* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download PH212Chapter10_12
Modified Newtonian dynamics wikipedia , lookup
Tensor operator wikipedia , lookup
Classical mechanics wikipedia , lookup
Coriolis force wikipedia , lookup
Theoretical and experimental justification for the Schrödinger equation wikipedia , lookup
Brownian motion wikipedia , lookup
Photon polarization wikipedia , lookup
Fictitious force wikipedia , lookup
Angular momentum operator wikipedia , lookup
Old quantum theory wikipedia , lookup
Jerk (physics) wikipedia , lookup
Newton's theorem of revolving orbits wikipedia , lookup
Symmetry in quantum mechanics wikipedia , lookup
Moment of inertia wikipedia , lookup
Earth's rotation wikipedia , lookup
Work (physics) wikipedia , lookup
Seismometer wikipedia , lookup
Classical central-force problem wikipedia , lookup
Centripetal force wikipedia , lookup
Newton's laws of motion wikipedia , lookup
Equations of motion wikipedia , lookup
Hunting oscillation wikipedia , lookup
Chapter 10 Rotational Motion (rigid object about a fixed axis) What is meant by a “rigid object”? and a “rigid object about a fixed axis”? Our approach • Introduction to thinking about rotation • Translational – Rotational motion analogy • Angular quantities – constant angular acceleration motion • • • • Torque and Rotational inertia Rotational dynamics problem solving Determining moments of inertial Rotational Kinetic Energy – Energy Conservation • “Rolling friction” - comment Introduction • The goal – Describe rotational motion – Explain rotational motion • Help along the way – Analogy between translation and rotation – Separation of translation and rotation • The Bonus – Easier than it looks – Good review of translational motion – Encounter “modern” topics Introduction • The goal Just like translational motion – Describe rotational motion kinematics – Explain rotational motion dynamics • Help along the way – Analogy between translation and rotation – Separation of translation and rotation • The Bonus – Easier than it looks – Good review of translational motion – Encounter “modern” topics Introduction • The goal – Describe rotational motion – Explain rotational motion • Help along the way A fairy tale – Analogy between translation and rotation – Separation of translation and rotation • The Bonus – Easier than it looks – Good review of translational motion – Encounter “modern” topics Introduction • The goal – Describe rotational motion – Explain rotational motion • Help along the way – Analogy between translation and rotation – Separation of translation and rotation • The Bonus A puzzle – Easier than it looks – Good review of translational motion – Encounter “modern” topics • A book is rotated about a specific vertical axis by 900 and then about a specific horizontal axis by 1800. If we start over and perform the same rotations in the reverse order, the orientation of the object: 1. will be the same as before. 2. will be different than before. 3. depends on the choice of axis. • A book is rotated about a specific vertical axis by 900 and then about a specific horizontal axis by 1800. If we start over and perform the same rotations in the reverse order, the orientation of the object: 1. will be the same as before. 2. will be different than before. 3. depends on the choice of axis. Some implications: Math, Quantum Mechanics … interesting!!! Translational - Rotational Motion Analogy • What do we mean here by “analogy”? – Diagram of the analogy (on board) – Pair learning exercise on translational quantities and laws – Summation discussion on translational quantities and laws • Introduction of angular quantities • Formulation of the specific analogy – Validation of analogy Translational - Rotational Motion Analogy (precisely) If qti corresponds to qri for each translational and rotation quantity, then L(qt1,qt2,…) is a translational dynamics formula or law, if and only if L(qr1,qr2,…) is a rotational dynamics formula or law. (To the extent this is not true, the analogy is said to be limited. Most analogies are limited.) Angular quantities • • • • • • Radians Average and instantaneous quantities Translational-angular connections Example Example Vector nature (almost) of angular quantities – Tutorial on rotational motion Constant angular acceleration • What is expected in analogy with the translational case? • And what is the mathematical and graphical representation for the case of constant angular acceleration? • Example (Physlet E10.2) Torque • Pushing over a block? • Dynamic analogy with translational motion – When angular velocity is constant, what?... – What keeps a wheel turning? • Definition of torque magnitude – 5-step procedure: 1.axis, 2.force and location, 3.line of force, 4.perpendicalar distance to axis, 5. torque = r┴ F – Question – Ranking tasks 101,93 – Example (You create one) Torque and Rotational Inertia • Moment of inertia – Derivation involving torque and Newton’s 2nd Law – Intuition from experience – Definition • Ranking tasks 99,100,98 • …More later… Rotational Dynamics Problem Solving • What are the lessons from translational dynamics? • Use of extended free body diagrams – For what purpose do simple free body diagrams still work very well? • Dealing with both translation and rotation • Examples – inc. Tutorial on Dynamics of Rigid Bodies Questions • How could the moment of inertia of a particular object be determined? • What considerations are important to keep in mind? Determining moment of inertia • • • • • By experiment From mass density Use of parallel-axis theorem Use of perpendicular-axis theorem Question – Ranking tasks 90,91,92 – Proposed experiment Rotational kinetic energy & the Energy Representation • Rotational work, kinetic energy, power • Conservation of Energy – Rotational kinetic energy as part of energy – question • Rolling motion – question • Rolling races – question • Jeopardy problems 1 2 3 4 • Examples “Rolling friction” • Optional topic • Worth a look, comments only The end • Pay attention to the Summary of Rotational Motion. • A disk is rotating at a constant rate about a vertical axis through its center. Point Q is twice as far from the center of the disk as point P is. Draw a picture. The angular velocity of Q at a given time is: 1. 2. 3. 4. twice as big as P’s. the same as P’s. half as big as P’s. None of the above. back • When a disk rotates counterclockwise at a constant rate about the vertical axis through its center (Draw a picture.), the tangential acceleration of a point on the rim is: 1. 2. 3. 4. positive. zero. negative. not enough information to say. back • 1. 2. 3. 4. A wheel rolls without slipping along a horizontal surface. The center of the wheel has a translational speed v. Draw a picture. The lowermost point on the wheel has a net forward velocity: 2v v zero not enough information to say back • 1. 2. 3. 4. The moment of inertia of a rigid body about a fixed axis through its center of mass is I. Draw a picture. The moment of inertia of this same body about a parallel axis through some other point is always: smaller than I. the same as I. larger than I. could be either way depending on the choice of axis or the shape of the object. back • A ball rolls (without slipping) down a long ramp which heads vertically up in a short distance like an extreme (and dysfunctional) ski jump. The ball leaves the ramp straight up. Refer to picture. Assume no air drag and no mechanical energy is lost, the ball will: 1. reach the original height. 2. exceed the original height. 3. not make the original height. back (5kg)(9.8m/s2)(10m) = (1/2)(5kg)(v)2 + (1/2)(2/5)(5kg)(.1m)2(v/(.1m))2 Draw a picture and label relevant quantities. back (5kg)(9.8m/s2)(10m) = (1/2)(5kg)(v)2 + (1/2)(2/5)(5kg)(.1m)2(v/(.1m))2 (5kg)(9.8m/s2)(h) = (1/2)(5kg)(v)2 Draw a picture and label relevant quantities. back (1/2)(5kg)(.1m/s)2 + (1/2)(1/2)(5kg)(.2m)2(.1m/s/(.1m))2 = (1/2)(5kg)(v)2 + (1/2)(1/2)(5kg)(.2m)2(v/(.2m))2 Draw a picture and label relevant quantities. back • • Suppose you pull up on the end of a board initially flat and hinged to a horizontal surface. How does the amount of force needed change as the board rotates up making an angle Θ with the horizontal? a. Decreases with Θ b. Increases with Θ c. Remains constant back • Several solid spheres of different radii, densities and masses roll down an incline starting at rest at the same height. • In general, how do their motions compare as they go down the incline, assuming no air resistance or “rolling friction”? Make mathematical arguments on the white boards. back (1kg)(9.8m/s2)(1m) = (1/2)(1/2)(.25kg)(.05m)2(v/.05m)2 + (1/2)(1kg)v2 Draw a picture and label relevant quantities. back