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

The tension in the string in the pulley system shown in .

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 figure is in equilibrium. Find the magnitude of tension in each string, T_(1), T_(2), T_(3) and T_(4) ( g = 10 m//s^(-2))

All pulleys are massless The string is light and inextensible Find acceleration of centre of pulley 'p' in m//s^(2)

Two identical particles A and B are situated respectively at the midpoint and at the end of a string. The particles always remain collinear and move in concentric circles. The ratio of the tensions T_(1) and T_(2) will be

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.

If the arrangement in fig is given a downward acceleration then the ratio of tensions T_(1) and T_(2) is strings is-