In the figure shown a ring of mass M and a block of mass m are in equilibrium. The string is light and pulley P does not offer any friction and coefficient of friction between pole and M is `mu.` The frictional force offered by the pole to M is

A block of mass m=2kg is placed in equilibrium on a moving plank accelerating with a=4m//s^(2) . If coefficient of friction between plank and block mu=0.2 . The friction force acting on theblock is:

A block of mass m=2kg is placed in equilibrium on a moving plank accelerating with a=1m//s^(2) . If coefficient of friction between plank and block mu=0.2 . The friction force acting on theblock is:

A wedge of mass 2m and a cube of mass m are shown in figure. Between cube and wedge, there is no friction. The minimum coefficient of friction between wedge and ground so that wedge does not move is

Find the minimum force required to keep a block of mass m in equilibrium on a rough inclined plane with inclination alpha and coefficient of friction mu( lt tan alpha) .

A block of mass m is stationary on a horizontal surface. It is connected with a string which has no tension. The coefficient of friction between the block and surface is m . Then , the frictional force between the block and surface is:

In the arrangement shown in figure, coefficient of friction between the two blocks is mu=1//2 . The force of friction acting between

A block of mass m is placed at rest on an inclination theta to the horizontal.If the coefficient of friction between the block and the plane is mu , then the total force the inclined plane exerts on the block is

Figure-2.84 shows a man ofmass M standing on a board of mass m.What minimum force is required to exert on string to slide the board. The friction coefficient between board and floor is mu and there is sufficient friction between man and board so that man does not slip. [(mu(M+m)g)/(1+mu)]