A force-time graph for the motion of a body is shown in fig. change in linear momentum between 0 and 8 s is:-

F rarr t graph for a body is shown in figure. The change in value of momentum of the body in the interval 0.02 s to 0.06 s is ..

Velocity versus time graph of a body is shown in figure. It explains that

The velocity-time graph of a linear motion is shown in figure. The displacement & distance from the origin after 8 sec is :-

F rarr t graph for a body is shown in the . What is the change in the value of momentum in the intital tie interval of 0.03 sec .

A force of 10 Newton acts on a body of mass 20 kg for 10 seconds. Change in its momentum is

Position time graph of a particle of mass 2 kg is shown in figrure. Total work done on the particle from t=0 to t=4s is

A 100 g block is connected to a horizontal massless spring of force constant 25.6(N)/(m) As shown in Fig. the block is free to oscillate on a horizontal frictionless surface. The block is displaced 3 cm from the equilibrium position and , at t=0 , it is released from rest at x=0 It executes simple harmonic motion with the postive x-direction indecated in Fig. The position time (x-t) graph of motion of the block is as shown in Fig. Q. When the block is at position B on the graph its.

Position-time graph of a particle in motion is shown in fig. Calculate - (i) Total distance covered (ii) Displacement (iii) Average speed (iv) Average velocity.

The position-time graph of a body of mass 2 kg is as given in figure. What is the impulse on the body at t = 0 s and t = 4s.

Assertion: In the projectile motion projected boyd behave just like a freelty falling body. Reason: There is no change in linear momentum in projectile motion.