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1. Projectile motion can be described by the horizontal and vertical components of motion.

# 1 Notes Chapter 3. 1. Projectile motion can be described by the horizontal and vertical components of motion. 2. How many forces are acting upon the glider ?. Forces ?. In the previous chapter we studied simple straight-line motion—linear motion.

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1. Projectile motion can be described by the horizontal and vertical components of motion.

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  1. # 1 Notes Chapter 3 1. Projectile motion can be described by the horizontal and vertical components of motion.

  2. 2. How many forces are acting upon the glider ? • Forces ?

  3. In the previous chapter we studied simple straight-line motion—linear motion. 3. Now we extend these ideas to nonlinear motion—motion along a curved path. Throw a baseball and the path it follows is a combination of constant-velocity horizontal motion and accelerated vertical motion.

  4. #1. Notes 3.1Vector and Scalar Quantities 4. A vector quantity includes both magnitude and direction, but a scalar quantity includes only magnitude.

  5. #1 Notes 3.1Vector and Scalar Quantities 5. A quantity that requires both magnitude and direction for a complete description is a vector quantity. 6. Examples : Velocity is a vector quantity, as is acceleration. Other quantities, such as momentum, are also vector quantities.

  6. 3.1Vector and Scalar Quantities 7. A quantity that is completely described by magnitude is a scalar quantity. Scalars can be added, subtracted, multiplied, and divided like ordinary numbers. 8. Examples : • When 3 kg of sand is added to 1 kg of cement, the resulting mixture has a mass of 4 kg. • When 5 liters of water are poured from a pail that has 8 liters of water in it, the resulting volume is 3 liters. • If a scheduled 60-minute trip has a 15-minute delay, the trip takes 75 minutes.

  7. # 2 Reflection CFU Vector and Scalar Quantities How does a scalar quantity differ from a vector quantity?

  8. #1 Notes 3.2Velocity Vectors 9. The resultant of two perpendicular vectors is the diagonal of a rectangle constructed with the two vectors as sides.

  9. 5.2Velocity Vectors 10. Drawing Only : By using a scale of 1 cm = 20 km/h and drawing a 3-cm-long vector that points to the right, you represent a velocity of 60 km/h to the right (east).

  10. 5.2Velocity Vectors 11. Drawing only : The airplane’s velocity relative to the ground depends on the airplane’s velocity relative to the air and on the wind’s velocity.

  11. 5.2Velocity Vectors The velocity of something is often the result of combining two or more other velocities. • If a small airplane is flying north at 80 km/h relative to the surrounding air and a tailwind blows north at a velocity of 20 km/h, the plane travels 100 kilometers in one hour relative to the ground below. • What if the plane flies into the wind rather than with the wind? The velocity vectors are now in opposite directions. The resulting speed of the airplane is 60 km/h.

  12. 5.2Velocity Vectors Now consider an 80-km/h airplane flying north caught in a strong crosswind of 60 km/h blowing from west to east. The plane’s speed relative to the ground can be found by adding the two vectors. 12. The result of adding these two vectors, called the resultant, is the diagonal of the rectangle described by the two vectors.

  13. 5.2Velocity Vectors 13. An 80-km/h airplane flying in a 60-km/h crosswind has a resultant speed of 100 km/h relative to the ground.

  14. 14. The Trigonometric Functions SINE COSINE TANGENT

  15. SINE • Prounounced “sign”

  16. COSINE • Prounounced “co-sign”

  17. TANGENT • Prounounced “tan-gent”

  18. Greek Letter q • Prounounced “theta” Represents an unknown angle

  19. hypotenuse hypotenuse opposite opposite adjacent adjacent

  20. We need a way to remember all of these ratios…

  21. Sin 16. SOHCAHTOA Opp Hyp Cos Adj Hyp Tan Opp Adj Old Hippie

  22. 17. Finding sin, cos, and tan

  23. SOHCAHTOA 10 8 6

  24. 18.Find the sine, the cosine, and the tangent of angle A. • Give a fraction and decimal answer (round to 4 places). 10.8 9 A 6

  25. 19. Find the values of the three trigonometric functions of . ? Pythagorean Theorem: 4 5 (3)² + (4)² = c² 5 = c 3

  26. #3 Group Work :Find the sine, the cosine, and the tangent of angle A Give a fraction and decimal answer (round to 4 decimal places). B 24.5 8.2 A 23.1

  27. 21.Finding a side

  28. 21.Ex. A surveyor is standing 50 feet from the base of a large tree. The surveyor measures the angle of elevation to the top of the tree as 71.5°. How tall is the tree? tan 71.5° ? tan 71.5° 71.5° y = 50 (tan 71.5°) 50 y = 50 (2.98868)

  29. #4. CW A person is 200 yards from a river. Rather than walk directly to the river, the person walks along a straight path to the river’s edge at a 60° angle. How far must the person walk to reach the river’s edge? cos 60° x (cos 60°) = 200 200 60° x x X = 400 yards

  30. 5.2Velocity Vectors #5. CW/HW The 3-unit and 4-unit vectors at right angles add to produce a resultant vector of 5 units, at 37° from the horizontal.

  31. 5.2Velocity Vectors #6 CW/ HW The diagonal of a square is , or 1.414, times the length of one of its sides.

  32. #7 aThink, Explain,Small Group, Big GroupVelocity Vectors think! Suppose that an airplane normally flying at 80 km/h encounters wind at a right angle to its forward motion—a crosswind. Will the airplane fly faster or slower than 80 km/h?

  33. #7 Think, Explain, Small G, Big G. Velocity Vectors think! Suppose that an airplane normally flying at 80 km/h encounters wind at a right angle to its forward motion—a crosswind. Will the airplane fly faster or slower than 80 km/h? Answer:A crosswind would increase the speed of the airplane and blow it off course by a predictable amount.

  34. #8. Reflection CFU Velocity Vectors What is the resultant of two perpendicular vectors?

  35. #1. Notes 5.3Components of Vectors 22. The perpendicular components of a vector are independent of each other.

  36. 5.3Components of Vectors 23. Often we will need to change a single vector into an equivalent set of two component vectors at right angles to each other: 24. Any vector can be “resolved” into two component vectors at right angles to each other. 25. Two vectors at right angles that add up to a given vector are known as the components of the given vector. • The process of determining the components of a vector is called resolution.

  37. 5.3Components of Vectors 26.A ball’s velocity can be resolved into horizontal and vertical components.

  38. 5.3Components of Vectors 27.Vectors X and Y are the horizontal and vertical components of a vector V.

  39. #10. Reflection CFU Components of Vectors How do components of a vector affect each other?

  40. #9 HW/CW Review Questions : Answer the questions in complete sentences. P 40 ( #s 1-6) • Problem Solving Follow the steps in solving word problems. P 41 ( #s 19 -26 )

  41. 5.4Projectile Motion 28. The horizontal component of motion for a projectile is just like the horizontal motion of a ball rolling freely along a level surface without friction. 29. The vertical component of a projectile’s velocity is like the motion for a freely falling object.

  42. 5.4Projectile Motion 30. A projectile is any object that moves through the air or space, acted on only by gravity (and air resistance, if any). A cannonball shot from a cannon, a stone thrown into the air, a ball rolling off the edge of a table, a spacecraft circling Earth—all of these are examples of projectiles.

  43. 5.4Projectile Motion 31. Projectiles near the surface of Earth follow a curved path that at first seems rather complicated. These paths are surprisingly simple when we look at the horizontal and vertical components of motion separately.

  44. 5.4Projectile Motion Projectile motion can be separated into components. • Roll a ballalong a horizontal surface, and its velocity is constant because no component of gravitational force acts horizontally.

  45. 5.4Projectile Motion 32. Projectile motion can be separated into components. • Roll a ballalong a horizontal surface, and its velocity is constant because no component of gravitational force acts horizontally. • Drop it, and it accelerates downward and covers a greater vertical distance each second.

  46. 5.4Projectile Motion 33. Most important, the horizontal component of motion for a projectile is completely independent of the vertical component of motion. 34. Each component is independent of the other. 35. Their combined effects produce the variety of curved paths that projectiles follow.

  47. #10. Reflection CFU Projectile Motion Describe the components of projectile motion.

  48. 5.5Projectiles Launched Horizontally 36. The downward motion of a horizontally launched projectile is the same as that of free fall.

  49. 5.5Projectiles Launched Horizontally 37. A strobe-light photo of two balls released simultaneously–one ball drops freely while the other one is projected horizontally.

  50. 5.5Projectiles Launched Horizontally There are two important things to notice in the photo of two balls falling simultaneously: 38.The ball’s horizontal component of motion remains constant. Gravity acts only downward, so the only acceleration of the ball is downward. 39. Both balls fall the same vertical distance in the same time. The vertical distance fallen has nothing to do with the horizontal component of motion.

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