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1 - 10 of 27 results for: AA ; Currently searching autumn courses. You can expand your search to include all quarters

AA 100: Introduction to Aeronautics and Astronautics

This class introduces the basics of aeronautics and astronautics through applied physics, hands-on activities, and real world examples. The principles of fluid flow, flight, and propulsion for aircraft will be illustrated, including the creation of lift and drag, aerodynamic performance including takeoff, climb, range, and landing. The principles of orbits, maneuvers, space environment, and propulsion for spacecraft will be illustrated. Students will be exposed to the history and challenges of aeronautics and astronautics.
Terms: Aut | Units: 3 | UG Reqs: WAY-SMA, GER:DB-EngrAppSci, WAY-AQR
Instructors: Arya, M. (PI)

AA 118N: How to Design a Space Mission: from Concept to Execution

Space exploration is truly fascinating. From the space race led by governments as an outgrowth of the Cold War to the new era of space commercialization led by private companies and startups, more than 50 years have passed, characterized by great leaps forward and discoveries. We will learn how space missions are designed, from concept to execution, based on the professional experience of the lecturer and numerous examples of spacecraft, including unique hardware demonstrations by startups of the Silicon Valley. We will study the essentials of systems engineering as applicable to a variety of mission types, for communication, navigation, science, commercial, and military applications. We will explore the various elements of a space mission, including the spacecraft, ground, and launch segments with their functionalities. Special emphasis will be given to the design cycle, to understand how spacecraft are born, from the stakeholders' needs, through analysis, synthesis, all the way to their integration and validation. We will compare the current designs with those employed in the early days of the space age, and show the importance of economics in the development of spacecraft. Finally, we will brainstorm startup ideas and apply the concepts learned to a notional space mission design as a team.
Terms: Aut | Units: 3 | UG Reqs: WAY-SMA, WAY-AQR
Instructors: Ermakov, A. (PI)

AA 121Q: It IS Rocket Science!

It's an exciting time for space exploration. Companies like SpaceX and Blue Origin are launching rockets into space and bringing them back for reuse. NASA is developing the world's most powerful rocket. Startups are deploying constellations of hundreds of cubesats for communications, navigation, and earth monitoring. The human race has recently gotten a close look at Pluto, soft landed on a comet, and orbited two asteroids. The upcoming launch of the James Webb Space Telescope will allow astronomers to look closer to the beginning of time than ever before. The workings of space systems remain mysterious to most people, but in this seminar we'll pull back the curtain for a look at the basics of "rocket science." How does a SpaceX rocket get into space? How do Skybox satellites capture images for Google Earth? How did the New Horizons probe find its way to Pluto? How do we communicate with spacecraft that are so distant? We'll explore these topics and a range of others during the quarter. We'll cover just enough physics and math to determine where to look in the sky for a spacecraft, planet, or star. Then we'll check our math by going outside for an evening pizza party observing these objects in the night sky. We'll also visit a spacecraft production facility or Mission Operations Center to see theory put into practice.
Terms: Aut | Units: 3 | UG Reqs: WAY-SMA, WAY-AQR
Instructors: Barrows, A. (PI)

AA 126: Aerospace Prototyping Lab

This course is focused on developing practical skills in designing, building, and testing aerospace systems. Practical laboratory exercises will introduce students to tools and diagnostics used in software, electronics, and mechanical design relevant to spacecraft, aircraft, structural testing, and robotics. Enrollment priority will be given to declared Aero/Astro sophomores and juniors.Prerequisites: None
Terms: Aut | Units: 1
Instructors: Lee, N. (PI)

AA 131: Space Flight

This class is all about how to build a spacecraft. It is designed to introduce undergraduate engineering students to the engineering fundamentals of conceiving, designing, implementing, and operating satellites and other space systems. Topics include orbital dynamics, attitude dynamics, mission design, and subsystem technologies. The space environment and the seven classic spacecraft subsystems - propulsion, attitude control and navigation, structure, thermal, power, telemetry and command, and payload - will be explored in detail. Prerequisites: Freshman-level physics, basic calculus and differential equations, AA 100 (Introduction to Aeronautics and Astronautics).
Terms: Aut | Units: 3 | UG Reqs: WAY-AQR
Instructors: D'Amico, S. (PI)

AA 146A: Aircraft Design

Air Capstone I. Required for Aero/Astro majors. This capstone design class allows students to apply knowledge from prior classes in a way that emphasizes the interactions between disciplines and demonstrates how theoretical topics are synthesized in the practical design of an aircraft concept. Prerequisites are MATH 19, 20, 21, CME 100, CME 102 or MATH 51, 53. CME 104 or Math 52 recommended. Elementary physics, and AA100 or equivalent classes. Additional required AA courses dealing with aero, structures, and controls.
Terms: Aut | Units: 3
Instructors: Kroo, I. (PI)

AA 151: Lightweight Structures

The development of lightweight structures aids in enhancing the robustness, efficiency, and cost of aerospace systems. In this course, the theoretical principles used to analyze stress-strain behavior, beam bending, torsion, and thin-walled structures will be reviewed and exercised. In addition, students will study structures under various loading conditions found in real-world applications such as the design of airframes, high-altitude balloons, and solar sails. Students from various disciplines of engineering can benefit from this course. ENGR 14 (Introduction to Solid Mechanics) is a highly recommended prerequisite.
Terms: Aut | Units: 3 | UG Reqs: WAY-AQR
Instructors: Senesky, D. (PI)

AA 174A: Principles of Robot Autonomy I (CS 137A, EE 160A)

Basic principles for endowing mobile autonomous robots with perception, planning, and decision-making capabilities. Algorithmic approaches for robot perception, localization, and simultaneous localization and mapping; control of non-linear systems, learning-based control, and robot motion planning; introduction to methodologies for reasoning under uncertainty, e.g., (partially observable) Markov decision processes. Extensive use of the Robot Operating System (ROS) for demonstrations and hands-on activities. Prerequisites: CS 106A or equivalent, CME 100 or equivalent (for linear algebra), and CME 106 or equivalent (for probability theory).
Terms: Aut | Units: 3-4
Instructors: Pavone, M. (PI)

AA 190: Directed Research and Writing in Aero/Astro

For undergraduates. Experimental or theoretical work under faculty direction, and emphasizing development of research and communication skills. Written report(s) and letter grade required; if this is not appropriate, enroll in 199. Consult faculty in area of interest for appropriate topics, involving one of the graduate research groups or other special projects. May be repeated for credit. Prerequisite: consent of instructor.
Terms: Aut, Win, Spr | Units: 3-5 | Repeatable for credit

AA 191: Practical Training

For undergraduate students. Educational opportunities in high technology research and development labs in industry. Students engage in internship work and integrate that work into their academic program. Following internship work, students complete a research report outlining work activity, problems investigated, key results, and follow-up projects they expect to perform. Meets the requirements for curricular practical training for students on F-1 visas. Student is responsible for arranging own internship/employment and faculty sponsorship. Register under faculty sponsor's section number. All paperwork must be completed by student and faculty sponsor, as the Student Services Office does not sponsor CPT. Students are allowed only two quarters of CPT per degree program. Course may be repeated twice.
Terms: Aut, Win, Spr | Units: 1-3 | Repeatable 3 times (up to 3 units total)
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