Displacement `s` of a particle at time `t` is expressed as `s=1/2t^3-6t`. Find the acceleration at the time when the velocity vanishes (i.e., velocity tends to zero).

If the displacement of a particle is givne by s=((1)/(2)t^(2)+4sqrtt)m . Find the velocity and acceleration at t = 4 seconds.

The distance moved by the particle in time t is given by x=t^(3)-12t^(2)+6t+8 At the instant when its acceleration is zero, the velocity is

If s = 5 sin 2t, then the velocity at the end of pi/4 second is

The distance s feet travelled by a particle in time t second is given by s = t^3 - 6t^2 - 4t -8 . It acceleration vanishes at time t =

The distance s feet travelled by a particle in time t seconds is given by s = t^(3) - 6 t^(2) - 4t - 8 . Its acceleration vanishes at time t =

The acceleration a' in ms-2 of a particle is given by a = 3t^2 +2t+2, where is the time. If the particle starts with a velocity v = 2 m s-at i=0 then velocity at the end of 2 sec is:

If the displacement s at a time t is given by s = sqrt(1-t) , than the velocity is

If the distance 's' metres traversed by a particle in 1 seconds is given by s=t^(3)-3t^(2) , then the velocity of the particle when the acceleration is zero, in metres/sec. is

If the displacement of a particle is given by y(t)=A sin (omega t +phi) , then find the maximum velocity of the particle.

The position x of a particle varies with time t as x = at^(2) -bt^(3) . For what value of time acceleration is zero?