D-Lab is a design studio course in which students work on international development projects for under served communities. The class is focused on a participatory, iterative prototyping design process, with particular attention on the constraints faced when designing for developing communities. Students work in multidisciplinary teams on term-long projects in collaboration with community partners, field practitioners, and experts in relevant fields. Students will learn about their partner communities through the collaborative design process and be exposed to many hands-on fabrication and prototyping skills relevant to development at MIT and manufacturing in their partner community. The course will consist of hands-on labs, guest speakers, and a guided design process with review by experts and professionals in development and design.
"This course introduces the principles and methods of Systems Engineering. Lectures follow the "V"-model of Systems Engineering, including needs identification, requirements formulation, concept generation and selection, trade studies, preliminary and detailed design, component and subsystem test and integration as well as functional testing and delivery and operations. Additional concepts such as tradeoffs between performance, cost and system operability will be discussed. Systems Engineering standards and selected journal articles serve as a basis for readings, and individual homework Assignments and Labs will apply the concepts from class. Both aeronautical and astronautical applications are covered. The class serves as preparation for the systems field exam in the Department of Aeronautics and Astronautics."
In 16.89/ESD.352 the students will first be asked to understand the key challenges in designing ground and space telescopes, the stakeholder structure and value flows, and the particular pros and cons of the proposed project. The first half of the class will concentrate on performing a thorough architectural analysis of the key astrophysical, engineering, human, budgetary and broader policy issues that are involved in this decision. This will require the students to carry out a qualitative and quantitative conceptual study during the first half of the semester and recommend a small set of promising architectures for further study at the Preliminary Design Review (PDR).Both lunar surface telescopes as well as orbital locations should be considered. The second half of the class will then pick 1-2 of the top-rated architectures for a lunar telescope facility and develop the concept in more detail and present the detailed design at the Critical Design Review (CDR). This should not only sketch out the science program, telescope architecture and design, but also the stakeholder relationships, a rough estimate of budget and timeline, and also clarify the role that human explorers could or should play during both deployment and servicing/operations of such a facility (if any).
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