Electrical Engineering, B.S.E.E.

Program Educational Objectives:

The electrical engineering program prepares graduates who will:

Be successful as practicing professionals in diverse career paths or in graduate school.
Distinguish themselves in breadth of perspective and the ability to solve complex problems.
Be effective communicators and team members, with many assuming leadership roles.
Be active in their profession and participate in continuing education opportunities to foster personal and organizational growth.
Demonstrate a concern for justice, ethical behavior, and societal improvement through participation in professional and civic organizations.

Student Outcomes:

The Shiley School of Engineering prepares engineering majors with the following outcomes so that as graduates, they can attain the Program Educational Objectives listed above.

An ability to identify, formulate, and solve complex engineering problems by applying principles of engineering, science, and mathematics.
An ability to apply engineering design to produce solutions that meet specified needs with consideration of public health, safety, and welfare, as well as global, cultural, social, environmental, and economic concerns.
An ability to communicate effectively with a range of audiences.
An ability to recognize ethical and professional responsibilities in engineering situations and make informed judgments, which must consider the impact of engineering solutions in global, economic, environmental and societal contexts.
An ability to function effectively on a team whose members come together to provide leadership, create a collaborative and inclusive environment, establish goals, plan tasks, and meet objectives.
An ability to develop and conduct appropriate experimentation, analyze and interpret data, and use engineering judgment to draw conclusions.
An ability to acquire and apply new knowledge as needed, using appropriate learning strategies.

Electrical engineers improve lives by designing, testing, and supporting a wide range of products and systems, such as medical imaging, renewable energy, robots, wireless communications, computers, and all sorts of other electronic devices. The program begins with a foundation of mathematics, science, and engineering fundamentals during the first and second years. Courses during the junior year provide additional theoretical foundation and laboratory experience. Capstone course work during the senior year enables students to pursue special areas of interest through in-depth analysis, experimentation, and design. EE electives and professional electives are available in various specialties for students to pursue their particular field of interest. Development of written and oral communication skills and teamwork are incorporated as important components of the educational experience. The electrical engineering program leads to a bachelor of science in electrical engineering (B.S.E.E.) degree accredited by the Engineering Accreditation Commission of ABET.

Common Engineering Requirements — 36 credit hours

CHM 207	General Chemistry I	3
CHM 277	General Chemistry I Lab	1
EGR 110	Introduction to Engineering	2
EGR 111	Engineering Computing with Applications	2
EGR 352	Engineering Economics	2
EGR 361	Analysis of Engineering Data	3
MTH 201	Calculus I	4
MTH 202	Calculus II	4
MTH 301	Vector Calculus	4
MTH 321	Ordinary Differential Equations	3
PHY 204	General Physics I	3
PHY 274	General Physics Lab I	1
PHY 205	General Physics II	3
PHY 275	General Physics Lab II	1

EGR 110: For transfer students into the Shiley School who have declared a major and have not had an Introduction to Engineering course, the dean may approve the substitution of an engineering or computer science elective depending on the student’s educational background.

Electrical Engineering Requirements — 56 credit hours

CS 203	Introduction to Computer Science	3
CS 273	Computer Science Laboratory	1
CS 305	Data Structures	3
EE 231	Logic Design	3
EE 261	Electrical Circuits	3
EE 262	Signals and Systems	3
EE 271	Electrical Circuits Laboratory	1
EE 300	Electrical Engineering Seminar	1
EE 301	Electromagnetic Fields	3
EE 332	Digital Systems Design	3
EE 334	Embedded Systems Design	3
EE 351	Electronic Circuits I	3
EE 352	Electronic Circuits II	3
EE 371	Electronic Circuits Laboratory	1
EE 373	Digital Systems Design Laboratory	1
EE 483	Electrical Engineering Capstone Project I	3
	Or
EGR 483	Multi-disciplinary Capstone Project I	3
EE 484	Electrical Engineering Capstone Project II	3
	Or
EGR 484	Multi-disciplinary Capstone Project II	3

Dual degrees within engineering: Students completing dual degrees within the Shiley School have two options for completing the XX 483/484 requirement: 1) The student takes EGR 483 and EGR 484 and the student’s contributions to the capstone project include both disciplines, or 2) The student takes both discipline-specific 483 and 484 courses.

Credit minima: 30 credit hours of math and science; 45 credit hours of engineering

Electrical Engineering Electives - 12 credit hours

EE4xx, does not include EE 48x courses. Must be taken for a grade A - F.

Engineering, Math, or Science Elective - 3 credit hours

Select one 3 credit hour engineering, computer science, math or science course at the 300-level or higher. Must be taken for a grade A - F.

Professional Electives - 9 credit hours

The professional electives may be a combination of courses (each 3-credit hours or more unless approved by the program chair) offered by the University at the 200-level or higher. Professional electives include the following: courses offered by the Shiley School, courses that comprise a University minor, and courses included in an approved cluster. Professional elective credit may not be awarded for AP and IB examinations, or ROTC credit. Must be taken for a grade A - F.