In the given figure, Find mass of the block A, if it remains at rest, when the system is released from rest. Pulleys and strings are massless. `[g=10m//s^(2)]`

Find the mass M so that it remains at rest in the abjoining figure. Both the pulley and string are light and friction is absent everywhere. (g = 10 m//s^(2))

The block of mass m is at rest. Find the tension in the string A .

In the arrangement shown in figure, what should be the mass of block A so that the system remains at rest. Also find force exerted by string on the pulley Q. (g = 10 m//s^(2))

In the system shown in figure, the block A is released from rest. Find Tension in the string.

Consider the situation as shown. Initially the spring is unstretched when the block of mass m is released from rest assuming the pulley frictionless and light the spring and string massless. Find the extension of sprinig when the block is in equilibrium also find the maximum extension of the spring.

In the figure given below, with what acceleration does the block of mass m will move? (Pulley and strings are massless and frictionless)

In the figure given below, with what accelerating does the block of mass m will move? ( Pulley and strings are massless and frictionless)

An arrangement of the masses and pulleys is shown in the figure. Strings connecting masses A and B with pulley are horizontal and all pulleys and strings are light. Friction coefficient between the surface and the block B is 0.2 and between block A and B is 0.7 . The system is released from rest. (use g=10m//s^(2))