Figure shows a block of mass 2m sliding on a block of mass m. Find the acceleration of each block . ( All surface are smoth )

Figure shows a block of mass m_(1) sliding on a block of mass m_(2) , with m_(1) gt m_(2) . Find the (a) acceleration of each block (b) tension in the string (c ) force exerted by m_(1) on m_(2) . ltbr. (d) force exerted by m_(2) on the incline.

A block of mass m slides down a rough inclined plane with an acceleration g/2

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 .

In the adjoining figure, block A is of mass (m) and block B is of mass2 m. The spring has force constant k. All the surfaces are smooth and the system is released form rest with spring unstretched. .

Two block of masses m_(1) and m_(2) are placed side by side on a smooth horizontal surface as shown in fig. A horizontal force F is applied on the block . (a) Find the acceleration of each block. (b) Find the normal reaction between the two blocks.

Two blocks are placed at rest on a smooth fixed inclined place. A force F acts on block of mass m_1 and is parallel to the inclined plane as shown in figure. Both blocks move up the incline. Then (i) Draw free body diagram blocks of mass m_1 and blocks mass m_2 (ii) Find acceleration of blocks of mass m_1 and blocks mass m_2 (iii) Find normal reaction between the blocks of mass m_1 and m_2

Two blocks of masses m_1 and m_2 are connected as shown in the figure. The acceleration of the block m_2 is :

A block of mass m is placed on a triangular block of mass M(M = 2m) , as shown. All surfaces are smooth. Calculate the velocity of triangular block when the smaller block reaches at bottom.

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

In the figure shown, all surfaces are smooth and the pulley is massless. A constant force of magnitude F = (mg)/(2) is acting on the block of mass M. The acceleration of the block M is :