Three mass 0.1 kg ,0.3 kg and 0.4 kg are suspended at end of a spring. When is 0.4 kg mass is removed , the system oscillates with a period 2 s . When the 0.3 kg mass is also removed , the system will oscillates with a period

Three masses of 500 g , 300 g and 100 g are suspended at the end of a spring as shown and are in equilibrium. When the 500 g mass is removed suddenly, the system oscillates with a period of 2 s . When the 300 g mass is also removed, it will oscillate with period T . Find the value of T .

Three masses 700g, 500g, and 400 g are suspended at the end of a spring a shown and are in equilibrium. When the 700 g mass is removed, the system oscillacts with a period of 3 seconds, when the 500 gm mass is also removed, it will oscillate with a period of

When a mass of 5 kg is suspended from a spring of negligible mass and spring constant K, it oscillates with a periodic time 2pi . If the mass is removed, the length of the spring will decrease by

Three particles of masses 0.50 kg, 1.0 kg and are placed at the corners of a right angle triangle, as shown in fig. Locate the centre of mass of the system.

Three masses 2 kg , 3kg and 4kg are lying at the corners of an equilateral triangle of side I. The X coordinate of center of mass is

Two masses 8 kg 4 kg are suspended together by a massless spring of spring constant 1000 Nm^(-1) . When the masses are in equilibrium 8 kg is removed without disturbing the system . The amplitude of oscillation is

Three point particles of masses 1.0 kg 2 kg and 3 kg are placed at three comers of a right angle triangle of sides 4.0 cm , 3.0 cm and 5.0 cm as shown in the figure . The centre of mass of the system is at point :

Three point particles of masses 1.0 kg 2 kg and 3 kg are placed at three comers of a right angle triangle of sides 4.0 cm , 3.0 cm and 5.0 cm as shown in the figure . The centre of mass of the system is at point :

A body of mass m is attached to the lower end of a spring whose upper end is fixed. The spring has negligible mass. When the mass m is slightly pulled down and released, it oscillates with a time period of 3s. When the mass m is increased by 1 kg , the time period of oscillations becomes 5s. The value of m in kg is

Two masses m_(1) = 1kg and m_(2) = 0.5 kg are suspended together by a massless spring of spring constant 12.5 Nm^(-1) . When masses are in equilibrium m_(1) is removed without disturbing the system. New amplitude of oscillation will be