In the system shown in figure the friction coefficient between ground and bigger block is `mu`. There is no frinction between both the blocks. The string connecting both the block is light, all three pulleys are light and frictionless. Then the minimum limiting value of `mu` so that the system remains in equilibrium is

In the system shown in Fig the friction coefficient between ground and bigger block is mu There is no friction between both the block .The string connecting both the block is light all three pulley are light and frictionless Then the minimum limiting value of mu so that the system remain in equilibrium , is

In the system shown in Fig the friction coefficient between ground and bigger block is mu There is no friction between both the block .The string connecting both the block is light all three pulley are light and frictionless Then the minimum limiting value of mu so that the system remain in equilibrium , is

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

If coefficient of friction between both the block is mu- (1)/(2) . Find friction force acting between both block.

For the arrangement shown in the figure the coefficient of friction between the two blocks is mu . If both the blocks are identical and moving ,then the acceleration of each block is

For the arrangement shown in the figure the coefficient of friction between the two blocks is mu . If both the blocks are identical and moving ,then the acceleration of each block is

Two blocks A and B are lying on the table as shown in the figure. The coefficient of friciton between block A and block B is mu . The coefficient of friction between block B and ground also mu . An external force F is applied in the direction shown. The maximum value of the force F that can be applied without moving the blocks.

Two blocks A and B are lying on the table as shown in the figure. The coefficient of friciton between block A and block B is mu . The coefficient of friction between block B and ground also mu . An external force F is applied in the direction shown. The maximum value of the force F that can be applied without moving the blocks.

The coefficient of friction between the block A of mass m & block B of mass 2m is mu . There is no friction between block B & the inclined plane. If the system of blocks A & B is released from rest & there is no slipping between A & B then :

In the arrangement shown in figure, pulley and string are light. Friction coefficient between the two blocks is mu whereas the incline is smooth. Block A has mass m and difference in mass of the two blocks is deltam . Find minimum value of m for which the system will not accelerate when released from rest.