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Lecture Outline Chapter 10 Physics, 4th Edition James S. Walker
Copyright © 2010 Pearson Education, Inc.
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Rotational Kinematics and Energy
Chapter 10 Rotational Kinematics and Energy
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Units of Chapter 10 Angular Position, Velocity, and Acceleration
Rotational Kinematics Connections Between Linear and Rotational Quantities Rolling Motion Rotational Kinetic Energy and the Moment of Inertia Conservation of Energy
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10-1 Angular Position, Velocity, and Acceleration
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10-1 Angular Position, Velocity, and Acceleration
Degrees and revolutions:
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10-1 Angular Position, Velocity, and Acceleration
Arc length s, measured in radians:
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10-1 Angular Position, Velocity, and Acceleration
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10-1 Angular Position, Velocity, and Acceleration
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10-1 Angular Position, Velocity, and Acceleration
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10-1 Angular Position, Velocity, and Acceleration
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10-2 Rotational Kinematics
If the angular acceleration is constant:
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10-2 Rotational Kinematics
Analogies between linear and rotational kinematics:
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10-3 Connections Between Linear and Rotational Quantities
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10-3 Connections Between Linear and Rotational Quantities
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10-3 Connections Between Linear and Rotational Quantities
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10-3 Connections Between Linear and Rotational Quantities
This merry-go-round has both tangential and centripetal acceleration.
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10-4 Rolling Motion If a round object rolls without slipping, there is a fixed relationship between the translational and rotational speeds:
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10-4 Rolling Motion We may also consider rolling motion to be a combination of pure rotational and pure translational motion:
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10-5 Rotational Kinetic Energy and the Moment of Inertia
For this mass,
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10-5 Rotational Kinetic Energy and the Moment of Inertia
We can also write the kinetic energy as Where I, the moment of inertia, is given by
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10-5 Rotational Kinetic Energy and the Moment of Inertia
Moments of inertia of various regular objects can be calculated:
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10-6 Conservation of Energy
The total kinetic energy of a rolling object is the sum of its linear and rotational kinetic energies: The second equation makes it clear that the kinetic energy of a rolling object is a multiple of the kinetic energy of translation.
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10-6 Conservation of Energy
If these two objects, of the same mass and radius, are released simultaneously, the disk will reach the bottom first – more of its gravitational potential energy becomes translational kinetic energy, and less rotational.
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Summary of Chapter 10 Describing rotational motion requires analogs to position, velocity, and acceleration Average and instantaneous angular velocity: Average and instantaneous angular acceleration:
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Summary of Chapter 10 Period:
Counterclockwise rotations are positive, clockwise negative Linear and angular quantities:
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Summary of Chapter 10 Linear and angular equations of motion:
Tangential speed: Centripetal acceleration: Tangential acceleration:
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Summary of Chapter 10 Rolling motion: Kinetic energy of rotation:
Moment of inertia: Kinetic energy of an object rolling without slipping: When solving problems involving conservation of energy, both the rotational and linear kinetic energy must be taken into account.
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