A car is moving on a straight road. The velocity of the car varies with time as shown in the figure. Initially (at t=0), the car was at `x=0`, where, x is the position of the car at any time 't'.

The displacement time graph will be best represented by :-

A car is moving on a straight road. The velocity of the car varies with time as shown in the figure. Initially (at t=0), the car was at x=0 , where, x is the position of the car at any time 't'. Average speed from t=0 to t=70 s will be :-

A car is moving on a straight road. The velocity of the car varies with time as shown in the figure. Initially (at t=0), the car was at x=0 , where, x is the position of the car at any time 't'. The maximum displacement from the starting position will be :-

A car is moving on a straight road. The velocity of the car varies with time as shown in the figure. Initially (at t=0), the car was at x=0 , where, x is the position of the car at any time 't'. The variation of acceleration (a) with time (t) will be best represented by :-

A car is moving on a straight road. The velocity of the car varies with time as shown in the figure. Initially (at t=0), the car was at x=0 , where, x is the position of the car at any time 't'. The time interval during which the car is retarding can be :-

A constant power P is applied to a car starting from rest. If v is the velocity of the car at time t, then:

The velocity time graph of the motion of a car is given here.

Velocity-time graph of a particle moving in a straight line is shown in figure. Plot the corresponding displacement-time graph of the particle if at time t=0, displacement s=0.

Car A and car B move on a straight road and their velocity versus time graph are as shown in figure. Comparing the motion or car A in between t=0 to t =8 sec . And motion of car B in between t=0 to t=7 sec ., pick up the correct statement. .