A force F is applied horizontally on mass `m_(1)` as shown in figure. Find the contact force between `m_(1)` and `m_(2)`

Two blocks of masses '3m' and '2m' are in contact on a smooth table. A force P is first applied horizontally on block of mass '3 m' and then on mass '2m'. The contact forces between the two blocks in the two cases are in the ratio:

Two blocks of masses '3m' and '2m' are in contact on a smooth table. A force P is first applied horizontally on block of mass '3m' and then on mass '2m'. The contact forces between the two blocks in the two cases are in the ratio?

Two blocks of masses '3m' and '2m' are in contact on a smooth table. A force P is first applied horizontally on block of mass '3 m' and then on mass '2m'. The contact forces between the two blocks in the two cases are in the ratio:

Two blocks A and B of masses m and M are attached with ideal string and pulley, and placed on smooth horizontal surface. Force F is applied horizontally as shown in figure. Find the ratio of the acceleration of A to that of B.

Two blocks A and B of masses m and M are attached with ideal string and pulley, and placed on smooth horizontal surface. Force F is applied horizontally as shown in figure. Find the ratio of the acceleration of A to that of B.

A constant force F=m_2g/s is applied on the block of mass m_1 as shown in figure. The string and the pulley are light and the surface of the table is smooth. Find the acceleration of m_1

A constant force F=m_2g/s is applied on the block of mass m_1 as shown in figure. The string and the pulley are light and the surface of the table is smooth. Find the acceleration of m_1

A constant force F = m_(2)g//2 is applied on the block of mass m_(1) as shown in fig. The string and the pulley are light and the surface of the table is smooth. The acceleration of m_(1) is :

A constant force F = m_(2)g//2 is applied on the block of mass m_(1) as shown in fig. The string and the pulley are light and the surface of the table is smooth. The acceleration of m_(1) is :

The arrangement shown in the figure, the systme of masses m_(1), m_(2) and m_(3) is being pushed by a force F applied on m_(1) horizontally. In order to prevent the downwards slipping of m_(2) between m_(1) and m_(3) if coefficient of friction between m_(2) and m_(3) is mu and all the other surface are smooth, the minimum value of F :