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Welcome to the Mechanical Engineering Undergraduate Student Handbook. The goal of this handbook is to provide information about services and activities that will enrich your undergraduate experience and facilitate the practical aspects of receiving an education at the University of Michigan.

At the University of Michigan, the Bachelor of Science in Engineering degree (BSE) in ME provides students with an excellent foundation in the core technical competencies of the discipline: thermal and fluid sciences, solid mechanics and materials, and dynamics and control. Within each of these disciplines, students will complete rigorous coursework that follows the traditional classroom format of lectures, discussions, homework, projects and exams. In addition, an array of technical electives is offered to enable students to tailor their mechanical engineering education to best suit their career goals.

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In addition to the regular BSE degree in Mechanical Engineering, there are numerous other programs offered to enrich education, such as dual-degrees (ME degree and a second degree from another engineering program), Sequential Undergraduate/Graduate Studies (SUGS), the Engineering Global Leadership Program (EGL), Study Abroad (listed among CoE minors), and Independent Study opportunities with ME faculty.

ME-EM is the largest department at Michigan Technological University and among the largest mechanical engineering departments in the US, both undergraduate and graduate. With that, there are many resources to help you be successful in your graduate education. There is much information that can be found on many webpages. A good starting place is the Department of Mechanical Engineering-Engineering Mechanics.

There are several differences between the graduate program and what a student has experienced in an undergraduate program. The objective of the undergraduate program is to provide a student with a broad education and background in an engineering discipline. Also, a number of technical skills must be developed by the undergraduate so the student is capable of addressing engineering challenges associated with a given discipline, and contributing to the growth of that discipline whether by employment or more advanced education.

The graduate degree program prepares a student for a professional career in the design, research, and development of advanced engineering systems and technologies. In the case of the PhD, the preparation must also consider a possible career path as a scientist or faculty member. After earning a graduate engineering degree, a person will be given greater responsibility for directing and managing technical projects or research programs. It is inevitable and essential that the graduate-degree engineer becomes an independent thinker. The graduate student's goal should be to develop the ability to form critical judgments of others as well as themselves. Of course, it will be necessary to meet the requirements of a variety of advanced courses, but what matters most is whether the student can learn independently, how well the student can interpret, evaluate, and communicate technical information, and how well one is able to generate and critically evaluate ideas.

Virtually all highly respected mechanical engineering departments have a strong graduate program. The reputation of a department is highly dependent on the vitality of its graduate program through the production of archival publications, success and placement of its graduate students, and research productivity. A quality graduate program positively impacts the ability of a department to recruit world-class faculty and students. The Department of Mechanical Engineering-Engineering Mechanics values its reputation and wishes to continue to attract the most capable people to the Department, so that our highly respected graduate program will continue to be a top priority. The Department offers a wide range of graduate courses and offers several graduate degrees and graduate certificates. The degrees offered by the Department are; the Master of Science in Mechanical Engineering (MSME), Master of Science in Engineering Mechanics (MSEM), and Doctor of Philosophy (PhD) in ME-EM.

The engineering profession demands the highest ethical conduct and integrity to protect the welfare of the public and the profession. Michigan Tech and ME-EM also demand a high level of academic integrity by students. Academic misconduct, whether by plagiarism, prohibited sharing of work, misrepresenting oneself to gain access to a class, or other actions that a mechanical engineering graduate student fully understands are academically inappropriate, are considered academic misconduct. The Michigan Tech standards for academic and community conduct are found at:

ME 499 (Special Study) is a course in which you do an independent research project with a tenured/tenure-track Faculty Member. You will be working in the laboratory of the Faculty Member as opposed to taking a lecture. For the list of the faculty members with whom you can work, please visit the ME Faculty Page. You cannot do an independent research project with an ME Lecturer. As part of the ME Curriculum, you are permitted to do one 3-unit ME 499 course. The first step in the process is for you to contact one or more faculty members in the list to discuss the possibility of doing such a project with them. It is, course, best to contact someone who has been an Instructor in a course you have taken and done well.If you are in the BSME with bioengineering emphasis program, the ME 499 independent research project must lie in the bioengineering area. If a faculty member agrees, and you are excited with the project, you will need to fill out the ME 499 Application Form and return to the ME Office. You will be issued a schedule number to enroll in the course after the completed and signed form is submitted to the ME Office.

The Undergraduate Handbook contains important information about the undergraduate program in Mechanical Engineering at SDSU. It is expected that you will study this handbook carefully in conjuction with the SDSU general catalog. If there are specific questions that are not addressed in this handbook, on the website, or in the general catalog, please feel free to contact the ME department office.

The undergraduate program in Mechanical Engineering at Stanford exposes each student to theoretical and practical experiences that form a foundation from which to develop solutions, and provides an environment that allows for the accumulation of knowledge and self discovery so as to extend the domain within which solutions can be formulated. Graduates of the program have many professional options and opportunities, from entry-level work as mechanical engineers to graduate studies in either an engineering discipline or other fields where a broad engineering background is useful. Regardless of the ultimate career choice, graduates leave the program with a solid grounding in the principals and practice of mechanical engineering, equipped to embark upon a lifetime of learning, while employing new concepts, technologies and methodologies.

Professional licensing is an important aspect of professional responsibility. Although civil engineers may find professional registration more important in securing employment, mechanical engineers should seriously consider pursuing licensing as well. A professional license can be important if you work as a consultant or at a small start-up. An engineer working for a start-up or small technical company must fill a much wider spectrum of professional roles than would be the case working for a larger company. Those roles would typically include certifying drawings and other technical materials that require a license as a professional engineer.

I found a handbook at Half Priced Books a few years ago that has everything you need to know but don't want to memorize for Mechanical Engineering. It has derivative and integral tables, exponential powers of numbers, material properties, and equations and brief explanations for just about all the course material you'd find in a standard, BSME curriculum.

I'm a Chemical Engineer who now works mostly in a mechanical engineering role (equipment design, high frequency welding, temperature chambers, etc.) and was curious if there are any great Mechanical Engineering resource books similar to Perry's Chemical Engineering Handbook. Perry's has been a bible during college and when I worked mainly as a Chemical Engineer.

Mechanical engineering students are required to complete a total of 120 credit hours across courses for their major, the Coulter School of Engineering's common curriculum and the Clarkson Common Experience. The 73 credit hours in mechanical engineering include classes in applied physics, applied mathematics, engineering science and mechanical engineering. Mechanical engineering majors are required to complete the following courses:

Students must select a three-credit-hour engineering elective in mechanical engineering, aeronautical engineering or engineering science. Typical courses include Computer-Aided Engineering (CAD), Optimal Engineering, Biomechanics, Additive Manufacturing or Welding and Metallurgy.

The professional electives requirement can be satisfied with upper-division courses in mathematics, physics, other engineering disciplines or mechanical engineering (e.g., Applied Statistics, Fourier Series or Boundary-Value Problems).

Aerospace engineering students are required to complete a total of 120 credit hours across courses for their major, the Coulter School of Engineering's common curriculum and the Clarkson Common Experience. The 87 credit hours in aerospace engineering include classes in applied physics, applied mathematics, engineering science and mechanical engineering. Aerospace engineering majors are required to complete the following courses:

In addition, students must complete nine credits of professional electives, which are upper-division courses in mathematics, physics and other engineering disciplines. Examples include Applied Statistics, Fourier Series and Boundary-Value Problems, Computer-Aided Engineering (CAD), Optimal Engineering, Biomechanics, Additive Manufacturing and Welding and Metallurgy. ff782bc1db