The average velocity of a particles is equal to its displacement-time graph ?

The velocity of particle (whose displacement time graph is shown) at t=3 .

Acceleration v/s displacement graph of a particle moving in a straight line is as shown in the figure. The initial velocity of the particle is zero. The velocity v/s displacement graph of the particle would be :

Assertion: In successive time intervals if the average velocities of a particle are equal then the particle must be moving with constant velocity. Reason: When a particle moves with uniform velocity, its displacement always increases with time.

Assertion: The average velocity of a particle is zero in a time interval. It is possible that the instantaneous acceleration is never zero in the interval. Reason: The magnitude of average velocity in an interval is equal to its average speed in that interval.

What can be said about velocity of the object if its displacement-time graph is parallel to displacement axis?

Assertion: Average speed of a particle in a given time interval is never less than the magnitude of the average velocity. Reason: The magnitude of the velocity (instantaneous velocity) of a particle is equal to its speed.

" Find corresponding velocity - time graph for given displacement-time graph "

Assertion: When a particle moves with constant velocity its average velocity, its insttantaneous velocity and its speed are all equal in magnitude. Reason: If the average velocity of a particle moving on a straight line is zero in a time interval, then it is possible that the instantaneous velocity is never zero in the internal.

Draw velocity-time graphof uniform motion and prove that the area under the velocity-time graph of a particle gives the displacement of the particle in a given time.

Assertion: The slope of displacement-time graph of a body moving with high velocity is steeper than the slope of displacement-time graph of a body with low velocity. Reason: Slope of displacement-time graph = Velocity of the body.