Activities | percentages |
---|---|
Homework (8 Assignments at 5% each) | 40% |
Exams (2 Exams at 15% each) | 30% |
Project | 25% |
Participation | 5% |
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This course is a junior/senior level elective on machine elements and mechanical design. With your help, this course will be a great learning experience exposing you to interesting material, challenging you to think deeply, and providing skills useful in professional practice.
This course meets in two classroom sessions and one lab session each week. We expect you to be present at these sessions and to participate thoughtfully.
The class sessions will be used to introduce new material, to amplify with examples, to do interactive exercises, and to provide feedback on homework assignments, exams, and the project. The weekly lab sessions are devoted to hands-on activities that support learning the content, advancing the term projects, and complementing homework and exam activities.
The team project is a central experience in this course, in which students apply electro-mechanical design principles for a variety of machine elements. Teams of 3 to 5 people will work on a project of their choice (from a list of suggested topics), and be limited to a $500 budget. The project requirements include:
The course grade will be determined as follows:
Activities | percentages |
---|---|
Homework (8 Assignments at 5% each) | 40% |
Exams (2 Exams at 15% each) | 30% |
Project | 25% |
Participation | 5% |
There is no required textbook for the course, although the following books are suggested for purchase by students. They are sometimes used as a source of material in handouts and as a source of some questions in the problem sets.
Shigley, J. E., C. R. Mischke, and R. G. Budynas. Mechanical Engineering Design. 7th ed. Burr Ridge, IL: McGraw-Hill, 2003. ISBN: 9780072921939.
Hamrock, B. J., et al. Fundamentals of Machine Elements. 2nd ed. Burr Ridge, IL: McGraw-Hill, 2004. ISBN: 9780072465327.
Norton, R. L. Design of Machinery. 3rd ed. Burr Ridge, IL: McGraw-Hill, 2003. ISBN: 9780072864472.
Oberg, E., et al. Machinery's Handbook. 27th ed. New York, NY: Industrial Press, Inc., 2004. ISBN: 9780831127114.
Computation is essential to modern mechanical engineering design. However, it is not a primary objective of this subject to develop your proficiency with any particular software tool. We have developed assignments that require substantial computation, but we leave it to each student to select the software to use. We will be using Mathcad® fairly extensively for in class demonstrations and exercises, so it behooves you to learn the basics of this program. However, you may turn in assignments done with MATLAB®, MiniTab®, Excel, Mathematica®, or whatever tools you wish to use.
In engineering design, it is helpful to give careful considerations to objectives and to the form in which they are expressed. To the extent possible, the learning objectives of this subject were developed following the guidelines articulated by Richard Felder including use of action verbs and inclusion of objectives in levels 4-6 of Bloom's taxonomy of educational objectives as shown below.
Educational Objectives | Associated Action Verbs |
---|---|
6. Evaluation | Judge, Critique, Justify |
5. Synthesis | Design, Invent, Propose |
4. Analysis | Predict, Model, Derive |
3. Application | Calculate, Solve |
2. Comprehension | Explain, Paraphrase |
1. Knowledge | List, Recite |
After taking this course, students should be able to:
The units on an MIT subject correspond to the time that an adequately prepared student is expected to spend in a normal week. This is divided into three numbers associated with the subject (X-Y-Z) with X being class time, Y being laboratory time, and Z being work outside of class. The numbers associated with 2.72 are (3-3-6) making this a 12-unit subject. Thus, the overall weekly time commitment is expected to be about 12 hours. This includes to 6 hours per week scheduled in class and 6 hours per week out of class. The out-of-class time will roughly be split between homework assignments and project work.
This course will not be graded on a curve. In principle, everyone in the course can earn an A, but that is not usually what happens. Historically 50% to 25% of students earn a B and a small number earn a C or worse. All problems will be graded on a letter basis according to the MIT definition of grades:
A - Exceptionally good performance, demonstrating a superior understanding of the subject matter, a foundation of extensive knowledge, and a skillful use of concepts and/or materials.
B - Good performance, demonstrating capacity to use the appropriate concepts, a good understanding of the subject matter, and an ability to handle the problems and materials encountered in the subject.
C - Adequate performance, demonstrating an adequate understanding of the subject matter, an ability to handle relatively simple problems, and adequate preparation for moving on to more advanced work in the field.
D - Minimally acceptable performance, demonstrating at least partial familiarity with the subject matter and some capacity to deal with relatively simple problems, but also demonstrating deficiencies serious enough to make it inadvisable to proceed further in the field without additional work.
F - Unsatisfactory performance.
Plusses and minuses will be used in conjunction with the letters in grading all work. The final grade will include plusses and minuses.
The fundamental principle of academic integrity is that one must fairly represent the source of the intellectual content of the work one submits for credit. Students are trusted to adhere to this principle and its meaning in the context of this subject as subsequently explained. Official Institute policy regarding academic honesty can be found in the current Bulletin under "Academic Procedures and Institute Regulations".
What is the policy on examinations?
The examinations in this subject are to represent individual work. You may not receive any help from other students or any other individuals.
What about home assignments? Can we work together?
We encourage students to work together in this subject to understand the homework assignments and to learn in general. There is much to be gained in sharing the learning process. However, the final submission should represent your own expression of the final response to the assignment and not a copy of someone else's expression thereof, whether directly from a person or as recorded on paper (e.g. a book) or electronically (e.g. on a Web site). Furthermore, you must fairly represent the authorship of the intellectual content of the work you submit for credit by acknowledging the contribution of sources (e.g., books, Web sites) you consult in the process of completing assignments. In addition, at the end of each assignment on which you collaborated with other students, you must cite the students and the interaction. The purpose of this is to acknowledge their contribution to your work. Some examples follow:
*This academic honesty policy is adapted from the policy used in 16.01 Unified Engineering.