For a particle of mass m executing SHM with angular frequency `omega,` the kinetic energy k is given by `k=k_(0)cos^(2)omegat`. The equation of its displacement can be

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

When a particle executes SHM oscillates with a frequency v, then the kinetic energy of the particle

A particle of mass m executing SHM with amplitude A and angular frequency omega . The average value of the kinetic energy and potential energy over a period is

A particle of mass m executing SHM with angular frequency omega_0 and amplitude A_0 , The graph of velocity of the particle with the displacement of the particle from mean position will be (omega_0 = 1)

A particle of mass m executes SHM with amplitude 'a' and frequency 'v'. The average kinetic energy during motion from the position of equilibrium to the end is:

A particle of mass 0.10 kg executes SHM with an amplitude 0.05 m and frequency 20 vib/s. Its energy of oscillation is

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

A particle is executing SHM with an amplitude 4 cm. the displacment at which its energy is half kinetic and half potential is

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

The displacement of a particle executing simple harmonic motion is given by y=A_(0)+A sin omegat+B cos omegat . Then the amplitude of its oscillation is given by