Vector addition and subtraction
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Scott Edwards (赵安得)
目录
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1 Week 1
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1.1 Introduction
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1.2 Interactions cause change
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1.3 Vectors: components and magnitude
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1.4 What vectors can and cannot do
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1.5 Unit vectors
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1.6 Vector addition and subtraction
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1.7 Displacement and velocity
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1.8 Predicting a new position
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1.9 Instantaneous velocity
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1.10 Example: spacecraft
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1.11 Momentum
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1.12 Change in momentum
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2 Week 2
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2.1 Newton's 2nd Law
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2.2 Impulse
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2.3 How to predict the future (part 1)
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2.4 How to predict the future (part 2)
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2.5 What about F = ma?
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2.6 Updating position
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2.7 Non-constant force
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2.8 Iterative prediction of motion
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2.9 Can't we just use calculus?
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2.10 A special case: constant force
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2.11 Example: soccer penalty kick
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2.12 Estimating interaction times
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3 Week 3
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3.1 Classifying interactions
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3.2 Gravitation
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3.3 Example: Earth and the Moon
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3.4 Solving the Earth's orbit iteratively
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3.5 Gravitation near the Earth's surface
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3.6 The electric force
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3.7 Limitations on predicting the future
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3.8 The ball-and-spring model of matter
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3.9 Tension
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3.10 Friction
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4 Week 4
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4.1 Conservation of momentum
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4.2 Center of mass
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4.3 Instantaneous version of Newton's 2nd Law
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4.4 Statics: dp/dt = 0
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4.5 Example: pushing a box, with friction
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4.6 Judging the direction of dp/dt
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4.7 Curving motion: parallel and perpendicular components of dp/dt
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4.8 Components from the vector dot product
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4.9 Example: a falling ball
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4.10 Rate of change of direction
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4.11 Example: kissing circle for falling ball
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4.12 Example: swinging a bucket
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5 Week 5
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5.1 The Energy Principle
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5.2 Energy of a single particle
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5.3 Kinetic energy
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5.4 Work
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5.5 Examples: cricket ball, neutron decay
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5.6 Proof of the Energy Principle
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5.7 Work done by a non-constant force
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5.8 Potential energy
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5.9 Gravitational potential energy
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5.10 Example: Spacecraft leaving an asteroid
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5.11 Bound and unbound states
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5.12 Electrical potential energy
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6 Week 6
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6.1 Force is the negative gradient of potential energy
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6.2 Spring potential energy
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6.3 Example: bungee jumping
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6.4 Path independence of potential energy
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6.5 Internal energy
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6.6 Dissipation and power
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6.7 Translational and rotational kinetic energy
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6.8 Moment of inertia
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6.9 Calculating moment of inertia
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6.10 Parallel axis theorem
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6.11 Example: rolling down a hill
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7 Week 7
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7.1 Translational angular momentum
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7.2 Direction of the angular momentum vector
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7.3 Vector cross product
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7.4 Example: a falling ball
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7.5 Rotational angular momentum
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7.6 Total angular momentum
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7.7 Torque and the Angular Momentum Principle
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7.8 Example: a comet
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7.9 Angular Momentum Principle for multiparticle systems
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7.10 Example: a seesaw
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7.11 Example: a diver
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7.12 Example: a stick sliding on ice
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8 Week 8
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8.1 Electric charge
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8.2 Example: force between two protons
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8.3 Electric field
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8.4 Field of a single point charge
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8.5 Example: where is the charge?
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8.6 Superposition
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8.7 Example: superposition of two charges
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8.8 Electric dipole – parallel axis (part 1)
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8.9 Electric dipole – parallel axis (part 2)
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8.10 Electric dipole – perpendicular axis
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8.11 Example: interaction between a dipole and a point charge
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8.12 Dipole moment
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9 Week 9
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9.1 Charged particles in matter
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9.2 How do objects become charged?
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9.3 Example: how much charge on a piece of tape?
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9.4 Polarization of atoms
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9.5 Interaction between a neutral atom and a point charge
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9.6 Polarization of insulators
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9.7 Polarization of conductors
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9.8 Charge motion in metals
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9.9 Example: a rod and a ball
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9.10 Practical limits on measuring the field
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10 Week 10
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10.1 Uniform thin rod: introduction
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10.2 Uniform thin rod: break it into pieces
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10.3 Uniform thin rod: add up the pieces
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10.4 Uniform thin rod: check the answer
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10.5 Example: a hollow cylinder
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10.6 Uniform thin ring
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10.7 Uniform disk (part 1)
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10.8 Uniform disk (part 2)
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10.9 Example: a rod and a disk
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10.10 Two uniform disks: a capacitor
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10.11 Spherical charge distributions
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11 Week 11
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11.1 Systems of charged objects
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11.2 Potential difference in a uniform field
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11.3 Field from potential difference
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11.4 Potential difference in a non-uniform field
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11.5 Potential difference near a point charge
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11.6 Path independence
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11.7 Potential at one location
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11.8 Example: potential of a uniform ring
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11.9 Potential difference in an insulator
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11.10 Energy density and electric field
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12 Week 12
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12.1 Magnetic field
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12.2 Biot-Savart Law for a single moving charge
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12.3 Electron current
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12.4 Conventional current
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12.5 Biot-Savart Law for currents
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12.6 Magnetic field of a long straight wire
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12.7 Magnetic field of a circular current loop
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12.8 Magnetic dipole moment
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12.9 Magnetic field of a bar magnet
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12.10 Atomic structure of magnets
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13 Week 13
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13.1 Magnetic force on a moving charge
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13.2 Magnetic force on a current-carrying wire
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13.3 Combining electric and magnetic forces
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13.4 The Hall effect
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13.5 Motional emf
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13.6 Magnetic torque
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13.7 Potential energy for a magnetic dipole
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13.8 Force on a magnetic dipole
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13.9 Example: the Stern-Gerlach experiment
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13.10 Motors and generators
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14 Week 14
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14.1 Patterns of electric field
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14.2 Electric flux
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14.3 Gauss’s Law (part 1)
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14.4 Gauss’s Law (part 2)
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14.5 Reasoning from Gauss’s Law
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14.6 Proving some important properties of metals
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14.7 Gauss’s Law for magnetism
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14.8 Patterns of magnetic field: Ampere’s Law
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14.9 Applications of Ampere’s Law
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14.10 Maxwell’s equations
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15 Week 15
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15.1 Curly electric fields
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15.2 Faraday’s Law (part 1)
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15.3 Faraday’s Law (part 2)
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15.4 Faraday’s Law and motional emf
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15.5 Maxwell's equations (again)
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15.6 Inductance
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15.7 Energy density in magnetic fields
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15.8 The Ampere-Maxwell Law
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15.9 Fields traveling through space (part 1)
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15.10 Fields traveling through space (part 2)
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