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

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 is executing simple harmonic motion. At a displacement x, its potential energy is E_1 and a displacement y, its potential energy is E_2 . The potential energy E at a displacement (x+y) is

The displacement of a particle executing S.H.M. is given by, y = 0.20 sin (100 t) cm. The maximum speed of the particle is

A body starting from mean position is executing simple harmonic motion. Its time . period is 24 s. After 4 s, its velocity is pi" "m//s then its path length is

A particle is executing simple harmonic motion with a time period T . At time t=0, it is at its position of equilibium. The kinetice energy -time graph of the particle will look like

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

A particle executing simple harmonic motion has amplitude of 10 centimeter and time period 4 second. At t = 0. x = 5 going towards positive x direction. Then the equation for the displacement x at time t

A particle is executing simple harmonic motion with a period of T seconds and amplitude a metre . The shortest time it takes to reach a point a/sqrt2 from its mean position in seconds is

A particle is executing simple harmonic motion with an amplitude of 2 m. The difference in the magnitude of its maximum acceleration and maximum velocity is 4. The time period of its oscillation and its velocity when it is l m away from the mean position are respectively