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

Three identical particles are joined together by a thread as shown in figure All the partical are moving in a horizontal plane If the vertical of the outermost particle is v_(0) then the ratio of tension in the three sections of the string (T_(1):T_(2):T_(3) = ?) is

The voltage V and current I v graphs for a conductor at two different temperatures T_(1) and T_(2) are shown in the figure. The relation between T_(1) and T_(2) is

For the arrangement shown in figure, angle theta for which tension T_1 in the left string will be minimum is (Pulley and strings are ideal)

In the figure shown, find acceleration of the system and tenslons T_(1),T_(2) and T_(3) (Take = 10 m//s^(2))

In the arrangement shown in the figure the mass M is very heavy compared to m (M gt gt m) . The tension T in the string suspende from the ceiling is

Two particles each of mass m are moving in horizontal circle with same angular speed. If both string are of same length then the ratio of tension in string (T_(1))/(T_(2)) is

The whole set up shown in the figure is rotating with constant angular velocity omega on a horizontal frictionless table. The ratio of tensions (T_(1))/(T_(2)) is ("Given" (l_(2))/(l_(2)) = 2/1 )

Activities of three radioactive substances A, B and C are represented by the curves A, B and C, in the figure. Then their half- lives T_(1/2)(A): T_(1/2) (B): T_(1/2)(C ) are in the ratio :

Three identical particles are joined together by a thread as shown in figure. All the three particles are moving in a horizontal plane. If the velocity of the outermost particle is v_(0) , then the ratio of tensions in the three sections of the string is (T_(BC):T_(AB):T_(DA))

Four blocks of the same mass m connected by cords are pulled by a force F on a smooth horizontal surface as shown in Determine the tensions T_1 ,T_2 and T_3 in the cords.