A simple pendulum is oscillating with amplitude 'A' and angular frequency '`omega`' . At displacement 'x' from mean position, the ratio of kinetic energy to potential energy is

At the mean position, the potential energy of a particle performing S.H.M. is

A ring of radius R is made of a thin wire of material of density rho , having cross-section area a and Young's modulus y. The ring rotates about an axis perpendicular to its plane and through its centre. Angular frequency of rotation is omega . The ratio of kinetic energy to potential energy is

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

The velocity of a particle in simple harmonic motion at displacement y from mean position is

A particle executes simple harmonic motion of amplitude A. (i) At what distance from the mean positio is its kinetic energy equal to its potential energy? (ii) At what points is its speed half the maximum speed?

A hollow sphere of mass 'M' and radius 'R' is rotating with angular frequency 'omega’. It suddenly stops rotating and 75% of kinetic energy is converted to heat. If 'S' is the specific heat of the material in J//kg K then rise in temperature of the sphere is (M.I. of hollow sphere = 2/3 MR^2 )

A particle executes linear simple harmonic motion with an amplitude of 3 cm . When the particle is at 2 cm from the mean position, the magnitude of its velocity is equal to that of its acceleration. Then, its time period in seconds is

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

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