Chapter 33 Lenses and Optical Instruments

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Presentation transcript:

Chapter 33 Lenses and Optical Instruments The Final Exam Study Guide is posted online Chapter 33 opener. Of the many optical devices we discuss in this Chapter, the magnifying glass is the simplest. Here it is magnifying part of page 886 of this Chapter, which describes how the magnifying glass works according to the ray model. In this Chapter we examine thin lenses in detail, seeing how to determine image position as a function of object position and the focal length of the lens, based on the ray model of light. We then examine optical devices including film and digital cameras, the human eye, eyeglasses, telescopes, and microscopes.

32-3 Formation of Images by Spherical Mirrors Example 32-7: Convex rearview mirror. An external rearview car mirror is convex with a radius of curvature of 16.0 m. Determine the location of the image and its magnification for an object 10.0 m from the mirror. Solution: The ray diagram for a convex lens appears in Figure 32-19b. A convex mirror has a negative focal length, giving di = -4.4 m and M = +0.44. The image is virtual, upright, and smaller than the object.

Problem 26 26. (II) A shaving or makeup mirror is designed to magnify your face by a factor of 1.35 when your face is placed 20.0 cm in front of it. (a) What type of mirror is it? (b) Describe the type of image that it makes of your face. (c) Calculate the required radius of curvature for the mirror.

32-3 Formation of Images by Spherical Mirrors We use ray diagrams to determine where an image will be. For mirrors, we use three key rays, all of which begin on the object: A ray parallel to the axis; after reflection it passes through the focal point. A ray through the focal point; after reflection it is parallel to the axis. A ray perpendicular to the mirror; it reflects back on itself.

Sign Conventions for Mirrors Mirror Equation Sign Conventions for Mirrors Quantity Positive “+” Negative “-” Object distance d0 Real Virtual Image distance, di Focal length, f Concave: f=r/2 Convex: f=-r/2 Magnification, m Upright Upside down f≠d0+di

32-4 Index of Refraction In general, light slows somewhat when traveling through a medium. The index of refraction of the medium is the ratio of the speed of light in vacuum to the speed of light in the medium:

32-5 Refraction: Snell’s Law Light changes direction when crossing a boundary from one medium to another. This is called refraction, and the angle the outgoing ray makes with the normal is called the angle of refraction. Figure 32-21. Refraction. (a) Light refracted when passing from air (n1) into water (n2): n2 > n1. (b) Light refracted when passing from water (n1) into air (n2): n2 < n1.

32-5 Refraction: Snell’s Law The angle of refraction depends on the indices of refraction, and is given by Snell’s law:

32-5 Refraction: Snell’s Law Refraction is what makes objects half-submerged in water look odd. Figure 32-22. Ray diagram showing why a person’s legs look shorter when standing in waist-deep water: the path of light traveling from the bather’s foot to the observer’s eye bends at the water’s surface, and our brain interprets the light as having traveled in a straight line, from higher up (dashed line).

32-5 Refraction: Snell’s Law Example 32-8: Refraction through flat glass. Light traveling in air strikes a flat piece of uniformly thick glass at an incident angle of 60, as shown. If the index of refraction of the glass is 1.50, (a) what is the angle of refraction θA in the glass; (b) what is the angle θB at which the ray emerges from the glass? Solution: a. Applying Snell’s law gives sin θA = 0.577, or θA = 35.3°. b. Snell’s law gives sin θB = 0.866, or θB = 60°. The outgoing ray is parallel to the incoming ray.

Problem 43 43. (II) A light beam strikes a 2.0-cm-thick piece of plastic with a refractive index of 1.62 at a 45° angle. The plastic is on top of a 3.0-cm-thick piece of glass for which What is the distance D in Fig. 32–48?

32-6 Visible Spectrum and Dispersion The visible spectrum contains the full range of wavelengths of light that are visible to the human eye. Figure 32-26. The spectrum of visible light, showing the range of wavelengths for the various colors as seen in air. Many colors, such as brown, do not appear in the spectrum; they are made from a mixture of wavelengths.

32-6 Visible Spectrum and Dispersion This spreading of light into the full spectrum is called dispersion. Figure 32-20. (a) Ray diagram explaining how a rainbow (b) is formed. If Light goes from air to a certain medium:  

32-7 Total Internal Reflection If light passes into a medium with a smaller index of refraction, the angle of refraction is larger. There is an angle of incidence for which the angle of refraction will be 90°; this is called the critical angle:

32-7 Total Internal Reflection; Fiber Optics If the angle of incidence is larger than the critical angle, no refraction occurs. This is called total internal reflection. Figure 32-31. Since n2 < n1, light rays are totally internally reflected if the incident angle θ1 > θc, as for ray L. If θ1 < θc, as for rays I and J, only a part of the light is reflected, and the rest is refracted.

32-7 Total Internal Reflection; Fiber Optics Conceptual Example 32-11: View up from under water. Describe what a person would see who looked up at the world from beneath the perfectly smooth surface of a lake or swimming pool. Figure 32-32. (a) Light rays, and (b) view looking upward from beneath the water (the surface of the water must be very smooth). Example 32–11. Solution: The critical angle for an air-water interface is 49°, so the person will see the upwards view compressed into a 49° circle.

33-1 Thin Lenses; Ray Tracing Thin lenses are those whose thickness is small compared to their radius of curvature. They may be either converging (a) or diverging (b). Figure 33-2. (a) Converging lenses and (b) diverging lenses, shown in cross section. Converging lenses are thicker in the center whereas diverging lenses are thinner in the center. (c) Photo of a converging lens (on the left) and a diverging lens (right). (d) Converging lenses (above), and diverging lenses (below), lying flat, and raised off the paper to form images.

Thin Lenses Thickest in the center Thickest on the edges

33-1 Thin Lenses; Ray Tracing Parallel rays are brought to a focus by a converging lens (one that is thicker in the center than it is at the edge). Figure 33-3. Parallel rays are brought to a focus by a converging thin lens.

33-1 Thin Lenses; Ray Tracing A diverging lens (thicker at the edge than in the center) makes parallel light diverge; the focal point is that point where the diverging rays would converge if projected back. Figure 33-5. Diverging lens.

33-1 Thin Lenses; Ray Tracing The power of a lens is the inverse of its focal length: Lens power is measured in diopters, D: 1 D = 1 m-1.

33-1 Thin Lenses; Ray Tracing Ray tracing for thin lenses is similar to that for mirrors. We have three key rays: The ray that comes in parallel to the axis and exits through the focal point. The ray that comes in through the focal point and exits parallel to the axis. The ray that goes through the center of the lens and is undeflected.

Thin Lenses: Converging Focal point is on both sides of the lens equidistant from the lens image f object f Principle axis Image: Upright or upside down Real or virtual Bigger or smaller Parallel ray goes through f Ray through center Ray through f comes out parallel

Thin Lenses: Diverging Virtual images are formed in front of the lens object f image f f Image: Upright or upside down Real or virtual Bigger or smaller Parallel ray goes through f Ray through center is straight Ray through f comes out parallel

33-2 The Thin Lens Equation; Magnification The sign conventions are slightly different: The focal length is positive for converging lenses and negative for diverging. The object distance is positive when the object is on the same side as the light entering the lens (not an issue except in compound systems); otherwise it is negative. The image distance is positive if the image is on the opposite side from the light entering the lens; otherwise it is negative. The height of the image is positive if the image is upright and negative otherwise.

33-2 Magnification: Magnification = image height / object height = - image distance (di) / object distance (d0) Negative m = upside down Negative di =virtual di d0 d0 -di

Lens Equation Sign Conventions for lenses and mirrors Quantity Positive “+” Negative “-” Object distance d0 Real Virtual Image distance, di Real and behind the lens Virtual and same side as object Focal length, f Converging Diverging Magnification, m Upright Upside down