Phy105 Waves & Optics Notes PDF

Summary

These notes cover the basics of optics, including reflection and refraction from plane surfaces. It discusses light, mirrors, and prisms. They contain definitions and examples.

Full Transcript

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 OPTICS
Optics is the study of Light. By light we mean the visible part of the
electromagnetic spectrum.
Early scientists were curious to study light because without it human
sense of vision cannot be stimulated.
OPTICS
 Vocabulary
Image: That which is formed when light is
reflected or refracted.
Real Image: –
It is made from “real” light rays that converge at
a point.
Can be projected unto a screen because light
actually passes through the point where the
image appears.
Always inverted.
 Vocabulary

Virtual Image–
“Not Real” because it cannot be
projected on a screen
It is formed from virtual rays.
Normal: An imaginary line that is
perpendicular to the reflecting
surface.
Reflection of light from a smooth plane surface

Laws of Reflection
The incident and

I
reflected rays lie in the
same plane with the
normal.

The angle of incidence

l
equals the angle of
r reflection.
θi = θr
 Image formation.
When scattered light from an
object falls on a plane smooth
surface such as a mirror, the light
is reflected, resulting in image 0
formation

k
The image is located behind the
mirror.
Image properties:

Ear
i) virtual
ii) Erect
iii) Same size as the object
iv) Same distance from the reflecting
surface as the object.
v) Laterally inverted
Virtual Images in Plane Mirrors

1
of
Since light energy doesn't flow from the
image, the image is "virtual".
LATERAL INVERSION

I
Diffuse vs Specular Reflection

Diffuse Reflection
Light incident upon a
rough surface

kf
Laws of reflection still
hold; Normals are not
parallel.
Specular Reflection
__
Mirror like reflection
All Normals are parallel

t.it ft
Deviation of Light by a Plane-Mirror 1
1 3
The total angle between the straight-line path of 0 90 i i

p
the incident ray and the reflected ray is twice the
glancing angle
This is called the deviation of the light. It is a it adjacent

measure of the angle through which the light has Grgtfe.to
strayed from its initial straight-line path. joadjacentB
D = 2θ
1 20 2
θ = 90 -i Grazing
D = 180 – 2i
2C
 Effects of Reflection From Plane surfaces
To view your full image in a mirror, the mirror
length needs to be only half your height.

“real” you

mirror only your image
needs to be half as
high as you are tall. Your
image will be twice as far from you
as the mirror.
Effect of mirror rotation
When a mirror is rotated through angle θ about the point of incidence,
the reflected ray rotates through angle 2θ

Plane of the mirror before M1
rotation Incident ray before and
after mirror rotation
θ

θθ
Plane of the mirror N2
after rotation

We can see that the reflected ray has rotated through angle 2θ. Because the reflected ray ends virtually
on the image, the image moves on an arc which also substends angle 2θ at the point of incidence.
Worked Example

A point object is placed 5 cm away from a plane mirror. Calculate the length of
the arc that is traced by the image of the object as the mirror is rotated through
angle 150

5 cm
I1 5 cm

Length of arc I1 I2 = (15/360)(2πx30) ≈ 7.9 cm
 Applications of Reflection From Smooth Plane
Surfaces
Plane mirrors are used as looking glasses (dressing mirrors)
In periscopes
In solar cookers
In kaleidoscopes a
Mirror Periscope

71
 Refraction
Refraction: Sudden change in the direction of a wave as it goes
from one medium to another.
For refraction to occur, light ray must enter the medium obliquely
It is always accompanied by change in speed

A

1 Trirefraction

A B

ta tB ra v
ff
A XB
 1 2
Refraction at Plane Surfaces
Laws of Refraction insr
1. The incident ray, the normal and the refracted ray all lie
in the same plane.
2. For two particular media, the ratio of the sine of the
o
self
f angle of incidence to the sine of the angle of refraction is
a constant, i.e.

TETE
sin i

11800
= constant = n2/n1
sin r
n1 = Refractive index in the first medium
n2 = Refractive index in the second medium
The second law of refraction is also known as Snell’s Law.
 ifi 1.5
9 11
o

Refraction from plane surfaces
In both cases the speed of the wave has decreased.
114 Except
This is indicated by the decrease in wavelength!

N Na

i O r 0

sister 8 e
g 1 57 2
11
Refraction
In which medium does light travel faster? (glass rod
appears bent)
NOT Light ray

f

e
Observe
Absolute Refractive Index of a medium

v is the speed of light in the
new medium.

n is the absolute index of c = 3.0 x 108 m/s
refraction. This is a
measure of optical
density. n is defined as As the index increases the
the ratio of the speed of speed decreases.
light in air (and vacuum) Note: n(air) = 1.0
to the speed of light in a
new medium.
Relative Refractive Index
When light travels from medium 1 of ◆ If nrel < 1 ;
absolute refractive index n1 to speeds up
medium 2 of absolute refractive index
n2, then relative refractive index from ◆ If nrel > 1 ;
medium 1 to medium2 is given by: slows down
n2 c c
n rel = = 
n1 v2 v1
n2 v1
n rel = =
n1 v2
 Snell’s Law of Refraction (nksinθk = constant)

When a wave slows down it bends closer to the normal.{n2>n1}
When a wave speeds up it bends away from the normal. {n2