A massless rope is wrapped around a ring (with a groove along its circumference) having radius `R` and mass `m`. The ring is allowed to move download. The linear acceleration of the ring is

An impulse J is applied on a ring of mass m along a line passing through its centre O . The ring is placed on a rough horizontal surface. The linear velocity of centre of ring once it starts rolling without slipping is

Find the centre of mass of a uniform semicircular ring of radius R and mass M .

A vertical cylindrical region has a horizontal radial magnetic field inside it. A wire ring is made of a wire of cross section S, density d and resistivity rho . Radius of the ring is r. The ring is kept horizontal with its centre on the axis of the cylindrical region and released. The field strength at all points on the circumference of the ring is B. At a certain instant velocity of the ring is v downward. Find (a) Current in the ring and (b) Acceleration of the ring at the instant.

A uniform semicurcular ring having mass m and radius r is hanging at one of its ends freely as shown if Fig. The ring is slightly disturbed so the it oscillates in its own plane. The time period of oscillation of the ring is

A particle of mass m is rigidly attached at A to a ring of mass 3m and radius r . The system is released from rest and rolls without sliding. The angular acceleration of ring just after release is

A uniform rope tightly wraps around a uniform thin ring the mass M and radius R. The mass of the segment of the rope around the ring (i.e. , mass of the length 2 pi R of the rope) is also M. The ends of the rope are fixed one above the other and it is taut. The ring is let go. Find its acceleration. Assume no slipping and thickness of the rope to be negligible.

A point mass m = 1 kg is attached to a point P on the circumference of a uniform ring of mass M = 3kg and radius R = 2.0 m . The ring is placed on a horizontal surface and is released from rest with line OP in horizontal position (O is centre of the ring). Friction is large enough to prevent sliding. Calculate the following quantities immediately after the ring is released- (a) angular acceleration (alpha) of the ring, (b) normal reaction of the horizontal surface on the ring and (c) the friction force applied by the surface on the ring. [Take g = 10 m//s^(2) ]

A smooth ring of mass m and radius R = 1 m is pulled at P with a constant acceleration a= 4 ms^(-2) on a horizontal surface such that the plane of the ring lies on the surface. Find the angular acceleration of the ring at the given position. (in rad//s^(2) )

A ring is allowed to roll down on an incline of 1 in 10 without slipping. The acceleration of its centre of mass is