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151 - 160 of 184 results for: ME

ME 391: Engineering Problems

Directed study for graduate engineering students on subjects of mutual interest to student and staff member. May be used to prepare for experimental research during a later quarter under 392. Faculty sponsor required.
Terms: Aut, Win, Spr, Sum | Units: 1-10 | Repeatable for credit

ME 392: Experimental Investigation of Engineering Problems

Graduate engineering students undertake experimental investigation under guidance of staff member. Previous work under 391 may be required to provide background for experimental program. Faculty sponsor required.
Terms: Aut, Win, Spr, Sum | Units: 1-10 | Repeatable for credit
Instructors: Alonso, J. (PI) ; Aquino Shluzas, L. (PI) ; Bao, Z. (PI) ; Bohg, J. (PI) ; Boies, A. (PI) ; Boslough, A. (PI) ; Cai, W. (PI) ; Cappelli, M. (PI) ; Cargnello, M. (PI) ; Chang, F. (PI) ; Chaudhuri, O. (PI) ; Chu, S. (PI) ; Chueh, W. (PI) ; Collins, S. (PI) ; Currano, R. (PI) ; Cutkosky, M. (PI) ; Darve, E. (PI) ; Dauskardt, R. (PI) ; DeSimone, J. (PI) ; Delitto, D. (PI) ; Delp, S. (PI) ; Diaz Marin, C. (PI) ; Dionne, J. (PI) ; Dresselhaus-Marais, L. (PI) ; Edwards, M. (PI) ; Fan, J. (PI) ; Farhat, C. (PI) ; Feig, V. (PI) ; Fischer, M. (PI) ; Follmer, S. (PI) ; Fuller, G. (PI) ; Gao, G. (PI) ; George, P. (PI) ; Gerdes, J. (PI) ; Glenzer, S. (PI) ; Gold, G. (PI) ; Goodson, K. (PI) ; Gorle, C. (PI) ; Gu, W. (PI) ; Hanson, R. (PI) ; Hong, G. (PI) ; Iaccarino, G. (PI) ; Ihme, M. (PI) ; Kennedy, M. (PI) ; Kenny, T. (PI) ; Kogan, F. (PI) ; Krishnan, S. (PI) ; Kuhl, E. (PI) ; Lai, C. (PI) ; Larson, N. (PI) ; Lele, S. (PI) ; Levenston, M. (PI) ; Lew, A. (PI) ; Mabogunje, A. (PI) ; Majumdar, A. (PI) ; Mani, A. (PI) ; Mannix, A. (PI) ; Marsden, A. (PI) ; Mayalu, M. (PI) ; McKeon, B. (PI) ; Milroy, J. (PI) ; Moin, P. (PI) ; Okamura, A. (PI) ; Pavone, M. (PI) ; Poon, A. (PI) ; Prinz, F. (PI) ; Sakovsky, M. (PI) ; Santiago, J. (PI) ; Schwager, M. (PI) ; Shaqfeh, E. (PI) ; Skylar-Scott, M. (PI) ; Somen, D. (PI) ; Suckale, J. (PI) ; Switky, A. (PI) ; Tang, S. (PI) ; Tarpeh, W. (PI) ; Tartakovsky, D. (PI) ; Wall, D. (PI) ; Wang, H. (PI) ; Zeineh, M. (PI) ; Zhao, R. (PI) ; Zheng, X. (PI)

ME 393: Master's Directed Research

Directed research experience for MS students in mechanical engineering who are pursuing the Distinction in Research (DiR). The student is responsible for securing a faculty research advisor and will register under that advisor's section number. Students must provide confirmation of faculty research advisor's agreement to supervise DiR, at which time they will receive a permission code from ME Student Services allowing them to enroll. Course may be repeated for credit.
Terms: Aut, Win, Spr, Sum | Units: 1-10 | Repeatable for credit

ME 393W: Master's Directed Research: Writing the Report

This course is for MS students in mechanical engineering who are finishing up their Distinction in Research (DiR) and focusing on the writing of their technical report. Faculty supervision is required and students will register under their advisor's section number. Permission codes apply and can be obtained from ME Student Services. Technical report should be read and signed off by advisor no later than two weeks prior to the end of the quarter in which an MS-DiR student plans to confer their degree.
Terms: Aut, Win, Spr, Sum | Units: 3

ME 395: Seminar in Solid Mechanics

Required of Ph.D. candidates in solid mechanics. Guest speakers present research topics related to mechanics theory, computational methods, and applications in science and engineering. May be repeated for credit.
Terms: Aut, Win, Spr | Units: 1 | Repeatable for credit
Instructors: Larson, N. (PI)

ME 397: Design Research Theory and Methodology Seminar

This is a participatory graduate seminar that offers graduate students hands-on support in developing their design research methodology skills, including study formation and analysis plan, quantitative and qualitative methods, lab and field experiment design, self-report data collection and analysis, and other skills necessary to do quality research. Students interested in honing their human-subject research skills are encouraged to attend. Students bring their own current and/or future projects to discuss and develop with fellow students and instructors.
Last offered: Spring 2025 | Units: 1 | Repeatable for credit

ME 398: Ph.D. Research Rotation

Directed research experience for first-year Mechanical Engineering Ph.D. students with faculty sponsors. The student is responsible for arranging the faculty sponsor and registering under the faculty sponsor's section number. Course may be repeated up to four times in the first year. A different faculty sponsor must be selected each time.
Terms: Aut, Win, Spr, Sum | Units: 1-4 | Repeatable 4 times (up to 16 units total)

ME 400: Thesis (Engineer Degree)

Investigation of some engineering problems. Required of Engineer degree candidates
Terms: Aut, Win, Spr, Sum | Units: 2-15 | Repeatable for credit

ME 403: Quantum Field Theory (QFT) for Engineering Applications (MATSCI 405)

QFT principles for engineering applications in nano and microelectronics. Examples include quantum computing, topological quantum computing, and superconductivity. Focus on solids and quasiparticles. Relation between energy, momentum, and mass. Quantization, Klein Gordon, Dirac, Pauli, and Schrödinger equation. Introduction to topological states and the Majorana condition. Lagrange invariance and the need for gauge fields (electrodynamics).
Terms: Aut | Units: 3
Instructors: Prinz, F. (PI)

ME 405: Asymptotic Methods in Computational Engineering

This course is not a standard teaching of asymptotic methods as thought in the applied math programs. Nor does it involve such elaborate algebra and analytical derivations. Instead, the class relies on students' numerical programming skills and introduces improvements on numerical methods using standard asymptotic and scaling ideas. The main objective of the course is to bring physical insight into numerical programming. The majority of the problems to be explored involve one- and two-dimensional transient partial differential equations inspired by thermal-fluid and transport engineering applications. Topics include: 1-Review of numerical discretization and numerical stability, 2-Implicit versus explicit methods, 3-Introduction to regular and singular perturbation problems, 4-Method of matched asymptotic expansions, 5-Stationary thin interfaces: boundary layers, Debye layers, 6-Moving thin interfaces: shocks, phase-interfaces, 7-Reaction-diffusion problems, 8-Directional equilibrium and lubrication theory.
Terms: Win | Units: 3
Instructors: Mani, A. (PI) ; Le, H. (TA)
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