Two bodies of masses 1 kg and 4 kg are connected to a vertical spring, as shown in the figure. The smaller mass executes simple harmonic motion of angular frequency `"25 rad s"^(-1)`, and amplitude 1.6 cm while the bigger mass remains stationary on the ground. The maximum force exerted by the system on the floor is `("take "g=10ms^(-2))`.

Two simple harmonic motions of angular frequency 100 rad s^(-1) and 1000 rad s^(-1) have the same displacement amplitude. The ratio of their maximum accelerations is

A block of mass 5 kg executes simple harmonic motion under the restoring force of a spring. The amplitude and the time period of the motion are 0.1 m and 3.14 s respectively. Find the maximum force exerted by the spring on the block.

Three point particles of masses 1.0 kg, 1.5 kg and 2.5 kg are placed at three corners of a right angle triangle as shown in figure. The centre of mass of the system is at a point :

Three point particles of masses 1.0 kg, 1.5 kg and 2.5 kg are placed at three corners of a right angle triangle as shown in figure. The centre of mass of the system is at a point :

Two blocks of masses 10 kg and 20 kg are connected by a light spring as shown. A force of 200 N acts on the 20 mass as shown. At a certain instant the acceleration of 10 kg mass is 12 ms^(-2) towards right direction.

A body of mass 0.01 kg executes simple harmonic motion about x = 0 under the influence of a force as shown in figure. The time period of SHM is

Two masses 6 kg and 4 kg are connected by massless flexible and inextensible string passing over massless and frictionless pulley.The acceleration of centre of mass is (g=10ms^2)

A mass of 2.0kg is put on a that pan attached to a vertical spring fixed on the ground as shown in the figure The mass of the spring and the pen is negligible the mass executing a simple harmonic motion The spring constant is 200N//m what should be the minimum amplitude of the motion so that the mass get detached from the pan? (Taking g = 10m//s^(2))

Two point masses of 3.0 kg and 1.0 kg are attached to opposite ends of a horizontal spring whose spring constant is 300 N m^(-1) as shown in the figure. The natural vibration frequency of the system is of the order of :

Two point masses of 3 kg and 6 kg are attached to opposite ends of horizontal spring whose spring constant is 300 Nm^(-1) as shown in the figure. The natural vibration frequency of the system is approximately