1 / 29

What is Projectile Motion?

What is Projectile Motion?. Projectile Motion. Two-dimensional motion of an object Vertical Horizontal. Projectile Motion. The ball is in free fall vertically and moves at constant speed horizontally!!!. y. v 0. x. y. x. y. x. y. x. y. x. y. Motion is accelerated

zavad
Télécharger la présentation

What is Projectile Motion?

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. What is Projectile Motion?

  2. Projectile Motion • Two-dimensional motion of an object • Vertical • Horizontal

  3. Projectile Motion The ball is in free fall vertically and moves at constant speed horizontally!!!

  4. y v0 x

  5. y x

  6. y x

  7. y x

  8. y x

  9. y • Motion is accelerated • Acceleration is constant, and downward • a = g = -9.81m/s2 • The horizontal (x) component of velocity is constant • The horizontal and vertical motions are independent of each other, but they have a common time g = -9.81m/s2 x

  10. Types of Projectile Motion • Horizontal • Motion of a ball rolling freely along a level surface • Horizontal velocity is ALWAYS constant • Vertical • Motion of a freely falling object • Force due to gravity • Vertical component of velocity changes with time • Parabolic • Path traced by an object accelerating only in the vertical direction while moving at constant horizontal velocity

  11. Projectile Motion

  12. Examples of Projectile Motion • Launching a Cannon ball

  13. Projectile Motion y x

  14. Problem 1: • Two tennis ball launchers shoot balls at the same time, angle and initial speed from different floors of a tall building. • The balls land in the street below. Ignore air resistance.

  15. Problem 1: • a. Which ball will have the greater acceleration while in flight? Explain your reasoning. • Both have the same vertical acceleration since the net force is due to gravity alone (there is no horizontal acceleration.) Even if the balls were of different mass the acceleration would be the same.

  16. Problem 1: • b. Which ball will hit farther from the base of the building? Explain your reasoning. • Ball A will hit farther from the building since it has a higher starting position and will therefore be in the air longer before it hits the ground. The longer it is in the air, the more time it has to move horizontally.

  17. Problem 1: • c. Which ball will reach a greater maximum height? Explain your reasoning. • Ball A will reach a greater maximum height since its launcher is above B's launcher.

  18. Problem 1: • d. Which ball will be going faster just before hitting the street? Explain your reasoning. • Ball A will be going faster. Both have the same x-velocity, but A will have a greater y-velocity since it has accelerated from a higher height.

  19. Problem 2: • A roadrunner runs directly off a cliff with an initial velocity of 3.5 m/s. What are the components of this velocity? Answer: Vx = 3.5 m/s Vy = 0 m/s • What will be the horizontal velocity 2 seconds after the bird leaves the cliff? Answer: 3.5 m/s – horizontal velocity is unchanging • If the cliff is 300 m high, at what time will the roadrunner reach the ground? (v0 and d0 are both zero) h = dy = ½ * 10 * t2 = 300 t2 = 300 * 2 / 10 = 60 t = 7.75 s

  20. Problem 2: • How far from the cliff will this bird land? • dx = 3.5 * 7.75 = 27.125 m • What is the final vertical velocity at which the roadrunner is traveling? [The vertical velocity at the time when the bird reaches the ground] • Vy = 0 + 9.8 * 7.75 = 77.5 m/s • What is the final horizontal velocity at which the roadrunner is traveling? [The horizontal velocity at the time when the bird reaches the ground] • Vx = 3.5 m/s

  21. Projectile Motion and Satellites

  22. Curvature of the earth enters into our calculations Satellites If I start 5 m above the surface, it will still be at 5 m after one second if it is moving 8000 m/sec

  23. Satellites Throw at 8000 m/sec This is about 18,000 mph Earth circumference is 25,000 miles Takes 25000/18000 = 1.4 hours = 84 minutes Higher altitude longer

  24. Satellites Force of gravity on bowling ball is at 90o to velocity, so it doesn’t change the velocity!!! If no air resistance, gravity doesn’t change speed of satellite, only direction!!!

  25. Farther out you go, the bigger the circumference of the orbit It takes longer for the trip Also, gravity weakens by inverse square law the farther out you go Make the distance so that it takes 24 hours for the orbit Satellite is stationary in the sky!!! Communications Satellites

  26. Distance is about 240,000 miles Takes 27.3 days to make an orbit The Moon

  27. Give the object a speed a bit greater than 8 km/sec and the orbit will be elliptical Elliptical Orbits

  28. Elliptical Orbits

  29. Elliptical Orbits Sum of distances from foci to point on the ellipse is a constant!!!

More Related