The radio of kinetic energy at the mean position to potential energy at `A//2` of a particle performing SHM is

Ratio of kinetic energy at mean position to potential energy at A/2 of a particle performing SHM

Statement-1: kinetic energy of SHM at mean position is equal to potential energy at ends for a particle moving in SHM. Statement-2: Total energy in SHM is conserved.

The ration of kinetic energy to the potential energy of a particle executing SHM at a distance equal to half its amplitude , the distance being measured from its equilibrium position is

The total energy of particle performing SHM depend on : -

Draw the graph between displacement and potential energy for a particle executing SHM.

Distinguish between Kinetic energy and potential energy

STATEMENT-1 , The total energy of a particle executing S.H.M( of given amplitude) of depends on the mass of particle but does not depend on its displacement from mean position and STATEMENT -2 : The total energy of a particle executing S.H.M. ismaximum at the mean position.

Force acting on a particle is F=-8x in S.H.M. The amplitude of oscillation is 2 (in m) and mass of the particle is 0.5 kg. The total mechanical energy of the particle is 20 J. Find the potential energy of the particle in mean position (in J).

Differentiate between Kinetic energy and potential energy.

A particle starts oscillating simple harmonically from its equilibrium position then, the ratio of kinetic energy and potential energy of the particle at the time T//12 is: (T="time period")