For the small damping oscillator, the mass of the block is 500 g and value of spring constant is k = 50 N/m and damping constant is 10 g s^(-1) The time period of oscillation is (approx.)

For a damped oscillator the mass 'm' of the block is 200 g, k = 90 N m^(-1) and the damping constant b is 40 g s^(-1) . Calculate the period of oscillation.

For the damped oscillator shown in Fig, the mass of the block is 200 g, k = 80 N m^(-1) and the damping constant b is 40 gs^(-1) Calculate (a) The period of oscillation (b) Time taken for its amplitude of vibrations to drop to half of its initial values (c) The time for the mechanical energy to drop to half initial values

The time period of small oscillations of mass m :-

For the damped oscillator shown in previous Figure, the mass m of the block is 400 g, k=45 Nm^(-1) and the damping constant b is 80 g s^(-1) . Calculate . (a) The period of osciallation , (b) Time taken for its amplitude of vibrations to drop to half of its initial value and (c ) The time taken for its mechanical energy to drop to half its initial value.

In damped oscillatory motion a block of mass 20kg is suspended to a spring of force constant 90N//m in a medium and damping constant is 40g//s . Find (a) time period of oscillation (b) time taken for amplitude of oscillation to drop to half of its intial value (c) time taken for its mechanical energy to drop to half of its initial value.

Find the time period of oscillation of block of mass m. Spring, and pulley are ideal. Spring constant is k.

For the damped oscillator shown in previous figure, k= 180 Nm^(-1) and the damping constant b is 40 gs^(-1) .Period of oscillation is given as 0.3 s, find the mass of the block . (Assume b is much less than sqrt(km)) .

By what fraction does the mass of a spring is 200 g at its natural lenth and the spring constant is 500 N m ^(-1)

A load of mass M is attached to the bottom of a spring of mass 'M //3' and spring constant 'K'. If the system is set into oscillation, the time period of oscillation is