A cage of mass M hangs from a light spring of force constant `k`. A body of mass m falls from height h inside the cage and stricks to its floor. The amplitude of oscillations of the cage will be-

A block of mass m is hanging from a light string of length l . A bullet of mass m strikes the hanging mass and gets embedded into it. The value of v such that tension in string and the speed of combined mass becomes zero simultaneously during the subsequent motion , is :-

A block of mass m suspended from a spring of spring constant k . Find the amplitude of S.H.M.

Figure shows a system consisting of a massless pulley, a spring of force constant k and a block of mass m. If the block is slightly displaced vertically down from is equilibrium position and then released, the period of its vertical oscillation is

A block of mass M is attached to the lower end of a vertical spring. The spring is hung from a ceiling and has force constant value k. The mass is released from rest with spring initially unstretched. The maximum extension produced in the length of the spring will be............

A body of mass 1.0 kg is suspended from a weightless spring having force constant 600Nm^(-1) . Another body of mass 0.5 kg moving vertically upwards hits the suspended body with a velocity of 3.0ms^(-1) and gets embedded in it. Find the frequency of oscillations .

A vessel filled with water is kept on a weighing pan and the scale adjusted to zero .A block of mass M and density rho is suspended by a massless spring of spring constant k. This block is submerged inside into the water in the vessel .What is the reading of the scale ?

A mass M is suspended from a light spring. An additional mass m added to it displaces the spring further by distance x then its time period is

Two spring of force constants k and 2k are connected to a mass as shown in figure. The frequency of oscillation of the mass is……..

A mass M is in static equilibrium on a massless vertical spring as shown in the figure. A ball of mass m dropped from certain height sticks to the mass M after colliding with it.The oscillations they perform reach to height a above the original level of scales & depth 'b' below it. (a) Find the constant of force of the spring., (b) Find the oscillation frequency.

Two identical small discs each of mass m placed on a frictionless horizontal floor are connected with the help of a light spring of force constant k. The discs are also connected with two light rods each of length 2sqrt(2)m that are pivoted to a nail driven into the floor as shown as shown in the figure by a top view of the situation. If period of small oscillations of the system is 2pi sqrt((m//k)) , find relaxed length (in meters) of the spring.