At time `t=0s` particle starts moving along the `x-` axis. If its kinetic energy increases uniformly with time `'t'`, the net force acting on it must be proportional to

If the kinetic energy of a body is directly proportional to time t, the magnitude of the force acting on the body is

In a satellite if the time of revolution is T , then kinetic energy is proportional to

At the moment t=0 a particle starts moving along the x axis so that its velocity projection varies as v_(x)=35 cos pi t cm//s , where t is expressed in seconds. Find the distance that this particle covers during t=2.80s after the start.

Let kinetic energy of a satellite is x, then its time of revolution T is proportional to

The position (x) of a particle of mass 2 kg moving along x-axis at time t is given by x=(2t^(3)) metre. Find the work done by force acting on it in time interval t=0 to t=2 is :-

A particle is moving along the x-axis with its cordinate with time 't' given by x(t)=10+8t-3t^(2) . Another particle is moving along the y-axis with its coordinate as a FIGUREunction oFIGURE time given by y(t)= 5-8t^(2) At t=1 s, the speed oFIGURE the4 second particle as measured in the FIGURErame oFIGURE the FIGUREirst particle is given as sqrtv . Then v (in m//s) is

A particle is moving along X-axis Its acceleration at time t is proportional to its velocity at that time. The differential equation of the motion of the particle is

The position (x) of a particle of mass 1 kg moving along X-axis at time t is given by (x=1/2 t^(2)) metre. Find the work done by force acting on it in time interval from t=0 to t=3 s .

The position (x) of a particle of mass 1 kg moving along x-axis at time t is given by (x=(1)/(2)t^(2)) metre. Find the work done by force acting on it in time interval from t=0 to t=3 s.