If a body of mass 0.98 kg is made to oscillate on a spring of force constant 4.84 N/m the angular frequency of the body is

A body of mass 1 kg oscillates on a spring of force constant 16 N/m. Calculate the angular frequency.

A body of mass 16 kg is made to oscillate on a spring of force constant 100 N kg^(-1) . Deduce the angular frequency.

A body of mass 1 kg is made to oscillate on a spring of force constant 16 N/m. Calculate (a) Angular frequncy , (b) Frequency of vibrations.

A body of mass 2 kg is made to oscillate using a spring of force constant 8Nm^(-1) find (i) angular frequency (ii) frequency of vibration (iii) time period of vibration.

A body of mass 'm' is suspended to an ideal spring of force constant 'k'. The expected change in the position of the body due to an additional force 'F' acting vertically downwards is

A block of mass 0.2 kg is attached to a mass less spring of force constant 80 N/m as shown in figure. Find the period of oscillation. Take g=10 m//s^(2) . Neglect friction

A body of mass 1 kg suspended by a light vertical spring of spring constant 100 N/m executes SHM. Its angular frequency and frequency are

A mass of 2kg oscillates on a spring with force constant 50 N//m . By what factor does the frequency of oscillation decrease when a damping force with constant b = 12 is introduced ?

A body of mass 0.5 kg is suspended by a weightless spring of force constant 500 Nm^(-1) . Another body of mass 0.1 kg moving vertically upwards with velocity of 5 ms^(-1) hits the suspended body and gets embeded into the suspended body. What will be the frequency of oscillation ?

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 and amplitude of motion.