A cylinder is rolling without slipping on a horizontal plane `P`. The friction between the plank `P` and the cylinder is sufficient for no slipping. The coefficient of friction between the plank and the ground surface is zero. Initially, `P` is attached with a string `S` as shown in the figure. If the string is now burned, then.

A sphere S rolls without slipping moving with a constant speed on a plank P . The friction between the upper surface of P and the sphere is sufficient to prevent slipping, while the lower surface of P is smooth and rest on the ground. Initially P is fixed on the ground by a pin N . If N is suddenly removed

A solid cylinder is rolling without slipping on a plane having inclination theta and the coefficient of static friction mu_(s) . The relation between theta and mu_(s) is

A cylinder of radius R is to roll without slippoing between two planks as shown in the figure. Then

If a solid cylinder rolls without slipping on an inclined plane of inclination 45° then the minimum coefficient of friction required to support pure rolling is

Show that a cylinder will slip on an inclined plane if the coefficient of static friction between the plane and the cylinder is less than 1/3tantheta where theta is the angle of the inclination with the horizontal.

If a solid cylinder rolls without slipping on an inclined plane of inclination 45°, then the minimum coefficient of friction required to support pure rolling is

A small block of mass 'm' is placed on a plank of mass 'M'. The block is connected to plank with the help of a light string passing over a light smooth pulley as shown in figure. The co-efficient of static friction between the block and plank is mu . The co-efficient of friction between the plank and the horizontal surface is zero. What maximum horizontal force F applied on the block of mass m can make the block and plank not to slide relatively?

A solid cylinder is rolling down on an inclined plane of angle theta . The minimum value of the coefficient of friction between the plane and the cylinder to allow pure rolling

A cylinder of radius R and mass M rolls without slipping down a plane inclined at an angle theta . Coeff. of friction between the cylinder and the plane is mu . For what maximum inclination theta , the cylinder rolls without slipping ?

A solid cylinder rolls without slipping down a 30^@ slope. The minimum coefficient of friction needed to prevent slipping, will be