Figure shows the position of a particle moving on the X-axis as a function of time.

Figure shows the displacement of a particle going along the X-axis as a function of time. The force acting on the particle is zero in the region

(a) The position of a particle moving along the x-axis depends on the time according to equation. x=(3t^(2)-t^(3)) m. At what time does the particle reaches its maximum x-position? (b) What is the displacement during the first 4s.

In the diagram shown, the displacement of particles is given as a function of time. The particle a is moving under constant velocity of 9 m//s . The particle B is moving under variable acceleration. From time t=0 s to t=6 s . The average velocity of the particle B will be equal to :-

The position of a particle moving along x-axis varies with time t according to equation x=sqrt(3) sinomegat-cosomegat where omega is constants. Find the region in which the particle is confined.

Figure shows velocity time graph of a particle moving in straight line. Which of the following statement(s) is / are CORRECT :-

V_(x) is the velocity of a particle of a particle moving along the x- axis as shown. If x=2.0m at t=1.0s , what is the position of the particle at t=6.0s ?

The position of a particle moving along x-axis varies eith time t as x=4t-t^(2)+1 . Find the time interval(s) during which the particle is moving along positive x-direction.

Find out the position of particle as a function of time which is moving in a straight line with an acceleration a=5 x , where x is position. (i) At t=0 the particle is at x=0 (ii) Mass of the object is 5 kg

The rate of doing work by force acting on a particle moving along x-axis depends on position x of particle and is equal to 2x. The velocity of particle is given by expression :-

The fig. shows the v-t graph of a particle moving in straight line. Find the time when particle returns to the starting point.