The fig. shows the displacement time graph of a particle moving on a straight line path. What is the magnitude of average velocity of the particle over 10 seconds?

The velocity-time graph of a car moving along a straight road is shown in figure. The average velocity of the car in first 25 seconds is

The velocity-time graph of a car moving along a straight road is shown in figure. The average velocity of the car is first 25 seconds is

Read each statement below carefully and state with reasons , if it is true of false : (a) The magnitude of a vector is always a scalar , (b) each component of a vector is always a scalar , (c ) the total path length is always equal to the magnitude of the displacement vector of a particle . (d) the average speed of a either greater or equal to the magnitude of average velocity of the particle over the same interval of time , (e ) Three vectors not lying in a plane can never add up to give a null vector .

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

Acceleration time graph of a particle moving along a straight line is given. Then average acceleration between t=0 & t=4 is :-

The displacement 'x' of a particle moving along a straight line at time t is given by x=a_(0)+a_(1)t+a_(2)t^(2) . The acceleration of the particle is :-

The acceleration-time graph of a particle moving along a straight line is as shown in. At what time the particle acquires its initial velocity? .

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

The acceleration (a) of a particle moving in a straight line varies with its displacement (s) as a=2s+1 . The velocity of the particle is zero at zero displacement. Find the corresponding velocity-displacement equation.

The variation of velocity of a particle moving along a straight line is illustrated in the following figure. The distance covered by the particle in 4 seconds is :