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

If 'O' is at equilibrium then the values of the tension T_(1) and T_(2) are x, y, if 20 N is vertically down. Then x, y are

The masses M_(1), M_(2) and M_(3) are 5, 2 and 3 kg respectively. These have been joined using massless, inextensible pieces of strings as shown in the figure. If the whole system is going upward with an acceleration of 2ms^(-2) , then the value of tensions T_(1), T_(2) and T_(3) respectively are ["take "g=9.8ms^(-2)]

If 'O' is in equilibrium then tensions T_1 and T_2 are (Tan 37^@ = 3//4 )

If 'P' is in equilibrium then T_(1)//T_(2) is

A pendulum is hanging from the ceiling of a cage. When the cage is moving up with certain acceleration and when it is moving down with the same acceleration, the tensions in the string are T_(1) and T_2 respectively. When the cage moves horizontally with the same acceleration, the tension in the string is,

For a given exothermic reaction , K_P and K_p' are the equilibrium constant at temperature T_1 and T_2 respectively .Assuming that heat of reaction is constant in temperature range between T_1 and T_2 , it is readly observed that

Three concentric wires of radii a,b and c contain two different liquid films of surface tension T_1 and T_2 respectively , as shown in the figure. The outermost and the innermost wires are fixed. The tension in the middle wire is (neglect the effect of gravity)

What will be the tension T_(1) and T_(2) in the given figure?

Determine tension T_(4) in fig.

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 :-