A small bell starts moving from `A` over `a` fixed track as shown in the figure . Surface `AB` is friction from `A` to `B` the bell roll ralis without sipping `BC` is friction , `K_(A)K_(B)` and` K_(C)` are kinetic energy of the bell at `A, B` and `C` respacecvely.Then

A ball moves over a fixed track as shown in the figure. From A to B the ball rolls without slipping. If surface BC is frictionless and K_(A),K_(B) and K_(C) are kinetic energies of the ball at A, B and C respectively then (a). h_(A)gth_(C),K_(B)gtK_(C) (b). h_(A)gth_(C),K_(C)gtK_(A) (c). h_(A)=h_(C),K_(B)=K_(C) (d). h_(A)lth_(C),K_(B)gtK_(C)

A small block of mass m slides along a smooth frictional track as shown in the figure. If it starts from rest at P, what is the resultant force acting on it at Q?

Three weights are hanging over a smooth fixed pulley as shown in the figure. What is the tension in the string connecting weights B and C ?

Portion AB of the wedge shown in figure is rough and BC is smooth. A solid cylinder rolld without slipping from A to B . Find the ratio of translational kinetic energy to rotational kinetic energy, when the cylinder reaches point C . .

A wire, which passes through the hole in a small bead, is bent in the form of quarter of a circle. The wire is fixed vertically on ground as shown in the figure. The bead is released from near the top of the wire and it slides along the wire without friction. As the bead moves from A to B, the force it applies on the wire is

A sphere is rolling without slipping on a fixed horizontal plane surface. In the figure, A is the point of contact, B is the centre of the sphere and C is its topmost point. Then

In the figure shown, force of friction on A from B will always be right wards Friction always opposes the relative motion between two bodies in contact.

Two blocks A and B of equal masses are released on two sides of a fixed wedge C as shown in figure. Find the acceleration of centre of mass of blocks A and B. Neglect friction.

Three identical solid spheres move down three incline A, B and C are all of the same dimensions. A is without friction, the friction between B and a sphere is sufficient to cause rolling without slipping, the friction between C and a sphere causes rolling with slipping. The kinetic energies, of A, B, C at the bottom of the inclines are E_(A),E_(B),E_(C) .

A solid sphere of mass m is placed on a rough incline plane as shown in figure. The coefficient of friction (mu) is insufficient to start pure rolling. The sphere slides length l on incline from rest and its kinetic energy becomes k. Then work done by friction will be