Three blocks are kept as shown in figure Acceleration of `20 kg` block with respect to ground is

Three blocks are suspended as shown in the figure. The acceleration of the 500 g block is

In the figure shown acceleration of the block is

A block of mass m=5kg is placed on the wedge of mass M=32kg as shown in the figure. Find the acceleration of wedge with respect to ground. (Neglect any type of friction. Spring and pulley are ideal)

Figure shows a block A constrained to slide along the inclined plane of the wedge B shown. Block A is attached with a string which passes through three ideal pulleys and connected to the wedge B. If wedge is pulled toward right with an acceleration a, find (a) the acceleration of the block with respect to wedge (b) the acceleration of the block with respect to ground.

The acceleration of the 10 kg mass block shown in the figure is : -

A spring block system is kept inside the smooth surface of a trolley as shown in figure. At t = 0 trolley is given an acceleration 'a' in the direction shown in figure. Write S - t equation of the block (a) with respect to trolley. (b) with respect to ground.

A block of mass 10 kg is placed on a horizontal surface as shown in the figure and a force F = 100 N is applied on the block as shown, in the figure. The block is at rest with respect to ground. If the contact force between block and ground is 25n (in Newton) then value of n is : (Take g = 10 m//s^(2))

Two blocks of mass 10 kg and 30 kg are kept as shown in the figure. The surface between the block is fricitional while the ground is smooth. A horizontal force of magnitude 60 N is applied horizontally on the upper block. Find the frictional force on block of mass 30 kg ?

A 2 kg block is present against a rough wall by a force F = 20 N as shown in figure .Find acceleration of the block and force of friction acting on it . (Take g = 10 m//s^(2))

A force of F=0.5 N is applied on lower block as shown in figure. The work done by lower block on upper block for a displacement of 3 m of the upper block with respect to ground is (Take, g=10 ms^(-2) )