A particle is executing S.H.M. along a straight line. The graph showing the variation of kinetic, potential and total energy K, U and T respectively with displacement is -

Draw a graph to show the variation of P.E., K.E. and total energy of a simple harmonic oscillator with displacement.

When the displacement in S.H.M is one third of the amplitude, the fraction of the potential energy to total energy is

A particle of mass m executing S.H.M. about its mean position. The total energy of the particle at given instant is

A particle is executing SHM along a straight line. Its velocities at distances x_(1) and x_(2) from the mean position are v_(1) and v_(2) , respectively. Its time period is

For a particle executing S.H.M., the displacement x is given by x=Acosωt. Identify the graph which represents the variation of potential energy (U) as a function of time t and displacement x.

A particle executes S.H.M. with a period 8 s . Find the time in which half the total energy is potential.

A particle is in S.H.M. along a straight line 0.2 m long with a period of 6 s. Its displacement after 1/2 second, if its epoch is ((pi)/(6))^c , will be

A particle is moving in a circular path of radius a under the action of an attractive potential U=-(k)/(2r^(2)) . Its total energy is :

A particle is performing linear S.H.M of amplitude a. What fraction of the total energy is kinetic, given the displacement is half the amplitude

A particle is executing SHM with amplitude A. At displacement x=(-A/4) , force acting on the particle is F, potential energy of the particle is U, velocity of particle is v and kinetic energy is K. Assuming potential energyh to be zero at mean position. At displacement x=A/2