The amplitude of a particle in damped oscillation is given by `A=A_0e^(-kt) where symbols have usual meanings if at time t=4s,the amplitude is half of initial amplitude then the amplitude is `1/8` of initial value t=

The total force acting on the mass at any time t, for damped oscillator is given as (where symbols have their usual meanings)

Equation of motion for a particle performing damped harmonic oscillation is given as x=e^(-0.1t) cos(10pit+phi) . The time when amplitude will half of the initial is :

Equation of motion for a particle performing damped harmonic oscillation is given as x=e^(-1t) cos(10pit+phi) . The time when amplitude will half of the initial is :

Given vecF=(veca)/(t) where symbols have their usual meaning. The dimensions of a is .

A particle is performing damped oscillation with frequency 5Hz . After every 10 oscillations its amplitude becmoes half. Find time from beginning after which the amplitude becomes 1//1000 of its initial amplitude :

In damped oscillations damping froce is directly proportional to speed of ocillatior .If amplitude becomes half to its maximum value is 1 s, then after 2 s amplitude will be ( A_(0) - initial amplitude)

The amplitude of a damped oscillator becomes half in one minutes. The amplitude after 3 minutes will be 1/x times of the original . Determine the value of x.

The amplitude of a lightly damped oscillator decreases by 4.0% during each cycle. What percentage of mechanical energy of the oscillator is lost in each cycle?

The displacement of a damped harmonic oscillator is given by x(t)-e^(-0.1t) cos(10pit+varphi) .Here t is in seconds. The time taken for its amplitude of vibration to drop to half of its initial value is close to :

(b) The displacement of a particle executing simple harmonic motion is given by the equation y=0.3sin20pi(t+0.05) , where time t is in seconds and displacement y is in meter. Calculate the values of amplitude, time period, initial phase and initial displacement of the particle.