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HW #4, Due Sep. 21 Ch. 2: P28, PH8, PH16 Ch. 3: P3, P5.

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Presentation on theme: "HW #4, Due Sep. 21 Ch. 2: P28, PH8, PH16 Ch. 3: P3, P5."— Presentation transcript:

1 HW #4, Due Sep. 21 Ch. 2: P28, PH8, PH16 Ch. 3: P3, P5

2 Lecture 9 (chapter 3 continued)
Quick Review: Reflection from Curved Mirrors (Convex Mirrors) The ray rules This Lecture: Ray rules for concave mirrors Finding the image Lenses

3 Chapter 3 Mirrors and Lenses
Read , 3.2, 3.3 (A, B, C* , D), 3.4, 3.5** * Anamorphic Art ** Aberrations

4 Flat mirror revisited virtual image Read Text about the Kaleidoscope

5 (simply apply the law of reflection)
Spherical Mirrors Where is the image? What is the field of view? Ray Tracing (simply apply the law of reflection)

6 Reflection in Curved Mirrors
Convex and Concave Mirrors

7 axis O C F center focal point
Paraxial Rays: Rays that are close to the axis

8 Ray Rules for a Convex Mirror
Ray Rule 1: All rays incident parallel to the axis are reflected so that they appear to be coming form the the focal point, F. Ray Rule 2: All rays that (when extended) pass through center C are reflected back to themselves. Ray Rule 3: All rays that (when extended) pass through F are reflected back parallel to the axis.

9 C F O 1 C F O 3 C F O 2

10 Locating the Image Mirrors *Concave Mirrors
*Concave Lens: virtual image *Convex Mirrors spherical aberration

11

12 “Hand with Reflecting Globe”
M. C. Escher, “Hand with Reflecting Globe” Fig 3.9

13 Concave Mirror axis O C F center focal point

14 Ray Rules for a Concave Mirror
Ray Rule 1: All rays incident parallel to the axis are reflected so that they appear to be coming form the the focal point, F. Ray Rule 2: All rays that (when extended) pass through center C are reflected back to themselves. Ray Rule 3: All rays that (when extended) pass through F are reflected back parallel to the axis.

15 *Concave Mirrors

16 Spherical Lenses

17 Refraction at Curved Surfaces
axis O C center n2 n1 Simply apply the laws of refraction

18 I R axis O C center n2 n1

19 Thin Spherical Lenses Converging Lens: focal length (f) is positive

20 Thin Spherical Lenses Converging Lens: focal length (f) is negative

21 Ray Rules for Converging (and Diverging) Lenses
Ray Rule 1: All rays incident parallel to the axis are deflected through F’ (or as if it came from F’) Ray Rule 2: All rays passing through the center of the lens Continue undeviated. Ray Rule 3: All rays that (when extended, if necessary) pass through F are deflected parallel to the axis.

22 Example: Ray Rules for a converging lens
| F’ F | f f= focal length F’ F |

23 *Magnification (Magnifying Glass)
* Lens Action (Many Applets) principle rays *Thick Lens (Spherical Aberration)

24 Fresnel Lenses

25 Lens Aberrations Chromatic *Thick Lens (Spherical Aberration)
spherical aberration

26 Spherical Aberration

27 *Thick Lens (Spherical Aberration)
spherical aberrationv

28 Curvature, Coma

29 Astigmatism

30 Distortion

31 *Thick Lens (Spherical Aberration)
spherical aberration

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