The string and the pulley are massless and the system is in equilibrium. Find the ratio of Tension `T_(A)` and `T_(B)`

If 'O' is at equilibrium then the values of the tension T_(1) and T_2 respectively.

In the figure shown, the strings and pulleys are massless. The blocks are in equilibrium. If the force by the clamp on the pulley is sqrt(8/3) mg then (M)/(m) is equal to

In the arrangment shown in the figure, the ratio of tensions T_(1): T_(2) : T_(3) is:

In the system shown in figure pully is smooth. Strings is massless and inextensible.Find acceleration of the system a, tension T_(1) and T_(2) (g=10m//s^(2))

The system shown in the figure is in equilibrium at rest. The spring and string are massless Now the string is cut. Find the acceleration of the blocks just after the string is cut.

Consider the system of masses and pulleys shown in fig. with massless string and fricitionless pulleys. (a) Give the necessary relation between masses m_(1) and m_(2) such that system is in equilibrium and does not move. (b) If m_(1)=6kg and m_(2)=8kg , calculate the magnitude and direction of the acceleration of m_(1) .

In the figure the masses of the blocks A and B are same and each equal to m. The tensions in the strings OA and AB are T_(2) and T_(1) respectively. The system is in equilibrium with a constant horizontal force mg on B. The tension T_(1) is :-

Find the tension T_(2) in the system shown in fig.

The pulley is light and smooth : the strings are inextensible and light. The system is released from rest, find the acceleration of each block, tensions in the strings and reaction in pulley.

In the following figure, the pulley is massless and frictionless. The relation between T_(1), T_(2) and T_(3) will be :-