In simple harmonic motion of a particle, maximum kinetic energy is 40 J and maximum potential energy is 60 J. then

In a simple harmonic motion (i) the maximum potential energy equal the maximum kinetic energy (ii) the minimum potential energy equals the minimum kinetic energy (iii) the minimum potential energy equals the maximum kinetic energy (iv) the maximum potential energy equals the minimum kinetic energy

The particle executing simple harmonic motion has a kinetic energy K_(0) cos^(2) omegat . The maximum values of the potential energy and the total energy are respectively:

The particle executing simple harmonic motion has a kinetic energy K_(0) cos^(2) omega t . The maximum values of the potential energy and the energy are respectively

In position A kinetic energy of a particle is 60 J and potential energy is -20 J. In position B, kinetic energy is 100 J and potential energy is 40 J. Then, in moving the particle from A to B

A pendulum is executing simple harmonic motion and its maximum kinetic energy is K_(1) . If the length of the pendulum is doubled and it perfoms simple harmonuc motion with the same amplitude as in the first case, its maximum kinetic energy is K_(2) Then:

A particle is executing a simple harmonic motion its maximum acceleration is a and maximum velocity is beta .Then its time of vibration will be

A particle executes simple harmonic motion along a straight line with an amplitude A . The potential energy is maximum when the displacement is

A particle is executing simple harmonic motion with frequency f . The frequency at which its kinetic energy changes into potential energy is

When the displacement of a particle executing simple harmonic motion is half its amplitude, the ratio of its kinetic energy to potential energy is