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8.01 Physics I (MIT) 8.01 Physics I (MIT)

Description

Physics I is a first-year physics course which introduces students to classical mechanics. Topics include: space and time; straight-line kinematics; motion in a plane; forces and equilibrium; experimental basis of Newton's laws; particle dynamics; universal gravitation; collisions and conservation laws; work and potential energy; vibrational motion; conservative forces; inertial forces and non-inertial frames; central force motions; rigid bodies and rotational dynamics. Physics I is a first-year physics course which introduces students to classical mechanics. Topics include: space and time; straight-line kinematics; motion in a plane; forces and equilibrium; experimental basis of Newton's laws; particle dynamics; universal gravitation; collisions and conservation laws; work and potential energy; vibrational motion; conservative forces; inertial forces and non-inertial frames; central force motions; rigid bodies and rotational dynamics.

Subjects

classical mechanics | classical mechanics | Space and time | Space and time | straight-line kinematics | straight-line kinematics | motion in a plane | motion in a plane | experimental basis of Newton's laws | experimental basis of Newton's laws | particle dynamics | particle dynamics | universal gravitation | universal gravitation | collisions and conservation laws | collisions and conservation laws | work and potential energy | work and potential energy | vibrational motion | vibrational motion | conservative forces | conservative forces | central force motions | central force motions | inertial forces and non-inertial frames | inertial forces and non-inertial frames | rigid bodies and rotational dynamics | rigid bodies and rotational dynamics | forces and equilibrium | forces and equilibrium | space | space | time | time | space-time | space-time | planar motion | planar motion | forces | forces | equilibrium | equilibrium | Newton?s laws | Newton?s laws | collisions | collisions | conservation laws | conservation laws | work | work | potential energy | potential energy | inertial forces | inertial forces | non-inertial forces | non-inertial forces | rigid bodies | rigid bodies | rotational dynamics | rotational dynamics

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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16.07 Dynamics (MIT) 16.07 Dynamics (MIT)

Description

Dynamics starts with fundamentals of Newtonian mechanics. Further topics include kinematics, particle dynamics, motion relative to accelerated reference frames, work and energy, impulse and momentum, systems of particles and rigid body dynamics. Applications to aerospace engineering are discussed, including introductory topics in orbital mechanics, flight dynamics, inertial navigation and attitude dynamics. Dynamics starts with fundamentals of Newtonian mechanics. Further topics include kinematics, particle dynamics, motion relative to accelerated reference frames, work and energy, impulse and momentum, systems of particles and rigid body dynamics. Applications to aerospace engineering are discussed, including introductory topics in orbital mechanics, flight dynamics, inertial navigation and attitude dynamics.

Subjects

Curvilinear motion | Curvilinear motion | carteian coordinates | carteian coordinates | dynamics | dynamics | equations of motion | equations of motion | intrinsic coordinates | intrinsic coordinates | coordinate systems | coordinate systems | work | work | energy | energy | conservative forces | conservative forces | potential energy | potential energy | linear impulse | linear impulse | mommentum | mommentum | angular impulse | angular impulse | relative motion | relative motion | rotating axes | rotating axes | translating axes | translating axes | Newton's second law | Newton's second law | inertial forces | inertial forces | accelerometers | accelerometers | Newtonian relativity | Newtonian relativity | gravitational attraction | gravitational attraction | 2D rigid body kinematics | 2D rigid body kinematics | conservation laws for systems of particles | conservation laws for systems of particles | 2D rigid body dynamics | 2D rigid body dynamics | pendulums | pendulums | 3D rigid body kinematics | 3D rigid body kinematics | 3d rigid body dynamics | 3d rigid body dynamics | inertia tensor | inertia tensor | gyroscopic motion | gyroscopic motion | torque-free motion | torque-free motion | spin stabilization | spin stabilization | variable mass systems | variable mass systems | rocket equation | rocket equation | central foce motion | central foce motion | Keppler's laws | Keppler's laws | orbits | orbits | orbit transfer | orbit transfer | vibration | vibration | spring mass systems | spring mass systems | forced vibration | forced vibration | isolation | isolation | coupled oscillators | coupled oscillators | normal modes | normal modes | wave propagation | wave propagation | cartesian coordinates | cartesian coordinates | momentum | momentum | central force motion | central force motion

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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8.01T Physics I (MIT) 8.01T Physics I (MIT)

Description

This freshman-level course is an introduction to classical mechanics. The subject is taught using the TEAL (Technology Enabled Active Learning) format which features small group interaction via table-top experiments utilizing laptops for data acquisition and problem solving workshops. Acknowledgements The TEAL project is supported by The Alex and Brit d'Arbeloff Fund for Excellence in MIT Education, MIT iCampus, the Davis Educational Foundation, the National Science Foundation, the Class of 1960 Endowment for Innovation in Education, the Class of 1951 Fund for Excellence in Education, the Class of 1955 Fund for Excellence in Teaching, and the Helena Foundation. This freshman-level course is an introduction to classical mechanics. The subject is taught using the TEAL (Technology Enabled Active Learning) format which features small group interaction via table-top experiments utilizing laptops for data acquisition and problem solving workshops. Acknowledgements The TEAL project is supported by The Alex and Brit d'Arbeloff Fund for Excellence in MIT Education, MIT iCampus, the Davis Educational Foundation, the National Science Foundation, the Class of 1960 Endowment for Innovation in Education, the Class of 1951 Fund for Excellence in Education, the Class of 1955 Fund for Excellence in Teaching, and the Helena Foundation.

Subjects

classical mechanics | classical mechanics | Space and time | Space and time | straight-line kinematics | straight-line kinematics | motion in a plane | motion in a plane | forces and equilibrium | forces and equilibrium | experimental basis of Newton's laws | experimental basis of Newton's laws | particle dynamics | particle dynamics | universal gravitation | universal gravitation | collisions and conservation laws | collisions and conservation laws | work and potential energy | work and potential energy | vibrational motion | vibrational motion | conservative forces | conservative forces | inertial forces and non-inertial frames | inertial forces and non-inertial frames | central force motions | central force motions | rigid bodies | rigid bodies | rotational dynamics | rotational dynamics | rigid bodies and rotational dynamics | rigid bodies and rotational dynamics

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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A Forgotten Catastrophe? A Forgotten Catastrophe? Chasing Lettow-Vorbeck -- A Forgotten Catastrophe? Chasing Lettow-Vorbeck -- A Forgotten Catastrophe?

Description

For those of you who have never read the articles at Cracked.com, I can’t say I would heartily recommend the experience.  While they’re of some value, sometimes, in bringing to popular attention subjects and people that might otherwise languish in … Continue reading → For those of you who have never read the articles at Cracked.com, I can’t say I would heartily recommend the experience.  While they’re of some value, sometimes, in bringing to popular attention subjects and people that might otherwise languish in … Continue reading →

Subjects

Strange Meetings | Strange Meetings | Unconventional Soldiers | Unconventional Soldiers | 356 (Foot forces & warfare) | 356 (Foot forces & warfare) | 358 (Other specialized forces & services) | 358 (Other specialized forces & services) | 900 (History & geography) | 900 (History & geography) | DT (History of Africa) | DT (History of Africa) | UA (Armies: Organization – distribution – military situation) | UA (Armies: Organization – distribution – military situation) | UD (Infantry) | UD (Infantry) | 356 (Foot forces & warfare) | 356 (Foot forces & warfare) | 358 (Other specialized forces & services) | 358 (Other specialized forces & services) | 900 (History & geography) | 900 (History & geography)

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8.01 Physics I (MIT)

Description

Physics I is a first-year physics course which introduces students to classical mechanics. Topics include: space and time; straight-line kinematics; motion in a plane; forces and equilibrium; experimental basis of Newton's laws; particle dynamics; universal gravitation; collisions and conservation laws; work and potential energy; vibrational motion; conservative forces; inertial forces and non-inertial frames; central force motions; rigid bodies and rotational dynamics.

Subjects

classical mechanics | Space and time | straight-line kinematics | motion in a plane | experimental basis of Newton's laws | particle dynamics | universal gravitation | collisions and conservation laws | work and potential energy | vibrational motion | conservative forces | central force motions | inertial forces and non-inertial frames | rigid bodies and rotational dynamics | forces and equilibrium | space | time | space-time | planar motion | forces | equilibrium | Newton?s laws | collisions | conservation laws | work | potential energy | inertial forces | non-inertial forces | rigid bodies | rotational dynamics

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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8.01 Physics I (MIT)

Description

Physics I is a first-year physics course which introduces students to classical mechanics. Topics include: space and time; straight-line kinematics; motion in a plane; forces and equilibrium; experimental basis of Newton's laws; particle dynamics; universal gravitation; collisions and conservation laws; work and potential energy; vibrational motion; conservative forces; inertial forces and non-inertial frames; central force motions; rigid bodies and rotational dynamics.

Subjects

classical mechanics | Space and time | straight-line kinematics | motion in a plane | experimental basis of Newton's laws | particle dynamics | universal gravitation | collisions and conservation laws | work and potential energy | vibrational motion | conservative forces | central force motions | inertial forces and non-inertial frames | rigid bodies and rotational dynamics | forces and equilibrium | space | time | space-time | planar motion | forces | equilibrium | Newton?s laws | collisions | conservation laws | work | potential energy | inertial forces | non-inertial forces | rigid bodies | rotational dynamics

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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8.01 Physics I (MIT)

Description

Physics I is a first-year physics course which introduces students to classical mechanics. Topics include: space and time; straight-line kinematics; motion in a plane; forces and equilibrium; experimental basis of Newton's laws; particle dynamics; universal gravitation; collisions and conservation laws; work and potential energy; vibrational motion; conservative forces; inertial forces and non-inertial frames; central force motions; rigid bodies and rotational dynamics.

Subjects

classical mechanics | Space and time | straight-line kinematics | motion in a plane | experimental basis of Newton's laws | particle dynamics | universal gravitation | collisions and conservation laws | work and potential energy | vibrational motion | conservative forces | central force motions | inertial forces and non-inertial frames | rigid bodies and rotational dynamics | forces and equilibrium | space | time | space-time | planar motion | forces | equilibrium | Newton?s laws | collisions | conservation laws | work | potential energy | inertial forces | non-inertial forces | rigid bodies | rotational dynamics

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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1.364 Advanced Geotechnical Engineering (MIT) 1.364 Advanced Geotechnical Engineering (MIT)

Description

1.364 examines site characterization and geotechnical aspects of the design and construction of foundation systems. Topics include: site investigation (with emphasis on in situ testing), shallow (footings and raftings) and deep (piles and caissons) foundations, excavation support systems, groundwater control, slope stability, soil improvement (compaction, soil reinforcement, etc.), and construction monitoring. This course is a core requirement for the Geotechnical Master of Engineering program at MIT. 1.364 examines site characterization and geotechnical aspects of the design and construction of foundation systems. Topics include: site investigation (with emphasis on in situ testing), shallow (footings and raftings) and deep (piles and caissons) foundations, excavation support systems, groundwater control, slope stability, soil improvement (compaction, soil reinforcement, etc.), and construction monitoring. This course is a core requirement for the Geotechnical Master of Engineering program at MIT.

Subjects

geotechnical engineering | geotechnical engineering | soil | soil | soil mechanics | soil mechanics | foundations | foundations | earth retaining structures | earth retaining structures | site investigation | site investigation | ultimate limit | ultimate limit | serviceability limit | serviceability limit | soil improvement | soil improvement | gravity walls | gravity walls | composite construction | composite construction | reinforced earth | reinforced earth | structural support | structural support | excavations | excavations | bracing | bracing | tieback anchors | tieback anchors | tiebacks | tiebacks | safety factors | safety factors | boreholes | boreholes | soil sampling | soil sampling | stratigraphy | stratigraphy | SPT | SPT | FV | FV | PCPT | PCPT | spread foundation design | spread foundation design | in situ tests | in situ tests | bearing capacity | bearing capacity | strength parameters | strength parameters | allowable settlements | allowable settlements | sand | sand | clay | clay | soil-structure interaction | soil-structure interaction | pile types | pile types | pile selection | pile selection | pile behavior | pile behavior | pile capacity | pile capacity | pile driving | pile driving | pile load tests | pile load tests | slope stability | slope stability | cantilevers | cantilevers | propper walls | propper walls | braced excavations | braced excavations | reinforced soil | reinforced soil | soil nailing | soil nailing | geosynthetic reinforcement | geosynthetic reinforcement

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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8.01L Physics I: Classical Mechanics (MIT) 8.01L Physics I: Classical Mechanics (MIT)

Description

8.01L is an introductory mechanics course, which covers all the topics covered in 8.01T. The class meets throughout the fall, and continues throughout the Independent Activities Period (IAP). 8.01L is an introductory mechanics course, which covers all the topics covered in 8.01T. The class meets throughout the fall, and continues throughout the Independent Activities Period (IAP).

Subjects

Introductory classical mechanics | Introductory classical mechanics | space | space | time | time | straight-line kinematics | straight-line kinematics | motion in a plane | motion in a plane | forces | forces | static equilibrium | static equilibrium | particle dynamics | particle dynamics | conservation of momentum | conservation of momentum | relative inertial frames | relative inertial frames | non-inertial force | non-inertial force | work | work | potential energy | potential energy | conservation of energy | conservation of energy | ideal gas | ideal gas | rigid bodies | rigid bodies | rotational dynamics | rotational dynamics | vibrational motion | vibrational motion | conservation of angular momentum | conservation of angular momentum | central force motions | central force motions | fluid mechanics | fluid mechanics | Technology-Enabled Active Learning | Technology-Enabled Active Learning

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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9.98 Neuropharmacology (MIT) 9.98 Neuropharmacology (MIT)

Description

The neuropharmacology course will discuss the drug-induced changes in functioning of the nervous system. The specific focus of this course will be to provide a description of the cellular and molecular actions of drugs on synaptic transmission. This course will also refer to specific diseases of the nervous system and their treatment in addition to giving an overview of the techniques used for the study of neuropharmacology. This course is offered during the Independent Activities Period (IAP), which is a special 4-week term at MIT that runs from the first week of January until the end of the month. The neuropharmacology course will discuss the drug-induced changes in functioning of the nervous system. The specific focus of this course will be to provide a description of the cellular and molecular actions of drugs on synaptic transmission. This course will also refer to specific diseases of the nervous system and their treatment in addition to giving an overview of the techniques used for the study of neuropharmacology. This course is offered during the Independent Activities Period (IAP), which is a special 4-week term at MIT that runs from the first week of January until the end of the month.

Subjects

antidepressant | antidepressant | psychopharmacology | psychopharmacology | neurology | neurology | neuroscience | neuroscience | pharmacology | pharmacology | synapse | synapse | seratonin | seratonin | drug | drug | disposition | disposition | tolerance | tolerance | physical dependence model | physical dependence model | depot binding | depot binding | classic antipsychotic drugs | classic antipsychotic drugs | experimental substance use | experimental substance use | anabolic steroid dependence | anabolic steroid dependence | biobehavioral effects | biobehavioral effects | positive reinforcement model | positive reinforcement model | phenethylamine hallucinogens | phenethylamine hallucinogens | discriminative stimulus effects | discriminative stimulus effects | nicotine reinforcement | nicotine reinforcement | somatodendritic autoreceptors | somatodendritic autoreceptors | selected brain areas | selected brain areas | many psychoactive drugs | many psychoactive drugs | terminal autoreceptors | terminal autoreceptors | abstinence signs | abstinence signs | motor side effects | motor side effects | drug reinforcement | drug reinforcement | other psychostimulants | other psychostimulants | postsynaptic cell | postsynaptic cell | nicotine tolerance | nicotine tolerance | abstinent smokers | abstinent smokers | behavioral tolerance | behavioral tolerance | chronic drug use | chronic drug use | susceptibility models | susceptibility models

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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RES.12-001 Topics in Fluid Dynamics (MIT) RES.12-001 Topics in Fluid Dynamics (MIT)

Description

This collection of three essays was developed from the author's experience teaching the course Fluid Dynamics of the Atmosphere and Ocean, offered to graduate students entering the MIT/WHOI Joint Program in Oceanography. The essays are: 1. Dimensional Analysis of Models and Data Sets: Similarity Solutions and Scaling Analysis,2. A Coriolis Tutorial, and3. Lagrangian and Eulerian Representations of Fluid Flow: Kinematics and the Equations of Motion The goal of this resource is to help each student master the concepts and mathematical tools that make up the foundation of classical and geophysical fluid dynamics. These essays treat these topics in considerably greater depth than a comprehensive fluids textbook can afford, and they are accompanied by data files (MATLAB® and Fortan) that a This collection of three essays was developed from the author's experience teaching the course Fluid Dynamics of the Atmosphere and Ocean, offered to graduate students entering the MIT/WHOI Joint Program in Oceanography. The essays are: 1. Dimensional Analysis of Models and Data Sets: Similarity Solutions and Scaling Analysis,2. A Coriolis Tutorial, and3. Lagrangian and Eulerian Representations of Fluid Flow: Kinematics and the Equations of Motion The goal of this resource is to help each student master the concepts and mathematical tools that make up the foundation of classical and geophysical fluid dynamics. These essays treat these topics in considerably greater depth than a comprehensive fluids textbook can afford, and they are accompanied by data files (MATLAB® and Fortan) that a

Subjects

simple pendulum | simple pendulum | inviscid pendulum | inviscid pendulum | viscous pendulum | viscous pendulum | Reynolds number | Reynolds number | decay rate | decay rate | nonlinear projectile problem | nonlinear projectile problem | Coriolis force | Coriolis force | inertial forces | inertial forces | centrifugal force | centrifugal force | energy budget | energy budget | Lagrangian velocity | Lagrangian velocity | Eulerian velocity | Eulerian velocity | Eulerian equations | Eulerian equations

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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citizen soldiers: recruiting technical experts on the Western Front citizen soldiers: recruiting technical experts on the Western Front The 'other' citizen soldiers: recruiting technical experts on the Western Front The 'other' citizen soldiers: recruiting technical experts on the Western Front

Description

The term ‘citizen soldier’ evokes a particularly powerful image in Britain. The poignant histories of the ‘Pals’ Battalions’, raised utilizing the attraction of geographical and occupational connections, have contributed greatly to the lasting public impression of the conflict. Names such … Continue reading → The term ‘citizen soldier’ evokes a particularly powerful image in Britain. The poignant histories of the ‘Pals’ Battalions’, raised utilizing the attraction of geographical and occupational connections, have contributed greatly to the lasting public impression of the conflict. Names such … Continue reading →

Subjects

Machine | Machine | Unconventional Soldiers | Unconventional Soldiers | 355 (Military science) | 355 (Military science) | 358 (Other specialized forces & services) | 358 (Other specialized forces & services) | 900 (History & geography) | 900 (History & geography) | U (Military Science) | U (Military Science) | UA (Armies: Organization - distribution - military situation) | UA (Armies: Organization - distribution - military situation) | UG (Military engineering. Air forces) | UG (Military engineering. Air forces) | 358 (Other specialized forces & services) | 358 (Other specialized forces & services) | 900 (History & geography) | 900 (History & geography)

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Boeing B-29 (Super fortress) - Homestead Boeing B-29 (Super fortress) - Homestead

Description

Subjects

airplane | airplane | florida | florida | aircraft | aircraft | aviation | aviation | airplanes | airplanes | homestead | homestead | wright | wright | boeing | boeing | bomber | bomber | fifi | fifi | caf | caf | militaryaviation | militaryaviation | b29 | b29 | superfortress | superfortress | r3350 | r3350 | b29bomber | b29bomber | usaaf | usaaf | b29a | b29a | boeingb29superfortress | boeingb29superfortress | boeingb29asuperfortress | boeingb29asuperfortress | commemorativeairforce | commemorativeairforce | boeingrenton | boeingrenton | confederateairforce | confederateairforce | superfort | superfort | unitedstatesarmyairforces | unitedstatesarmyairforces | boeingb29 | boeingb29 | boeingsuperfortress | boeingsuperfortress | n529b | n529b | boeingairplanecompany | boeingairplanecompany | 4462070 | 4462070 | wrightr3350 | wrightr3350 | usaaf4462070 | usaaf4462070 | boeingb29a | boeingb29a | af4462070 | af4462070 | b29a60bn | b29a60bn

License

No known copyright restrictions

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8.01 Physics I: Classical Mechanics (MIT)

Description

8.01 is a first-semester freshman physics class in Newtonian Mechanics, Fluid Mechanics, and Kinetic Gas Theory. In addition to the basic concepts of Newtonian Mechanics, Fluid Mechanics, and Kinetic Gas Theory, a variety of interesting topics are covered in this course: Binary Stars, Neutron Stars, Black Holes, Resonance Phenomena, Musical Instruments, Stellar Collapse, Supernovae, Astronomical observations from very high flying balloons (lecture 35), and you will be allowed a peek into the intriguing Quantum World. Also by Walter Lewin Courses: Electricity and Magnetism (8.02) - with a complete set of 36 video lectures from the Spring of 2002 Vibrations and Waves (8.03) - with a complete set of 23 video lectures from the Fall of 2004 Talks: For The Love Of Physics - Profes

Subjects

units of measurement | powers of ten | dimensional analysis | measurement uncertainty | scaling arguments | velocity | speed | acceleration | acceleration of gravity | vectors | motion | vector product | scalar product | projectiles | projectile trajectory | circular motion | centripetal motion | artifical gravity | force | Newton's Three Laws | eight | weightlessness | tension | friction | frictionless forces | static friction | dot products | cross products | kinematics | springs | pendulum | mechanical energy | kinetic energy | universal gravitation | resistive force | drag force | air drag | viscous terminal velocity | potential energy | heat; energy consumption | heat | energy consumption | collisions | center of mass | momentum | Newton's Cradle | impulse and impact | rocket thrust | rocket velocity | flywheels | inertia | torque | spinning rod | elliptical orbits | Kepler's Laws | Doppler shift | stellar dynamics | sound waves | electromagnets | binary star | black holes | rope tension | elasticity | speed of sound | pressure in fluid | Pascal's Principle | hydrostatic pressure | barometric pressure | submarines | buoyant force | Bernoulli's Equations | Archimede's Principle | floating | baloons | resonance | wind instruments | thermal expansion | shrink fitting | particles and waves | diffraction

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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8.01 Physics I: Classical Mechanics (MIT)

Description

8.01 is a first-semester freshman physics class in Newtonian Mechanics, Fluid Mechanics, and Kinetic Gas Theory. In addition to the basic concepts of Newtonian Mechanics, Fluid Mechanics, and Kinetic Gas Theory, a variety of interesting topics are covered in this course: Binary Stars, Neutron Stars, Black Holes, Resonance Phenomena, Musical Instruments, Stellar Collapse, Supernovae, Astronomical observations from very high flying balloons (lecture 35), and you will be allowed a peek into the intriguing Quantum World. Also by Walter Lewin Courses: Electricity and Magnetism (8.02) - with a complete set of 36 video lectures from the Spring of 2002 Vibrations and Waves (8.03) - with a complete set of 23 video lectures from the Fall of 2004 Talks: For The Love Of Physics - Profes

Subjects

units of measurement | powers of ten | dimensional analysis | measurement uncertainty | scaling arguments | velocity | speed | acceleration | acceleration of gravity | vectors | motion | vector product | scalar product | projectiles | projectile trajectory | circular motion | centripetal motion | artifical gravity | force | Newton's Three Laws | eight | weightlessness | tension | friction | frictionless forces | static friction | dot products | cross products | kinematics | springs | pendulum | mechanical energy | kinetic energy | universal gravitation | resistive force | drag force | air drag | viscous terminal velocity | potential energy | heat; energy consumption | heat | energy consumption | collisions | center of mass | momentum | Newton's Cradle | impulse and impact | rocket thrust | rocket velocity | flywheels | inertia | torque | spinning rod | elliptical orbits | Kepler's Laws | Doppler shift | stellar dynamics | sound waves | electromagnets | binary star | black holes | rope tension | elasticity | speed of sound | pressure in fluid | Pascal's Principle | hydrostatic pressure | barometric pressure | submarines | buoyant force | Bernoulli's Equations | Archimede's Principle | floating | baloons | resonance | wind instruments | thermal expansion | shrink fitting | particles and waves | diffraction

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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IV (MIT) IV (MIT)

Description

The basic objective of Unified Engineering is to give a solid understanding of the fundamental disciplines of aerospace engineering, as well as their interrelationships and applications. These disciplines are Materials and Structures (M); Computers and Programming (C); Fluid Mechanics (F); Thermodynamics (T); Propulsion (P); and Signals and Systems (S). In choosing to teach these subjects in a unified manner, the instructors seek to explain the common intellectual threads in these disciplines, as well as their combined application to solve engineering Systems Problems (SP). Throughout the year, the instructors emphasize the connections among the disciplines.Technical RequirementsMicrosoft® Excel software is recommended for viewing the .xls files The basic objective of Unified Engineering is to give a solid understanding of the fundamental disciplines of aerospace engineering, as well as their interrelationships and applications. These disciplines are Materials and Structures (M); Computers and Programming (C); Fluid Mechanics (F); Thermodynamics (T); Propulsion (P); and Signals and Systems (S). In choosing to teach these subjects in a unified manner, the instructors seek to explain the common intellectual threads in these disciplines, as well as their combined application to solve engineering Systems Problems (SP). Throughout the year, the instructors emphasize the connections among the disciplines.Technical RequirementsMicrosoft® Excel software is recommended for viewing the .xls files

Subjects

Unified | Unified | Unified Engineering | Unified Engineering | aerospace | aerospace | CDIO | CDIO | C-D-I-O | C-D-I-O | conceive | conceive | design | design | implement | implement | operate | operate | team | team | team-based | team-based | discipline | discipline | materials | materials | structures | structures | materials and structures | materials and structures | computers | computers | programming | programming | computers and programming | computers and programming | fluids | fluids | fluid mechanics | fluid mechanics | thermodynamics | thermodynamics | propulsion | propulsion | signals | signals | systems | systems | signals and systems | signals and systems | systems problems | systems problems | fundamentals | fundamentals | technical communication | technical communication | graphical communication | graphical communication | communication | communication | reading | reading | research | research | experimentation | experimentation | personal response system | personal response system | prs | prs | active learning | active learning | First law | First law | first law of thermodynamics | first law of thermodynamics | thermo-mechanical | thermo-mechanical | energy | energy | energy conversion | energy conversion | aerospace power systems | aerospace power systems | propulsion systems | propulsion systems | aerospace propulsion systems | aerospace propulsion systems | heat | heat | work | work | thermal efficiency | thermal efficiency | forms of energy | forms of energy | energy exchange | energy exchange | processes | processes | heat engines | heat engines | engines | engines | steady-flow energy equation | steady-flow energy equation | energy flow | energy flow | flows | flows | path-dependence | path-dependence | path-independence | path-independence | reversibility | reversibility | irreversibility | irreversibility | state | state | thermodynamic state | thermodynamic state | performance | performance | ideal cycle | ideal cycle | simple heat engine | simple heat engine | cycles | cycles | thermal pressures | thermal pressures | temperatures | temperatures | linear static networks | linear static networks | loop method | loop method | node method | node method | linear dynamic networks | linear dynamic networks | classical methods | classical methods | state methods | state methods | state concepts | state concepts | dynamic systems | dynamic systems | resistive circuits | resistive circuits | sources | sources | voltages | voltages | currents | currents | Thevinin | Thevinin | Norton | Norton | initial value problems | initial value problems | RLC networks | RLC networks | characteristic values | characteristic values | characteristic vectors | characteristic vectors | transfer function | transfer function | ada | ada | ada programming | ada programming | programming language | programming language | software systems | software systems | programming style | programming style | computer architecture | computer architecture | program language evolution | program language evolution | classification | classification | numerical computation | numerical computation | number representation systems | number representation systems | assembly | assembly | SimpleSIM | SimpleSIM | RISC | RISC | CISC | CISC | operating systems | operating systems | single user | single user | multitasking | multitasking | multiprocessing | multiprocessing | domain-specific classification | domain-specific classification | recursive | recursive | execution time | execution time | fluid dynamics | fluid dynamics | physical properties of a fluid | physical properties of a fluid | fluid flow | fluid flow | mach | mach | reynolds | reynolds | conservation | conservation | conservation principles | conservation principles | conservation of mass | conservation of mass | conservation of momentum | conservation of momentum | conservation of energy | conservation of energy | continuity | continuity | inviscid | inviscid | steady flow | steady flow | simple bodies | simple bodies | airfoils | airfoils | wings | wings | channels | channels | aerodynamics | aerodynamics | forces | forces | moments | moments | equilibrium | equilibrium | freebody diagram | freebody diagram | free-body | free-body | free body | free body | planar force systems | planar force systems | equipollent systems | equipollent systems | equipollence | equipollence | support reactions | support reactions | reactions | reactions | static determinance | static determinance | determinate systems | determinate systems | truss analysis | truss analysis | trusses | trusses | method of joints | method of joints | method of sections | method of sections | statically indeterminate | statically indeterminate | three great principles | three great principles | 3 great principles | 3 great principles | indicial notation | indicial notation | rotation of coordinates | rotation of coordinates | coordinate rotation | coordinate rotation | stress | stress | extensional stress | extensional stress | shear stress | shear stress | notation | notation | plane stress | plane stress | stress equilbrium | stress equilbrium | stress transformation | stress transformation | mohr | mohr | mohr's circle | mohr's circle | principal stress | principal stress | principal stresses | principal stresses | extreme shear stress | extreme shear stress | strain | strain | extensional strain | extensional strain | shear strain | shear strain | strain-displacement | strain-displacement | compatibility | compatibility | strain transformation | strain transformation | transformation of strain | transformation of strain | mohr's circle for strain | mohr's circle for strain | principal strain | principal strain | extreme shear strain | extreme shear strain | uniaxial stress-strain | uniaxial stress-strain | material properties | material properties | classes of materials | classes of materials | bulk material properties | bulk material properties | origin of elastic properties | origin of elastic properties | structures of materials | structures of materials | atomic bonding | atomic bonding | packing of atoms | packing of atoms | atomic packing | atomic packing | crystals | crystals | crystal structures | crystal structures | polymers | polymers | estimate of moduli | estimate of moduli | moduli | moduli | composites | composites | composite materials | composite materials | modulus limited design | modulus limited design | material selection | material selection | materials selection | materials selection | measurement of elastic properties | measurement of elastic properties | stress-strain | stress-strain | stress-strain relations | stress-strain relations | anisotropy | anisotropy | orthotropy | orthotropy | measurements | measurements | engineering notation | engineering notation | Hooke | Hooke | Hooke's law | Hooke's law | general hooke's law | general hooke's law | equations of elasticity | equations of elasticity | boundary conditions | boundary conditions | multi-disciplinary | multi-disciplinary | models | models | engineering systems | engineering systems | experiments | experiments | investigations | investigations | experimental error | experimental error | design evaluation | design evaluation | evaluation | evaluation | trade studies | trade studies | effects of engineering | effects of engineering | social context | social context | engineering drawings | engineering drawings | 16.01 | 16.01 | 16.02 | 16.02 | 16.03 | 16.03 | 16.04 | 16.04

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6.641 Electromagnetic Fields, Forces, and Motion (MIT) 6.641 Electromagnetic Fields, Forces, and Motion (MIT)

Description

6.641 examines electric and magnetic quasistatic forms of Maxwell's equations applied to dielectric, conduction, and magnetization boundary value problems. Topics covered include: electromagnetic forces, force densities, and stress tensors, including magnetization and polarization; thermodynamics of electromagnetic fields, equations of motion, and energy conservation; applications to synchronous, induction, and commutator machines; sensors and transducers; microelectromechanical systems; propagation and stability of electromechanical waves; and charge transport phenomena.Technical RequirementsRealOne™ Player software is required to run the .rm files found on this course site.RealOne™ is a trademark or a registered trademark of RealNetworks, Inc. 6.641 examines electric and magnetic quasistatic forms of Maxwell's equations applied to dielectric, conduction, and magnetization boundary value problems. Topics covered include: electromagnetic forces, force densities, and stress tensors, including magnetization and polarization; thermodynamics of electromagnetic fields, equations of motion, and energy conservation; applications to synchronous, induction, and commutator machines; sensors and transducers; microelectromechanical systems; propagation and stability of electromechanical waves; and charge transport phenomena.Technical RequirementsRealOne™ Player software is required to run the .rm files found on this course site.RealOne™ is a trademark or a registered trademark of RealNetworks, Inc.

Subjects

electromagnetic | electromagnetic | electromagnetic field | electromagnetic field | forces | forces | motion | motion | electric | electric | magnetic | magnetic | quasistatic | quasistatic | Maxwell's equations | Maxwell's equations | dielectric | dielectric | conduction | conduction | magnetization | magnetization | boundary value problems | boundary value problems | force densities | force densities | stress tensors | stress tensors | polarization | polarization | thermodynamics | thermodynamics | equations of motion | equations of motion | energy conservation | energy conservation | synchronous | synchronous | induction | induction | commutator machines | commutator machines | sensors | sensors | transducers | transducers | microelectromechanical systems | microelectromechanical systems | electromechanical waves | electromechanical waves | charge transport phenomena | charge transport phenomena

License

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1.259J Transit Management (MIT) 1.259J Transit Management (MIT)

Description

1.259J discusses management methods of relevance to public transportation systems. Topics include: strategic planning management; labor relations; maintenance planning and administration; financing; marketing and fare policy; and management information and decision support systems. The course focuses on how these general management tasks are addressed in the transit industry and presents alternative strategies. It identifies alternative arrangements for service provision, including different ways of involving the private sector in public transportation. 1.259J discusses management methods of relevance to public transportation systems. Topics include: strategic planning management; labor relations; maintenance planning and administration; financing; marketing and fare policy; and management information and decision support systems. The course focuses on how these general management tasks are addressed in the transit industry and presents alternative strategies. It identifies alternative arrangements for service provision, including different ways of involving the private sector in public transportation.

Subjects

public transportation systems | public transportation systems | strategic planning management | strategic planning management | labor relations | labor relations | maintenance planning | maintenance planning | administration | administration | financing | financing | marketing policy | marketing policy | fare policy | fare policy | management information | management information | decision support systems | decision support systems | transit industry | transit industry | service provision | service provision | private sector | private sector | management methods | management methods | urban public transportation systems | urban public transportation systems | maintenance administration | maintenance administration | public transport service organizations | public transport service organizations | privatization | privatization | deregulation | deregulation | performance assessment | performance assessment | budgeting | budgeting | pricing | pricing | budgets | budgets | workforce planning | workforce planning | workforce management | workforce management | 1.259 | 1.259 | 11.542 | 11.542 | ESD.227 | ESD.227

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17.460 Defense Politics (MIT) 17.460 Defense Politics (MIT)

Description

This course focuses on the institutional relationships that affect the raising, maintenance and use of military forces in the United States. It is about civil/military, government/industry, military/science and military service/military service relations. The course examines how politicians, defense contractors, and military officers determine the military might of the United States. It analyzes the military strategies of the nation and the bureaucratic strategies of the armed services, contractors, and defense scientists. It offers a combination of military sociology, organizational politics, and the political economy of defense. This course focuses on the institutional relationships that affect the raising, maintenance and use of military forces in the United States. It is about civil/military, government/industry, military/science and military service/military service relations. The course examines how politicians, defense contractors, and military officers determine the military might of the United States. It analyzes the military strategies of the nation and the bureaucratic strategies of the armed services, contractors, and defense scientists. It offers a combination of military sociology, organizational politics, and the political economy of defense.

Subjects

United States; defense; policy; institutional relationships; military; forces; civil; government; industry; science; military relations; politicians; defense contractors; officers; strategies; bureaucracy; armed services; contractors; defense scientists; sociology; organization; politics; political economy; congress; president; terror; war; homeland;intraservice; interservice; cargo; security | United States; defense; policy; institutional relationships; military; forces; civil; government; industry; science; military relations; politicians; defense contractors; officers; strategies; bureaucracy; armed services; contractors; defense scientists; sociology; organization; politics; political economy; congress; president; terror; war; homeland;intraservice; interservice; cargo; security | United States | United States | defense | defense | policy | policy | institutional relationships | institutional relationships | military | military | forces | forces | civil | civil | government | government | industry | industry | science | science | military relations | military relations | politicians | politicians | defense contractors | defense contractors | officers | officers | strategies | strategies | bureaucracy | bureaucracy | armed services | armed services | contractors | contractors | defense scientists | defense scientists | sociology | sociology | organization | organization | politics | politics | political economy | political economy | congress | congress | president | president | terror | terror | war | war | homeland | homeland | intraservice | intraservice | interservice | interservice | cargo | cargo | security | security

License

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8.01SC Physics I: Classical Mechanics (MIT)

Description

Physics I is a first-year, first-semester course that provides an introduction to Classical Mechanics. It covers the basic concepts of Newtonian mechanics, fluid mechanics, and kinetic gas theory.

Subjects

classical mechanics | space and time | straight-line kinematics | motion in a plane | forces and equilibrium | experimental basis of Newton's laws | particle dynamics | universal gravitation | collisions and conservation laws | work and potential energy | vibrational motion | conservative forces | inertial forces and non-inertial frames | central force motions | rigid bodies | rotational dynamics | rigid bodies and rotational dynamics

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6.641 Electromagnetic Fields, Forces, and Motion (MIT) 6.641 Electromagnetic Fields, Forces, and Motion (MIT)

Description

Includes audio/video content: AV faculty introductions. This course examines electric and magnetic quasistatic forms of Maxwell's equations applied to dielectric, conduction, and magnetization boundary value problems. Topics covered include: electromagnetic forces, force densities, and stress tensors, including magnetization and polarization; thermodynamics of electromagnetic fields, equations of motion, and energy conservation; applications to synchronous, induction, and commutator machines; sensors and transducers; microelectromechanical systems; propagation and stability of electromechanical waves; and charge transport phenomena. Acknowledgments The instructor would like to thank Thomas Larsen and Matthew Pegler for transcribing into LaTeX the homework problems, homework solutions, and Includes audio/video content: AV faculty introductions. This course examines electric and magnetic quasistatic forms of Maxwell's equations applied to dielectric, conduction, and magnetization boundary value problems. Topics covered include: electromagnetic forces, force densities, and stress tensors, including magnetization and polarization; thermodynamics of electromagnetic fields, equations of motion, and energy conservation; applications to synchronous, induction, and commutator machines; sensors and transducers; microelectromechanical systems; propagation and stability of electromechanical waves; and charge transport phenomena. Acknowledgments The instructor would like to thank Thomas Larsen and Matthew Pegler for transcribing into LaTeX the homework problems, homework solutions, and

Subjects

electromagnetic | electromagnetic | electromagnetic field | electromagnetic field | forces | forces | motion | motion | electric | electric | magnetic | magnetic | quasistatic | quasistatic | Maxwell's equations | Maxwell's equations | dielectric | dielectric | conduction | conduction | magnetization | magnetization | boundary value problems | boundary value problems | force densities | force densities | stress tensors | stress tensors | polarization | polarization | thermodynamics | thermodynamics | equations of motion | equations of motion | energy conservation | energy conservation | synchronous | synchronous | induction | induction | commutator machines | commutator machines | sensors | sensors | transducers | transducers | microelectromechanical systems | microelectromechanical systems | electromechanical waves | electromechanical waves | charge transport phenomena | charge transport phenomena

License

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IV (MIT) IV (MIT)

Description

Includes audio/video content: AV selected lectures, AV faculty introductions, AV special element video. The basic objective of Unified Engineering is to give a solid understanding of the fundamental disciplines of aerospace engineering, as well as their interrelationships and applications. These disciplines are Materials and Structures (M); Computers and Programming (C); Fluid Mechanics (F); Thermodynamics (T); Propulsion (P); and Signals and Systems (S). In choosing to teach these subjects in a unified manner, the instructors seek to explain the common intellectual threads in these disciplines, as well as their combined application to solve engineering Systems Problems (SP). Throughout the year, the instructors emphasize the connections among the disciplines. Includes audio/video content: AV selected lectures, AV faculty introductions, AV special element video. The basic objective of Unified Engineering is to give a solid understanding of the fundamental disciplines of aerospace engineering, as well as their interrelationships and applications. These disciplines are Materials and Structures (M); Computers and Programming (C); Fluid Mechanics (F); Thermodynamics (T); Propulsion (P); and Signals and Systems (S). In choosing to teach these subjects in a unified manner, the instructors seek to explain the common intellectual threads in these disciplines, as well as their combined application to solve engineering Systems Problems (SP). Throughout the year, the instructors emphasize the connections among the disciplines.

Subjects

Unified | Unified | Unified Engineering | Unified Engineering | aerospace | aerospace | CDIO | CDIO | C-D-I-O | C-D-I-O | conceive | conceive | design | design | implement | implement | operate | operate | team | team | team-based | team-based | discipline | discipline | materials | materials | structures | structures | materials and structures | materials and structures | computers | computers | programming | programming | computers and programming | computers and programming | fluids | fluids | fluid mechanics | fluid mechanics | thermodynamics | thermodynamics | propulsion | propulsion | signals | signals | systems | systems | signals and systems | signals and systems | systems problems | systems problems | fundamentals | fundamentals | technical communication | technical communication | graphical communication | graphical communication | communication | communication | reading | reading | research | research | experimentation | experimentation | personal response system | personal response system | prs | prs | active learning | active learning | First law | First law | first law of thermodynamics | first law of thermodynamics | thermo-mechanical | thermo-mechanical | energy | energy | energy conversion | energy conversion | aerospace power systems | aerospace power systems | propulsion systems | propulsion systems | aerospace propulsion systems | aerospace propulsion systems | heat | heat | work | work | thermal efficiency | thermal efficiency | forms of energy | forms of energy | energy exchange | energy exchange | processes | processes | heat engines | heat engines | engines | engines | steady-flow energy equation | steady-flow energy equation | energy flow | energy flow | flows | flows | path-dependence | path-dependence | path-independence | path-independence | reversibility | reversibility | irreversibility | irreversibility | state | state | thermodynamic state | thermodynamic state | performance | performance | ideal cycle | ideal cycle | simple heat engine | simple heat engine | cycles | cycles | thermal pressures | thermal pressures | temperatures | temperatures | linear static networks | linear static networks | loop method | loop method | node method | node method | linear dynamic networks | linear dynamic networks | classical methods | classical methods | state methods | state methods | state concepts | state concepts | dynamic systems | dynamic systems | resistive circuits | resistive circuits | sources | sources | voltages | voltages | currents | currents | Thevinin | Thevinin | Norton | Norton | initial value problems | initial value problems | RLC networks | RLC networks | characteristic values | characteristic values | characteristic vectors | characteristic vectors | transfer function | transfer function | ada | ada | ada programming | ada programming | programming language | programming language | software systems | software systems | programming style | programming style | computer architecture | computer architecture | program language evolution | program language evolution | classification | classification | numerical computation | numerical computation | number representation systems | number representation systems | assembly | assembly | SimpleSIM | SimpleSIM | RISC | RISC | CISC | CISC | operating systems | operating systems | single user | single user | multitasking | multitasking | multiprocessing | multiprocessing | domain-specific classification | domain-specific classification | recursive | recursive | execution time | execution time | fluid dynamics | fluid dynamics | physical properties of a fluid | physical properties of a fluid | fluid flow | fluid flow | mach | mach | reynolds | reynolds | conservation | conservation | conservation principles | conservation principles | conservation of mass | conservation of mass | conservation of momentum | conservation of momentum | conservation of energy | conservation of energy | continuity | continuity | inviscid | inviscid | steady flow | steady flow | simple bodies | simple bodies | airfoils | airfoils | wings | wings | channels | channels | aerodynamics | aerodynamics | forces | forces | moments | moments | equilibrium | equilibrium | freebody diagram | freebody diagram | free-body | free-body | free body | free body | planar force systems | planar force systems | equipollent systems | equipollent systems | equipollence | equipollence | support reactions | support reactions | reactions | reactions | static determinance | static determinance | determinate systems | determinate systems | truss analysis | truss analysis | trusses | trusses | method of joints | method of joints | method of sections | method of sections | statically indeterminate | statically indeterminate | three great principles | three great principles | 3 great principles | 3 great principles | indicial notation | indicial notation | rotation of coordinates | rotation of coordinates | coordinate rotation | coordinate rotation | stress | stress | extensional stress | extensional stress | shear stress | shear stress | notation | notation | plane stress | plane stress | stress equilbrium | stress equilbrium | stress transformation | stress transformation | mohr | mohr | mohr's circle | mohr's circle | principal stress | principal stress | principal stresses | principal stresses | extreme shear stress | extreme shear stress | strain | strain | extensional strain | extensional strain | shear strain | shear strain | strain-displacement | strain-displacement | compatibility | compatibility | strain transformation | strain transformation | transformation of strain | transformation of strain | mohr's circle for strain | mohr's circle for strain | principal strain | principal strain | extreme shear strain | extreme shear strain | uniaxial stress-strain | uniaxial stress-strain | material properties | material properties | classes of materials | classes of materials | bulk material properties | bulk material properties | origin of elastic properties | origin of elastic properties | structures of materials | structures of materials | atomic bonding | atomic bonding | packing of atoms | packing of atoms | atomic packing | atomic packing | crystals | crystals | crystal structures | crystal structures | polymers | polymers | estimate of moduli | estimate of moduli | moduli | moduli | composites | composites | composite materials | composite materials | modulus limited design | modulus limited design | material selection | material selection | materials selection | materials selection | measurement of elastic properties | measurement of elastic properties | stress-strain | stress-strain | stress-strain relations | stress-strain relations | anisotropy | anisotropy | orthotropy | orthotropy | measurements | measurements | engineering notation | engineering notation | Hooke | Hooke | Hooke's law | Hooke's law | general hooke's law | general hooke's law | equations of elasticity | equations of elasticity | boundary conditions | boundary conditions | multi-disciplinary | multi-disciplinary | models | models | engineering systems | engineering systems | experiments | experiments | investigations | investigations | experimental error | experimental error | design evaluation | design evaluation | evaluation | evaluation | trade studies | trade studies | effects of engineering | effects of engineering | social context | social context | engineering drawings | engineering drawings

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2.20 Marine Hydrodynamics (13.021) (MIT) 2.20 Marine Hydrodynamics (13.021) (MIT)

Description

In this course the fundamentals of fluid mechanics are developed in the context of naval architecture and ocean science and engineering. The various topics covered are: Transport theorem and conservation principles, Navier-Stokes' equation, dimensional analysis, ideal and potential flows, vorticity and Kelvin's theorem, hydrodynamic forces in potential flow, D'Alembert's paradox, added-mass, slender-body theory, viscous-fluid flow, laminar and turbulent boundary layers, model testing, scaling laws, application of potential theory to surface waves, energy transport, wave/body forces, linearized theory of lifting surfaces, and experimental project in the towing tank or propeller tunnel.This subject was originally offered in Course 13 (Department of Ocean Engineering) as 13.021. In 2005, In this course the fundamentals of fluid mechanics are developed in the context of naval architecture and ocean science and engineering. The various topics covered are: Transport theorem and conservation principles, Navier-Stokes' equation, dimensional analysis, ideal and potential flows, vorticity and Kelvin's theorem, hydrodynamic forces in potential flow, D'Alembert's paradox, added-mass, slender-body theory, viscous-fluid flow, laminar and turbulent boundary layers, model testing, scaling laws, application of potential theory to surface waves, energy transport, wave/body forces, linearized theory of lifting surfaces, and experimental project in the towing tank or propeller tunnel.This subject was originally offered in Course 13 (Department of Ocean Engineering) as 13.021. In 2005,

Subjects

fundamentals of fluid mechanics | fundamentals of fluid mechanics | naval architecture | naval architecture | ocean science and engineering | ocean science and engineering | transport theorem | transport theorem | conservation principles | conservation principles | Navier-Stokes' equation | Navier-Stokes' equation | dimensional analysis | dimensional analysis | ideal and potential flows | ideal and potential flows | vorticity and Kelvin's theorem | vorticity and Kelvin's theorem | hydrodynamic forces in potential flow | hydrodynamic forces in potential flow | D'Alembert's paradox | D'Alembert's paradox | added-mass | added-mass | slender-body theory. Viscous-fluid flow | slender-body theory. Viscous-fluid flow | laminar and turbulent boundary layers | laminar and turbulent boundary layers | model testing | model testing | scaling laws | scaling laws | application of potential theory to surface waves | application of potential theory to surface waves | energy transport | energy transport | wave/body forces | wave/body forces | linearized theory of lifting surfaces | linearized theory of lifting surfaces | experimental project in the towing tank or propeller tunnel | experimental project in the towing tank or propeller tunnel

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6.641 Electromagnetic Fields, Forces, and Motion (MIT) 6.641 Electromagnetic Fields, Forces, and Motion (MIT)

Description

6.641 examines electric and magnetic quasistatic forms of Maxwell's equations applied to dielectric, conduction, and magnetization boundary value problems. Topics covered include: electromagnetic forces, force densities, and stress tensors, including magnetization and polarization; thermodynamics of electromagnetic fields, equations of motion, and energy conservation; applications to synchronous, induction, and commutator machines; sensors and transducers; microelectromechanical systems; propagation and stability of electromechanical waves; and charge transport phenomena. Acknowledgement The instructor would like to thank Thomas Larsen for transcribing into LaTeX selected homework problems, homework solutions, and exams. 6.641 examines electric and magnetic quasistatic forms of Maxwell's equations applied to dielectric, conduction, and magnetization boundary value problems. Topics covered include: electromagnetic forces, force densities, and stress tensors, including magnetization and polarization; thermodynamics of electromagnetic fields, equations of motion, and energy conservation; applications to synchronous, induction, and commutator machines; sensors and transducers; microelectromechanical systems; propagation and stability of electromechanical waves; and charge transport phenomena. Acknowledgement The instructor would like to thank Thomas Larsen for transcribing into LaTeX selected homework problems, homework solutions, and exams.

Subjects

electromagnetic | electromagnetic | electromagnetic field | electromagnetic field | forces | forces | motion | motion | electric | electric | magnetic | magnetic | quasistatic | quasistatic | Maxwell's equations | Maxwell's equations | dielectric | dielectric | conduction | conduction | magnetization | magnetization | boundary value problems | boundary value problems | force densities | force densities | stress tensors | stress tensors | polarization | polarization | thermodynamics | thermodynamics | equations of motion | equations of motion | energy conservation | energy conservation | synchronous | synchronous | induction | induction | commutator machines | commutator machines | sensors | sensors | transducers | transducers | microelectromechanical systems | microelectromechanical systems | electromechanical waves | electromechanical waves | charge transport phenomena | charge transport phenomena

License

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TALAT Lecture 2301: Design of Members

Description

This lecture gives background to calculation methods for aluminium members in order to understand the specific behavior of statically loaded aluminium alloy structures. Basic structural mechanic, design philosophy and structural aluminium alloys and product forms is assumed.

Subjects

aluminium | aluminum | european aluminium association | EAA | Training in Aluminium Application Technologies | training | metallurgy | technology | lecture | design | product | member | joint | static | safety | serviceability | geometrical imperfections | extruded profiles | welded profiles | residual stresses | mechanical properties | Bauschinger effect | heat affected zones | stress-strain relationship | strength | reduced strength | partial coefficients | resistance factors | gross section | net section | local buckling | cross section classes | slender plates | effective cross section | class 4 cross sections | deflections of beams | breathing | bending moment | yielding | slenderness parameter | element classification | effective thickness | welded section | section with holes | lateral torsional buckling | axial force | tensile force | compressive force | Euler load | squash load | flexural buckling | reduction factor | buckling length | splices | end connections | welded columns | columns with bolt holes | cut-outs | longitudinal welds | transverse welds | columns with unfilled bolt-holes | built-up members | intermediate stiffeners | edge stiffeners | single-sided rib | multi-stiffened plates | orthotropic plates | shear force | plate girder webs | shear buckling | shear resistance | webs with stiffeners | plate girders with intermediate stiffeners | corrugated webs | closely stiffened webs | concentrated loads | beam webs without stiffeners | beam webs with stiffeners | shear centre | closed sections | open sections | torsion without warping | torsion with warpin | bending and axial tension | bending and axial compression | strength of beam-column segments | rectangular section | strain hardening | plastic theory | I-section | H-section | thin walled cross sections | T-section | biaxial bending | linear stress distribution | shear lag | flange curling | lateral deflection | non-symmetrical flanges | corematerials | ukoer

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