A cylinder is released from rest from the top of an incline of inclination `theta` and length 'L'. If the cylinder rolls without slipping. What will be its speed when it reaches the bottom?

A hollow sphere is released from top of an inclined plane of inclination 30º and length of inclined plane is /. If sphere rolls without slipping then its speed at bottom is

A solid cylinder is rolling down a rough inclined plane of inclination theta . Then

Two objects, a ring and a spherical shell of same mass and radius are released from the top of two Identical inclined plane. If they are rolling without slipping, then ratio of speed of center of mass of the two objects when they will reach the bottom of the inclined plane is

A solid cylinder of mass M and radius R rolls down an inclined plane of height h without slipping. The speed of its centre when it reaches the bottom is.

A solid cylinder of mass M and radius R rolls down an inclined plane without slipping. THE speed of its centre of mass when it reaches the bottom is

A solid cylinder and a solid sphere, both having the same mass and radius, are released from a rough inclined plane of inclination theta one by one. They roll on the inclined plane without slipping. The force of friction that acts

A uniform cylinder of mass M and radius R is released from rest on a rough inclined surface of inclination theta with the horizontal as shown in figure. As the cylinder rolls down the inclined surface, the maximum elongation it the spring stiffness k is

Two uniform solid spheres having unequal radii are released from rest from the same height on a rough incline. If the spheres roll without slipping

A solid cylinder rolls up an inclined plane of inclination theta with an initial velocity v . How far does the cylinder go up the plane ?

A ring starts to roll down the inclined plane of height h without slipping . The velocity when it reaches the ground is