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What do we see?

What do we see?. Law of Reflection. Properties of Spherical Mirrors. Ray Tracing. Images and the Equations. Physics 212 and 222. Magnetic Forces. TOC. 2. Physics 212 and 222. Magnetic Forces. TOC. θ. θ. Dr. Mike. Dr. Mike. Law of Reflection. 3. Physics 212 and 222.

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What do we see?

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  1. What do we see? Law of Reflection Properties of Spherical Mirrors Ray Tracing Images and the Equations

  2. Physics 212 and 222 Magnetic Forces TOC 2

  3. Physics 212 and 222 Magnetic Forces TOC θ θ Dr. Mike Dr. Mike Law of Reflection 3

  4. Physics 212 and 222 Magnetic Forces TOC Dr. Mike Dr. Mike 4

  5. Physics 212 and 222 Magnetic Forces TOC Dr. Mike Dr. Mike 5

  6. For all reflected light rays, the angle of incidence θ is equal to the angle of reflection θ’. The eye sees the point from which the light originated as though it were in a straight line from the angle of the reflected ray. The eye will not see the reflection of any point on the object unless one of the rays originating from that object strikes the mirror and reflects into the eye. The eye will not see any part of an object for which all rays approaching the eye hits the back of the mirror.

  7. The law of reflection states that: The incident ray, the reflected ray and the normal to the mirror all lie in the same plane. The angle of reflection equals the angle of incidence. θ θ

  8. The law of reflection states that: The incident ray, the reflected ray and the normal to the mirror all lie in the same plane. The angle of reflection equals the angle of incidence. θ θ

  9. C r For a spherical mirror, rays that start at the center point will go back through the center point. This is because the normal to any point on the spherical surface of the mirror points to the center of the sphere.

  10. C The principal axis is any line which crosses through the center point of the mirror and touches the mirror itself. The most commonly used axis is the one that bisects the mirror.

  11. F C f For any mirror, the focal point is defined as the point where parallel rays that are near to the principal axis reflect to a point. Any rays that originate at the focal point will reflect parallel to the principal axis.

  12. C F There are two types of spherical mirrors: concave (converging) and convex (diverging). Parallel rays reflecting off a convex mirror do not reflect to a point. Instead they diverge in such a way as to appear to be coming from the focal point.

  13. C F Although any ray may be traced to find out where an image point is, there are three principal rays that make the job easier. 1. Parallel Ray: Comes in parallel to the principal axis and goes out through the focal point. 2. Focal Ray: Comes in through the focal point and goes out parallel to the principal axis. 3. Radial Ray: Comes in through the center point and retraces its path.

  14. C F Although any ray may be traced to find out where an image points is, there are three principal rays that make the job easier. 1. Parallel Ray: Comes in parallel to the principal axis and goes out as though it came from the focal point. 2. Focal Ray: Comes in toward the focal point and goes out parallel to the principal axis. 3. Radial Ray: Comes in toward the center point and retraces its path.

  15. Images are real if all of the light rays pass through them. Otherwise they are virtual. Real images are inverted, virtual images are upright. For mirrors, real images are found on the same side of the mirror as the object. Virtual images are not. Images may be smaller or larger than the object.

  16. Physics 212 and 222 F C F C Magnetic Forces f, do , ho and di are all positive and hi is negative. TOC f and di are negative and do, ho and hi are positive. Focal length (f), object distance (do) and image distance (di) switch signs as you move across the mirror. Heights (ho for object and hi for image) are positive if the image or object is upright and negative if they are inverted. 16

  17. The same equation may be used to find the image distance, object distance or focal length for both types of spherical mirrors. This is called the mirror equation. The magnification equation may be used to find the height of the image or object or to find the magnification of a mirror.

  18. What do we see? Law of Reflection Properties of Spherical Mirrors Ray Tracing Images and the Equations

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