A particle of mass `m` is allowed to oscillate near the minimum of a vertical parabolic path having the equaiton `x^(2) =4ay`. The angular frequency of small oscillation is given by

A point mass m is displaced slightly from point O and released. It is constrained to move along parabolic path having equation x^(2)=ky then its angular frequency of oscillation is :

A simple harmonic motion is represented by x(t) = sin^2 omegat - 2 cos^(2) omegat . The angular frequency of oscillation is given by

A particle of mass m moves in a one dimensional potential energy U(x)=-ax^2+bx^4 , where a and b are positive constant. The angular frequency of small oscillation about the minima of the potential energy is equal to

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

A particle executing SHM has a maximum speed of 0.5ms^(-1) and maximum acceleration of 1.0ms^(-2) . The angular frequency of oscillation is

From the given figure find the frequency of oscillation of the mass m

A block of mass m connected with a smooth prismatic wedge of mass M is released from rest when the spring is relaxed. Find the angular frequency of oscillation.

A disk of mass m is connected to two springs of stiffness k_(1) and k_(2) as shown in the figure. Find the angular frequency of the system for small oscillation. Disc can roll on the surface without slipping

A particle is attached to a vertical spring and is pulled down a distance 4 cm below its equilibrium and is released from rest. The initial upward acceleration is 0.5ms^(-2) . The angular frequency of oscillation is

A disc of mass M = 4 kg, radius R = 1 m is attached with two blocks A and B of masses 1 kg and 2 kg respectively on rim and is resting on a horizontal surface as shown in the figure. Find angular frequency of small oscillation of arrangement: