1. The lecture
Geometric optics By
Mukhamedgaliyeva M.A.

2. Geometric optics
The overall study of how light behaves is called optics.
The branch of optics that focuses on the creation of images is called geometric optics, because it is based on relationships between angles and lines that describe light rays.

3. Reflection and Refraction
A lens is an optical device that is used to bend light in a specific way.
A converging lens bends light so that the light rays come together to a point.
A diverging lens bends light so it spreads light apart instead of coming together.

4. Reflection and Refraction
Mirrors reflect light and allow us to see ourselves.
A prism is another optical device that can cause light to change directions.
A prism is a solid piece of glass with flat polished surfaces.

5. Reflection
Images appear in mirrors because of how light is reflected by mirrors.
The incident ray follows the light falling onto the mirror.
The reflected ray follows the light bouncing off the mirror.

6. Reflection
In specular reflection each incident ray bounces off in a single direction.
A surface that is not shiny creates diffuse reflection.
In diffuse reflection, a single ray of light scatters into many directions.

7. Law of Reflection The incident ray strikes the mirror.
The reflected ray bounces off.
The angle of incidence equals the angle of reflection.

8. Refraction
Light rays may bend as they cross a boundary from one material to another, like from air to water.
This bending of light rays is known as refraction.
The light rays from the straw are refracted (or bent) when they cross from water back into air before reaching your eyes.

9. Refraction
When a ray of light crosses from one material to another, the amount it bends depends on the difference in index of refraction between the two materials.

10. Index of refraction
The ability of a material to bend rays of light is described by the index of refraction (n).

12. Snell's law of refraction
Snell’s law is the relationship between the angles of incidence and refraction and the index of refraction of both materials.
Angle of refraction
(degrees)
Angle of incidence
(degrees)
ni sin Qi = nr sin Qr
Index of refraction of incident material
Index of refraction of refractive material

13. Dispersion and prisms
When white light passes through a glass prism, blue is bent more than red.
Colors between blue and red are bent proportional to their position in the spectrum.

14. Dispersion and prisms
The variation in refractive index with color is called dispersion.
A rainbow is an example of dispersion in nature.
Tiny rain droplets act as prisms separating the colors in the white light rays from the sun.

15. Mirrors, Lenses, and Images
We see a world of images created on the retina of the eye by the lens in the front of the eye.

16. Mirrors, Lenses, and Images
Objects are real physical things that give off or reflect light rays.
Images are “pictures” of objects that are formed in space where light rays meet.

17. Mirrors, Lenses, and Images
The most common image we see every day is our own reflection in a mirror.
The image in a mirror is called a virtual image because the light rays do not actually come together.
The virtual image in a flat mirror is created by the eye and brain.

18. Mirrors, Lenses, and Images
Light rays that enter a converging lens parallel to its axis bend to meet at a point called the focal point.
The distance from the center of the lens to the focal point is called the focal length.
The optical axis usually goes through the center of the lens.

19. A converging lens bends an incident light ray parallel to the optical axis toward the focal point.
A diverging lens bends an incident light ray parallel to the axis outward, away from the focal point

20. The image formed by a lens
A lens can form a virtual image just as a mirror does.
Rays from the same point on an object are bent by the lens so that they appear to come from a much larger object.

21. The image formed by a lens
A converging lens can also form a real image.
In a real image, light rays from the object actually come back together.

22. Drawing ray diagrams
A ray diagram is the best way to understand what type of image is formed by a lens, and whether the image is magnified or inverted.
These three rays follow the rules for how light rays are bent by the lens:
A light ray passing through the center of the lens is not deflected at all (A).
A light ray parallel to the axis passes through the far focal point (B).
A light ray passing through the near focal point emerges parallel to the axis (C).

25. Optical Systems
An optical system is a collection of mirrors, lenses, prisms, or other optical elements that performs a useful function with light.
Characteristics of optical systems are:
The location, type, and magnification of the image.
The amount of light that is collected.
The accuracy of the image in terms of sharpness, color, and distortion.
The ability to change the image, like a telephoto lens on a camera.
The ability to record the image on film or electronically.

26. The sharpness of an image
Defects in the image are called aberrations and can come from several sources.
Chromatic aberration is caused by dispersion, when different colors focus at different distances from the lens.

27. The sharpness of an image
Spherical aberration causes a blurry image because light rays farther from the axis focus to a different point than rays near the axis.

28. The sharpness of an image
Diffraction causes a point on an object to focus as a series of concentric rings around a bright spot.

29. Thin lens formula 1 + 1 = 1 do di df
The thin lens formula is a mathematical way to do ray diagrams with algebra instead of drawing lines on graph paper.
= 1
do di df
Object
distance
focal
length
Image distance

30. Image relay
A technique known as image relay is used to analyze an optical system made of two or more lenses.

31. Application: The Telescope

32. Thank you for attention