Power supplied to a mass `2 kg` varies with time as `P = (3t^(2))/(2)` watt. Here `t` is in second . If velocity of particle at `t = 0 is v = 0`, the velocity of particle at time `t = 2s` will be:

Power supplied to a particle of mass 3 kg varies with time as p = 4t ^(3) watt, where t in time is seconds. If velocity of particle at t =0s is u=2 m//s. The velocity of particle at time t =3s will be :

Power supplied to a particle of mass 3 kg varies with time as p = 4t ^(3) watt, where t in time is seconds. If velocity of particle at t =0s is u=2 m//s. The velocity of particle at time t =3s will be :

The velocity of a particle is zero at time t = 2s, then

Power applied to a particle varies with time as P=(4t^(3)-5t+2) watt, where t is in second. Find the change its K.F. between time t = 2 and t = 4 sec.

The acceleration of paticle varies with time as : a(t) = 3t^(2) +4 If the initial velocity of particle is 2 m//s , find the velocity of particle at t = 3sec .

Velocity of a particle is given as v = (2t^(2) - 3)m//s . The acceleration of particle at t = 3s will be :

Power applied to a particle varices with time as P =(3t^(2)-2t + 1) watt, where t is in second. Find the change in its kinetic energy between time t=2s and t = 4 s .

Power applied to a particle varices with time as P =(3t^(2)-2t + 1) watt, where t is in second. Find the change in its kinetic energy between time t=2s and t = 4 s .

If acceleration a(t) = 3t^(2) and initial velocity u=0 m/s , then the velocity of the particle after time t=4 s

The position of a particle is expressed as vecr = ( 4t^(2) hati + 2thatj) m, where t is time in second. Find the velocity o the particle at t = 3 s