The equation
`(d^2y)/(dt^2)+b(dy)/(dt)+omega^2y=0`
represents the equation of motion for a

If the differential equation given by (d^(2)y)/(dt^(2))+2k(dy)/(dt)+omega^(2)y=F_(0)sin pi t describes the oscillatory motion of body in a dissipative medium under the influence of a periodic force, then the state of maximum amplitude of the oscillation is a measure of

In the differl equation (d^(2)x)/(dt^(2))+omega^(2)x=0 , for a simple harmonic motion, the term omega^(2) represents

The equation of a damped simple harmonic motion is m(d^2x)/(dt^2)+b(dx)/(dt)+kx=0 . Then the angular frequency of oscillation is

Order and degree of the differential equation (d^(2)x)/(dt^(2))+((dx)/(dt))^(2)+7=0 respectively are

Let x=x(t) and y=y(t) be solutions of the differential equations (dx)/(dt)+ax=0 and (dy)/(dt)+by=0] , respectively, a,b in R .Given that x(0)=2,y(0)=1 and 3y(1)=2x(1) ,the value of "t" ,for which, [x(t)=y(t) ,is :

If the solution of the equation (d^(2)x)/(dt^(2))+4(dx)/(dt)+3x = 0 given that for t = 0, x = 0 and (dx)/(dt) = 12 is in the form x = Ae^(-3t) + Be^(-t) , then

The equation of a damped simple harmonic motion is 2m(d^(2)x)/(dt^(2))+2a_(0)(dx)/(dt)+kx=0 . Then the angualr frequency of oscillation is

The equation of SHM of a particle is (d^2y)/(dt^2)+ky=0 , where k is a positive constant. The time period of motion is

The differnetial equation of S.H.M is given by (d^2x)/(dt^2)+propx=0 . The frequency of motion is