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 particle is attached to a vertical spring and is pulled down a distance 0.04m below its equilibrium position and is released from rest. The initial upward acceleration of the particle is 0.30 ms^(-2) . The period of the oscillation is

A particle is attached to a vertical spring and is pulled down a distance 0.04m below its equilibrium position and is released from rest. The initial upward acceleration of the particle is 0.30 ms^(-2) . The period of the 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

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

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

A particle executive SHM has maximum speed of 0.5ms^(-1) and maximum acceleration of 1.0ms^(-2) . The angular freqyency of Oscillation is

If at some instant of time, the displacement of a simple harmonic oscillator is 0.02 m and its acceleration is 2ms^(-2) , then the angular frequency of the oscillator is

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

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.