The velocity of particle is `v=v_(0)+"gt"+ft^(2)`. If its position is `x=0` at `t=0` then its displacement after unit time `(t=1)` is

The velocity of a particle is v=v_(0)+gt+ft^(2) .If its position is x=0 at t=0, then its displacement after 1s is

The velocity of a particle is v = v_(0) + gt + ft^(2) . If its position is x=0 at t= 0 , then its displacement after unit time ( t = 1 ) is

The velocity of a particle is v = v_0 + g t + ft^2 . If its position is x = 0 at t = 0 , then its displacement after unit time (t = 1) is.

The velocity of a particle is v=v_(0)+g t+Ft^(2) . Its position is x=0 at t=0, then its displacement after time (t=1) is :

The velocity of a particle is given by v=u_(0) + g t+ 1/2 at^(2) . If its position is x =0 at t=0 , then what is its displacement after t=1 s ?

If velocity of a moving particle in is v= a + g t + ft^2 (a,g,f are constants). At t=0 body is at origin. Find displacement after t=1s.

If velocity of a particle is given by v=3t^(2)-6t +4 . Find its displacement from t=0 to 3 secs .

A particle moves along x-axis and its acceleration at any time t is a = 2 sin ( pit ), where t is in seconds and a is in m/ s^2 . The initial velocity of particle (at time t = 0) is u = 0. Q. Then the magnitude of displacement (in meters) by the particle from time t = 0 to t = t will be :

A particle is moving in a straight line and its velocity varies with its displacement as v=sqrt(4+4s) m/s. Assume s=0 at t=0. find the displacement of the particle in metres at t=1s.

The velocity of a particle is given by v=v_(0) sin omegat , where v_(0) is constant and omega=2pi//T . Find the average velocity in time interval t=0 to t=T//2.