CPO Science Foundations of Physics PDF

Summary

This document is a presentation on geometrical optics, covering fundamental concepts like reflection, refraction, lenses, and mirrors. It's structured as a series of slides and is a good resource for secondary school science.

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CPO Science
Foundations of
Physics

Unit 6, Chapter
 Unit 6: Light and Optics
Chapter 17 Light and Color

 17.1 Reflection and Refraction
 17.2 Mirrors, Lenses, and Images
 17.3 Optical Systems
 Chapter 17 Objectives
1. Describe the functions of convex and
concave lenses, a prism, and a flat mirror.
2. Describe how light rays form an image.
3. Calculate the angles of reflection and
refraction for a single light ray.
4. Draw the ray diagram for a lens and a mirror
showing the object and image.
5. Explain how a fiber-optic circuit acts like a
pipe for light.
6. Describe the difference between a real
image and a virtual image and give an
example of each.
 Chapter 17 Vocabulary Terms
 lens  index of  magnifying glass
 mirror refraction  spherical
 prism  focal point aberration
 optics  focal length  reflection
 geometric  optical axis  diffraction
optics  light ray  telescope
 specular  magnification  focus
reflection  critical angle  total internal
 diffuse  Snell’s law reflection
 converging  real image  resolution
 diverging  virtual image  pixel image
 law of reflection  chromatic  focal plane
 normal line aberration  thin lens formula
 ray diagram  refraction
 magnification  fiber optics
 object  dispersion
17.1 Reflection and Refraction
 Key Question:
How do we describe
the reflection and
refraction of light?
 17.1 Reflection and Refraction
 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.
 17.1 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.
 17.1 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.
 17.1 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.
 17.1 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.
 Law of Reflection
The incident
ray strikes the
mirror.
The reflected
ray bounces
off.
The angle of
incidence
equals the
angle of
reflection.
 17.1 Law of reflection

30o 30o

 A light ray is incident on a plane mirror with a
30 degree angle of incidence.
 Sketch the incident and reflected rays and
determine the angle of reflection.
 17.1 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.
 17.1 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.
 17.1 Index of refraction
The ability of a material to bend rays of light is
described by the index of refraction (n).
 17.1 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 incidence Angle of refraction
(degrees) (degrees)

ni sin i= nr sin
Index of r
refraction of Index of
incident refraction of
material refractive
material
17.1 Calculate the angle of
refraction
 A ray of light traveling
through air is incident
on a smooth surface
of water at an angle of
30° to the normal.
 Calculate the angle of
refraction for the ray
as it enters the water.
 N1 = 1.00 (air)  (N1/N2) sin#1 = sin#2

 N2 = 1. 33 (water)
 Use: sin-1 or
 #1 = 30  Use: arcsin
 #2 = ?
 sin-1(N1/N2) sin#1 = sin-1
 N1sin#1 = sin#2
N2sin#2
 sin-1[(N1/N2) sin#1] =
#2
17.1 Dispersion and prisms
17.1 Dispersion and prisms
17.2 Mirrors, Lenses, and Images

Key Question:
How does a lens or
mirror form an image?
17.2 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.
17.2 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.
17.2 Mirrors, Lenses, and Images

 The virtual image in a flat
mirror is created by the eye
and brain. Sounds are created
by your ears and brain.
17.2 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.
17.2 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.
17.2 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.
 17.2 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:
1. A light ray passing through the center of the
lens is not deflected at all (A).
2. A light ray parallel to the axis passes
through the far focal point (B).
3. A light ray passing through the near focal
point emerges parallel to the axis (C).
 17.3 Optical Systems

Key Question:
How are the properties
of images
determined?
 17.3 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.
 17.3 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.
17.3 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.
17.3 The sharpness of an image

— Diffraction causes a point on an object to
focus as a series of concentric rings
around a bright spot.
 17.3 Thin lens formula
 The thin lens formula is a mathematical way to do
ray diagrams with algebra instead of drawing
lines on graph paper.

1 +1 =
1
Object do di
distance focal
(cm) df length (cm)
Image distance
(cm)
 17.3 Use the thin lens formula

 Calculate the location of the image if the
object is 6 cm in front of a converging lens
with a focal length of 4 cm.
 17.3 Image relay
 A technique known as image relay is used to
analyze an optical system made of two or
more lenses.
Application: The Telescope