1. Reflection
Regular reflection occurs when parallel light rays strike a smooth surface and reflect in the same direction.
Diffuse reflection occurs when light rays reflect off a rough surface and are scattered in different directions.

2. Reflection
The Law of Reflection: When light reflects off a surface, the angle of incidence is always equal to the angle of reflection.
Where are plane mirrors used?

4. Plane mirrors
A virtual image is any image formed by rays that do not actually pass through the location of the image. Light rays are not coming from where the image appears to be.

7. Curved Mirrors Concave and convex
Curved mirrors obey the law of reflection.

8. Concave vs. Convex mirrors
When rays that are parallel to the principal axis strike a concave mirror, they are ALL reflected through the same point, called the focal point.
If several groups of parallel rays are reflected by a concave mirror, each group converges at a point.

9. Concave vs. Convex mirrors
Concave mirrors are also called converging mirrors
Concave mirrors are designed to collect light and bring it to a single point
Examples: Cosmetic mirrors to produce an enlarged image, Telescopes to collect light from a distance source and focus it for viewing
Concave mirrors can also be used to send out beams of light rays
Examples: flashlights, car headlights, dental examination lights

10. Concave vs. Convex mirrors

11. Concave vs. Convex mirrors
Convex mirrors are also called diverging mirrors
Convex mirrors spread out rays
They allow you to view a large region that you could not see with a plane mirror of the same size
Examples: Store security, parking lot safety, side-view mirrors, camera phones

12. Curved mirror definitions
When parallel light rays strike a curved mirror, the reflected rays eventually meet at a common point. The point where the light rays meet, or appear to meet, is called the focal point, F.
The middle of a curved mirror is the vertex. The principal axis is an imaginary line draw through the vertex.
The distance from the vertex to the focal point is the focal length, f.
The center of curvature, C, is the center of the circle that would be formed if you extended the curve of the mirror.
The focal point is half way between the center of curvature and the vertex.

13. Finding the image
Each time you find the image, you must determine the following:
Size: Is it smaller, bigger, or the same size as the object?
Attitude: Is it upright or inverted?
Location: Is it behind or in front of the mirror?
Type: Is it real of virtual?

14. Real vs. Virtual
A real image is formed by light rays that converge at the location of the image.
A real image can be projected onto a screen: If you place a piece of paper at the spot where a real image forms, a focused image will appear on the piece of paper.
A virtual image is any image formed by rays that do not actually pass through the location of the image.
Light rays are not coming from where the image appears to be.
Unlike a real image, a virtual image cannot be projected onto a screen.

16. Drawing a CONCAVE MIRROR ray diagram
(Converging mirror)
Note: Show real rays using solid lines and virtual rays using dashed-lines.
Ray 1: parallel from a point on the object to the principal axis (Rays that are parallel to the principal axis will reflect through the focal point on a concave mirror.)

17. Ray 2: from a point on the object through the focal point
Ray 2: from a point on the object through the focal point. (Rays that pass through the focal point on a concave mirror will be reflected back parallel to the principal axis.)

18. Ray 3: Draw a line from the same point on the object through the center of curvature. When the ray hits the mirror, it will reflect back on itself. This line determines the quality of the mirror. Draw the image where the rays intersect.
Size: Smaller
Attitude: Inverted
Location: In front
Type: Real

19. Complete the following table
LOCATION OF OBJECT
SIZE OF IMAGE
ATTITUDE OF IMAGE
LOCATION OF IMAGE
TYPE OF IMAGE
More than two focal lengths away from mirror
Smaller
Inverted
In front
Real
Between one and two focal lengths away from the mirror
Object is at the focal point
Object is between the mirror and the focal point

20. Drawing a Concave Mirror Ray Diagram Summary
Ray 1: parallel from a point on the object to the principal axis (Rays that are parallel to the principal axis will reflect through the focal point on a concave mirror.)
Ray 2: from a point on the object through the focal point. (Rays that pass through the focal point on a concave mirror will be reflected back parallel to the principal axis.)
Ray 3: Draw a line from the same point on the object through the center of curvature. When the ray hits the mirror, it will reflect back on itself. This line determines the quality of the mirror.
Draw the image where the rays intersect.

21. Object is between one and two focal lengths
Size: Larger
Attitude: Inverted
Location: In front
Type: Real

22. Object is at the focal point
No Image Formed

23. Object is between mirror and focal point
Size: Larger
Attitude: Upright
Location: Behind
Type: Virtual

24. Magnification One use of concave mirrors is magnification.
Magnification: How large or small an image is compared to with the object.

25. Using the formula
Distances are positive if they are in front of the mirror, and negative if they are behind the mirror.
Positive heights are above the principle axis, and negative heights are below the principle axis.
Positive magnifications are above the principle axis, and negative magnifications are below the principle axis
If the image is bigger than the object, then the magnification will be greater than 1.
If the image is smaller than the object, then the magnification will be less than 1.

27. Convex mirrors (Diverging)
Instead of collecting light rays, a convex mirror spreads out the rays.
Drawing a convex ray diagram:
Ray 1: from a point on the ray parallel to the principal axis (Any ray that is parallel to the principal axis will appear to have originated from the focal point.)
Ray 2: from a point on the object toward the focal point (Any ray that is directed at the focal point on a diverging mirror will be reflected back parallel to the principal axis.)
Draw the virtual image where the rays appear to intersect.
WHAT ARE THE PROPERTIES OF THE IMAGE PRODUCED?

28. Ray 1: from a point on the ray parallel to the principal axis (Any ray that is parallel to the principal axis will appear to have originated from the focal point.)

29. Ray 2: from a point on the object toward the focal point (Any ray that is directed at the focal point on a diverging mirror will be reflected back parallel to the principal axis.)

30. Draw the virtual image where the rays appear to intersect.

31. Mirror Equation Rules:
Concave mirrors have positive focal length and convex mirrors have negative focal length
Distances are positive if they are in front of the mirror, and negative if they are behind the mirror.
All measurements are made along the principal axis from the surface of the mirror.

32. References Pearson Investigating Science 10