About the Program
Energy Systems Engineering is a 30 credit hour interdisciplinary master's program, designed to provide systems-based knowledge in energy engineering through four core courses and in-depth knowledge in automotive energy and distributed energy systems through six elective courses. The core courses deal with sustainable energy sources, energy generation and storage, energy and environmental policies, and risk-benefit analysis. The elective courses can be selected from a range of courses offered in mechanical, electrical and manufacturing aspects of energy engineering. The elective courses covers a variety of topics, such as hybrid and electric vehicles, alternative energy systems for vehicles, emissions, power electronics, power distribution, design and manufacturing for environment, etc.
The Energy Systems Engineering program has been designed to address the educational need for graduate students interested in energy engineering. Significant growth and investment are expected to occur in energy industries in the State of Michigan and elsewhere in the next several decades. Both small and large energy-related companies are starting up in the State and many of them are located in the metro-Detroit area. The automotive companies are also accelerating research and development in new power generation and propulsion technologies for future vehicles, such as electric batteries and fuel cells. As a result, there is a need for engineers with specialized knowledge in the alternative and renewable energy production, utilization and distribution.
The candidate for the Master's of Science in Engineering in Energy Systems Engineering must meet the requirements for the Bachelor of Science degree in engineering at this campus or the equivalent of these requirements. Undergraduate degrees must be from an accredited program, and for regular admission must be with an average of B (3 points on a 4 point scale) or better. An applicant with a lower GPA may be considered for admission consistent with the Rackham guidelines.
Online program option:
The Energy Systems Engineering program is also offered online through the Distance Learning Network (DLN). The online courses utilize video streaming of the lectures given on campus. The online students have the opportunity to interact with the instructors and with fellow students (both on campus as well as online) through CANVAS. The class lectures, notes and discussions are posted on CANVAS for online students' access.
To provide students with systems-oriented graduate level knowledge in the fields of energy systems engineering.
- A strong foundation in the theoretical principles and techniques from science, engineering, and mathematics needed for advanced engineering design and development.
- An ability to use modern engineering software, processes, devices, and diagnostic tools for advanced engineering design and development.
The candidate must complete at least 30 semester hours of graduate work approved by the program advisor/graduate advisory committee with a grade point average of at least a B (3 points on a 4-point scale) covering all courses elected. These 30 credit hours must include four required core courses and six elective courses. Students cannot have more than one B- in the program and must maintain a B average to remain in good academic standing. A grade of B- in more than one course will not count for graduate credit. Any grade below B- is not acceptable.
All ESE students are required to take four core courses:
- ESE 500 Sustainable Energy Systems
- ESE 501 or 502 Energy Conversion / Energy Storage
- ESE 503 Energy Policy, Economics and Environment
ESE 504 Energy Evaluation, Risk Analysis and Optimization
Select any 6 courses from the following list. Additional elective courses from other units in UM-Dearborn may also be considered with the ESE program director's approval. Thesis option may be elected with the approval of the graduate program director. It will count for six (6) credit hours of graduate coursework replacing two courses in the Elective area and will extend at least two terms.
- AENG 547 Powertrains I
- AENG 588 Design and Manufacturing for Environment
- AENG 596 Internal Combustion Engines I
- AENG 598 Energy Systems for Automotive Vehicles
- ECE 5462 Electrical Aspects for Hybrid Electric Vehicles
- ECE 646 Advanced Study in Electric Drive Transportation
- ME 548 Powertrains II
- ME 597 Internal Combustion Engines II
- ME 598 Engine Emissions
Electric Power Concentration
- ECE 517 Advanced Industrial Drives and Motor Control
- ECE 519 Advanced Topics in EMC
- ECE 542 Introduction to Power Management and Reliability
- ECE 615 Advanced Topics in Power Electronics
- ME 512 Structural Analysis
- ME 514 Advanced Stress Analysis
- ME 522 Advanced Fluid Mechanics
- ME 525 Computational Thermo-Fluids
- ME 528 Fundamentals of Boiling and Condensation
- ME 532 Combustion Processes
- ME 535 Advanced Thermodynamics
- ME 558 Fracture and Fatigue Considerations in Design
- ME 571 Conduction Heat Transfer
- ME 572 Convection Heat Transfer
- ME 591 Degradation of Materials
- ECE 560 Modern Control Theory
- ECE 565 Digital Control Systems
- ECE 580 Digital Signal Processing
- ECE 665 Optimal Control Systems
- EMGT 505 Systems Engineering
- IMSE 506 Stochastic Models
- IMSE 515 Fundamentals of Program Management
- IMSE 516 Project Management and Control
- IMSE 5205 Engineering Risk-Benefit Analysis
- IMSE 5215 Program Budget, Cost Estimation and Control
- IMSE 561 Total Quality Management
- IMSE 5655 Supply Chain Management
- IMSE 567 Reliability Analysis