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  4. Geometric optics and image
  5. Images formed by plane mirrors

2.1 Images formed by plane mirrors

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By the end of this section, you will be able to:
  • Describe how an image is formed by a plane mirror.
  • Distinguish between real and virtual images.
  • Find the location and characterize the orientation of an image created by a plane mirror.

You only have to look as far as the nearest bathroom to find an example of an image formed by a mirror. Images in a plane mirror    are the same size as the object, are located behind the mirror, and are oriented in the same direction as the object (i.e., “upright”).

To understand how this happens, consider [link] . Two rays emerge from point P , strike the mirror, and reflect into the observer’s eye. Note that we use the law of reflection to construct the reflected rays. If the reflected rays are extended backward behind the mirror (see dashed lines in [link] ), they seem to originate from point Q . This is where the image of point P is located. If we repeat this process for point P , we obtain its image at point Q . You should convince yourself by using basic geometry that the image height (the distance from Q to Q ) is the same as the object height (the distance from P to P ). By forming images of all points of the object, we obtain an upright image of the object behind the mirror.

Figure shows cross section of a flat mirror in the center, a bottle to its left and a faded bottle (indicating that it is an image) to its right. The distances of the object and the image from the base of the mirror are labeled d subscript o and d subscript i respectively. Two rays originating from point P, at the base of the object hit the mirror at two separate points. The reflected rays from these points reach the eye of the observer, shown at the top left. The rays are extended to the right by dotted lines, such that they seem to originate from point Q, at the base of the image. Similarly, two rays, starting from point P prime, at the top of the object hit the mirror and are reflected to the eye of the observer. When extended at the back, these reflected rays seem to originate from point Q prime, at the top of the image.
Two light rays originating from point P on an object are reflected by a flat mirror into the eye of an observer. The reflected rays are obtained by using the law of reflection. Extending these reflected rays backward, they seem to come from point Q behind the mirror, which is where the virtual image is located. Repeating this process for point P gives the image point Q . The image height is thus the same as the object height, the image is upright, and the object distance d o is the same as the image distance d i . (credit: modification of work by Kevin Dufendach)

Notice that the reflected rays appear to the observer to come directly from the image behind the mirror. In reality, these rays come from the points on the mirror where they are reflected. The image behind the mirror is called a virtual image    because it cannot be projected onto a screen—the rays only appear to originate from a common point behind the mirror. If you walk behind the mirror, you cannot see the image, because the rays do not go there. However, in front of the mirror, the rays behave exactly as if they come from behind the mirror, so that is where the virtual image is located.

Later in this chapter, we discuss real images; a real image    can be projected onto a screen because the rays physically go through the image. You can certainly see both real and virtual images. The difference is that a virtual image cannot be projected onto a screen, whereas a real image can.

Locating an image in a plane mirror

The law of reflection tells us that the angle of incidence is the same as the angle of reflection. Applying this to triangles PAB and QAB in [link] and using basic geometry shows that they are congruent triangles. This means that the distance PB from the object to the mirror is the same as the distance BQ from the mirror to the image. The object distance    (denoted d o ) is the distance from the mirror to the object (or, more generally, from the center of the optical element that creates its image). Similarly, the image distance    (denoted d i ) is the distance from the mirror to the image (or, more generally, from the center of the optical element that creates it). If we measure distances from the mirror, then the object and image are in opposite directions, so for a plane mirror, the object and image distances should have the opposite signs:

Questions & Answers

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In physics and mechanics, torque is the rotational equivalent of linear force. It is also referred to as the moment, moment of force, rotational force or turning effect, depending on the field of study.
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Source:  OpenStax, University physics volume 3. OpenStax CNX. Nov 04, 2016 Download for free at http://cnx.org/content/col12067/1.4
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