Electrical Engineering (BS)
Electrical engineering is the driving force behind the technological innovations that will shape the future. It's the realm where the boundaries of possibility are constantly pushed, as engineers harness the power of electricity, electronics, and electromagnetism to forge new pathways towards progress. In this dynamic field, engineers are crafting the infrastructure of tomorrow's world, where renewable energy sources fuel our cities, smart grids optimize and secure power distribution, electric vehicles revolutionize transportation, and innovations in biomedical devices dramatically improve the quality of life.
Moreover, with the rapid advancement of electronics and telecommunications, electrical engineers are at the forefront of creating the next generation of connected devices, from wearables to Internet of Things ecosystems, that will enhance our lives and transform industries. As we race into the future, electrical engineers are poised to drive innovation, sustainability, and connectivity, propelling humanity toward new heights of technological achievement and societal advancement.
Core Courses
The electrical and computer engineering curricula share core courses comprising a substantial portion of the first three years of study. Many of the core courses are offered three times a year in fall, spring, and summer. A strong emphasis is placed on fundamental concepts in core courses so that graduates are prepared for rapid technological changes common in the electrical and computer engineering professions. A comprehensive foundation in mathematics and the physical sciences in the freshman year is followed in subsequent years by additional core courses in mathematics, physics, electric circuit theory, digital logic, computer systems, electronics, electromagnetics, and linear systems. Laboratory work is designed to demonstrate fundamental principles and to provide experience in designing and testing electronic hardware and computer software. Both curricula have a required two semester senior design project which gives students comprehensive experience in designing, building, and testing physical systems.
Curricula
In addition to the core courses described above, students in the electrical engineering curriculum take two foundational electives and four specialization electives in areas of their choice within the discipline and two technical electives that can be in either electrical engineering or selected engineering courses offered by other departments. Additionally, a variety of elective courses are offered in communications, computational intelligence, controls, digital signal processing, digital systems, nanotechnology, mechatronics, microelectronics, networking, robotics, and VLSI design. There are typically a dozen or more of these courses offered each fall and spring semester and two or three available each summer.
Plan Requirements
| Code | Title | Hours |
|---|---|---|
| Major Field of Study Requirements | ||
| Math | ||
| 紼插泭141 | Calculus I 1,2 | 4 |
| 紼插泭241 | Calculus II 1,2 | 4 |
| 紼插泭242 | Calculus III | 4 |
| 釦啦泭371 | Introduction to Probability and Distribution Theory | 3 |
| Science | ||
| 唬晨泭101 &硃鳥梯;泭唬晨泭102 | Chemistry - A Molecular Science and General Chemistry Laboratory 1,2 | 4 |
| 捩喊泭205 &硃鳥梯;泭捩喊泭206 | Physics for Engineers and Scientists I and Physics for Engineers and Scientists I Laboratory 1,2 | 4 |
| 捩喊泭208 &硃鳥梯;泭捩喊泭209 | Physics for Engineers and Scientists II and Physics for Engineers and Scientists II Laboratory | 4 |
| Electrical Engineering Core | ||
| 楚唬楚泭109 | Introduction to Computer Systems 3 | 3 |
| 楚唬楚泭200 | Introduction to Signals, Circuits and Systems 3 | 4 |
| 楚唬楚泭209 | Computer Systems Programming | 3 |
| 楚唬楚泭211 | Electric Circuits 3 | 4 |
| 楚唬楚泭212 | Fundamentals of Logic Design | 3 |
| 楚唬楚泭220 | Analytical Foundations of Electrical and Computer Engineering 3 | 3 |
| 楚唬楚泭301 | Linear Systems | 3 |
| 楚唬楚泭302 | Microelectronics | 4 |
| 楚唬楚泭303 | Electromagnetic Fields | 3 |
| 楚唬楚泭380 | Engineering Profession for Electrical Engineers | 1 |
| 棗娶泭楚唬楚泭381 | Engineering Profession for Computer Engineers | |
| 棗娶泭楚唬楚泭383 | Introduction to Entrepreneurship and New Product Development | |
| 楚唬楚泭484 | Electrical and Computer Engineering Senior Design I | 3 |
| 棗娶泭楚唬楚泭482 | Engineering Entrepreneurship Senior Design I | |
| 楚唬楚泭485 | Electrical and Computer Engineering Senior Design II | 3 |
| 棗娶泭楚唬楚泭483 | Engineering Entrepreneurship Senior Design II | |
| Other Major | ||
| ECE Foundation Electives | 6 | |
| EE Elective | 6 | |
Two courses must be selected from the same EE area. | ||
| ECE Elective | 6 | |
| Open/Technical Elective | 6 | |
| 唬倏紼泭110 | Public Speaking | 3 |
| 楚捧勞泭331 | Communication for Engineering and Technology | 3 |
| College Requirements | ||
| 楚泭101 | Introduction to Engineering & Problem Solving | 1 |
| 楚泭102 | Engineering in the 21st Century | 2 |
| 楚泭115 | Introduction to Computing Environments | 1 |
| Other | ||
| 楚唬泭205 | Fundamentals of Economics | 3 |
| 棗娶泭楚唬泭201 | Principles of Microeconomics | |
| 棗娶泭插賊楚泭201 | Introduction to Agricultural & Resource Economics | |
| 棗娶泭插賊楚泭201A | Introduction to Agricultural & Resource Economics | |
| Total Hours | 101 | |
- 1
Course required for Change of Degree Audit (CODA).
- 2
A grade of C or higher is required.
- 3
A grade of C- or higher is required.
| Code | Title | Hours |
|---|---|---|
| GEP Courses | ||
| 楚捧勞泭101 | Academic Writing and Research | 4 |
| GEP Humanities | 6 | |
| GEP Social Sciences | 3 | |
| GEP Health and Exercise Studies | 2 | |
| GEP Elective | 3 | |
| GEP Interdisciplinary Perspectives | 3 | |
| GEP Global Knowledge (verify requirement) | ||
| GEP Foundations of American Democracy (verify requirement) | ||
| World Language Proficiency (verify requirement) | ||
| Total Hours | 21 | |
EE Electives泭
| Code | Title | Hours |
|---|---|---|
| ECE and EE Electives | ||
| Comm, Sig, Proc Sys | ||
| Communications Engineering | ||
| Introduction to Signal Processing | ||
| Introduction to Machine Learning | ||
| Wireless Communication Systems | ||
| Introduction to Signal Processing | ||
| Systems Biology Modeling of Plant Regulation | ||
| Advanced Digital Signal Processing | ||
| Random Processes | ||
| Digital Communications | ||
| Neural Networks and Deep Learning | ||
| Digital Imaging Systems | ||
| LTE and 5G Communications | ||
楚唬楚泭582 | ||
| Control Sys | ||
| Digital Control Systems | ||
| Industrial Robot Systems | ||
| Mechatronics | ||
| System Control Engineering | ||
| Medical Instrumentation | ||
| Digital Control System Projects | ||
| Autonomous Robot Systems | ||
| Circ, E&M Sys | ||
| Electronics Engineering | ||
| Transmission Lines and Antennas for Wireless | ||
| Radio System Design | ||
| Analog Electronics Laboratory | ||
| Analog Electronics | ||
楚唬楚泭532 | ||
| Electromagnetic Fields | ||
| Antennas and Arrays | ||
| Design Of Electronic Packaging and Interconnects | ||
| RF Design for Wireless | ||
| Nano Sys | ||
| Introduction to Solid-State Devices | ||
| Wearable Biosensors and Microsystems | ||
| Introduction to Photonics and Optical Communications | ||
| Introduction to Integrated Circuit Technology and Fabrication | ||
| Conventional and Emerging Nanomanufacturing Techniques and Their Applications in Nanosystems | ||
| Solid State Solar and Thermal Energy Harvesting | ||
| Neural Interface Engineering | ||
| Photonics and Optical Communications | ||
| Physics of Semiconductors | ||
楚唬楚泭531 | ||
| Integrated Circuits Technology and Fabrication | ||
| Principles Of MOS Transistors | ||
| Power Sys | ||
| Fundamentals of Power Electronics | ||
| Power System Analysis | ||
| Renewable Electric Energy Systems | ||
| Electric Motor Drives | ||
| Power Electronics Design & Packaging | ||
| Power Electronics | ||
| Design of Electromechanical Systems | ||
| Power System Operation and Control | ||
| Smart Electric Power Distribution Systems | ||
| Semiconductor Power Devices | ||
| Electric Motor Drives | ||
| Electric Power System Protection | ||
| Electric Power Engineering Practicum I | ||
| Electric Power Engineering Practicum II | ||
| The Business of the Electric Utility Industry | ||
| Communication and SCADA Systems for Smart Grid | ||
| Power System Transients Analysis | ||
| Comp Arch Sys | ||
| Architecture Of Parallel Computers | ||
| Microprocessor Architecture | ||
| ASIC and FPGA Design with Verilog | ||
| VLSI Systems Design | ||
| Embed Sys | ||
ECE 460/560 | ||
| Embedded System Analysis and Optimization | ||
| Networking Sys | ||
| Introduction to Computer Networking | ||
| Internetworking | ||
| Cloud Computing Technology | ||
| Computer Networks | ||
| Internet Protocols | ||
| Computer and Network Security | ||
| Introduction to Wireless Networking | ||
| Networking Services: QoS, Signaling, Processes | ||
| Switched Network Management | ||
| Introduction to Computer Performance Modeling | ||
| Software Sys | ||
| Operating Systems Design | ||
| Compiler Optimization and Scheduling | ||
| Object-Oriented Design and Development | ||
| Special Topics | ||
| Special Topics in Electrical and Computer Engineering | ||
ECE Electives
ECE Elective
| Code | Title | Hours |
|---|---|---|
| 楚唬楚泭402 | Communications Engineering | 3 |
| 楚唬楚泭403 | Electronics Engineering | 3 |
| 楚唬楚泭404 | Introduction to Solid-State Devices | 3 |
| ECE 406/506 | Architecture Of Parallel Computers | 3 |
| 楚唬楚泭407 | Introduction to Computer Networking | 3 |
| ECE 410/510 | Introduction to Signal Processing | 3 |
| 楚唬楚泭411 | Introduction to Machine Learning | 3 |
| ECE 418/518 | Wearable Biosensors and Microsystems | 3 |
| 楚唬楚泭420 | Wireless Communication Systems | 3 |
| 楚唬楚泭421 | Introduction to Signal Processing | 3 |
| 楚唬楚泭422 | Transmission Lines and Antennas for Wireless | 3 |
| 楚唬楚泭423 | Introduction to Photonics and Optical Communications | 3 |
| ECE 424/524 | Radio System Design | 3 |
| 楚唬楚泭426 | Analog Electronics Laboratory | 3 |
| 楚唬楚泭434 | Fundamentals of Power Electronics | 3 |
| 楚唬楚泭436 | Digital Control Systems | 3 |
| 楚唬楚泭442 | Introduction to Integrated Circuit Technology and Fabrication | 3 |
| 楚唬楚泭451 | Power System Analysis | 3 |
| ECE 452/552 | Renewable Electric Energy Systems | 3 |
| 楚唬楚泭453 | Electric Motor Drives | 3 |
| 楚唬楚泭455 | Industrial Robot Systems | 3 |
| ECE 456/556 | Mechatronics | 3 |
| ECE 460/560 | 3 | |
| ECE 461/561 | Embedded System Analysis and Optimization | 3 |
| ECE 463/563 | Microprocessor Architecture | 3 |
| ECE 464/564 | ASIC and FPGA Design with Verilog | 3 |
| ECE 465/565 | Operating Systems Design | 3 |
| ECE 466/566 | Compiler Optimization and Scheduling | 3 |
| ECE 468/568 | Conventional and Emerging Nanomanufacturing Techniques and Their Applications in Nanosystems | 3 |
| 楚唬楚泭470 | Internetworking | 3 |
| ECE 488/588 | Systems Biology Modeling of Plant Regulation | 3 |
| ECE 489/589 | Solid State Solar and Thermal Energy Harvesting | 3 |
| 楚唬楚泭492 | Special Topics in Electrical and Computer Engineering | 1-4 |
| 楚唬楚泭505 | Neural Interface Engineering | 3 |
| 楚唬楚泭511 | Analog Electronics | 3 |
| 楚唬楚泭513 | Advanced Digital Signal Processing | 3 |
| 楚唬楚泭514 | Random Processes | 3 |
| 楚唬楚泭515 | Digital Communications | 3 |
| 楚唬楚泭516 | System Control Engineering | 3 |
| 楚唬楚泭517 | Object-Oriented Design and Development | 3 |
| 楚唬楚泭522 | Medical Instrumentation | 3 |
| 楚唬楚泭523 | Photonics and Optical Communications | 3 |
| 楚唬楚泭530 | Physics of Semiconductors | 3 |
| 楚唬楚泭531 | 3 | |
| 楚唬楚泭532 | 3 | |
| 楚唬楚泭533 | Power Electronics Design & Packaging | 3 |
| 楚唬楚泭534 | Power Electronics | 3 |
| 楚唬楚泭535 | Design of Electromechanical Systems | 3 |
| 楚唬楚泭536 | Digital Control System Projects | 3 |
| 楚唬楚泭538 | Integrated Circuits Technology and Fabrication | 3 |
| 楚唬楚泭540 | Electromagnetic Fields | 3 |
| 楚唬楚泭541 | Antennas and Arrays | 3 |
| 楚唬楚泭542 | Neural Networks and Deep Learning | 3 |
| 楚唬楚泭544 | Design Of Electronic Packaging and Interconnects | 3 |
| 楚唬楚泭546 | VLSI Systems Design | 3 |
| 楚唬楚泭547 | Cloud Computing Technology | 3 |
| 楚唬楚泭549 | RF Design for Wireless | 3 |
| 楚唬楚泭550 | Power System Operation and Control | 3 |
| 楚唬楚泭551 | Smart Electric Power Distribution Systems | 3 |
| 楚唬楚泭553 | Semiconductor Power Devices | 3 |
| 楚唬楚泭554 | Electric Motor Drives | 3 |
| 楚唬楚泭555 | Autonomous Robot Systems | 3 |
| 楚唬楚泭557 | Principles Of MOS Transistors | 3 |
| 楚唬楚泭558 | Digital Imaging Systems | 3 |
| 楚唬楚泭570 | Computer Networks | 3 |
| 楚唬楚泭573 | Internet Protocols | 3 |
| 楚唬楚泭574 | Computer and Network Security | 3 |
| 楚唬楚泭575 | Introduction to Wireless Networking | 3 |
| 楚唬楚泭576 | Networking Services: QoS, Signaling, Processes | 3 |
| 楚唬楚泭577 | Switched Network Management | 3 |
| 楚唬楚泭578 | LTE and 5G Communications | 3 |
| 楚唬楚泭579 | Introduction to Computer Performance Modeling | 3 |
| 楚唬楚泭581 | Electric Power System Protection | 3 |
| 楚唬楚泭582 | 3 | |
| 楚唬楚泭583 | Electric Power Engineering Practicum I | 3 |
| 楚唬楚泭584 | Electric Power Engineering Practicum II | 3 |
| 楚唬楚泭585 | The Business of the Electric Utility Industry | 3 |
| 楚唬楚泭586 | Communication and SCADA Systems for Smart Grid | 3 |
| 楚唬楚泭587 | Power System Transients Analysis | 3 |
| 楚唬楚泭591 | Special Topics In Electrical Engineering | 1-6 |
| 楚唬楚泭592 | Special Topics In Electrical Engineering | 1-6 |
Open/Tech Electives泭
Open Electives
Choose from the ECE Elective List or the other Open Electives listed below
ECE Elective
| Code | Title | Hours |
|---|---|---|
| 楚唬楚泭402 | Communications Engineering | 3 |
| 楚唬楚泭403 | Electronics Engineering | 3 |
| 楚唬楚泭404 | Introduction to Solid-State Devices | 3 |
| ECE 406/506 | Architecture Of Parallel Computers | 3 |
| 楚唬楚泭407 | Introduction to Computer Networking | 3 |
| ECE 410/510 | Introduction to Signal Processing | 3 |
| 楚唬楚泭411 | Introduction to Machine Learning | 3 |
| ECE 418/518 | Wearable Biosensors and Microsystems | 3 |
| 楚唬楚泭420 | Wireless Communication Systems | 3 |
| 楚唬楚泭421 | Introduction to Signal Processing | 3 |
| 楚唬楚泭422 | Transmission Lines and Antennas for Wireless | 3 |
| 楚唬楚泭423 | Introduction to Photonics and Optical Communications | 3 |
| ECE 424/524 | Radio System Design | 3 |
| 楚唬楚泭426 | Analog Electronics Laboratory | 3 |
| 楚唬楚泭434 | Fundamentals of Power Electronics | 3 |
| 楚唬楚泭436 | Digital Control Systems | 3 |
| 楚唬楚泭442 | Introduction to Integrated Circuit Technology and Fabrication | 3 |
| 楚唬楚泭451 | Power System Analysis | 3 |
| ECE 452/552 | Renewable Electric Energy Systems | 3 |
| 楚唬楚泭453 | Electric Motor Drives | 3 |
| 楚唬楚泭455 | Industrial Robot Systems | 3 |
| ECE 456/556 | Mechatronics | 3 |
| ECE 460/560 | 3 | |
| ECE 461/561 | Embedded System Analysis and Optimization | 3 |
| ECE 463/563 | Microprocessor Architecture | 3 |
| ECE 464/564 | ASIC and FPGA Design with Verilog | 3 |
| ECE 465/565 | Operating Systems Design | 3 |
| ECE 466/566 | Compiler Optimization and Scheduling | 3 |
| ECE 468/568 | Conventional and Emerging Nanomanufacturing Techniques and Their Applications in Nanosystems | 3 |
| 楚唬楚泭470 | Internetworking | 3 |
| ECE 488/588 | Systems Biology Modeling of Plant Regulation | 3 |
| ECE 489/589 | Solid State Solar and Thermal Energy Harvesting | 3 |
| 楚唬楚泭492 | Special Topics in Electrical and Computer Engineering | 1-4 |
| 楚唬楚泭505 | Neural Interface Engineering | 3 |
| 楚唬楚泭511 | Analog Electronics | 3 |
| 楚唬楚泭513 | Advanced Digital Signal Processing | 3 |
| 楚唬楚泭514 | Random Processes | 3 |
| 楚唬楚泭515 | Digital Communications | 3 |
| 楚唬楚泭516 | System Control Engineering | 3 |
| 楚唬楚泭517 | Object-Oriented Design and Development | 3 |
| 楚唬楚泭522 | Medical Instrumentation | 3 |
| 楚唬楚泭523 | Photonics and Optical Communications | 3 |
| 楚唬楚泭530 | Physics of Semiconductors | 3 |
| 楚唬楚泭531 | 3 | |
| 楚唬楚泭532 | 3 | |
| 楚唬楚泭533 | Power Electronics Design & Packaging | 3 |
| 楚唬楚泭534 | Power Electronics | 3 |
| 楚唬楚泭535 | Design of Electromechanical Systems | 3 |
| 楚唬楚泭536 | Digital Control System Projects | 3 |
| 楚唬楚泭538 | Integrated Circuits Technology and Fabrication | 3 |
| 楚唬楚泭540 | Electromagnetic Fields | 3 |
| 楚唬楚泭541 | Antennas and Arrays | 3 |
| 楚唬楚泭542 | Neural Networks and Deep Learning | 3 |
| 楚唬楚泭544 | Design Of Electronic Packaging and Interconnects | 3 |
| 楚唬楚泭546 | VLSI Systems Design | 3 |
| 楚唬楚泭547 | Cloud Computing Technology | 3 |
| 楚唬楚泭549 | RF Design for Wireless | 3 |
| 楚唬楚泭550 | Power System Operation and Control | 3 |
| 楚唬楚泭551 | Smart Electric Power Distribution Systems | 3 |
| 楚唬楚泭553 | Semiconductor Power Devices | 3 |
| 楚唬楚泭554 | Electric Motor Drives | 3 |
| 楚唬楚泭555 | Autonomous Robot Systems | 3 |
| 楚唬楚泭557 | Principles Of MOS Transistors | 3 |
| 楚唬楚泭558 | Digital Imaging Systems | 3 |
| 楚唬楚泭570 | Computer Networks | 3 |
| 楚唬楚泭573 | Internet Protocols | 3 |
| 楚唬楚泭574 | Computer and Network Security | 3 |
| 楚唬楚泭575 | Introduction to Wireless Networking | 3 |
| 楚唬楚泭576 | Networking Services: QoS, Signaling, Processes | 3 |
| 楚唬楚泭577 | Switched Network Management | 3 |
| 楚唬楚泭578 | LTE and 5G Communications | 3 |
| 楚唬楚泭579 | Introduction to Computer Performance Modeling | 3 |
| 楚唬楚泭581 | Electric Power System Protection | 3 |
| 楚唬楚泭582 | 3 | |
| 楚唬楚泭583 | Electric Power Engineering Practicum I | 3 |
| 楚唬楚泭584 | Electric Power Engineering Practicum II | 3 |
| 楚唬楚泭585 | The Business of the Electric Utility Industry | 3 |
| 楚唬楚泭586 | Communication and SCADA Systems for Smart Grid | 3 |
| 楚唬楚泭587 | Power System Transients Analysis | 3 |
| 楚唬楚泭591 | Special Topics In Electrical Engineering | 1-6 |
| 楚唬楚泭592 | Special Topics In Electrical Engineering | 1-6 |
| Code | Title | Hours |
|---|---|---|
| 楚唬楚泭303 | Electromagnetic Fields | 3 |
| 楚泭304 | Introduction to Nano Science and Technology | 3 |
| 楚唬楚泭305 | Principles of Electromechanical Energy Conversion | 3 |
| 楚唬楚泭306 | Introduction to Embedded Systems | 3 |
| 楚唬楚泭308 | Elements of Control Systems | 3 |
| 楚唬楚泭309 | Data Structures and Object-Oriented Programming for Electrical and Computer Engineers | 3 |
| 楚唬楚泭310 | Design of Complex Digital Systems | 3 |
| 楚唬楚泭384 | Practical Engineering Prototyping | 3 |
| 唬楚泭214 | Engineering Mechanics-Statics | 3 |
| 棗娶泭紼插楚泭206 | Engineering Statics | |
| 紼釦楚泭200 | Mechanical Properties of Structural Materials | 3 |
| 棗娶泭紼釦楚泭201 | Structure and Properties of Engineering Materials | |
| 梆釦楚泭311 | Engineering Economic Analysis | 3 |
| 紼插楚泭208 | Engineering Dynamics | 3 |
| 紼插楚泭201 | Thermal-Fluid Sciences | 3 |
| MAE 302/BME泭525 | Engineering Thermodynamics II | 3 |
Semester Sequence
This is a sample.
| First Year | ||
|---|---|---|
| Fall Semester | Hours | |
| 唬晨泭101 | Chemistry - A Molecular Science 1 | 3 |
| 唬晨泭102 | General Chemistry Laboratory 1 | 1 |
| 楚泭101 | Introduction to Engineering & Problem Solving 1,2 | 1 |
| 楚泭115 | Introduction to Computing Environments 1,2 | 1 |
| 楚捧勞泭101 | Academic Writing and Research 1,2 | 4 |
| 紼插泭141 | Calculus I 1 | 4 |
| GEP Health and Exercise Studies | 1 | |
| 泭 | Hours | 15 |
| Spring Semester | ||
| 楚唬楚泭109 | Introduction to Computer Systems 2 | 3 |
| 紼插泭241 | Calculus II 1 | 4 |
| 捩喊泭205 | Physics for Engineers and Scientists I 1 | 3 |
| 捩喊泭206 | Physics for Engineers and Scientists I Laboratory | 1 |
| 楚泭102 | Engineering in the 21st Century | 2 |
| 楚唬泭205 | Fundamentals of Economics or Principles of Microeconomics or Introduction to Agricultural & Resource Economics or Introduction to Agricultural & Resource Economics | 3 |
| 泭 | Hours | 16 |
| Second Year | ||
| Fall Semester | ||
| 楚唬楚泭200 | Introduction to Signals, Circuits and Systems 2 | 4 |
| 楚唬楚泭209 | Computer Systems Programming 2 | 3 |
| 紼插泭242 | Calculus III | 4 |
| 捩喊泭208 | Physics for Engineers and Scientists II | 3 |
| 捩喊泭209 | Physics for Engineers and Scientists II Laboratory | 1 |
| 泭 | Hours | 15 |
| Spring Semester | ||
| 唬倏紼泭110 | Public Speaking | 3 |
| 楚唬楚泭211 | Electric Circuits 2 | 4 |
| 楚唬楚泭212 | Fundamentals of Logic Design 2 | 3 |
| 楚唬楚泭220 | Analytical Foundations of Electrical and Computer Engineering 2 | 3 |
| GEP Requirement | 3 | |
| 泭 | Hours | 16 |
| Third Year | ||
| Fall Semester | ||
| 楚唬楚泭301 | Linear Systems | 3 |
| 楚唬楚泭302 | Microelectronics | 4 |
| ECE Foundation Elective | 3 | |
| 釦啦泭371 | Introduction to Probability and Distribution Theory | 3 |
| GEP Health and Exercise Studies | 1 | |
| 泭 | Hours | 14 |
| Spring Semester | ||
| 楚唬楚泭303 | Electromagnetic Fields | 3 |
| Select one of the following: | 1 | |
| Engineering Profession for Electrical Engineers | ||
| Engineering Profession for Computer Engineers | ||
| Introduction to Entrepreneurship and New Product Development | ||
| ECE Foundation Elective | 3 | |
| Open/Technical Elective | 3 | |
| 楚捧勞泭331 | Communication for Engineering and Technology | 3 |
| GEP Requirement | 3 | |
| 泭 | Hours | 16 |
| Fourth Year | ||
| Fall Semester | ||
| 楚唬楚泭484 | Electrical and Computer Engineering Senior Design I | 3 |
| ECE Elective | 3 | |
| EE Elective | 3 | |
| Open/Technical Elective | 3 | |
| GEP Requirement | 3 | |
| 泭 | Hours | 15 |
| Spring Semester | ||
| 楚唬楚泭485 | Electrical and Computer Engineering Senior Design II | 3 |
| EE Elective | 3 | |
| ECE Elective | 3 | |
| GEP Requirement | 3 | |
| GEP Requirement | 3 | |
| 泭 | Hours | 15 |
| 泭 | Total Hours | 122 |
- 1
Courses required for Change of Degree Audit (CODA). CH 101, 102; MA 141, 241; PY 205, 206 must be completed with C or higher.
- 2
A grade of C- or higher is required.泭E 115 requires satisfactory completion (S).
An electrical engineering degree opens the door to a variety of dynamic career opportunities at the forefront of technological innovation. Graduates can pursue roles as power systems engineers, designing and optimizing the infrastructure that delivers electricity to homes and industries.
They may delve into the world of electronics, developing cutting-edge devices and systems such as smartphones, computers, and medical devices. Control systems engineers design and implement automated systems that regulate processes in industries ranging from manufacturing to aerospace. Renewable energy specialists work at the forefront of sustainable technology, designing and implementing solar, wind, and other alternative energy systems to combat climate change.
You can design and optimize communication networks, enabling seamless connectivity in today's digital world. Moreover, with the increasing integration of electronics and software, opportunities abound in fields such as embedded systems, robotics, and the Internet of Things, where engineers create innovative solutions that blend hardware and software to tackle real-world challenges.
Whether in traditional industries or emerging fields, electrical engineering graduates are well-positioned to drive technological progress and make meaningful contributions to society.
You can泭泭for examples of career paths.
Career Titles
- Computer Network Architects
- Control and Valve Installers and Repairers, Except Mechanical Door
- Electrical Drafter
- Electrical Engineer
- Electrical EngineeringTechnician
- Electro-Mechanical Technicians
- Electronic Drafter
- Electronics Engineer
- Electronics Technician
- Engineering Professor
- Instrument Technician
- Mechanical Drafter
- Mechatronics Engineers
- Photonics Engineers
- Radio Frequency Identification Device Specialists
- Sales Engineers
- Solar Energy Systems Engineers
Learn More About Careers
Explore North Carolinas central online resource for students, parents, educators, job seekers and career counselors looking for high quality job and career information.
Browse the Occupational Outlook Handbook published by the Bureau of Labor Statistics to view state and area employment and wage statistics. You can also identify and compare similar occupations based on your interests.
View videos that provide career details and information on wages, employment trends, skills needed, and more for any occupation. Sponsored by the U.S. Department of Labor.
(NC State student email address required)
This career, major and education planning system is available to current NC State students to learn about how your values, interests, competencies, and personality fit into the NC State majors and your future career. An NC State email address is required to create an account. Make an appointment with your to discuss the results.
(Available to prospective students)
A career assessment tool designed to support prospective students in exploring and choosing the right major and career path based on your unique personality, interests, skills and values. Get started with Focus 2 Apply and see how it can guide your journey at NC State.