"The velocity of a particle is `v=v_0+(gt)+ft^2`. If its position `x=0` at `t=0`, then its displacement afler time `(t= 1)` 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 ?

A particle is moving in a verticle circle. If v_1 is the velocity of particle at highest point and v_2 is the velocity of particle at lowest point , then the relation between v_1 and v_2 is

The position of a particle is given by the function s(t)= 2 t^2 + 3t - 4. Find the time t=c in the interval 0 le t le 4 when the instantaneous velocity of the particle equals to its average velocity in this interval.

A particle is executing SHM of periodic time T the time taken by a particle in moving from mean position to half the maximum displacement is (sin 30^(@)=0.5)

The displacement of a particle at time t is given by s= 2 t^3 - 5 t^2 + 4t -3. Find the time when the acceleration is 14 ft/ sec^2 , find the velocity and the displacement at that time.

The displacement s of a particle at time t is is given by s=2 t^3 - 4 t^2 -5t. Then find the time when the acceleration is 14ft/ sec^2

The displacement of a particle of mass 0.1 kg from . its mean position is given by, y = 0.05 sin 4pi(t+0.4) (where all the quantities are in S.I. unit). Period of motion is 0.1 s. The total energy of the particle is

The speed versus time graph of a moving particle is shown in the following figure. If 'u' is the initial speed at t=0 , v is the speed at time t, a is the acceleration and s' is the distance covered in time t , then total area OABC is best described using. (Assume O as origin)

The displacement x of a particle at time tis given by x= 160t-16t^2 . Show that its velocity at t=1 and t=9 are equal in magnitude but opposite in sign.