For a particle moving along a straight line, the displacement x depends on time t as `x = alpha t^(3) +beta t^(2) +gamma t +delta`. The ratio of its initial acceleration to its initial velocity depends

For a particle moving along a straight line, the displacement x depends on time t as x=At^(3)+Bt^(2)+Ct+D . The ratio of its initial velocity to its initial acceleration depends on:

The displacement (x) of particle depends on time (t) as x = alpha t^(2) - beta t^(3) .

The position of a particle moving on a straight line depends on time t as x=(t+3)sin (2t)

A particle moves along a straight line its velocity dipends on time as v=4t-t^(2) . Then for first 5 s :

For a particle moving in a straight line, the displacement of the particle at time t is given by S=t^(3)-6t^(2) +3t+7 What is the velocity of the particle when its acceleration is zero?

A particle moves along a straight line such that its displacement at any time t is given by s = 3t^(3)+7t^(2)+14t + 5 . The acceleration of the particle at t = 1s is

The displacement (x) of a particle depends on time t as x=alpha t^(2)-beta t^(3) . Choose the incorrect statements from the following.

A partical moves along a straight line such that its displacement s=alphat^(3)+betat^(2)+gamma , where t is time and alpha , beta and gamma are constant. Find the initial velocity and the velocity at t=2 .

A particle moves along x-axis and its displacement at any time is given by x(t) = 2t^(3) -3t^(2) + 4t in SI units. The velocity of the particle when its acceleration is zero is

(a) If the initial velocity of a particle is u and collinear acceleration at any time t is at, calculate the velocity of the particle after time t . (b) A particle moves along a straight line such that its displacement at any time t is given by s = (t^(3) - 6 t^(2) + 3t + 4)m . What is the velocity of the particle when its acceleration is zero?