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1/17/20068.01L IAP 2006  Last Lecture  Everything you need to know about dynamics of rotation  Today  Pendulums and Kinetic Energy of rotation  Important.

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Presentation on theme: "1/17/20068.01L IAP 2006  Last Lecture  Everything you need to know about dynamics of rotation  Today  Pendulums and Kinetic Energy of rotation  Important."— Presentation transcript:

1 1/17/20068.01L IAP 2006  Last Lecture  Everything you need to know about dynamics of rotation  Today  Pendulums and Kinetic Energy of rotation  Important Concepts  Equations for angular motion are mostly identical to those for linear motion with the names of the variables changed.  Kinetic energy of rotation adds a new term to the same energy equation, it does not add a new equation.  Kinetic energy can be simply written as a linear term and a rotational term

2 1/17/20068.01L IAP 2006 Important Reminders  Contact your tutor about session scheduling  Mastering Physics due tomorrow at 10pm.  Pset due this Friday at 11am.

3 1/17/20068.01L IAP 2006 Pendulums  Simple pendulum: Small mass at the end of a string  Period is where l is the length from the pivot to the center of the object.  Physical pendulum: More complex object rotating about any pivot  Period is where l is the distance from the pivot to the center of mass of the object, M is the total mass, and I is the moment of inertia around the pivot.

4 1/17/20068.01L IAP 2006 Parallel Axis Theorum  Very simple way to find moment of inertia for a large number of strange axis locations.  I 1 = I c.m. + Md 2 where M is the total mass. d c.m. Axis 1

5 1/17/20068.01L IAP 2006 Kinetic Energy with Rotation  Adds a new term not a new equation!  Rotation around any fixed pivot:  Moving and rotating:

6 1/17/20068.01L IAP 2006 Everything you need to know for Linear & Rotational Dynamics    This is true for any fixed axis and for an axis through the center of mass, even if the object moves or accelerates.  Rolling without slipping:  Friction does NOT do work!  Rolling with slipping:  Friction does work, usually negative.  Rarely solvable without using force and torque equations!

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