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16.885J Aircraft Systems Engineering (MIT) 16.885J Aircraft Systems Engineering (MIT)

Description

Aircraft are complex products comprised of many subsystems which must meet demanding customer and operational lifecycle value requirements. This course adopts a holistic view of the aircraft as a system, covering: basic systems engineering; cost and weight estimation; basic aircraft performance; safety and reliability; lifecycle topics; aircraft subsystems; risk analysis and management; and system realization. Small student teams "retrospectively analyze" an existing aircraft covering: key design drivers and decisions; aircraft attributes and subsystems; and operational experience. Finally, the student teams deliver oral and written versions of the case study. Aircraft are complex products comprised of many subsystems which must meet demanding customer and operational lifecycle value requirements. This course adopts a holistic view of the aircraft as a system, covering: basic systems engineering; cost and weight estimation; basic aircraft performance; safety and reliability; lifecycle topics; aircraft subsystems; risk analysis and management; and system realization. Small student teams "retrospectively analyze" an existing aircraft covering: key design drivers and decisions; aircraft attributes and subsystems; and operational experience. Finally, the student teams deliver oral and written versions of the case study.

Subjects

aircraft systems | aircraft systems | aircraft systems engineering | aircraft systems engineering | lifecycle | lifecycle | cost estimation | cost estimation | weight estimation | weight estimation | aircraft performance | aircraft performance | aircraft safety | aircraft safety | aircraft reliability | aircraft reliability | subsystems; risk analysis | subsystems; risk analysis | risk management | risk management | system realization | system realization | retrospective analysis | retrospective analysis | key design drivers | key design drivers | design drivers | design drivers | design decisions | design decisions | aircraft attributes | aircraft attributes | operational experience | operational experience | case study | case study | case studies | case studies | air transportation systems | air transportation systems | air defense system | air defense system | systems engineering | systems engineering | interface management | interface management | interface verification | interface verification | subsystem architecture | subsystem architecture | performance issures | performance issures | design closure | design closure | complex systems | complex systems | 16.885 | 16.885 | ESD.35 | ESD.35

License

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16.885J Aircraft Systems Engineering (MIT) 16.885J Aircraft Systems Engineering (MIT)

Description

Aircraft are complex products comprised of many subsystems which must meet demanding customer and operational lifecycle value requirements. This course adopts a holistic view of the aircraft as a system, covering: basic systems engineering; cost and weight estimation; basic aircraft performance; safety and reliability; lifecycle topics; aircraft subsystems; risk analysis and management; and system realization. Small student teams "retrospectively analyze" an existing aircraft covering: key design drivers and decisions; aircraft attributes and subsystems; and operational experience. Finally, the student teams deliver oral and written versions of the case study. Aircraft are complex products comprised of many subsystems which must meet demanding customer and operational lifecycle value requirements. This course adopts a holistic view of the aircraft as a system, covering: basic systems engineering; cost and weight estimation; basic aircraft performance; safety and reliability; lifecycle topics; aircraft subsystems; risk analysis and management; and system realization. Small student teams "retrospectively analyze" an existing aircraft covering: key design drivers and decisions; aircraft attributes and subsystems; and operational experience. Finally, the student teams deliver oral and written versions of the case study.

Subjects

aircraft systems | aircraft systems | aircraft systems engineering | aircraft systems engineering | lifecycle | lifecycle | cost estimation | cost estimation | weight estimation | weight estimation | aircraft performance | aircraft performance | aircraft safety | aircraft safety | aircraft reliability | aircraft reliability | subsystems; risk analysis | subsystems; risk analysis | risk management | risk management | system realization | system realization | retrospective analysis | retrospective analysis | key design drivers | key design drivers | design drivers | design drivers | design decisions | design decisions | aircraft attributes | aircraft attributes | operational experience | operational experience | case study | case study | case studies | case studies | air transportation systems | air transportation systems | air defense system | air defense system | systems engineering | systems engineering | interface management | interface management | interface verification | interface verification | subsystem architecture | subsystem architecture | performance issures | performance issures | design closure | design closure | complex systems | complex systems | 16.885 | 16.885 | ESD.35 | ESD.35

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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16.885J Aircraft Systems Engineering (MIT) 16.885J Aircraft Systems Engineering (MIT)

Description

Includes audio/video content: AV lectures, AV special element video. 16.885J offers a holistic view of the aircraft as a system, covering: basic systems engineering; cost and weight estimation; basic aircraft performance; safety and reliability; lifecycle topics; aircraft subsystems; risk analysis and management; and system realization. Small student teams retrospectively analyze an existing aircraft covering: key design drivers and decisions; aircraft attributes and subsystems; and operational experience. Oral and written versions of the case study are delivered. For the Fall 2005 term, the class focuses on a systems engineering analysis of the Space Shuttle. It offers study of both design and operations of the shuttle, with frequent lectures by outside experts. Students choose specific s Includes audio/video content: AV lectures, AV special element video. 16.885J offers a holistic view of the aircraft as a system, covering: basic systems engineering; cost and weight estimation; basic aircraft performance; safety and reliability; lifecycle topics; aircraft subsystems; risk analysis and management; and system realization. Small student teams retrospectively analyze an existing aircraft covering: key design drivers and decisions; aircraft attributes and subsystems; and operational experience. Oral and written versions of the case study are delivered. For the Fall 2005 term, the class focuses on a systems engineering analysis of the Space Shuttle. It offers study of both design and operations of the shuttle, with frequent lectures by outside experts. Students choose specific s

Subjects

16.885 | 16.885 | ESD.35 | ESD.35 | aircraft systems | aircraft systems | aircraft systems engineering | aircraft systems engineering | lifecycle | lifecycle | cost estimation | cost estimation | weight estimation | weight estimation | aircraft performance | aircraft performance | aircraft safety | aircraft safety | aircraft reliability | aircraft reliability | subsystems | subsystems | risk analysis | risk analysis | risk management | risk management | system realization | system realization | retrospective analysis | retrospective analysis | key design drivers | key design drivers | design drivers | design drivers | design decisions | design decisions | aircraft attributes | aircraft attributes | operational experience | operational experience | case study | case study | case studies | case studies | air transportation system | air transportation system | air defense system | air defense system | systems engineering | systems engineering | interface management | interface management | interface verification | interface verification | interface validation | interface validation | subsystem architecture | subsystem architecture | performance issues | performance issues | design closure | design closure | complex systems | complex systems | space shuttle | space shuttle | space systems | space systems | NASA | NASA | sound barrier | sound barrier | ascent | ascent | aeronautics | aeronautics | liftoff | liftoff | takeoff | takeoff

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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16.333 Aircraft Stability and Control (MIT) 16.333 Aircraft Stability and Control (MIT)

Description

This class includes a brief review of applied aerodynamics and modern approaches in aircraft stability and control. Topics covered include static stability and trim; stability derivatives and characteristic longitudinal and lateral-directional motions; and physical effects of the wing, fuselage, and tail on aircraft motion. Control methods and systems are discussed, with emphasis on flight vehicle stabilization by classical and modern control techniques; time and frequency domain analysis of control system performance; and human-pilot models and pilot-in-the-loop controls with applications. Other topics covered include V/STOL stability, dynamics, and control during transition from hover to forward flight; parameter sensitivity; and handling quality analysis of aircraft through variable fli This class includes a brief review of applied aerodynamics and modern approaches in aircraft stability and control. Topics covered include static stability and trim; stability derivatives and characteristic longitudinal and lateral-directional motions; and physical effects of the wing, fuselage, and tail on aircraft motion. Control methods and systems are discussed, with emphasis on flight vehicle stabilization by classical and modern control techniques; time and frequency domain analysis of control system performance; and human-pilot models and pilot-in-the-loop controls with applications. Other topics covered include V/STOL stability, dynamics, and control during transition from hover to forward flight; parameter sensitivity; and handling quality analysis of aircraft through variable fli

Subjects

aircraft static stability | aircraft static stability | static equilibrium | static equilibrium | aircraft dynamics | aircraft dynamics | aircraft longitudinal modes | aircraft longitudinal modes | aircraft lateral modes | aircraft lateral modes | aircraft control | aircraft control | classical control | classical control | state space control | state space control

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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AL79-098 Beech B17L cn 4 NC12584 Copenhagen 3Aug34

Description

Subjects

airplane | aircraft | aviation | navy | jacobs | r755 | beechcraft | beech | biplane | l4 | cn4 | staggerwing | beechcraftstaggerwing | beechcraft17 | beechstaggerwing | beech17 | beechcraftmodel17staggerwing | harrywhite | beechaircraft | b17l | beechmodel17staggerwing | beechmodel17 | beechcraftb17l | jacobsr755 | beeechaircraftcompany | beechcraftmodel17 | beechb17lstaggerwing | b17lstaggerwing | jacobsaircraftenginecompany | jacobsl4 | nc12584 | beechcraftmodel17lstaggerwing | beechcraftmodel17l | beechcraft17l | beechmodel17lstaggerwing | beechmodel17l | beech17lstaggerwing | beech17l | beechcraftb17lstaggerwing | jacobsr755d | r755d

License

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AL79-108 Beech B17L cn 4 NC12584 over Arizona 17Jan35

Description

Subjects

airplane | aircraft | aviation | navy | jacobs | r755 | beechcraft | beech | biplane | l4 | cn4 | staggerwing | beechcraftstaggerwing | beechcraft17 | beechstaggerwing | beech17 | beechcraftmodel17staggerwing | harrywhite | beechaircraft | b17l | beechmodel17staggerwing | beechmodel17 | beechcraftb17l | jacobsr755 | beeechaircraftcompany | beechcraftmodel17 | beechb17lstaggerwing | b17lstaggerwing | jacobsaircraftenginecompany | jacobsl4 | nc12584 | beechcraftmodel17lstaggerwing | beechcraftmodel17l | beechcraft17l | beechmodel17lstaggerwing | beechmodel17l | beech17lstaggerwing | beech17l | beechcraftb17lstaggerwing | jacobsr755d | r755d

License

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21A.501J Art, Craft, Science (MIT) 21A.501J Art, Craft, Science (MIT)

Description

This course examines how people learn, practice, and evaluate traditional and contemporary craft techniques. Social science theories of design, embodiment, apprenticeship learning, skill, labor, expertise, and tacit knowledge are used to explore distinctions and connections among art, craft, and science. We will also discuss the commoditization of craft into market goods, collectible art, and tourism industries. Ethnographic and historical case studies include textiles, glassblowing, quilting, cheese making, industrial design, home cooking, factory and laboratory work, CAD-CAM. In-class demonstrations and hands-on craft projects will be included. This course examines how people learn, practice, and evaluate traditional and contemporary craft techniques. Social science theories of design, embodiment, apprenticeship learning, skill, labor, expertise, and tacit knowledge are used to explore distinctions and connections among art, craft, and science. We will also discuss the commoditization of craft into market goods, collectible art, and tourism industries. Ethnographic and historical case studies include textiles, glassblowing, quilting, cheese making, industrial design, home cooking, factory and laboratory work, CAD-CAM. In-class demonstrations and hands-on craft projects will be included.

Subjects

21A.501 | 21A.501 | STS.074 | STS.074 | craft | craft | technique | technique | design | design | apprenticeship | apprenticeship | learning | learning | skill | skill | labor | labor | expertise | expertise | tacit knowledge | tacit knowledge | art | art | science | science | market goods | market goods | tourism industry | tourism industry | textiles | textiles | glassblowing | glassblowing | quilting | quilting | cheesemaking | cheesemaking | industrial design | industrial design | home cooking | home cooking | technology | technology | artisan | artisan | technician | technician | machine | machine | knitting | knitting | glass | glass | modernism | modernism | tools | tools | embodied practice | embodied practice | value | value | global economy | global economy | design politics | design politics | craft politics | craft politics | collecting | collecting | display | display | authenticity | authenticity | craftivism | craftivism

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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16.885J Aircraft Systems Engineering (MIT)

Description

Aircraft are complex products comprised of many subsystems which must meet demanding customer and operational lifecycle value requirements. This course adopts a holistic view of the aircraft as a system, covering: basic systems engineering; cost and weight estimation; basic aircraft performance; safety and reliability; lifecycle topics; aircraft subsystems; risk analysis and management; and system realization. Small student teams "retrospectively analyze" an existing aircraft covering: key design drivers and decisions; aircraft attributes and subsystems; and operational experience. Finally, the student teams deliver oral and written versions of the case study.

Subjects

aircraft systems | aircraft systems engineering | lifecycle | cost estimation | weight estimation | aircraft performance | aircraft safety | aircraft reliability | subsystems; risk analysis | risk management | system realization | retrospective analysis | key design drivers | design drivers | design decisions | aircraft attributes | operational experience | case study | case studies | air transportation systems | air defense system | systems engineering | interface management | interface verification | subsystem architecture | performance issures | design closure | complex systems | 16.885 | ESD.35

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

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16.885J Aircraft Systems Engineering (MIT)

Description

Aircraft are complex products comprised of many subsystems which must meet demanding customer and operational lifecycle value requirements. This course adopts a holistic view of the aircraft as a system, covering: basic systems engineering; cost and weight estimation; basic aircraft performance; safety and reliability; lifecycle topics; aircraft subsystems; risk analysis and management; and system realization. Small student teams "retrospectively analyze" an existing aircraft covering: key design drivers and decisions; aircraft attributes and subsystems; and operational experience. Finally, the student teams deliver oral and written versions of the case study.

Subjects

aircraft systems | aircraft systems engineering | lifecycle | cost estimation | weight estimation | aircraft performance | aircraft safety | aircraft reliability | subsystems; risk analysis | risk management | system realization | retrospective analysis | key design drivers | design drivers | design decisions | aircraft attributes | operational experience | case study | case studies | air transportation systems | air defense system | systems engineering | interface management | interface verification | subsystem architecture | performance issures | design closure | complex systems | 16.885 | ESD.35

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

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16.885J Aircraft Systems Engineering (MIT)

Description

16.885J offers a holistic view of the aircraft as a system, covering: basic systems engineering; cost and weight estimation; basic aircraft performance; safety and reliability; lifecycle topics; aircraft subsystems; risk analysis and management; and system realization. Small student teams retrospectively analyze an existing aircraft covering: key design drivers and decisions; aircraft attributes and subsystems; and operational experience. Oral and written versions of the case study are delivered. For the Fall 2005 term, the class focuses on a systems engineering analysis of the Space Shuttle. It offers study of both design and operations of the shuttle, with frequent lectures by outside experts. Students choose specific shuttle systems for detailed analysis and develop new subsystem design

Subjects

16.885 | ESD.35 | aircraft systems | aircraft systems engineering | lifecycle | cost estimation | weight estimation | aircraft performance | aircraft safety | aircraft reliability | subsystems | risk analysis | risk management | system realization | retrospective analysis | key design drivers | design drivers | design decisions | aircraft attributes | operational experience | case study | case studies | air transportation system | air defense system | systems engineering | interface management | interface verification | interface validation | subsystem architecture | performance issues | design closure | complex systems | space shuttle | space systems | NASA | sound barrier | ascent | aeronautics | liftoff | takeoff

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

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6.370 Robocraft Programming Competition (MIT) 6.370 Robocraft Programming Competition (MIT)

Description

The 6.370 Robocraft programming competition is a unique challenge that combines battle strategy and software engineering. In short, the objective is to write the best player program for the computer game Robocraft. The 6.370 Robocraft programming competition is a unique challenge that combines battle strategy and software engineering. In short, the objective is to write the best player program for the computer game Robocraft.

Subjects

Robocraft programming competition | Robocraft programming competition | battle strategy | battle strategy | software engineering | software engineering | best player program | best player program | best program | best program | computer game Robocraft | computer game Robocraft

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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Naval Aircraft Factory PT-1 Naval Aircraft Factory PT-1

Description

Subjects

airplane | airplane | aircraft | aircraft | aviation | aviation | pt | pt | usnavy | usnavy | usn | usn | naf | naf | biplane | biplane | militaryaviation | militaryaviation | pt1 | pt1 | navalaviation | navalaviation | unitedstatesnavy | unitedstatesnavy | navalaircraftfactory | navalaircraftfactory | a6044 | a6044 | liberty12 | liberty12 | libertyengine | libertyengine | libertyl12 | libertyl12 | navalaircraftfactorypt | navalaircraftfactorypt | navalaircraftfactorypt1 | navalaircraftfactorypt1 | nafpt | nafpt | nafpt1 | nafpt1 | bunoa6044 | bunoa6044

License

No known copyright restrictions

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Douglas DC-3 United AL publicity photo Douglas DC-3 United AL publicity photo

Description

Subjects

airplane | airplane | aircraft | aircraft | aviation | aviation | united | united | aeroplane | aeroplane | dac | dac | douglas | douglas | airlines | airlines | eastern | eastern | dc3 | dc3 | ual | ual | airliners | airliners | unitedairlines | unitedairlines | 1911 | 1911 | eal | eal | easternairlines | easternairlines | douglasdc3 | douglasdc3 | wrightcyclone | wrightcyclone | r1820 | r1820 | douglasaircraft | douglasaircraft | douglasdc3a | douglasdc3a | dc3a | dc3a | douglasaircraftcompany | douglasaircraftcompany | cn1911 | cn1911 | wrightcycloner1820 | wrightcycloner1820 | wrightr1820 | wrightr1820 | wrightr1820cyclone | wrightr1820cyclone | eiayo | eiayo | dc3a197 | dc3a197 | n655gp | n655gp | n333h | n333h | douglasdc3a197 | douglasdc3a197 | nc16071 | nc16071 | mainlinerlosangeles | mainlinerlosangeles | aircraftenterprises | aircraftenterprises | n65556 | n65556 | n255jb | n255jb | n8695e | n8695e | enhartmanufacturingcompany | enhartmanufacturingcompany | enhartmanufacturing | enhartmanufacturing | commanderaircraftsales | commanderaircraftsales

License

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16.333 Aircraft Stability and Control (MIT)

Description

This class includes a brief review of applied aerodynamics and modern approaches in aircraft stability and control. Topics covered include static stability and trim; stability derivatives and characteristic longitudinal and lateral-directional motions; and physical effects of the wing, fuselage, and tail on aircraft motion. Control methods and systems are discussed, with emphasis on flight vehicle stabilization by classical and modern control techniques; time and frequency domain analysis of control system performance; and human-pilot models and pilot-in-the-loop controls with applications. Other topics covered include V/STOL stability, dynamics, and control during transition from hover to forward flight; parameter sensitivity; and handling quality analysis of aircraft through variable fli

Subjects

aircraft static stability | static equilibrium | aircraft dynamics | aircraft longitudinal modes | aircraft lateral modes | aircraft control | classical control | state space control

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

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2.23 Hydrofoils and Propellers (13.04) (MIT) 2.23 Hydrofoils and Propellers (13.04) (MIT)

Description

This course deals with theory and design of hydrofoil sections; lifting and thickness problems for sub-cavitating sections, unsteady flow problems. It focuses on computer-aided design of low drag, cavitation free sections. The course also covers lifting line and lifting surface theory with applications to hydrofoil craft, rudder, and control surface design. Topics include propeller lifting line and lifting surface theory; computer-aided design of wake adapted propellers, unsteady propeller thrust and torque. The course is also an introduction to subjects like flow about axially symmetric bodies and low-aspect ratio lifting surfaces, and hydrodynamic performance and design of waterjets. We will also do an analysis of performance and design of wind turbine rotors in steady and stochastic win This course deals with theory and design of hydrofoil sections; lifting and thickness problems for sub-cavitating sections, unsteady flow problems. It focuses on computer-aided design of low drag, cavitation free sections. The course also covers lifting line and lifting surface theory with applications to hydrofoil craft, rudder, and control surface design. Topics include propeller lifting line and lifting surface theory; computer-aided design of wake adapted propellers, unsteady propeller thrust and torque. The course is also an introduction to subjects like flow about axially symmetric bodies and low-aspect ratio lifting surfaces, and hydrodynamic performance and design of waterjets. We will also do an analysis of performance and design of wind turbine rotors in steady and stochastic win

Subjects

Theory and design of hydrofoil sections | Theory and design of hydrofoil sections | lifting and thickness problems | lifting and thickness problems | sub-cavitating sections | sub-cavitating sections | unsteady flow problems | unsteady flow problems | computer-aided design | computer-aided design | low drag | low drag | cavitation free sections | cavitation free sections | Lifting line and lifting surface theory | Lifting line and lifting surface theory | hydrofoil craft | hydrofoil craft | rudder | rudder | and control surface design | and control surface design | propeller lifting line | propeller lifting line | lifting surface theory | lifting surface theory | wake adapted propellers | wake adapted propellers | unsteady propeller thrust and torque | unsteady propeller thrust and torque | axially symmetric bodies | axially symmetric bodies | low-aspect ratio lifting surfaces | low-aspect ratio lifting surfaces | Hydrodynamic performance | Hydrodynamic performance | design of waterjets | design of waterjets | wind turbine rotors in steady and stochastic wind | wind turbine rotors in steady and stochastic wind | hydrofoil craft | rudder | and control surface design | hydrofoil craft | rudder | and control surface design | 9. low drag | cavitation free sections | 9. low drag | cavitation free sections | 5. hydrofoil craft | rudder | and control surface design | 5. hydrofoil craft | rudder | and control surface design | low drag | cavitation free sections | low drag | cavitation free sections

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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13.04 Hydrofoils and Propellers (MIT) 13.04 Hydrofoils and Propellers (MIT)

Description

This course deals with theory and design of hydrofoil sections; lifting and thickness problems for sub-cavitating sections, unsteady flow problems. It focuses on computer-aided design of low drag, cavitation free sections. The course also covers lifting line and lifting surface theory with applications to hydrofoil craft, rudder, and control surface design. Topics include propeller lifting line and lifting surface theory; computer-aided design of wake adapted propellers, unsteady propeller thrust and torque. The course is also an introduction to subjects like flow about axially symmetric bodies and low-aspect ratio lifting surfaces, and hydrodynamic performance and design of waterjets. We will also do an analysis of performance and design of wind turbine rotors in steady and stochastic win This course deals with theory and design of hydrofoil sections; lifting and thickness problems for sub-cavitating sections, unsteady flow problems. It focuses on computer-aided design of low drag, cavitation free sections. The course also covers lifting line and lifting surface theory with applications to hydrofoil craft, rudder, and control surface design. Topics include propeller lifting line and lifting surface theory; computer-aided design of wake adapted propellers, unsteady propeller thrust and torque. The course is also an introduction to subjects like flow about axially symmetric bodies and low-aspect ratio lifting surfaces, and hydrodynamic performance and design of waterjets. We will also do an analysis of performance and design of wind turbine rotors in steady and stochastic win

Subjects

Theory and design of hydrofoil sections | Theory and design of hydrofoil sections | lifting and thickness problems | lifting and thickness problems | sub-cavitating sections | sub-cavitating sections | unsteady flow problems | unsteady flow problems | computer-aided design | computer-aided design | low drag | low drag | cavitation free sections | cavitation free sections | Lifting line and lifting surface theory | Lifting line and lifting surface theory | hydrofoil craft | hydrofoil craft | rudder | rudder | and control surface design | and control surface design | propeller lifting line | propeller lifting line | lifting surface theory | lifting surface theory | wake adapted propellers | wake adapted propellers | unsteady propeller thrust and torque | unsteady propeller thrust and torque | axially symmetric bodies | axially symmetric bodies | low-aspect ratio lifting surfaces | low-aspect ratio lifting surfaces | Hydrodynamic performance | Hydrodynamic performance | design of waterjets | design of waterjets | wind turbine rotors in steady and stochastic wind | wind turbine rotors in steady and stochastic wind | hydrofoil craft | rudder | and control surface design | hydrofoil craft | rudder | and control surface design | 9. low drag | cavitation free sections | 9. low drag | cavitation free sections | 5. hydrofoil craft | rudder | and control surface design | 5. hydrofoil craft | rudder | and control surface design | low drag | cavitation free sections | low drag | cavitation free sections | 2.23 | 2.23

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Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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16.851 Satellite Engineering (MIT) 16.851 Satellite Engineering (MIT)

Description

Satellite Engineering introduces students to subsystem design in engineering spacecraft. The course presents characteristic subsystems, such as power, structure, communication and control, and analyzes the engineering trades necessary to integrate subsystems successfully into a satellite. Discussions of spacecraft operating environment and orbital mechanics help students to understand the functional requirements and key design parameters for satellite systems. Satellite Engineering introduces students to subsystem design in engineering spacecraft. The course presents characteristic subsystems, such as power, structure, communication and control, and analyzes the engineering trades necessary to integrate subsystems successfully into a satellite. Discussions of spacecraft operating environment and orbital mechanics help students to understand the functional requirements and key design parameters for satellite systems.

Subjects

satellites | satellites | satellite engineering | satellite engineering | subsystems | subsystems | satellite design | satellite design | launch systems | launch systems | space environment | space environment | payloads | payloads | orbital mechanics | orbital mechanics | spacecraft mission design | spacecraft mission design | spacecraft | spacecraft | attitude determination | attitude determination | attitude control | attitude control | propulsion | propulsion | thermal systems | thermal systems | ground systems | ground systems | optics | optics | autonomy | autonomy | integrated concurrent engineering | integrated concurrent engineering | power subsystems | power subsystems | GPS | GPS | navigation | navigation | avionics | avionics | ISS operations | ISS operations | satellite tool kit | satellite tool kit | STK | STK

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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16.61 Aerospace Dynamics (MIT) 16.61 Aerospace Dynamics (MIT)

Description

This undergraduate course builds upon the dynamics content of Unified Engineering, a sophomore course taught in the Department of Aeronautics and Astronautics at MIT. Vector kinematics are applied to translation and rotation of rigid bodies. Newtonian and Lagrangian methods are used to formulate and solve equations of motion. Additional numerical methods are presented for solving rigid body dynamics problems. Examples and problems describe applications to aircraft flight dynamics and spacecraft attitude dynamics. This undergraduate course builds upon the dynamics content of Unified Engineering, a sophomore course taught in the Department of Aeronautics and Astronautics at MIT. Vector kinematics are applied to translation and rotation of rigid bodies. Newtonian and Lagrangian methods are used to formulate and solve equations of motion. Additional numerical methods are presented for solving rigid body dynamics problems. Examples and problems describe applications to aircraft flight dynamics and spacecraft attitude dynamics.

Subjects

aerospace dynamics | aerospace dynamics | Newtonian dynamics | Newtonian dynamics | 3D motion | 3D motion | gyroscopic | gyroscopic | rotational | rotational | dynamics | dynamics | coordinate transformations | coordinate transformations | Lagrangian | Lagrangian | motion | motion | aircraft | aircraft | flight | flight | stability | stability | spacecraft | spacecraft

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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SDASM Aircraft Image SDASM Aircraft Image

Description

Subjects

aviation | aviation | aircraft | aircraft | airplane | airplane | militaryaviation | militaryaviation | douglasaircraftcompany | douglasaircraftcompany | douglasaircraft | douglasaircraft | dac | dac | douglas | douglas | douglasa4skyhawk | douglasa4skyhawk | douglasa4 | douglasa4 | a4skyhawk | a4skyhawk | douglasskyhawk | douglasskyhawk | a4 | a4 | skyhawk | skyhawk | heinemannshotrod | heinemannshotrod | thescooter | thescooter | scooter | scooter

License

No known copyright restrictions

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21A.501J Art, Craft, Science (MIT)

Description

This course examines how people learn, practice, and evaluate traditional and contemporary craft techniques. Social science theories of design, embodiment, apprenticeship learning, skill, labor, expertise, and tacit knowledge are used to explore distinctions and connections among art, craft, and science. We will also discuss the commoditization of craft into market goods, collectible art, and tourism industries. Ethnographic and historical case studies include textiles, glassblowing, quilting, cheese making, industrial design, home cooking, factory and laboratory work, CAD-CAM. In-class demonstrations and hands-on craft projects will be included.

Subjects

21A.501 | STS.074 | craft | technique | design | apprenticeship | learning | skill | labor | expertise | tacit knowledge | art | science | market goods | tourism industry | textiles | glassblowing | quilting | cheesemaking | industrial design | home cooking | technology | artisan | technician | machine | knitting | glass | modernism | tools | embodied practice | value | global economy | design politics | craft politics | collecting | display | authenticity | craftivism

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

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21M.606 Introduction to Stagecraft (MIT) 21M.606 Introduction to Stagecraft (MIT)

Description

Offered annually in the spring term, Introduction to Stagecraft is a hands-on course that gets students working with the tools and techniques of theatrical production in a practical way. It is not a design course but one devoted to artisanship. Among the many remarkable final projects that have been proposed and presented at the end of the course have been a Renaissance hourglass blown in the MIT glass shop and set into a frame turned on our set shop lathe; a four harness loom built by a student who then wove cloth on it; a number of chain mail tunics and coifs; a wide variety of costume and furniture pieces and electrified period lighting fixtures. Offered annually in the spring term, Introduction to Stagecraft is a hands-on course that gets students working with the tools and techniques of theatrical production in a practical way. It is not a design course but one devoted to artisanship. Among the many remarkable final projects that have been proposed and presented at the end of the course have been a Renaissance hourglass blown in the MIT glass shop and set into a frame turned on our set shop lathe; a four harness loom built by a student who then wove cloth on it; a number of chain mail tunics and coifs; a wide variety of costume and furniture pieces and electrified period lighting fixtures.

Subjects

stagecraft | stagecraft | shop skills | shop skills | shop machines | shop machines | basic handwork | basic handwork | tools | tools | scenery | scenery | costume | costume | set constuction | set constuction | props | props | stage management | stage management | lighting | lighting | make-up | make-up | scene painting | scene painting

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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Mary Wollstonecraft Three notes to William Godwin

Description

Part of the Shelley's Ghost Exhibition. Even after their marriage Godwin and Wollstonecraft preferred to live independently during the day, and communicate by correspondence. They regularly exchanged anything from long, carefully composed letters to short notes dashed off on scraps of paper. Shown here are Mary's last three notes to Godwin, written while she was waiting impatiently for the delivery of her child ('the animal'), and seeking reassurance from the midwife, Mrs Blenkinsop. In her final note, Mary Wollstonecraft half-quotes her mother's last words; 'Have a little patience, and all will be over'. Her own daughter, Mary Wollstonecraft Godwin (later Mary Shelley), was born a few hours afterwards. It was a straightforward birth, but Mary Wollstonecraft soon contracted an infec Wales; http://creativecommons.org/licenses/by-nc-sa/2.0/uk/

Subjects

vindication of rights of women | bodleian | mary wollstonecraft | #greatwriters | s ghost | feminism | shelley | godwin | s ghost | feminism | shelley | godwin | 2010-10-18

License

http://creativecommons.org/licenses/by-nc-sa/2.0/uk/

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1.206J Airline Schedule Planning (MIT) 1.206J Airline Schedule Planning (MIT)

Description

Explores a variety of models and optimization techniques for the solution of airline schedule planning and operations problems. Schedule design, fleet assignment, aircraft maintenance routing, crew scheduling, passenger mix, and other topics are covered. Recent models and algorithms addressing issues of model integration, robustness, and operations recovery are introduced. Modeling and solution techniques designed specifically for large-scale problems, and state-of-the-art applications of these techniques to airline problems are detailed. Explores a variety of models and optimization techniques for the solution of airline schedule planning and operations problems. Schedule design, fleet assignment, aircraft maintenance routing, crew scheduling, passenger mix, and other topics are covered. Recent models and algorithms addressing issues of model integration, robustness, and operations recovery are introduced. Modeling and solution techniques designed specifically for large-scale problems, and state-of-the-art applications of these techniques to airline problems are detailed.

Subjects

Airline Schedule Planning | Airline Schedule Planning | Optimization | Optimization | Operations | Operations | Fleet Assignment | Fleet Assignment | Aircraft Maintenance Routing | Aircraft Maintenance Routing | Crew Scheduling | Crew Scheduling | Passenger Mix | Passenger Mix | Model Integration | Model Integration | Robustness | Robustness | Operations Recovery | Operations Recovery | models | models | optimization techniques | optimization techniques | airline schedule planning problems | airline schedule planning problems | schedule design | schedule design | fleet assignment | fleet assignment | aircraft maintenance routing | aircraft maintenance routing | crew scheduling | crew scheduling | robust planning | robust planning | passenger mix | passenger mix | integrated schedule planning | integrated schedule planning | solution techniques | solution techniques | decomposition | decomposition | Lagrangian relaxation | Lagrangian relaxation | column generation | column generation | partitioning | partitioning | applications | applications | algorithms | algorithms | model integration | model integration | robustness | robustness | operations recovery | operations recovery | airline schedule planning | airline schedule planning | 16.77 | 16.77 | ESD.215 | ESD.215

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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21A.211 Magic, Witchcraft, and the Spirit World (MIT) 21A.211 Magic, Witchcraft, and the Spirit World (MIT)

Description

Spiritual, magical, and "occult" aspects of human behavior in anthropological and historical perspective: magic, ritual curing, trance, spirit possession, sorcery, and accusations of witchcraft. Material drawn from traditional nonwestern societies, medieval and early modern Europe, and colonial and contemporary North America. Spiritual, magical, and "occult" aspects of human behavior in anthropological and historical perspective: magic, ritual curing, trance, spirit possession, sorcery, and accusations of witchcraft. Material drawn from traditional nonwestern societies, medieval and early modern Europe, and colonial and contemporary North America.

Subjects

anthropology | anthropology | sorcery | sorcery | spirit possession | spirit possession | ritual curing | ritual curing | magic | magic | witchcraft | witchcraft

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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21M.606 Introduction to Stagecraft (MIT) 21M.606 Introduction to Stagecraft (MIT)

Description

Offered in the spring and fall terms, Introduction to Stagecraft is a hands-on course that gets students working with the tools and techniques of theatrical production in a practical way. It is not a design course but one devoted to artisanship. Among the many remarkable final projects that have been proposed and presented at the end of the course have been a Renaissance hourglass blown in the MIT glass shop and set into a frame turned on our set shop lathe; a four harness loom built by a student who then wove cloth on it; a number of chain mail tunics and coifs; a wide variety of costume and furniture pieces and electrified period lighting fixtures. Offered in the spring and fall terms, Introduction to Stagecraft is a hands-on course that gets students working with the tools and techniques of theatrical production in a practical way. It is not a design course but one devoted to artisanship. Among the many remarkable final projects that have been proposed and presented at the end of the course have been a Renaissance hourglass blown in the MIT glass shop and set into a frame turned on our set shop lathe; a four harness loom built by a student who then wove cloth on it; a number of chain mail tunics and coifs; a wide variety of costume and furniture pieces and electrified period lighting fixtures.

Subjects

stagecraft | stagecraft | shop skills | shop skills | shop machines | shop machines | basic handwork | basic handwork | tools | tools | scenery | scenery | costume | costume | set constuction | set constuction | props | props | stage management | stage management | lighting | lighting | scene painting | scene painting | student project | student project | safety | safety | knots | knots

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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