geographic differences notably impact electrical engineer salary by state, with top-paying regions like California ($128,000), Massachusetts ($122,500), and Washington ($119,000) offering lucrative opportunities. Prospective students interested in various pathways might explore the top accredited online schools to align their education with these trends and the highest paying electrical engineering jobs 2025.

Selecting the right concentration in an electrical engineering degree is critical for aligning your education with career goals and personal strengths. Choosing wisely early in your program enables targeted skill development and positions you well for industry demands.

• Career aspirations and industry focus: Identify industries and roles that excite you most. Those interested in renewable energy or grid modernization should consider power engineering or energy systems. Embedded systems or controls engineering suit students aiming for smart devices and automation. The U.S. Bureau of Labor Statistics projects 9% employment growth for electrical engineers between 2023 and 2033, with especially strong demand in robotics, IoT, and aerospace sectors, enhancing job prospects upon graduation.
• Skill development and technical depth: Different concentrations emphasize varying technical competencies, such as signal processing in communications or circuit design in electronics. Assess whether your preference lies in hardware, software integration, or theoretical analysis to select a specialization that fosters deep expertise aligned with your goals.
• Program requirements and elective flexibility: Review your institution's offerings to ensure the electrical engineering concentration requirements and admission standards suit your academic background. Some programs allow customizable pathways, while others follow rigid tracks. Confirm prerequisites align with your status and that hands-on, practical experiences are integral to the track you choose.
• Personal interests and long-term growth: Reflect on the problems you enjoy solving and your ideal work environment. Innovations in machine learning or autonomous systems offer cutting-edge opportunities for those energized by emerging technologies. Conversely, established fields like power systems or telecommunications may appeal to those valuing stability and infrastructure longevity.

Aligning your concentration choice with these factors is essential to maximizing your educational outcomes and career potential. For insights into related workforce trends, consider exploring the highest paying job in trade school data to understand broader technical career opportunities.

• Electrical Engineering Specializations https://www.onlineengineeringprograms.com/electrical/ee-specializations
• 8 Top Specializations In Electrical & Computer Engineering https://collegepond.com/top-electrical-computer-engineering/
• Reader Question: What Is the Most Difficult Specialty Within Electrical Engineering? - News https://www.allaboutcircuits.com/news/reader-question-what-is-the-most-difficult-specialty-within-electrical-engineering/
• Electrical Engineering Outlook 2025 | StartUs Insights https://www.startus-insights.com/innovators-guide/electrical-engineering-outlook/
• Impact of the modality -onsite or online- on the students performance in the MSc in Electrical Engineering https://merit.url.edu/es/publications/impact-of-the-modality-onsite-or-online-on-the-students-performan-3
• Top Skills Every Electrical Engineer Must Have in 2025 https://www.jietjind.ac.in/top-skills-every-electrical-engineer-must-have-in-2025/
• Academic Catalog https://catalog.memphis.edu/preview_program.php
• Criteria for Accrediting Engineering Programs, 2025 - 2026 - ABET https://www.abet.org/accreditation/accreditation-criteria/criteria-for-accrediting-engineering-programs-2025-2026/
• Choosing Electrical Engineering Concentration https://engineerboards.com/threads/choosing-electrical-engineering-concentration.10635/