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

A particle is executing simple harmonic motion. Its total energy is proportional to its

A particle executing SHM has potential energy U_0 sin^2 omegat . The maximum kinetic energy and total energy respectively are

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

The amplitude of a particle executing simple harmonic motion with a frequency of 60 Hz is 0.01 m. Determine the maximum value of the acceleration of the particle.

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 simple harmonic motion (SHM) of amplitude A, along the x-axis, about x = 0. When its potential Energy (PE) equals kinetic energy (KE), the position of the particle will be :

A particle executing simple harmonic motion with an amplitude A and angularr frequency omega . The ratio of maximum acceleration to the maximum velocity of the particle is

For a particle executing SHM , the kinetic energy (K) is given by K = K_(0)cos^(2) omegat . The equation for its displacement is

If particle is excuting simple harmonic motion with time period T, then the time period of its total mechanical energy is :-

A particle executes simple harmonic motion with an amplitude of 10 cm. At what distance from the mean position are the kinetic and potential energies equal?