For what value of M will the masses be in equilibrium. Masses are placed on fixed wedge :

A wedge of mass m_(1) and a block of mass m_(2) are in equlibrium as shown. Inclined surface of the wedge has an inclination alpha with the horizontal. Each surface is frictionless. The noram reaction on the wedge may be -

A mass M is attached to a horizontal spring of force constant k fixed one side to a rigid support as shown in figure. The mass oscillates on a frictionless surface with time period T and amplitude A. When the mass M is in equilibrium position, another mass m is gently placed on it. When will be the new amplitude of ocillation?

In fig, all the pulleys and strings are massless and all the surfaces are frictionless. A small block of mass m is placed on fixed wedge (take f=10ms^(-2) ). The acceleration of m is

In fig, all the pulleys and strings are massless and all the surfaces are frictionless. A small block of mass m is placed on fixed wedge (take f=10ms^(-2) ). The tension in the string attached to m is

Coefficient of friction between block of mass m and fixed wedge is mu = 0.5 . For what value of (m)/(M) frictional force between block of mass m and wedge becomes zero ?

Block A of mass m is placed over a wedge of same mass m. Both the block and wedge are placed on a fixed inclined plane. Assuming all surfaces to be smooth calculate the displacement of the block A in ground frame in 1s .

Block A of mass m is placed over a wedge of same mass m. Both the block and wedge are placed on a fixed inclined plane. Assuming all surfaces to be smooth, the displacement of the block A in ground frame in 1s is (gsin^(2)theta)/(x+sin^(2)theta) then the value of x is:

A block of mass m is at rest over the rough surface of the fixed wedge.

A block of mass m is initially lying on a wedge of mass M with an angle of inclination theta as shown in figure. Calculate the displacement of the wedge when the block is released and reaches to the bottom of the wedge.