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`gs^(-1) The time period of oscillation is (approx.)

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 The period of oscillation

For the damped oscillator shown in 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.

The time period of small oscillations of mass m :-

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)) . Hint : T = 2pi sqrt((m)/(k))

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

A block of mass m hangs from three springs having same spring constant k. If the mass is slightly displaced downwards, the time period of oscillation will be

A block of mass m hangs from a vertical spring of spring constant k. If it is displaced from its equilibrium position, find the time period of oscillations.

A body of mass m attached to one end of an ideal spring of force constant k is executing simple harmonic motion. Establish that the time - period of oscillation is T=2pisqrt(m//k) .

A block of mass 200 g executing SHM under the influence of a spring of spring constant k=90Nm^(-1) and a damping constant b=40gs^(-1) . The time elapsed for its amplitude to drop to half of its initial value is (Given, ln (1//2)=-0.693 )

The angular frequency of the damped oscillator is given by omega=sqrt((k)/(m)-(r^(2))/(4m^(2))) ,where k is the spring constant, m is the mass of the oscillator and r is the damping constant. If the ratio r^(2)//(m k) is 8% ,the change in the time period compared to the undamped oscillator