1 / 76

Introduction to 2-Dimensional Motion

Introduction to 2-Dimensional Motion. Vectors . Two vectors are equal if they have the same magnitude (how big) and same direction. How to add vectors: Line them up head to tail Draw a vector that connects the tail of the first arrow to the head of the last arrow

belisma
Download Presentation

Introduction to 2-Dimensional 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. Introduction to 2-Dimensional Motion

  2. Vectors • Two vectors are equal if they have the same magnitude (how big) and same direction. • How to add vectors: • Line them up head to tail • Draw a vector that connects the tail of the first arrow to the head of the last arrow • Make sure your calculator is set to DEGREES • Always use UNITS

  3. 2-Dimensional Motion • Definition: motion that occurs with both x and y components. • Example: • Playing pool . • Throwing a ball to another person. • Each dimension of the motion can obey different equations of motion.

  4. Solving 2-D Problems • Resolve all vectors into components • x-component • Y-component • Work the problem as two one-dimensional problems. • Each dimension can obey different equations of motion. • Re-combine the results for the two components at the end of the problem.

  5. Sample Problem • You run in a straight line at a speed of 5.0 m/s in a direction that is 40o south of west. • How far west have you traveled in 2.5 minutes? • How far south have you traveled in 2.5 minutes?

  6. Sample Problem • You run in a straight line at a speed of 5.0 m/s in a direction that is 40o south of west. • How far west have you traveled in 2.5 minutes? • How far south have you traveled in 2.5 minutes? v = 40 m/s

  7. Sample Problem • You run in a straight line at a speed of 5.0 m/s in a direction that is 40o south of west. • How far west have you traveled in 2.5 minutes? • How far south have you traveled in 2.5 minutes? v = 5 m/s, Q = 40o, t = 2.5 min = 150 s vx= v cosQvy= v sin Q vx= 5 cos 40vy= 5 sin 40 vx= vy= x = vxt y = vyt x = ( )(150) y = ( )(150) x = y = vx vy v = 5 m/s

  8. Sample Problem A particle passes through the origin with a speed of 6.2 m/s traveling along the y axis. If the particle accelerates in the negative x direction at 4.4 m/s2. • What are the x and y positions at 5.0 seconds?

  9. Sample Problem A particle passes through the origin with a speed of 6.2 m/s traveling along the y axis. If the particle accelerates in the negative x direction at 4.4 m/s2. • What are the x and y positions at 5.0 seconds? Vo,y = 6.2 m/s, Vo,x = 0 m/s, t = 5 s, ax = -4.4 m/s2, ay = 0 m/s2 x = ? y = ? x = vo,x + at y = vo,y + at x = 0 + (-4.4)(5) y = 6.2 + (0)(5) x = y =

  10. Sample Problem A particle passes through the origin with a speed of 6.2 m/s traveling along the y axis. If the particle accelerates in the negative x direction at 4.4 m/s2. • What are the x and y components of velocity at this time?

  11. Sample Problem A particle passes through the origin with a speed of 6.2 m/s traveling along the y axis. If the particle accelerates in the negative x direction at 4.4 m/s2. • What are the x and y components of velocity at this time? vx = vo,x+ axtvy = voy + axt vx = 0+ (-4.4)(5)vy = 6.2+ 0(5) vx = vy =

  12. Mechanics Quiz • A mass experiences a force vector with components 30N to the right, and 40 N down . ExplainN how to determine the magnitude and direction (angle) of the force vectors. • The resultant vector can found graphically or mathematically. • 30N2 + 40N2 = 2500N2 = 50N

  13. Projectiles

  14. Projectile Motion • Something is fired, thrown, shot, or hurled near the earth’s surface. • Horizontal velocity is constant. • Vertical velocity is accelerated. • Air resistance is ignored.

  15. 1-Dimensional Projectile • Definition: A projectile that moves in a vertical direction only, subject to acceleration by gravity. • Examples: • Drop something off a cliff. • Throw something straight up and catch it. • You calculate vertical motion only. • The motion has no horizontal component.

  16. 2-Dimensional Projectile • Definition: A projectile that moves both horizontally and vertically, subject to acceleration by gravity in vertical direction. • Examples: • Throw a softball to someone else. • Fire a cannon horizontally off a cliff. • Shoot a monkey with a blowgun. • You calculate vertical and horizontal motion.

  17. Horizontal Component of Velocity • Is constant • Not accelerated • Not influence by gravity • Horizontal component velocity vx = v(cosQ) • Follows equation: • x = Vo,xt

  18. Horizontal Component of Velocity

  19. Vertical Component of Velocity • Undergoes accelerated motion • Accelerated by gravity (9.8 m/s2 down) • Vertical component of velocity vy = v(sinQ) • Vy = Vo,y - gt • y = yo + Vo,yt - 1/2gt2 • Vy2 = Vo,y2 - 2g(y – yo)

  20. Horizontal and Vertical

  21. Horizontal and Vertical

  22. Zero Launch Angle Projectiles

  23. Launch angle • Definition: The angle at which a projectile is launched. • The launch angle determines what the trajectory of the projectile will be. • Launch angles can range from -90o (throwing something straight down) to +90o (throwing something straight up) and everything in between.

  24. vo Zero Launch angle • A zero launch angle implies a perfectly horizontal launch.

  25. Sample Problem • The Zambezi River flows over Victoria Falls in Africa. The falls are approximately 108 m high. If the river is flowing horizontally at 3.6 m/s just before going over the falls, what is the speed of the water when it hits the bottom? Assume the water is in freefall as it drops.

  26. Sample Problem • The Zambezi River flows over Victoria Falls in Africa. The falls are approximately 108 m high. If the river is flowing horizontally at 3.6 m/s just before going over the falls, what is the speed of the water when it hits the bottom? Assume the water is in freefall as it drops. yo = 108 m, y = 0 m, g = -9.8 m/s2, vo,x = 3.6 m/s v = ?

  27. Sample Problem • The Zambezi River flows over Victoria Falls in Africa. The falls are approximately 108 m high. If the river is flowing horizontally at 3.6 m/s just before going over the falls, what is the speed of the water when it hits the bottom? Assume the water is in freefall as it drops. yo = 108 m, y = 0 m, g = 9.8 m/s2, vo,x = 3.6 m/s v = ? Gravity doesn’t change horizontal velocity. vo,x = vx =3.6 m/s Vy2 = Vo,y2 - 2g(y – yo) Vy2 = (0)2 – 2(9.8)(0 – 108) Vy =

  28. Sample Problem • The Zambezi River flows over Victoria Falls in Africa. The falls are approximately 108 m high. If the river is flowing horizontally at 3.6 m/s just before going over the falls, what is the speed of the water when it hits the bottom? Assume the water is in freefall as it drops. yo = 108 m, y = 0 m, g = 9.8 m/s2, vo,x = 3.6 m/s v = ? Gravity doesn’t change horizontal velocity. vo,x = vx =3.6 m/s Vy2 = Vo,y2 - 2g(y – yo) v = Vy2 = (0)2 – 2(9.8)(0 – 108) Vy =

  29. Sample Problem • An astronaut on the planet Zircon tosses a rock horizontally with a speed of 6.75 m/s. The rock falls a distance of 1.20 m and lands a horizontal distance of 8.95 m from the astronaut. What is the acceleration due to gravity on Zircon?

  30. Sample Problem • An astronaut on the planet Zircon tosses a rock horizontally with a speed of 6.75 m/s. The rock falls a distance of 1.20 m and lands a horizontal distance of 8.95 m from the astronaut. What is the acceleration due to gravity on Zircon? vo,x = 6.75 m/s, x = 8.95 m, y = 0 m, yo = 1.2, Vo,y = 0 m/s g = ? y = yo + Vo,yt - 1/2gt2 g = -2(y - yo - Vo,yt)/t2 g = -2[0 – 1.2 – (0)( )]/( )2 g = x = vo,xt t = x/vo,x t = 8.95/6.75 t =

  31. Sample Problem • Playing shortstop, you throw a ball horizontally to the second baseman with a speed of 22 m/s. The ball is caught by the second baseman 0.45 s later. • How far were you from the second baseman? • What is the distance of the vertical drop? Should be able to do this on your own!

  32. General Launch Angle Projectiles

  33. vo  General launch angle • Projectile motion is more complicated when the launch angle is not straight up or down (90o or –90o), or perfectly horizontal (0o).

  34. vo  General launch angle • You must begin problems like this by resolving the velocity vector into its components.

  35. Vo,y = Vo sin  Vo,x = Vo cos  Resolving the velocity • Use speed and the launch angle to find horizontal and vertical velocity components Vo 

  36. Vo,y = Vo sin  Vo,x = Vo cos  Resolving the velocity • Then proceed to work problems just like you did with the zero launch angle problems. Vo 

  37. Sample problem • A soccer ball is kicked with a speed of 9.50 m/s at an angle of 25o above the horizontal. If the ball lands at the same level from which is was kicked, how long was it in the air?

  38. Sample problem • A soccer ball is kicked with a speed of 9.50 m/s at an angle of 25o above the horizontal. If the ball lands at the same level from which is was kicked, how long was it in the air? vo = 9.5 m/s, q = 25o, g = -9.8 m/s2, Remember: because it lands at the same height: Dy = y – yo = 0 m and vy =- vo,y Find: Vo,y = Vo sin  and Vo,x = Vo cos  Vo,y = 9.5 sin 25 Vo,x = Vo cos  Vo,y = Vo,x = t = ? Vy = Vo,y - gt t = (Vy - Vo,y )/g t = [( ) – ( )]/9.8 don’t forget vy =- vo,y t =

  39. Sample problem • Snowballs are thrown with a speed of 13 m/s from a roof 7.0 m above the ground. Snowball A is thrown straight downward; snowball B is thrown in a direction 25o above the horizontal. When the snowballs land, is the speed of A greater than, less than, or the same speed of B? Verify your answer by calculation of the landing speed of both snowballs. • We’ll do this in class.

  40. Projectiles launched over level ground • These projectiles have highly symmetric characteristics of motion. • It is handy to know these characteristics, since a knowledge of the symmetry can help in working problems and predicting the motion. • Lets take a look at projectiles launched over level ground.

  41. y x Trajectory of a 2-D Projectile • Definition: The trajectory is the path traveled by any projectile. It is plotted on an x-y graph.

  42. y x Trajectory of a 2-D Projectile • Mathematically, the path is defined by a parabola.

  43. y x Trajectory of a 2-D Projectile • For a projectile launched over level ground, the symmetry is apparent.

  44. y x Range of a 2-D Projectile • Definition: The RANGE of the projectile is how far it travels horizontally. Range

  45. y x Maximum height of a projectile • The MAXIMUM HEIGHT of the projectile occurs when it stops moving upward. Maximum Height Range

  46. y x Maximum height of a projectile • The vertical velocity component is zero at maximum height. Maximum Height Range

  47. y x Maximum height of a projectile • For a projectile launched over level ground, the maximum height occurs halfway through the flight of the projectile. Maximum Height Range

  48. y g g g g g x Acceleration of a projectile • Acceleration points down at 9.8 m/s2 for the entire trajectory of all projectiles.

  49. y x Velocity of a projectile • Velocity is tangent to the path for the entire trajectory. v v v vo vf

  50. y x Velocity of a projectile • The velocity can be resolved into components all along its path. vx vx vy vy vx vy vx vy vx

More Related