Global Arc

An introduction to the properties of engineering materials that emphasizes the correlation between atomic and microscopic structure and the macroscopic properties of the materials. Topics include structural, mechanical, thermodynamic, and design-related issues important to engineering applications. Two lectures, one preceptorial.

This course addresses, in technical detail, the challenge of changing the future global energy system to accommodate constraints on the atmospheric carbon dioxide concentration. Energy production strategies are emphasized, including renewable energy, nuclear fission and fusion, the capture and storage of fossil-fuel carbon, and hydrogen and low-carbon fuels. Efficient energy use is also considered, as well as intersections of energy with economic development, international security, local environmental quality, and human behavior and values. Two 90-minute lectures.

Introduction to the performance, stability, and control of aircraft. Fundamentals of configuration aerodynamics. Methods for analyzing the dynamics of physical systems. Characterization of modes of motion and desirable flying qualities. Two 90-minute lectures and one preceptorial. Prerequisites: 206 and 222.

Building on strength of materials and calculus, this course integrates physical laws to analyze stress and displacement fields in structures. The course introduces basic concepts and equations in three dimensions and then applies them to aircraft structures. Phenomena to be discussed include elastic anisotropy, bending, buckling, fracture, and fatigue. The course is important for anyone interested in structured design. Two 90-minute lectures. Prerequisites: 335 or instructor's permission.

Low-speed incompressible potential flow theory and high speed compressible flows. Low-speed topics include circulation, vorticity, d'Alembert's paradox, potential flows, and finite wing theory. High-speed topics include speed of sound, nozzles, shock waves, expansion waves, and effects of heat addition and friction. Three lectures, one preceptorial. Prerequisites: 221, 222 or instructor's permission.

Independent work is intended for juniors doing only a one-term project. Students develop a topic of their own or select from a list of topics prepared by the faculty. They develop a work plan and select an adviser and are assigned a second reader. At the end of the term, students submit a written report. Enroll in either 339 for fall or 340 for spring. This course does not fulfill the departments independent work or thesis requirement.

Independent work with design is intended for juniors doing only a one-term project. Similar to 339, with the principal difference that the project must incorporate aspects and principles of design in a system, product, vehicle, device, apparatus, or other design element. At the end of the term, students submit a written report. Enroll in 339D for fall, or 340D for spring. This course does not fulfill the departments independent work or thesis requirement.

Independent work is intended for juniors doing only a one-term project. Students develop a topic of their own or select from a list of topics prepared by the faculty. They develop a work plan and select an adviser and are assigned a second reader. At the end of the term, students submit a written report. Enroll in either MAE 339 for fall or MAE 340 for spring. This course does not fulfill the departments independent work or thesis requirement.

Independent work with design is intended for juniors doing only a one-term project. Similar to MAE 340, with the principal difference that the project must incorporate aspects and principles of design in a system, product, vehicle, device, apparatus, or other design element. At the end of the term, students submit a written report. This course will fulfill the additional engineering science elective in the Mechanical Program. It will not fulfill the departments independent work or senior thesis requirement.

This course addresses the various concepts that form the basis of modern space flight and astronautics. The focus is on space flight analysis and planning and not hardware or spacecraft design. The topics include space flight history, orbital mechanics, orbit perturbations, near-Earth and interplanetary mission analysis, orbit determination and satellite tracking, spacecraft maneuvers and attitude control, launch, and entry dynamics. Use of advanced software for the planning and analysis of space missions. Two 90-minute lectures. Prerequisite: 305 or instructor's permission.