OHIO University Undergraduate Catalog 2015-16
[Archived Catalog]
Electrical Engineering (B.S.E.E.) |
Major code BS7253
Russ College of Engineering and Technology
School of Electrical Engineering and Computer Science
329 Stocker Center
Ohio University
Athens, OH 45701
Phone: 740.593.1568
Fax: 740.593.0007
http://www.ohio.edu/engineering/eecs/
Costas Vassiliadis, contact person
vassilia@ohio.edu
Program Overview
The electrical engineering program is administered by the School of Electrical Engineering and Computer Science (EECS). The School is the beneficiary of a major endowment from the late Dr. C. Paul Stocker, an electrical engineering alumnus. This endowment provides support for facilities and a level of excellence surpassed by few other electrical engineering and computer science schools in the nation.
The School of Electrical Engineering and Computer Science is located in Stocker Center, a modern facility housing undergraduate, graduate, and research activities. The program offers a Bachelor of Science in Electrical Engineering (B.S.E.E.) degree, which is accredited by the Engineering Accreditation Commission of the Accreditation Board of Engineering and Technology, 111 Market Place, Suite 1050, Baltimore MD 21202-4012–telephone: 410.347.7700.
The electrical engineering program offers two curriculum tracks leading to a B.S.E.E. degree. The electrical engineering (EE) track is intended for students who want to work in one of the many areas of electrical engineering. A computer engineering (CpE) track is available for students who intend to work in the area of computers. Students who are undecided as to which area they want to pursue should follow the electrical engineering track until they decide.
Electrical engineering addresses the wide application of electrical and electronic phenomena to real-world needs, from consumer goods to space exploration. It encompasses such diverse areas as research, development, design, sales, and operation of electrical and electronic systems. Areas of specialization include such varied fields as circuit design, communications, computers and automata, control systems, electromagnetics, energy sources and systems, power electronics, power system planning, electronics, and instrumentation. Students interested in digital computers may choose from courses in the School on programming, digital circuits, computer design, and software engineering.
Electrical engineering graduates hold challenging positions in such nonelectrical industries as chemical, nuclear, automotive, medical, textile, petroleum, and transportation, as well as in electronics, communications, power, control, and other electrical industries. The jobs performed by electrical engineering graduates include such diverse activities as research, development, design, production and manufacturing, and consulting.
The electrical engineering program has three major objectives for its undergraduate students (Program Educational objectives are broad statements that describe the career and professional accomplishments that the program is preparing the graduates to achieve):
- Depth and Breadth: Produce graduates that will have the theoretical, practical, and professional knowledge necessary to be productive upon entering the workforce or successful in advanced study;
- Staying Current: Produce graduates that will maintain and develop the knowledge and the skills needed to identify, formulate, and solve problems throughout their career; and
- Professionalism: Produce graduates that exhibit an understanding of the necessity for professional integrity, ethical behavior, and multicultural awareness.
All electrical engineering students must fulfill the University’s General Education requirements. Students will select elective courses in conjunction with their advisors. To develop the general knowledge and skills necessary to support the study and practice of engineering, students will take 8 courses in mathematics and the basic sciences. The purpose of the five general engineering courses is to give students an understanding of engineering fundamentals outside of electrical engineering.
The electrical engineering portion of the curriculum consists of several blocks of courses. The introductory block is intended to promote the students interested in electrical engineering, while introducing physical and logical concepts necessary for future studies. The goal of the foundations block is to develop the fundamental knowledge and analytical skills necessary for the study and practice of electrical engineering. The intermediate breadth block prepares the student to study the various areas of electrical engineering and computer engineering at the advanced level. EECS electives allow students to develop specialized knowledge and skills in one of the areas of electrical and computer engineering or explore other topics at the advanced level.
Because the ability to solve problems is critical for engineers, students will develop engineering design skills as they progress through the curriculum. Engineering design is addressed in most E E courses. In the intermediate design block, students will develop experience in experimental design and analysis. The design experience culminates in the senior year with the capstone design sequence of courses, where students complete a design project that simulates work found in professional practice.
Admissions Information
Freshman/First-Year Admission
No requirements beyond University admission requirements. Students are expected to take four years of mathematics, and a year of chemistry and physics in high school if possible.
Change of Program Policy
Students who wish to transfer into an engineering or computer science program must have earned a C or better in a math course and a science course. The math course must be equivalent to MATH 1200 or higher. The science course must be required for the program or preparatory for a required course such as CHEM 1210, 1500, 1510, PHYS 2001, 2051 or BIOS 1700. Students must have an overall GPA greater than 2.0 at Ohio University, for all courses in Russ College, and for all courses in Chemical Engineering. Students must have succeeded in all required courses taken previously in three or fewer attempts. For some courses, success means a grade of at least a C or C-.
External Transfer Admission
In addition to University guidelines, students should have earned a C (2.0) or better grade in a college math course equivalent to MATH 1200 or higher and a C (2.0) or better grade in a chemistry course equivalent to CHEM 1210 or higher or a physics course equivalent to PHYS 2001 or higher.
Opportunities Upon Graduation
Electrical engineering (EE), the largest engineering branch, deals with the study of electricity, electronics, and electromagnetism and the way these theories are applied to sub-disciplines such as: Generation, Transmission and Distribution of Electric Power, Telecommunication systems including Wireless Communications, Automatic Control Systems and Robotics, Aviation Electronic (Avionics) Systems, Aerospace and Electronics Systems, Computers and Microprocessors, Lasers, Optoelectronic and Superconductor Devices, Microelectronic Devices and Integrated Circuit Technology, Signal Processing, Microwave Systems and Electromagnetic Wave Propagation and Antennas, Audio, Speech, Video and Image Processing, Automotive Electronics, Industrial Sensors and Instrumentation, Power Electronics, Fuel Cells, Renewable Energy, Nanoelectronics and Nanofabrication, Ultrasonic Imaging, Bio-Engineering and Medical Electronics.
Electrical engineers design products affecting everything from public health to safety, and ranging from huge electric power generators to miniature microprocessor chips. These products include: devices for the generation and delivery of electric power to consumers: (homes/businesses/industry), electronic instruments to measure temperature, speed, pressure and flow rate, computers embedded into systems enriched with methods of data processing and storage, communications systems; radio, tv, satellite systems, telephones and fiber-optic systems, aircraft flight control and collision-avoidance systems, systems used in medical electronics, medical lasers, systems that education and entertain, computers and computer networks, compact-disk players, and multimedia systems.
Most electrical engineering jobs are in the following places: Engineering and Business Consulting Companies, Government Agencies, Manufacturers of Electrical and Electronic Equipment, Manufacturers of Computer and/or Industrial Equipment, Transportation, Communications and Utility Companies, Computer and Data Processing Services Companies.
Sample of companies that hire electrical engineers: AT&T, Microsoft, Ericsson, Inc., Milliken, General Electric, Procter and Gamble, IBM, Sprint Corporation, Intel Corporation, Texas Instruments, International Paper, Hewlett-Packard, Honeywell, Verizon, Walt Disney, AEP, Electronic Arts, Sun Microsystems, Qualcomm, Cisco Systems, 3Com, Nortel Networks, Audiovox, Johnson Controls, Raytheon, TRW, Silicon Graphics, Lucent, Kimberly-Clark, NASA, NSA, Rocwell, RoviSys, Ford Motor, Boeing, General Motors, Honda, and Lockheed Martin.
Requirements
Universitywide Graduation Requirements
To complete this program, students must meet all Universitywide graduation requirements .
College-Level Requirements for the Russ College of Engineering and Technology
View the College-Level Requirements for the Russ College of Engineering and Technology .
Core Curriculum
Complete the following course:
- ET 1500 - Engineering and Technology: Career Orientation Credit Hours: 0.5
Math and Basic Science
Complete the following courses:
- EE 2324 - Analytical Foundations of Electrical Engineering Credit Hours: 4.0
- EE 3713 - Applied Probability and Statistics for Electrical Engineers Credit Hours: 3.0
- CHEM 1510 - Fundamentals of Chemistry I Credit Hours: 4.0
- MATH 2301 - Calculus I Credit Hours: 4.0
- MATH 2302 - Calculus II Credit Hours: 4.0
- MATH 3300 - Calculus III Credit Hours: 4.0
- PHYS 2051 - General Physics Credit Hours: 5.0
Science Elective
Complete 4 hours of science with lab. Complete one course from the following categories:
Biological Sciences Option
Complete the following courses:
- BIOS 1700 - Biological Sciences I: Molecules and Cells Credit Hours: 3.0
- BIOS 1705 - Biological Sciences I Laboratory Credit Hours: 1.0
General Engineering
Complete the following courses and one programming elective and one engineering elective:
- CS 2400 - Introduction to Computer Science I Credit Hours: 4.0
- ET 2200 - Statics Credit Hours: 3.0
- ET 3300 - Engineering Economy Credit Hours: 2.0
Programming Elective
Complete one of the following couses:
- CS 2300 - Computer Programming in JAVA Credit Hours: 4.0
- CS 2401 - Introduction to Computer Science II Credit Hours: 4.0
Engineering Elective
Complete one of the following courses:
- CE 3400 - Fluid Mechanics Credit Hours: 3.0
- ET 2220 - Strength of Materials Credit Hours: 3.0
- ET 2240 - Dynamics Credit Hours: 3.0
- ET 2300 - Principles of Engineering Materials Credit Hours: 3.0
- ET 3200 - Engineering Thermodynamics Credit Hours: 3.0
Electrical Engineering Requirements
Complete the following courses:
- EE 1014 - Introduction to Electrical Engineering Credit Hours: 4.0
- EE 1024 - Introduction to Computer Engineering Credit Hours: 4.0
- EE 2104 - Circuits I Credit Hours: 4.0
- EE 2114 - Circuits II Credit Hours: 4.0
- EE 2213 - Instrumentation Laboratory Credit Hours: 3.0
- EE 3214 - Electromagnetics and Materials I Credit Hours: 4.0
- EE 3223 - Electromagnetics and Materials II Credit Hours: 3.0
- EE 3334 - Linear Signals and Systems Credit Hours: 4.0
- EE 3343 - Electronics I Credit Hours: 3.0
- EE 3513 - Digital Signals and Systems Credit Hours: 3.0
- EE 3954 - Microprocessors and Microcontrollers Credit Hours: 4.0
- EE 3963 - Electric Machines Credit Hours: 3.0
- EE 3973 - Electronics II Credit Hours: 3.0
- EE 4953 - Electrical and Computer Engineering Capstone Design I Credit Hours: 3.0
- EE 4963 - Electrical and Computer Engineering Capstone Design II Credit Hours: 3.0
Senior EE/CS Electives
Complete two of the following courses:
- CS 3560 - Software Engineering Tools and Practices Credit Hours: 3.0
- CS 4000 - Introduction to Distributed, Parallel, and Web-Centric Computing Credit Hours: 3.0
- CS 4040 - Design and Analysis of Algorithms Credit Hours: 3.0
- CS 4060 - Computation Theory Credit Hours: 3.0
- CS 4100 - Introduction to Formal Languages and Compilers Credit Hours: 3.0
- CS 4160 - Problem Solving with Bioinformatics Tools Credit Hours: 3.0
- CS 4170 - Data Mining With Applications in the Life Sciences Credit Hours: 3.0
- CS 4250 - Interactive Computer Graphics Credit Hours: 3.0
- CS 4440 - Data Communications Credit Hours: 3.0
- CS 4500 - Advanced Object Oriented Design and GUI Techniques Credit Hours: 3.0
- CS 4580 - Operating Systems II Credit Hours: 3.0
- CS 4620 - Database Systems Credit Hours: 3.0
- CS 4750 - Internet Engineering Credit Hours: 4.0
- CS 4800 - Artificial Intelligence Credit Hours: 3.0
- EE 3613 - Computer Organization Credit Hours: 3.0
- EE 3753 - Introduction to Computer Networks Credit Hours: 3.0
- EE 4053 - Physical and Power Electronics Credit Hours: 3.0
- EE 4143 - Design of Digital Circuits Credit Hours: 3.0
- EE 4183 - Micro and Nano Fabrication Credit Hours: 3.0
- EE 4213 - Feedback Control Theory Credit Hours: 3.0
- EE 4313 - Optoelectronics and Photonics Credit Hours: 3.0
- EE 4403 - Antenna and Microwave Theory Credit Hours: 3.0
- EE 4523 - Introduction to Electric Power System Engineering and Analysis Credit Hours: 3.0
- EE 4673 - Embedded Systems Credit Hours: 3.0
- EE 4683 - Computer Architecture Credit Hours: 3.0
- EE 4713 - Communication Engineering Credit Hours: 3.0
- EE 4853 - Electronic Navigation Systems Credit Hours: 3.0
- EE 4913 - Programmable Logic Controllers Credit Hours: 3.0