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Kinematics Equations Of Motion And Graphs

Show that an object dropped from rest near the Earth’s surface falls 19.6 m in 2.0 s. Take g = 9.81 m s⁻².

2 marks

A train brakes from 30 m s⁻¹ to rest with a uniform deceleration of magnitude 1.2 m s⁻². Calculate the braking distance.

3 marks

A cyclist accelerates uniformly from rest. State what happens to the distance travelled in a fixed time if the acceleration is doubled.

2 marks

A ball is thrown vertically upwards at 14 m s⁻¹ from a point 1.8 m above the ground. Take g = 9.81 m s⁻² and ignore air resistance. Determine the speed at which it strikes the ground.

4 marks

State what a horizontal line on a velocity-time graph represents.

1 mark

Describe the motion shown by a curved displacement-time graph that becomes steeper with time.

2 marks

A car travels at constant velocity, then brakes uniformly to rest, then remains stationary. Sketch the corresponding velocity-time graph and acceleration-time graph for the whole journey.

4 marks

State what is given by the area under an acceleration-time graph.

1 mark

A car decelerates from 30 m s⁻¹ at 5.0 m s⁻². Deduce whether the car can stop within 100 m.

4 marks

Explain how the instantaneous velocity is determined from a curved displacement-time graph at a particular time.

3 marks

A driver travelling at 25 m s⁻¹ sees an obstacle and applies the brakes. The reaction time is 0.70 s and the braking deceleration is 6.5 m s⁻². Discuss, with calculation, whether the car stops within 60 m of the obstacle. In your answer you should: • calculate the distance travelled during the reaction time • calculate the braking distance using uniformly accelerated motion • evaluate whether the total stopping distance exceeds 60 m.

6 marks