Energy systems engineering umich

Energy systems engineering umich DEFAULT

Sita Syal

Sita Syal

Ph.D. Student in Mechanical Engineering, admitted Autumn


Sita is a Ph.D. candidate and a National Science Foundation Graduate Fellow in Mechanical Engineering and Human-Centered Design at Stanford University. Her research focuses on quantifying human influence, cost, and equity in sustainable energy systems models through an integration of qualitative and quantitative methods. Her work spans applications in solar, wind, and sustainable transportation. She also studies data science problem solving processes and how these processes can be redefined to be more human-centric.

Sita grew up in Michigan and completed a B.S.E. in Chemical Engineering and an M.Eng in Energy Systems Engineering, both from the University of Michigan, Ann Arbor, as well as an M.S. in Product Design Engineering ("Design Impact") at Stanford. She was awarded a Morris K. Udall scholarship in for her work in sustainability and clean energy. Additionally, she completed a semester abroad at Delhi University and studied rural and urban solar implementation throughout India. Her experience spans energy, from biofuels development to topsides process engineering. Before graduate school, Sita worked in the energy industry and served as a process engineer onshore and an operations engineer on one of the largest oil rigs in the Gulf of Mexico. Outside of her academic life, Sita is passionate about supporting women and minorities in STEM fields and enjoys running long distances and playing her violin.

Education & Certifications

  • M.S., Stanford University, Product Design Engineering ("Design Impact")

  • M.Eng., University of Michigan - Ann Arbor, Energy Systems Engineering

  • B.S.E., University of Michigan - Ann Arbor, Chemical Engineering

All Publications

  • Quantifying the Importance of Solar Soft Costs: A New Method to Apply Sensitivity Analysis to a Value FunctionJOURNAL OF MECHANICAL DESIGNSyal, S. M., MacDonald, E. F; (12)
  • Agent-Based Modeling of Decisions and Developer Actions in Wind Farm Landowner Contract AcceptanceJOURNAL OF MECHANICAL DESIGNSyal, S. M., Ding, Y., MacDonald, E. F; (9)

The Master of Engineering (M.Eng.) in Energy Systems Engineering (ESE) program is designed for students who are motivated to take on the challenges facing society in the areas of sustainable energy generation, storage, and conversion. In this program, students learn about alternative and conventional energy technologies, the societal and environmental impact of technology developments, and the economic benefits of those developments.

The curriculum takes a holistic approach and exposes students to courses from across disciplines, including engineering, natural and social sciences, public policy, environmental science, and business. Students gain a depth and breadth of knowledge, and an interdisciplinary perspective of the need for energy solutions. Students also develop the skills to analyze often opaque cause and effect relationships across various fields (e.g., how a technological solution impacts legislation and society; or how the abundance and price of energy resources impact food supply, water quality, and sea life, etc.). Graduates are prepared to responsibly lead the future development of critically needed, sustainable infrastructures.

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MSE in Energy Systems Engineering

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.

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 cover a variety of topics, such as hybrid and electric vehicles, alternative energy systems for vehicles, emissions, power electronics, power distribution, design and manufacturing for the environment, etc.

The program may be completed entirely on campus, entirely online, or through a combination of on-campus and online courses. On-campus courses will be offered in the late afternoon and evening hours to enable students to earn their master's degree through part-time study.


Cornell vs. UMich - Energy Systems Engineering Masters

<p>Hello OP, I saw this post and thought I'd reply, even though it has been empty for quite some time.</p>

<p>I am currently a Master of Engineering student in the ESE program at UofM - AA. What I can say is that I'm very glad that I chose this concentration and this university. The program starts off in its first semester a little generic, giving some socio economic perspective to alternatives. After that, you go straight for the hardcore technical stuff. It is very interesting, challenging work, and has allowed me to develop some very valuable technical analysis skills.</p>

<p>Career wise I'm more focused on the controls aspect of advanced propulsion transportation vehicles and their energy sources. What I wanted to gain from this program is:
1) an understanding of the broad energy needs
2) gain a better understanding of the analysis and control of hybrid electric vehicles
3) broaden my horizons to the technical analysis and integration of other renewable technologies
4) develop knowledge on the development, analysis, and integration of hybrid batteries
5) gain perspective on the greater socio-economic impacts and needs</p>

<p>So far, this program has satisfied many of my requirements. The advantage here is taht you get access to top level professors doing advanced research in many of the areas they teach. For example, I never really had an interest in advanced ICEs until I took a course w. Professor Woolridge who runs the advanced combustion lab. Had the opportunity to learn about the design and analysis techniques for new engine technologies and how they impact the transportation industry. I just got done take a course in the Modeling, Control and Analysis of Hybrid Electric Vehicles. Next semester I'm slated to take the advanced battery course. The topics are interesting, the professors are smart, personable, and are involved in cutting edge research, and there are a lot of ways to get involved with industry and research. You will apply many of the technical concepts from undergrad and then they will push you hard to make the connections and applications.</p>

<p>Many of my colleagues here have had great internship opportunities within the transportation industry (General Motors advanced propulsion development etc) and the energy industry (DTE Energy, ITC Transmission Corp etc). </p>

<p>The campus and the city of Ann Arbor are both vibrant communities. The campus is spectacular and offers really great features. The city of Ann Arbor is fun and you can pretty much find anything that you are interested in. Also, MI, though lately may have had some economic struggles, offers great access to high tech companies, many of whom are becoming heavily involved in the alternatives and energy market.</p>


Systems engineering umich energy

Systems Engineering

The Systems Engineering program is designed for engineers and other professionals who are responsible for defining, planning, managing and supporting large integrated systems. The program consists of four graduate core courses and one graduate elective course.

The value of acquiring a systems engineering certificate includes:

  • Formal recognition of the participant’s systems engineering capabilities
  • Career advancement assistance
  • A portable systems engineering designation that is recognizable across industries
  • Professional development as a systems engineer, in addition to demonstrating a commitment to personal development
  • The Systems Engineering certificate program also provides students with a strong foundation to pursue Project Management Professional® (PMP®) certification and/or the International Council on Systems Engineering (INCOSE) multi-level professional certification program.

(15 credit hours)

The certificate can be completed entirely on campus, entirely online, or through a combination of on-campus and online courses.   

Admission Requirements: An undergraduate degree in engineering, business, a physical science, computer science, or applied mathematics, with a GPA of or higher. A probability & statistics course is a prerequisite for this certification program. 

Energy Systems Engineering at Oregon State University

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