To create a spherical mirror envision a large, silver, mylar beach ball - silly, I know, but stay with me here - that is reflective on both its inside and outside surfaces. After applying the reflective film, the ball hardens. Now, take a knife and cut out a section of the ball's surface. That section is a spherical mirror. If you hold the mirror so that you look into its outer, convex surface, then it will be a convex mirror and the only images you will see will those "trapped inside (behind) the mirror," that is: virtual, reduced, upright images. I call this a "shoplifting" mirror. You see them in the stores located at upper rear corners so that store managers can see what customers are doing in between tall aisle dividers. You may easily experience this by looking into the convex side of a serving spoon, your image is virtual, upright and reduced in size. These mirrors are considered to be negative mirrors since their mirrored surface faces "away from the center of the sphere (our mylar beach ball).
In the diagram shown below, the convex surface is the front of the mirror. The radius of the "mylar beach ball" is behind the mirror and is represented by the length of the line VC where V is the vertex of our convex mirror and C is the center of our ball. The focal length, f, is half of the radius, or the length of the line VF. F is called the focal point.
Back to our mylar, beach ball example. I want you to now hold up the mirrored segment so that you look into its inner, concave surface. That will be a concave mirror and you can see a variety of images depending on how far you stand from the mirror. If the light rays, once reflected off the mirror, converge back together, then the image will be real. It is called a real image because the actual, real, rays of light form the image. Real images can be projected onto screens. (Although not formed by mirrors, but by a lens, the image produced by an overhead projector is a real image that is projected onto the video screen for everyone to view.) Real images have the property that they are always inverted and left-right reversed. (You may have experienced this if you have ever placed slides into a slide projector. You quickly learned that the slides have to be inverted and flipped left-to-right so that the projected image is seen correctly - again an example of a real image produced by a lens, but the same principle applies to real images produced by mirrors. They are inverted and reversed left-to-right.)
In the diagram shown below, the concave surface is the front of the mirror. The radius of the "mylar beach ball" is in front of the mirror and is represented by the length the length of the line CV where C is the center of the ball and V is the vertex of our concave mirror. The focal length, f, is half of the radius, or the length of the line FV. F is called the focal point.
When you were drawing mirrors, you take a compass and sweep out an arc. You then bisect the distance from the center of the mirror to the vertex, that is the radius of the mirror, to find the position of the focus, F, so that CF = FV.
Open the following physlet and activate a mirror and a source. Notice that when the source is placed at the center of the mirror, the rays cross when they reflect from the mirror; also notice if the source can be placed directly on the focus, the rays reflect parallel to each other and to the axis.
Converging (Concave) Mirrors There are three primary rays which are used to locate the images formed by converging mirrors. Each ray starts from the top of the object.
Ray #1 (pink)
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runs parallel to the axis until it reaches the mirror; then it reflects off the mirror and leaves along a path that passes through the mirror's focus
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Ray #2 (gold)
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runs straight through the center of the mirror, reflects off the mirror, and reflects through the center, never bending
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Ray #3 (aqua)
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first passes through the focal point until it reaches the mirror; then it reflects off the mirror and leaves parallel to the mirror's axis
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Remember that ALL rays must have arrows! When all three rays meet, they will form the image. Also, the larger the aperture (or opening) of the mirror, the less aberration you will experience with your ray diagrams, that is, larger radii mirrors make better ray diagrams. In some textbooks, the mirror is actually represented by a vertical line labeled as a mirror. Six Special Cases In each of the following illustrations:
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Region I is greater than two focal lengths in front of the mirror.
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Region II is between one and two focal lengths in front of the mirror,
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Region III is within one focal length in front of the mirror; and, conversely
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Region IV is within one focal length behind the mirror,
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Region V is between one and two focal lengths behind the mirror, and
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Region VI is beyond two focal lengths behind the mirror.
Case #1: object located infinitely far away
Case #2: object is located in region 1 Case #3: object is located on the line between regions I and II, exactly two focal lengths in front of the mirror Case #4: object is located in region II Case #5: object is located on the line between regions II and III, exactly one focal length in front of the mirror Case #6: object is located in region III Take a moment and answer the following questions designed to test your conceptual understanding of the properties of the images formed by concave spherical mirrors.
You might also like to reopen this physlet and activate a concave mirror and an object. Place the object at the far side of the optical bench and move it closer and closer towards the mirror. Notice what happens to the images that are formed.
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