1. Chapter 34 Geometric Optics

2. What is Geometric Optics It is the study of light as particles. Geometric optics treats light as particles (or rays) that travels in straight lines. Physical optics (wave optics) deals with the wave nature of light, such as the spreading of waves (diffraction) and the interference of waves.

3. Two types of lens

4. Converging and Diverging Lens

5. Symbols Converging Lens = Convex Lens = Positive Lens Diverging Lens = Concave Lens = Negative Lens

6. Some notations F : focal point O : object I : image f : focal length i : image distance p : object distance Principle axis Your textbook: f : focal length s' : image distance s : object distance

7. Converging Lens

8. Converging Lens (thin) Rules: 1. Rays parallel to axis  Pass through focal point 2. Rays through focal point  Pass parallel to axis 3. Rays through the center  Pass through unaffected

9. Where is the image? Trace at least two light rays. The image is at where the rays meet.

10. How to find the image Trace two rays of light. Where they meet is where the image is.

11. Example Complete the light rays below to find the image. Image

12. What if you move the object beyond 2F?

13. Solution

14. In fact all light rays from the object pass through the image You only need two rays to find the image

15. What if you now move it between F and 2F?

16. At F?

17. Between 0 and F?

18. Demo Exploration of Physics

19. Summary

20. Real and Virtual Image Real image can be projected directly on a screen. Virtual image cannot be projected directly on a screen without extra lenses or mirrors. converge Real image forms when rays actually converge and meet. diverge backward Virtual image forms when rays diverge and do not meet. Position of a virtual image is found by tracing the rays backward.

21. Real and virtual image Real Virtual

22. Lens Equation

23. Lateral Magnification

24. Magnification is related to i and p

26. The sign of magnification m Since the image is inverted, we use minus sign in front.

27. The sign of i i is positive if the image is on the right i is negative if the image is on the left i >0i<0

28. The sign of m i >0, m<0, inverted i 0, upright

29. Example Assume f = 1m, complete the table below (in meters ). pim ∞ 3 2 1.5 1 0.5

30. Solution Assume f = 1m, complete the table below. pim ∞ 10 3 1.5-0.5 2 2 1.5 3-2 1 ∞∞ 0.5 +2

31. Diverging Lens (thin) Rules: 1. Rays parallel to axis  Pass through focal point 2. Rays through focal point  Pass parallel to axis 3. Rays through the center  Pass through unaffected

32. Negative f negative Diverging lens obeys the lens equation too. Except that f is now negative. 2cm Example: -2cm f =-2cm

33. Complete the light rays and find the image

34. Solution

35. Different p

36. The typical case for concave lens For concave lens, the image is always virtual and upright, no matter where the object is.

37. Can you see why i is always negative?

38. Example: Diverging Lens You are given a diverging lens of focal length 20cm. You want to form an virtual image that is 1/3 the height of the object. Where should the object be placed?

39. Ray Diagram for the Example

40. Converging or diverging lens? Converging

41. Converging or diverging lens? Diverging

42. Converging or diverging lens? Converging

43. Confusing signs Converging Lens Diverging Lens Converging Mirror Diverging Mirror Other name Convex Lens Concave Lens Concave Mirror Convex Mirror f+-+- i when image is on the left --++ i when image is on the right ++--

44. Lensmaker’s Equation Proof not required. No need to memorize, will be given in the exam. One question in Mastering Physics. R>0 if convex (bulging) toward the object.

45. Curved mirrors

46. Curved Mirrors Concave mirror Converging mirror Positive mirror Convex mirror Diverging mirror Negative mirror

47. Terminology

48. Symbols Converging Mirror = Concave Mirror Diverging Mirror = Convex Mirror

49. Only one focal point for curved mirrors A lens has two focal points (one on each side of the lens), but a curved mirror only has one focal point. It is important to remember where they are. Concave lens: F in front of the mirror Convex lens: F behind the mirror

50. Concave Mirror Rules F Rules: 1. Rays parallel to axis  Reflect through focal point 2. Rays through focal point  Reflect parallel to axis 3. Rays through the center  Reflect with equal angle Really the same rules as converging lens

51. Convex Mirror Rules F Rules: 1. Rays parallel to axis  Reflect through focal point 2. Rays through focal point  Reflect parallel to axis 3. Rays through the center  Reflect with equal angle Really the same rules as diverging lens

52. Summary

53. Lens Equation applies f is positive for concave mirror f is negative for convex mirror i is positive if image is in front of the mirror i is negative if image is behind the mirror

54. Concave mirror 1

55. Concave mirror 2

56. Concave mirror 3

57. Concave mirror 4

58. Concave mirror case 1 & 4

59. Convex mirror Find the image F Virtual image

60. Convex mirror For convex mirror, the image is always virtual and upright, no matter where the object is.

61. Convex mirror

62. Multiple lenses image in front of the first lens, In the case when the first lens form a image in front of the first lens, simply treat the image as the object for the second lens. We will skip the case when the first lens gives an image behind the second lens.

63. Example: Image of an image An object 8cm high is placed 12cm to the left of a converging lens of focal length 8cm. A second converging lens of focal length 6cm is placed 36cm to the right of the first lens. Find the position and size of the final image.

64. Virtual Object http://science.sbcc.edu/~physics/flash/optics/virtualobject.html p is negative for virtual objects

65. Confusing signs Converging Lens Diverging Lens Converging Mirror Diverging Mirror Other name Convex Lens Concave Lens Concave Mirror Convex Mirror f+-+- i when image is on the left --++ i when image is on the right ++--

66. Summary Both equations are true for lens and mirrors, but you have to be very careful about the signs!

67. Camera

68. Area of view and focal length Longer focal length, the less light is collected, need to compensate by increasing the diameter of the aperture D. You want to keep the “f-number” f/D constant for the same intensity.

69. The eye

70. Nearsighted Eye

71. Farsighted eye

72. Microscope

73. Telescope

74. Reflecting Telescope

75. IQ question A piece of glass is placed above the words “LEAD OXIDE”. LEAD appears inverted, but not oxide. Explain.

76. Angular Magnification

77. Blank Lens