When we graphically represent velocity from the mean position at frac(T)(2) its value is

When we graphically represent acceleration from the extreme position at frac(3T)(4) its value is

A particle executes linear simple harmonic motion with an amplitude of 2 cm . When the particle is at 1 cm from the mean position the magnitude of its velocity is equal to that of its acceleration. Then its time period in seconds is

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

The velocity of a particle performing linear S.H.M. at mean position is v0. What will be its velocity at the mean position when its amplitude is doubled and time period reduced to l /3 ?

When a body is projected vertically up from the ground, its velocity is reduced to (frac(1)(3))^(rd) of its initial value at height y above the ground . The maximum height reached by the body 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

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

The velocities of particle performing linear S.H.M. are 4 cm/s and 3 cm/s when it is at 3 cm and 4 cm respectively from mean position. Find its period and amplitude . Also find its velocity when it is at 5 cm from the mean position.

A particle executing S.H.M. starts from the mean position. Its phase, when it reaches the extreme position, is

A particle performs linear S.H.M. starting from the mean position. Its amplitude is A and time period is T. At the instance when its speed is half the maximum speed , its displacement x is