A body of mass `m`, accelerates uniformly from rest to `V_(1)` in time `t_(1)`. The instantaneous power delivered to the body as a function of time `t` is.

The position (x) of body moving along x-axis at time (t) is given by x=3t^(2) where x is in matre and t is in second. If mass of body is 2 kg, then find the instantaneous power delivered to body by force acting on it at t=4 s.

The position (x) of body moving along x-axis at time (t) is given by x=3t^(3) where x is in matre and t is in second. If mass of body is 2 kg, then find the instantaneous power delivered to body by force acting on it at t=2 s.

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

(v_(x) ,t) , and (v_(y) t) diagram for a body of unit mass. Find the force as a function of time.

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

A particle of mass 1 kg moves in a circular path of radius 1 m such that its speed varies with time as per equation v=3t^(2)m//s where time t is in seconds. The power delivered by the force acting on the paritcle at t=1s , is :-

A train accelerates from rest at a constant rate α a for distance x_(1) and time t _(1) . After that is retards at constant rate beta for distance x_(2) and time t_(2) and comes to the rest. Which of the following relation is correct:-

The velocity of a body of mass 2 kg as a function of t is given by v(t) = 2t hati + t^(2)hatj . Find the momentum and the force acting on it, at time t = 2s.

A particle of mass m, moving in a cicular path of radius R with a constant speed v_2 is located at point (2R,0) at time t=0 and a man starts moving with a velocity v_1 along the +ve y-axis from origin at time t=0 . Calculate the linear momentum of the particle w.r.t. the man as a function of time.

A body is falling from height 'h' it takes t_(1) time to rech the ground. The time taken to cover the first half of height is:-