A particle executives simple harmonic motion of amplitude A. The distance from the mean position where its kinetic energy is equal to its potential energy is

For a particle executing simple harmonic motion, find the distance from the mean position at which its potential and kinetic energies are equal.

When a particle executing SHM is at a distance of 0.02 m from its mean position, then its kinetic energy is thrice its potential energy. Calculate the amplitude of motion of the particle.

When a particle executing SHM is at a distance of 0.02 m from its position of equilibrium, then its kinetic energy is twice its potential energy. Calculate the distance from the position of equilibrium where its potential energy is twice its kinetic energy.

The velocity of a particle executing a simple harmonic motion is 13m*s^(-1) , when its distance from the equilibrium position (Q) is 3 m and its velocity is 12m*s^(-1) , when it is 5 m away from Q. The frequency of the simple harmonic motion is

At which points of its path, for a particle executing simple harmonic motion, will its velocity, acceleration, kinetic energy and potential energy be zero?

A particle is executing simple harmonic motion with a time period T. At time t = 0, it is at its position of equilibrium. The kinetic energy-time graph of the particle will look like

A particle executes SHM of period 8 s. After what time of its passing through the mean position will the energy be half kinetic and half potential?