Wednesday, Nov. 6, 2002
... Since the kinetic energy at the bottom of the hill must be equal to the potential energy at the top of the hill 1 I CM ...
... Since the kinetic energy at the bottom of the hill must be equal to the potential energy at the top of the hill 1 I CM ...
Rotational Dynamics SL and Honors 2016 2017
... • Note how the force vector in this figure has been broken up into its’ perpendicular and parallel components as shown. • This second method (which I like better) is to let the lever arm be the distance from the axis to the force, shown here as “r” and then just use the perpendicular component of th ...
... • Note how the force vector in this figure has been broken up into its’ perpendicular and parallel components as shown. • This second method (which I like better) is to let the lever arm be the distance from the axis to the force, shown here as “r” and then just use the perpendicular component of th ...
Class XI-Physics 2016-17
... Name the forces having the longest and shortest range of operation. When momentum of a body is doubled, how will its kinetic energy change? What is meant by a geostationary satellite? When does the streamline flow become turbulent? Find the dimensions of a and b in the equation E = (b-x2)/at where E ...
... Name the forces having the longest and shortest range of operation. When momentum of a body is doubled, how will its kinetic energy change? What is meant by a geostationary satellite? When does the streamline flow become turbulent? Find the dimensions of a and b in the equation E = (b-x2)/at where E ...
Slides for Chapters 9, 10, 11 and Review
... cable around a solid cylinder with mass M and radius R. The cylinder rotates with negligible friction about a stationary horizontal axis. We tie the free and of the cable to a block of mass m and release the block from rest at distance h above the floor. As the block falls, the cable unwinds without ...
... cable around a solid cylinder with mass M and radius R. The cylinder rotates with negligible friction about a stationary horizontal axis. We tie the free and of the cable to a block of mass m and release the block from rest at distance h above the floor. As the block falls, the cable unwinds without ...
Rotational Motion
... points in the object maintain the same relative position. When the object rotates, every point rotates through the same angle. The angle θ, measured relative to some starting position, gives the angular position of every point in the object. ...
... points in the object maintain the same relative position. When the object rotates, every point rotates through the same angle. The angle θ, measured relative to some starting position, gives the angular position of every point in the object. ...
Unit 4 Practice Test: Rotational Motion
... horizontal component of this force, Fh, is the centripetal force and this force Fc = mrω2. However, if F increases so does its vertical component. When F is large enough so that its vertical component is equal to the weight of the child, the child’s feet leave the ground. 36. Mass resists changes in ...
... horizontal component of this force, Fh, is the centripetal force and this force Fc = mrω2. However, if F increases so does its vertical component. When F is large enough so that its vertical component is equal to the weight of the child, the child’s feet leave the ground. 36. Mass resists changes in ...
