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Electrical Engineering at Princeton University offers a comprehensive and rigorous program designed to equip students with the fundamental principles and advanced techniques necessary to innovate and excel in the rapidly evolving field of electrical and computer engineering. The curriculum blends theoretical coursework with practical laboratory experience, fostering critical thinking and problem-solving skills applicable to diverse sectors such as telecommunications, renewable energy, robotics, computer hardware, and integrated circuits. Students are encouraged to engage in research projects alongside leading faculty members who are at the forefront of technological discovery, providing valuable opportunities for hands-on learning and contribution to cutting-edge developments. The program emphasizes a strong foundation in electrical circuits, signal processing, electromagnetics, microelectronics, and systems engineering, while also offering specialized tracks to tailor education according to individual interests and career goals. Beyond technical expertise, students develop vital skills in project management, collaboration, and communication, preparing them for leadership roles in industry, academia, or entrepreneurial ventures. Princeton’s rich academic environment promotes interdisciplinary approaches, encouraging students to explore intersections with computer science, physics, and applied mathematics. The program benefits from state-of-the-art laboratories and resources, fostering innovation and experimentation. Graduates of the Electrical Engineering program are well-prepared to pursue advanced studies or to enter the workforce in high-demand areas such as semiconductor design, wireless communication, energy systems, and embedded systems development. Overall, Princeton’s Electrical Engineering program combines tradition and innovation, producing graduates who are not only technically proficient but also socially responsible engineers capable of addressing complex societal challenges.
Example Program 1: No Advanced Placement in Math/Physics/Chemistry |
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Freshman Year |
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Math 103: Calculus Physics 103: Mechanics Chem 207: Materials Chemistry Elective: writing requirement |
Math 104: Calculus Physics 104: Elect. & Magnetism COS 126: Computer Science Elective: humanities/social science Elective: humanities/social science |
Sophomore Year |
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Math 203: Multivariable Calculus ELE 203: Electronic Circuit Analysis ELE 206: Contemporary Logic Design Elective Elective: humanities/social science |
Math 204: Linear Algebra ELE 201: Information and Systems ELE 208: Contemporary Electronic and Photonic Devices Elective Elective: humanities/social science |
Junior Year |
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ELE 301: Designing Real Systems Departmental Elective Upper Level Math Elective Elective Elective: humanities/social science |
ELE 302: Building Real Systems Departmental Elective Technical Elective Elective: humanities/social science |
Senior Year |
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Departmental Elective Departmental Elective Elective: humanities/social science Elective: Independent Research |
Departmental Elective Departmental Elective Elective Elective |
Example Program 2: One Course Advanced Placement in Math |
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Freshman Year |
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Math 104: Calculus Physics 103: Mechanics Chem 207: Materials Chemistry Elective: writing requirement |
Math 203: Multivariable Calculus Physics 104: Elect. & Magnetism COS 126: Computer Science Elective: humanities/social science Elective: humanities/social science |
Sophomore Year |
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Math 204: Linear Algebra ELE 203: Electronic Circuit Analysis ELE 206: Contemporary Logic Design Elective Elective: humanities/social science |
ELE 201: Information and Systems ELE 208: Contemporary Electronic and Photonic Devices Upper Level Math Elective Elective Elective: humanities/social science |
Junior Year |
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ELE 301: Designing Real Systems Departmental Elective Technical Elective Elective Elective: humanities/social science |
ELE 302: Building Real Systems Departmental Elective Elective: humanities/social science Elective: humanities/social science |
Senior Year |
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Departmental Elective Departmental Elective Elective: humanities/social science Elective: Independent Research |
Departmental Elective Departmental Elective Elective Elective |
- The Common Application or the Universal College Application
- Princeton Supplement
- Transcript
- School Report
- Guidance Counselor Letter
- Two (2) Teacher Recommendations
- SAT with Essay or ACT with Writing
- Two (2) SAT Subject Tests (recommended, but not required)
- TOEFL, IELTS Academic or PTE Academic (nonnative speakers of English without 3 years of high school in English)
The Electrical Engineering program at Princeton University offers a comprehensive and flexible structure that supports students in pursuing their academic and research interests while providing various opportunities for financial aid and funding. Undergraduate students typically finance their education through a combination of multiple sources, including university scholarships, fellowships, grants, loans, part-time employment, and research assistantships.
Princeton University is committed to meeting the full demonstrated financial need of admitted students through its need-based financial aid program. The university’s policy ensures that admitted students from families with varying financial backgrounds can afford to attend without the burden of excessive debt. Families with incomes below a certain threshold are often eligible for full-ride scholarships, covering tuition, fees, room, and board. This support is provided without requiring students to take out loans, fostering an inclusive academic environment.
Graduate students in the Electrical Engineering program typically receive funding packages that include teaching fellowships, research assistantships, or university-funded grants. These packages are designed to cover tuition costs and provide a stipend to support living expenses. The graduate program aims to ensure that students can focus on their research and coursework without financial hardship, encouraging diversity and excellence in the field.
In addition to institutional aid, students may also seek external fellowships from government agencies, private foundations, or industry partnerships, which can supplement their funding. The university’s Office of Financial Aid and the Graduate School offer resources and advising to help students identify and apply for these opportunities.
Internships and cooperative education programs are also integral to the educational experience, providing students with practical training and income while gaining industry experience. Many students participate in summer internships, which not only enhance their learning but may also provide stipends or hourly wages to help offset educational costs.
Furthermore, Princeton actively encourages its students to participate in research projects funded by grants, which often include stipends or travel allowances for presenting at conferences or conducting fieldwork. These research opportunities are typically integrated into the funding packages of graduate students and sometimes available to undergraduates involved in research.
Overall, the financing studies for the Electrical Engineering program at Princeton University are structured to support students financially through a combination of internal aid, external funding opportunities, part-time employment, and research-based funding sources. The university’s emphasis on need-blind admissions and meeting full demonstrated need ensures that financial barriers are minimized, allowing talented students to fully engage with the academic and research activities within the program.
The Electrical Engineering program at Princeton University offers a comprehensive curriculum designed to prepare students for a wide range of careers in technology, research, and industry. The program emphasizes a strong foundation in core principles of electrical engineering, including circuit analysis, digital systems, signal processing, electromagnetics, and communications. Students have the opportunity to engage in hands-on laboratory work, cutting-edge research projects, and interdisciplinary collaborations that enhance their technical skills and innovation capabilities.
Princeton's approach balances theoretical understanding with practical application, fostering critical thinking and problem-solving abilities. The program provides specialized electives in areas such as integrated circuits, photonics, power systems, control systems, artificial intelligence, and machine learning. Students can tailor their academic paths to their interests through a flexible course selection and research opportunities.
Undergraduate students may pursue a Bachelor of Science (B.S.) degree in Electrical Engineering, which typically includes coursework, a senior thesis or project, and participation in research with faculty members. The program encourages undergraduate research, with many students working alongside professors on pioneering projects in areas like quantum electronics, robotics, and advanced communication systems.
Facilities at Princeton support extensive learning and experimentation, including state-of-the-art laboratories and research centers. The program also benefits from Princeton’s interdisciplinary environment, enabling collaboration with Departments of Computer Science, Mechanical and Aerospace Engineering, and Applied and Computational Mathematics. This cross-disciplinary approach enhances students’ understanding of how electrical engineering integrates with other technological fields.
The faculty comprises leading researchers and educators recognized internationally for their contributions to the field. Students are mentored through seminars, workshops, and industry partnerships that connect academic research with real-world applications. Graduates of Princeton’s Electrical Engineering program are well-prepared to continue further studies in graduate and professional schools or to launch careers in sectors such as electronics, aerospace, telecommunications, energy, and manufacturing.
Princeton University also emphasizes ethical responsibility and sustainability in engineering design, ensuring graduates are aware of social and environmental impacts of technological development. With a rigorous academic environment and a vibrant campus community, the Electrical Engineering program aims to cultivate innovative, ethical, and resourceful engineers prepared for the evolving technological landscape.