Aspiring electrical engineers begin with a pre-engineering curriculum and are enrolled in the College of Engineering with a pre-engineering major for the first year or two of college.
Potential transfer students may complete a pre-engineering curriculum at a community college or another four-year university. Transfer students must successfully complete all prerequisite courses for entry into UW EE’s undergraduate program, and may take courses to satisfy requirements in the areas of visual, literary and performing arts, and individuals and societies.
Once admitted to UW EE, students spend two or more years completing the requirements for the Bachelor of Science in Electrical Engineering (BSEE) degree. The BSEE program is not intended for part-time study. Students are expected to engage in full-time study and meet standards of academic performance.
Undergraduates must choose one concentration, which will focus their studies. Concentrations are available in a wide variety across UW EE’s research areas. For additional information on the EE concentration areas, view the EE Concentration Chart.
- Analog Circuits: Design circuits to process continuous signals in devices such as stereo amplifiers and radio receivers.
- Digital Signal Processing: Improve digital signals, from speech recognition for voice-activated devices to compressing video for teleconferencing.
- Biomedical Instrumentation: Design biomedical instruments such as EKG preamplifiers to monitor the heart’s electrical activity.
- Large Scale Power Systems: Develop technology to efficiently generate and deliver electric energy within existing large scale power systems.
- Sensors and Devices: Design a variety of devices such as lasers, accelerometers and photovoltaic devices, which generate electricity from sunlight.
- Sustainable Electric Energy: Develop renewable energy solutions including solar, wind power and fuel cell technology.
- Digital Integrated Circuits: Design self-contained circuits for computer memory and logic gates, the building blocks of any digital system.
- Electromagnetics: Study the energy that drives optical-fiber communications, radar, antennas and wireless communications.
- Systems, Control and Robotics: Study the design and operation of systems ranging from robots and drones to medical devices and vehicles.
- Communications: Explore how information is transported and stored for cell phone technology, satellite communications and computer networking.
- Photonics: Apply physics, devices and systems involving light to biology, energy, medicine and next generation information technology.
- Embedded Computing Systems: Design digital circuits for digital cameras, home appliances and cars, with a focus on improving speed and power.
- Power Electronics and Electric Drives: Design the power-controlling circuitry and drives of hybrid car technology, renewable energy and robotics.
- Synthetic Biology: Apply engineering principles to biology to create genetic circuits and synthetic living systems to improve human health and advanced materials.