Falling Objects and Projectile Motion

Transcription

1 Falling Objects and Projectile Motion

2 Gravity influences motion in a particular way.

3 How does a dropped object behave? accelerate, or speed constant? What if they have: different masses? different shapes?

4 Acceleration Due to Gravity Earth exerts a gravitational force on objects that is attractive (towards Earth s surface). Near Earth s surface, this force produces a constant acceleration downward. Galileo s Incline Experiment

5 Distance fallen vs. time Flashes from a stroboscope Distance fallen increases each interval Since speed = Dist/Time speed must be increasing.

6 The velocity values steadily increase. Time Position Average velocity 0 s 0 cm 0.05 s 1.2 cm 24 cm/s 0.10 s 4.8 cm 72 cm/s 0.15 s 11.0 cm 124 cm/s 0.20 s 19.7 cm 174 cm/s 0.25 s 30.6 cm 218 cm/s 0.30 s 44.0 cm 268 cm/s 0.35 s 60.0 cm 320 cm/s

7 The velocity values steadily increase.

8 a 464 cm/s 72 cm/s 8 flashes 0.05 s flash 392 cm/s 0.4 s 980 cm/s m s 2

9 The diagram shows the positions at 0.10-sec intervals of a ball moving left to right. Is the ball accelerated? a) Yes. b) No. c) Unable to determine.

10 The diagram shows the positions at 0.05-sec intervals of two balls moving left to right. Are either or both of these balls accelerated? a) Ball A is accelerated. b) Ball B is accelerated. c) Both balls are accelerated. d) Neither ball is accelerated.

11 The feather falls more slowly than the brick, WHY?

12 Tracking a Falling Object How long does it take for the ball to reach the ground? How fast is it traveling when it gets there? Assuming air resistance effects are small, the ball accelerates at 9.8 m/s 2 10 m/s 2. Each second, its velocity increases by 10 m/s.

13 Tracking a Falling Object Starting from rest, its velocity has increased to 10 m/s after the first second; to 20 m/s after 2 s; to 30 m/s after 3 s; etc. 10 m/s 22 MPH 30 m/s 70 MPH! During the first second, its average velocity is 10 m/s 2 = 5 m/s, during which time it travels 5 m. In the first half second, it travels 1.25 m.

14 Tracking a Falling Object The distance increases in proportion to the square of the time:

15 The velocity-versus-time graph for a certain falling object is shown. Is the acceleration of this object a) Yes. b) No. c) Impossible to tell from this graph. constant?

16 Throwing a ball downward It will have a starting velocity different from zero. It will reach the ground more rapidly. It will have a larger velocity when it reaches the ground. v v 0 at d v 0 t 1 2 at 2

17 Throwing a Ball Upward What if the ball is thrown upward? Gravitational acceleration is always directed downward, toward the center of the Earth. The acceleration is in the opposite direction to the original upward velocity.

18 Let the initial velocity be 20 m/s upward. It immediately starts accelerating downward. Every second, the velocity decreases by 10 m/s. After 2 s, the ball has reached its highest point. Its velocity changes direction. Now, the downward acceleration increases the downward velocity.

19 What is the ball s acceleration at the top of its path a) zero. b) +10 m/s c) -10 m/s d) +10 m/s 2 e) -10 m/s 2 (at t=2 s)?

20 Projectile Motion The path that a moving object follows is called its trajectory. An object thrown horizontally is accelerated downward under the influence of gravity. Gravitational acceleration is only vertical, not horizontal. The object s horizontal velocity is unchanged, if we can neglect air resistance. Projectile motion involves the trajectories and velocities of objects that have been launched, shot, or thrown.

21 Does this represent a realistic trajectory? a) Yes. b) No. c) Maybe.

22 What does the trajectory look like? The acceleration of the horizontal motion is zero (if no of air resistance). The acceleration in the vertical direction is constant.

23 What does the trajectory look like? The total velocity at any point is found by adding the vertical component of the velocity, at that point, to the horizontal component of the velocity at that point.

24 What does the trajectory look like? Trajectories for different initial velocities of a ball rolling off a table:

25 Which of these three balls would hit the floor first if all three left the tabletop at the same time? a) The ball with v 0 = v 1. b) The ball with v 0 = v 2. c) The ball with v 0 = v 3. d) They would all hit at the same time.

26 Projectile Motion Treating the vertical motion independently of the horizontal motion, and then combining them to find the trajectory, is the secret. The projectile moves with constant horizontal velocity while it is accelerating downward.

27 Hitting a Target If the rifle is fired directly at the target in a horizontal direction, will the bullet hit the center of the target? Does the bullet fall during its flight?

28 Hitting a Target The trajectory depends on the initial velocity. launch angle.

29 Hitting a Target The greatest distance is achieved using an angle close to 45 if the effects of air resistance are negligible.

30 Hitting a Target For the lowest angle The horizontal velocity is large The ball does not go very high, so its time of flight is short.

31 Hitting a Target For the highest angle The vertical velocity is large The ball goes higher, so its time of flight is longer, but it does not travel very far horizontally.

32 Hitting a Target The intermediate angle of 45 divides the initial velocity equally between the vertical and the horizontal.

33 Which free-throw trajectory has the greatest chance of success? a) upper. b) middle. c) lower. What factors determine the best trajectory? Are these factors different for different situations?

34 An arched shot from farther away stays in the air longer than an arched shot from closer to the basket. Away from the basket, flatter trajectories allow more accurate control. Spin of the basketball, height of release, and other factors also play a role.

35 Which of the two trajectories shown will result in a longer time for the ball to reach home plate? a) The higher trajectory. b) The lower trajectory. c) They will take the same time.