A body is initially at rest. It undergoes one-dimensional motion with constant acceleration. The power delivered to it at time t is proportional to (i) `t^(1//2)` (ii) t (iii) `t^(3//2)` (iv) `t^(2)`

A particle moves a distance x in time t according to equation x=(t+5)^-1 the acceleration of the particle is proportional to:

The velocity-time graph of a particle in one-dimensional motion is shown in Fig. Which of the following formulae are correct for describing the motion of the particle over the time-interval t_(1) to t_(2) : (a) x(t_(2))=x(t_(1))+upsilon(t_(1))(t_(2)-t_(1))+(1//2)a(t_(2)-t_(1))^(2) (b) upsilon(t_(2))=upsilon(t_(1))+a(t_(2)-t_(1)) (c ) upsilon_("average")=(x(t_(2))-x(t_(1)))//(t_(2)-t_(1)) (d) a_("average")=(upsilon(t_(2))-upsilon(t_(1)))//(t_(2)-t_(1)) (e ) x(t_(2))=x(t_(1))+upsilon_("average")(t_(2)-t_(1))+(1//2)a_("average")(t_(2)-t_(1))^(2) (f) x(t_(2))-x(t_(1))= area under the upsilon-t curve bounded by the t-axis and the dotted line shown.

Differentiate the following : h(t) = (t - (1)/(t) )^(3//2)

A particle is kept at rest at the origin. A constant force rarrF starts acting on it at t = 0 . Find the speed of the particle at time t.

The displacement of a body is given by x = 2t^(3) - 6t^(2) + 12t + 6 . The acceleration of body is zero at time ti is equal to :

Differentiate the following : h(t)=(t-1/t)^(3/2)