In the equation of motion of a particle `y = 0.5 sin (0.3t + 0.1)`, the initial phase of motion is -

A point particle if mass 0.1 kg is executing SHM of amplitude 0.1 m . When the particle passes through the mean position, its kinetic energy is 8 xx 10^(-3)J . Write down the equation of motion of this particle when the initial phase of oscillation is 45^(@) .

A point particle of mass 0.1kg is executing SHM with amplitude of 0.1m . When the particle passes through the mean position. Its K.E. is 8xx10^(-3)J . Obtain the equation of motion of this particle if the initial phase of oscillation is 45^(@) .

A point particle of mass 0.1kg is executing SHM of amplitude 0.1m . When the particle passes through the mean position, its kinetic energy is 8xx10^-3J . Obtain the equation of motion of this particle if the initial phase of oscillation is 45^@ .

A particle of mass 0.2 kg is excuting SHM of amplitude 0.2 m. When it passes through the mean position its kinetic energy is 64 xx 10^(-3) J . Obtain the equation of motion of this particle if the initial phase of oscillation is pi//4 .

A point particle of mass 0.1 kg is executing SHM of amplitude 0.1m. When the particle passes through the mean position, its kinetic energy is 8xx10^(-3)J . Obtain the equation of motion of the particle if the initial phase of oscillation is 45^(@)

The equation of motion of a particle is x=a " cos"(alpha t)^(2) . The motion is

Given equation of S.H.M. is y = 10 sin(20t+0.5). The initial phase is

Given that the equation of motion of a mass is x = 0.20 sin (3,0 t) m . Find the velocity and acceleration of the mass when the object is 5 cm from its equilibrium position. Repeat for x = 0 .

If s=e^(t) (sin t - cos t) is the equation of motion of a moving particle, then acceleration at time t is given by