A hoop of radius R and mass M is hung from a nail and displaced from...

A hollow cylinder (hoop) of mass M and radius R starts rolling without slipping (with negligible...

A hollow cylinder (hoop) of mass M and radius R starts rolling without slipping (with negligible initial speed) from the top of an inclined plane with angle theta. The cylinder is initially at a height h from the bottom of the inclined plane. The coefficient of friction is u. The moment of inertia of the hoop for the rolling motion described is I= mR^2. a) What is the magnitude of the net force and net torque acting on the hoop?...

8. As in the diagram at right, a uniform cylindrical spool of mass M and radius...

8. As in the diagram at right, a uniform cylindrical spool of mass M and radius R unwinds an essentially mass-less rope under the weight of a mass m. If R = 12 cm, M = 400 gm and m = 50 gm, find the speed of m after it has descended 50 cm starting from rest. Solve the problem using Newton's laws.

A circular hoop (?hoop ?? ) of mass ? 5.00 kg, radius ? 2.00 m, and...

A circular hoop (?hoop ?? ) of mass ? 5.00 kg, radius ? 2.00 m, and infinitesimal thickness rolls without slipping down a ramp inclined at an angle ? 32.0° with the horizontal. (a) Draw a free body diagram of the hoop. [1] (b) Determine the magnitude of the hoop’s acceleration down the ramp. [4] (c) Determine the force of static friction on the hoop. [3]

A very thin circular hoop of mass m and radius r rolls without slipping down a...

A very thin circular hoop of mass m and radius r rolls without slipping down a ramp inclined at an angle θ with the horizontal, as shown in the figure. What is the acceleration a of the center of the hoop?

A uniform thin rod of length 0.984 m is hung from a horizontal nail passing through...

A uniform thin rod of length 0.984 m is hung from a horizontal nail passing through a small hole in the rod located 0.081 m from the rod's end. When the rod is set swinging about the nail at small amplitude, what is the period of oscillation? period of oscillation:

A uniform thin rod of length 0.766 m is hung from a horizontal nail passing through...

A uniform thin rod of length 0.766 m is hung from a horizontal nail passing through a small hole in the rod located 0.044 m from the rod's end. When the rod is set swinging about the nail at small amplitude, what is the period T of oscillation? T=______ s

A hoop of mass M and radius R, initially at rest, falls onto a disk of...

A hoop of mass M and radius R, initially at rest, falls onto a disk of the same mass and radius but an initial angular speed of ω1. There’s friction between the hoop and disk, but there’s no net external torque on the system consisting of the hoop and disk. (). a. For this process, the kinetic energy of the system consisting of the hoop and disk is conserved. True/False? b.For this process, the angular momentum of the system consisting...

A hoop (rotational inertia I=MR2 ) of mass M = 1.6 kg and radius R =...

A hoop (rotational inertia I=MR2 ) of mass M = 1.6 kg and radius R = 50 cm is rolling on a flat surface at a center-of-mass speed of v = 1.2 m/s. Part A The total kinetic energy of the rolling hoop can be expressed as The total kinetic energy of the rolling hoop can be expressed as 34Mv2 12Mv2 Mv2 56Mv2 32Mv2 Request Answer Part B If an external force does 16 J of a positive work on...

A hoop (rotational inertia ) of mass 2.00 kg and radius 0.50 m is rolling at...

A hoop (rotational inertia ) of mass 2.00 kg and radius 0.50 m is rolling at a centerof-mass speed of 2.50 m/s. An external force does 75.0 J of a positive work on the hoop. (a) Calculate the initial total kinetic energy KE and (b) find the new speed of the hoop. (hint: W = ∆KE = KEf − KEi , KE = KEtrans + KErot, w = v/R)

Problem 4 A hoop and a solid disk both with Mass (M=0.5 kg) and radius (R=...

Problem 4 A hoop and a solid disk both with Mass (M=0.5 kg) and radius (R= 0.5 m) are placed at the top of an incline at height (h= 10.0 m). The objects are released from rest and rolls down without slipping. a) The solid disk reaches to the bottom of the inclined plane before the hoop. explain why? b) Calculate the rotational inertia (moment of inertia) for the hoop. c) Calculate the rotational inertia (moment of inertia) for the...