Two particle A & B each of mass `m` are in equilibrium in a vertical plane under action of a horizontal force `F=mg` on particle B, as shown in figure Then :

Two particles A and B, each of mass m, are kept stationary by appyling a horizontal force F=mg on particle B as shown in fig.

Two partical A and B each of mass m are kept stationary by applying a horizontal force F = mg on partical B as show in figure .Then

A rod of mass m and length L is hinged at its top end. If the rod is in equilibrium making an angle of 30^(@) with the vertical when a horizontal force F is applied as shown in figure, then the value of F is:

Four particles each of mass M, move along a circle of radius R under the action of their mutual gravitational attraction as shown in figure. The speed of each particle is :

A particle of mass m is suspended from point O and undergoes circular motion in horizontal plane as conical pendulum as shown in figure.

A particle is projected in a smooth fixed square tube from point A. The tube is in vertical plane and D and B are at same horizontal level as shown in figure. Then : (Assume velocity of particle changes smoothly at corners)

Three particles, each of mass m are fixed at the vertices of an equilateral triangle of side length a . The only forces acting on the particles are their mutual gravitational forces. Then answer the following questions. Force acting on particle C , due to particle A and B

A block of mass m is taken from A to B under the action of a constant force F. Work done by this force is

Two particles each of mass M are connected by a massless rod. The rod is lying on the smooth horizontal surface. If one of the particle is given an impulse MV as shown in the figure then angular velocity of the system would be:

Can two particles be in equilibrium under the action of their mutual gravitational force? Can three particle be? Can one of the three particles be?