A particle of mass 4 kg is executing S.H.M. Its displacement is given by the equation Y=8 `cos[100t+pi//4]` cm. Its maximum kinetic energy is

A body of mass 1 is executing simple harmonic motion. Its displacement y(cm) at t seconds is given by y = 6 sin (100t + pi//4) . Its maximum kinetic energy is

A body of mass 1 kg is performing linear S.H.M. its displacement x (cm) at t (second) is given by x = 6 sin (100 t + (pi) /4) .Maximum kinetic energy of the body 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 of mass m executing S.H.M. about its mean position. The total energy of the particle at given instant is

The S.H.M. of a particle is given by the equation y=3 sin omegat + 4 cosomega t . The amplitude is

A body of mass 5 gm is executing S.H.M. about a point with amplitude 10 cm. If its maximum velocity is 100 cm/s then its velocity will be 50 cm/s at a distance of

The acceleration of a particle executing S.H.M, when it is at its mean position is

A body of mass 5 gm is executing S.H.M. about a point with amplitude 10 cm . Its maximum velocity is 100 cm / sec . Its velocity will be 50 cm / sec at a distance

The displacement of a particle is represented by the equation y = 3 cos [ pi/4 - 2omega t] . The motion of the particle is

A particle is executing a linear S.H.M. Its velocity at a distance x from the mean position is given by v^2=144-9x^2 . The maximum velocity of the particle is