For the damped oscillator, the mass m of the block is `400g, k = 120 Nm^(-1)` and the damping constant b is `50 gs^(-1)`. Calculate the period of oscillation.

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

For the damped oscillator, the mass m of the block is 400g, k = 120 Nm^(-1) and the damping constant b is 50 gs^(-1) . Calculate time taken for its amplitude of vibration to drop to half of the initial value.

For the damped oscillator, the mass m of the block is 200g, k = 90 Nm^(-1) and the damping constant b is 40 gs^(-1) . Calculate the time taken for its mechanical energy to drop to half its initial value.

For the damped oscillator, the mass m of the block is 200g, k = 90 Nm^(-1) and the damping constant b is 40 gs^(-1) . Calculate time taken for its amplitude of vibrations to drop to half of its initial value.

For the damped oscillator shown in Fig. 14.19, 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 (a) the period of oscillation, (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.

You are riding in an automobile of mass 3000 kg. Assuming that you are examining the oscillation characteristics of its suspension system. The suspension sags 15 cm when the entire automobile is placed on it. Also, the amplitude of oscillation decreases by 50% during one complete oscillation. Estimate the values of (a) the spring constant k and (b) the damping constant b for the spring and shock absorber system of one wheel, assuming that each wheel supports 750 kg.

In the arrangement shown in figure, pulleys are light and spring are ideal. K_(1) , k_(2) , k_(3) and k_(4) are force constant of the spring. Calculate period of small vertical oscillations of block of mass m .

Two springs of force constants k_(1) and k_(2) , are connected to a mass m as shown. The frequency of oscillation of the mass is f . If both k_(1) and k_(2) are made four times their original values, the frequency of oscillation becomes

Periodic time of oscillation T_1 is obtained when a mass is suspended from a spring if another spring is used with same mass then periodic time of oscillation is T_2 . Now if this mass is suspended from series combination of above spring then calculate the time period.