The system is released from rest. All surface are smooth . Find the angle theta at which the acceleration of wedge is maximum. ( given .`M/m=1/2`)

All the surfaces are smooth as shown in figure. The acceleration of mass m relative to wedge is :

In the adjoining figure, block A is of mass (m) and block B is of mass 2m. The spring has force constant k. All the surfaces are smooth and the system is released form rest with spring unstretched. Find the maximum extension in the spring and acceleration of block B at time of maximum extension .

All surface are smooth. Find the acceleration of mass m relative to wedge when wedge is moving with acceleration 'a'

A block of mass 'm' is kept on a smooth moving wedge. If the acceleration of the wedge is 'a'

In fig. mass m is being pulled on the incline of a wedge of mass M. All the surfaces are smooth. Find the acceleration of the wedge.

In the following figure all surfaces are smooth. The system is released from rest , then A. acceleration of wedge greater then g tanθ B. acceleration of m is g√(1+2cos⁡^2θ) C. acceleration of m is g D. acceleration of wedge is g sinθ

A block of mass m lies on a wedge of mass M. The wedge in turn lies on smooth horizontal surface. Friction is absent everywhere. The wedge block system is released from rest. All situations given in Table-1 are tol be estimated in the duration the block undergoes a vertical displacement 'h' starting from rest. Match the statement in Table-1 with the results in Table-2 ltbgt

In the system shown in figure all surfaces are smooth. Strings is massless and inextensible.Find acceleration of the system and tension T in the string (g=10m//s^(2))

A mass m_(1) lies on fixed, smooth cylinder . An ideal cord attached to m_(1) passes over the cylinder and is connected to mass m_(2) as shown in the figure. (a) Find the value of theta ( shown in diagram ) for which the system is in equilibrium. (b) Given m_(1)=5 kg, m_(2)=4kg . The system is released from rest when theta =30^(@) . Find the magnitude of acceleration of mass m_(1) just after the system is released.

All surfaces shown in figure are smooth. System is released from rest. x and y comonents of acceleration of COM are