The motion of a particle is described by the equation `x = a+bt^(2)` where `a = 15` cm and `b = 3 cm//s`. Its instantaneous velocity at time 3 sec will be

The motion of a particle along a straight line is described by the function x=(2t -3)^2, where x is in metres and t is in seconds. Find (a) the position, velocity and acceleration at t=2 s. (b) the velocity of the particle at the origin .

Position of a particle at any instant is given by x = 3t^(2)+1 , where x is in m and t in sec. Its average velocity in the time interval t = 2 sec to t = 3 sec will be :

The motion of a particle is described by X=30 sin (pit+pi//6) , where X is in cm and t in sec. potential energy of the particle is twice of kinetic energy for the first time after t=0 when the particle is at position….after…….time.

The motion of a particle is described as S =2-3t+4t^(3) what is the acceleration of the paricle at the point where its velocity is zero ?

The motion of a particle along a straight line is described by equation : x = 8 + 12 t - t^3 where x is in metre and t in second. The retardation of the particle when its velocity becomes zero is.

The relationship between the displacement travelled by a body and the time t is described by the equation s = A + Bt + Ct^(2) + Dt^(3) . Where C = 0.14m//s^(2) and D=0.01m//s^(3) . In what time after motion begins will the acceleration of the body be equal to 1 m//s^(2)?