The linear mass density , i.e mass per unit length of the rope as shown in figure , varies 0 to `lambda` from one end to another . The acceleration of the combined system of figure will be

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

A rod of mass m and length l is hinged at one of its end A as shown in figure. A force F is applied at a distance x from A. The acceleration of centre of mass a varies with x as

If linear charge density of a wire as shown in the figure is lambda

A rod of mass m and length l is hinged at one of its ends A as shown in figure. A force F is applied at a distance x from A . The acceleration of centre of mass varies with x as -

A rod of mass m and length l is hinged at one of its ends A as shown in figure. A force F is applied at a distance x from A . The acceleration of centre of mass varies with x as -

In the system shown in the figure, the acceleration of 1 kg mass is

Consider the system shown in figure Mass of block A= 3m , Mass of block B= 2m . Find the acceleration of A and B.

The co-ordinates of the centre of mass of the system as shown in figure are

A block A of mass 2m is hanging from a vertical massless spring of spring constant k and is in equilibrium. Another block B of mass m strikes the block A with velocity u and sticks to it as shown in the figure. The magnitude of the acceleration of the combined system of the blocks just after the collision is

The expansion of unit mass of a perfect gas at constant pressure as shown in the figure, then b and a