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 equation of motion of a particle is x = a cos (a t)^2. The motion is

A particle of mass (m) is executing oscillations about the origin on the (x) axis. Its potential energy is V(x) = k|x|^3 where (k) is a positive constant. If the amplitude of oscillation is a, then its time period (T) is.

The equation of motion of a projectile is y =ax - bx^2 where a and b are constants of motion. The horizontal range of the projectile is

The equation (d^2x / dt^2) + alpha x = 0 for a particle performing S.H.M. Then the time period of the motion will be

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

A particle of mass m is moving in a circular path of constant radius r such that its centripetal acceleration a_(c) is varying with time t as a_(c) = k^(2)rt^(2) , where k is a constant. The power delivered to the particle by the forces acting on it is :

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

A particle of mass 0.2 kg moves with simple harmonic motion of amplitude 2 cm. If the total energy of the particle is 4 xx10^(-5) J, then the time period of the motion is

The phase of a particle performing S.H.M. increases by pi//2 after every 4 seconds. Its time period of oscillation is

When a wave travels in a medium, the particle displacement is given by the equation y = alpha sin 2pi(bt -cx) where a, b and c are constants. The maximum particle velocity will be twice the wave velocity if