The distance x covered in time t by a body having initial velocity `v_(0)` and havig a constant acceleration a is given by `x=v_(0)t+((1)/(2))at^(2)`. This result follows from:-

The initial velocity of a particle is u and the acceleration is given by (kt), where k is a positive constant. The distance travelled in time t is:

Two bodies move in a straight line towards each other at initial velocities v_(1) and v_(2) and with constant acceleration a_(1) and a_(2) directed against the corresponding velocities at the initial instant. What must be the maximum initial separation between the bodies for which they meet during the motion ?

The displacement 'x' of a particle moving along a straight line at time t is given by x=a_(0)+a_(1)t+a_(2)t^(2) . The acceleration of the particle is :-

A particle starting from initial velocity v_0 moves on straight line with constant acceleration equation of distance travelled during n^"th" second will be …... .

The distance s moved by a particle in time t is given by s=t^(3)-6t^(2)+6t+8 . When the acceleration is zero, the velocity is ………..

A body covers one-third of the distance with a velocity v_(1) the second one-third of the distance with a velocity v_(2) , and the last one-third of the distance with a velocity v_(3) . The average velocity is:-

A block A is placed over a long rough plank B same mass as shown below. The plank is placed over a smooth horizontal surface. At time t = 0 , block A is given a velocity v_(0) in horizontal direction. Let v_(1) and v_(2) be the velocity of A & B at time 't'. Then choose the correct graph between v_(1) or v_(2) and t.

A particle is moving along a straight line along x-zxis with an initial velocity of 4 m//s towards positive x-axis. A constant acceleration of 1 m//s^(2) towards negative x-axis starts acting on particle at t=0 . Find velocity (in m//s ) of particle at t=2 s .

Which equation are dimensionally valid out of following equations (i) Pressure P= rho gh where rho = density of matter, g= acceleration due to gravity. H= height. (ii) F.S =(1)/(2) mv^(2)-(1)/(2) mv_(0)^(2) where F= force rho = displacement m= mass, v= final velocity and v_(0)= initial velocity (iii) s=v_(0)t+(1)/(2) (at)^(2) s= dispacement v_(0)= initial velocity, a= accelration and t= time (iv) F=(mxx a xx s)/(t) Where m= mass, a= acceleration, s= distance and t= time