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q. R. q. h. R - s ’. h ’. s - R. s ’. s. Mirrors. Overview : Nothing new here! objects and images convex mirrors Concave Spherical Mirrors The Mirror Eqn, Magnification, Sign Conventions Planar & Convex Spherical Mirrors. Text Reference: Chapter 34.1 examples: 34.1 and 2.
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q R q h R-s’ h’ s-R s’ s Mirrors
Overview : Nothing new here! objects and images convex mirrors Concave Spherical Mirrors The Mirror Eqn, Magnification, Sign Conventions Planar & Convex Spherical Mirrors Text Reference: Chapter 34.1 examples: 34.1 and 2 Today . . .
For the next two lectures we will be studying geometric optics. You already know the fundamentals of what is going on!!! Light propagates as rays in situations in which the length scales are >> than the light’s wavelength incident ray reflected ray qr q1 n1 n2 q2 refracted ray Nothing New! • Reflection: • Refraction: • We will use these laws to understand the properties of mirrors (perfect reflection) and lenses (perfect refraction). • We will also discover properties of combinations of lenses which will allow us to understand such applications as microscopes, telescopes, and eyeglasses.
Objects and Images Object: Light reflects off an object and rays go off in all directions Some rays travel to observer and are “processed” by her or him
object Light reflects off an object and rays go off in all directions Some rays travel to lens and are bent to form “image” Rays from image are seen by observer This image formation is behindmagnifying lens, microscopes and telescopes….. Real images and virtual images……. Objects and Images image
Common misbeliefs on reflection “One-way mirrors” or “one-way glass” These are often shown in “interrogation rooms” or police line-ups. A more familiar example is mirrored sunglasses. In all cases the transmission through the system has to be the same no matter which way the light is going. The sunglasses only appear (to the person looking at them) not to transmit any light because there is no light source behind them. Mirrors reverse right-left, but not up-down Actually, mirrors don’t invert up-down or left-right! They invert the other axis -- distance from the mirror
q R q • We start by considering the reflections from a concave spherical mirror in the paraxial approximation (i.e., small angles of incidence close to a single axis): Concave Spherical Mirrors • First draw a ray (light blue) from the tip of the arrow through the center of the sphere. This ray is reflected straight back since the angle of incidence = 0. • Now draw a ray (white) from the tip of the arrow parallel to the axis. This ray is reflected with angle qas shown.
Concave Spherical Mirrors …continued q R q a a These 3 rays are the “principal rays” • Note also that the green ray intersects the white ray at another point along the axis. We will call this point the focal point ( ). • Note that the blue and white rays intersect in a point, suggesting an inverted image. • To check this, draw another ray (green) which is incident at angle a, as shown. • Note that this ray intersects the other two at the same point, as it must if an image of the arrow is to be formed there.
Where do the rays which are reflected from the convex mirror shown intersect? 1A (b) to right of (a) to left of (c) they don’t intersect • What is the nature of the image of the arrow? 1B Lecture 25, ACT 1 (a) Inverted and in front of the mirror (b) Inverted and in back of the mirror (c) Upright and in back of the mirror
Where do the rays which are reflected from the convex mirror shown intersect? 1A R Lecture 25, ACT 1 (b) to right of (a) to left of (c) they don’t intersect • The angle of incidence = angle of reflection. • Blue ray has normal incidence and is reflected straight back. • White ray is reflected at larger angle than blue ray. • Therefore the reflected rays are diverging!! They do not intersect!
and smaller ! 1B R • What is the nature of the image of the arrow? Lecture 25, ACT 1 (a) Inverted and in front of the mirror (b) Inverted and in back of the mirror (c) Upright and in back of the mirror • Have you ever been to a 7-11, and looked at those mirrors in the corner? • What about the right-side mirror on a car or Jeep (see Jurassic Park / T-Rex scene) • Well, you are looking at a convex mirror like this. So, what is the answer? • To find the image of the arrow, we need to find the point where the reflected rays APPEAR to come from. • The intersection of the extrapolations of the reflected rays gives the image position as shown.
We will now transform the geometric drawings into algebraic equations: !! we want to relates, s’,andR!! a a R h g q b object image s’ s Forq a small angle we can approximate: Defining the focal length f = R/2, The Mirror Equation from triangles, eliminating a, Plugging these back into the above equation relating the angles, we get: This eqn is known as the mirror eqn. Note that there is no mention of qin this equation. Therefore, eqn works for all smallq, i.e., we have an image!
We have derived the mirror eqn which determines the image distance in terms of the object distance and the focal length: q R q h R-s’ h’ s-R s’ s Magnification • What about the size of the image? • How ish’related toh?? • Use similar triangles ….
Magnification …continued • What about the size of the image? • How is h’ related to h?? • From similar triangles: q R q h R-s’ h’ s-R s’ s Now, we can introduce a sign convention. We can indicate that this image is inverted if we define its magnification M as the negative number given by:
Consider an object distances which is less than the focal length: h’ q R q h s s’ f More Sign Conventions • Ray Trace: • Ray through the center of the sphere (light blue) is reflected straight back. • Ray parallel to axis (white) passes through focal pointf. • These rays diverge! I.e., these rays look like they are coming from a point behind the mirror. • Wecall this a “virtual image”, meaning that no light from the object passes through the image point. • This situation is described by the same mirror equations as long as we take the convention that images behind the mirror have negative image distancess΄. I.e.: s΄< 0 → virtual image M>0 → not inverted
What happens as we change the curvature of the mirror? Plane mirror: R = ¥ q q h h’ s s’ f Concave-Planar-Convex IMAGE: virtual upright (non-inverted) • Convex mirror: • R< 0 IMAGE: virtual upright (non-inverted)
In order for a real object to create a real, inverted enlarged image, Lecture 25, ACT 2 a)we must use a concave mirror. b)we must use a convex mirror. c)neither a concave nor a convex mirror can produce this image.
In order for a real object to create a real, inverted enlarged image, Lecture 25, ACT 2 a)we must use a concave mirror. b)we must use a convex mirror. c)neither a concave nor a convex mirror can produce this image. • A convex mirror can only produce a virtual image since all reflected rays will diverge. Therefore, b) is false. • To create a real image with a concave mirror, the object must be outside the focal point. • The example we just did gave a real, inverted reduced image. • Is it possible to choose the parameters such that the image is enlarged?? • The easy (but clever) answer: • h’ is a real image. • Therefore consider the OBJECT to be h’. The IMAGE will be h !!! • Therefore it certainly IS POSSIBLE!! equations follow…
In order for a real object to create a real, inverted enlarged image, • The example we just did gave a real, inverted reduced image. • Is it possible to choose the parameters such that the image is enlarged?? Thus to get a real image we need: Thus to get an inverted enlarged image we need: Thus to get a real, inverted enlarged image we need: Lecture 25, ACT 2 a)we must use a concave mirror. b)we must use a convex mirror. c)neither a concave nor a convex mirror can produce this image.
We have derived the equations for mirrors : Mirror concave convex real (front) virtual (back) real (front) virtual (back) Variable f > 0 f < 0 s > 0 s < 0 s’ > 0 s’ < 0 Summary when the following sign conventions are used: Principal rays “connect” object and image one goes through the center of the mirror the other goes parallel to the optic axis and then is reflected through a focal point the third one is like the second one….
We already know two ways to get a reflection Off a conductor (e.g., aluminum or silver mirror) Total internal reflection (e.g., binoculars) There are at least two other common methods “Fresnel” reflection at an interface between two dielectrics with different indices of refraction, n1 and n2: For light at normal incidence e.g., n1 = 1, nglass =1.5 R = 4% Interference between Fresnel reflections at interfaces separated by 1/4 or 1/2 the wavelength of light [Phys. 114] this can lead to very high reflectivities (>99.9995%, used to couple photons to atoms) or very low reflectivities (<0.1%, used as “anti-reflection” coatings on glasses, camera lenses, etc.) More reflections…
In some systems, e.g., metals and the atmosphere, transparency and color influenced by the oscillation of free (mobile) charges Gold (Au): Silver (Ag): Copper (Cu): Selective reflection: color in metals Al Cu “plasma edge” Au Ag
Lenses Lensmaker’s Formula Lens Equation Reading Assignment: Chapter 34.2 Examples: 34.3,4,6,7 and 8 Next time