Human Eye and Colorful World Notes PDF

Summary

These notes explain the structure and function of the human eye, including the cornea, iris, lens, and retina. It also details the eye's power of accommodation, common vision defects (myopia, hypermetropia, presbyopia), and their corrections using lenses.

Full Transcript

L-10 HUMAN EYE AND THE COLOURFUL WORLD
The human eye is one of the most valuable and sensitive sense organs which
helps us to see the colorful world around us. The human eye is like a
camera. The eyeball is approximately spherical in shape with a diameter of
about 2.3cm.
Human eye has the following parts and functions.
Refer fig 10.1
1.CORNEA: Cornea is a transparent membrane in front of the eye. Most
of the refraction of the light rays entering the eye occurs at the outer
surface of the cornea.
2. IRIS: Behind the cornea is a dark muscular diaphragm called iris which
controls the size of the PUPIL.
The pupil is a small opening in the iris through which the light enters the
eye and it regulates and controls the amount of light entering the eye.
In bright sunlight , the iris contracts the pupil to allow less light to enter the
eye and in dim light , the iris expands the pupil to admit more light to see
the objects clearly. Therefore it takes sometime to see clearly in dim light
when we enter a room from bright sunlight outside and vice versa.
3.EYE LENS: It is a convex lens made up of transparent jelly like material.
It is held in position by ciliary muscles.
4.CILIARY MUSCLES : helps to change the curvature of the lens and
hence changes its focal length.
These muscles are attached to the eye lens and can modify the shape of the
eyelens which leads to the variation in focal length.
When the muscles are relaxed, the lens becomes thin.Thus the curvature of
the eyelens decreases and the focal length increases. This enable us to see
distant object clearly.
When the muscles are contracted, the lens becomes thick. Thus the
curvature of the lens increases and the focal length decreases.This enable us
to see nearby objects clearly.
5.RETINA: The lens helps to focus the image of objects on the RETINA
The eye lens forms a real inverted image of the object on the retina by adjusting
its focal length with the help of ciliary muscles.. The light sensitive cells in the
retina then produce electrical signals which are carried by the optic nerves to the
brain. The brain processes the information and then we see the object.

POWER OF ACCOMMODATION OF THE EYE:
The ability of the of the eye lens to adjust its focal length and thereby enable us
to see object from a distance of 25cm to infinity.
The ciliary muscles are capable of modifying the curvature of the lens
and thereby affecting the focal length of the eye lens.
However, the focal length of the eye cannot be reduced below a
certain minimum limit.
If you read a book very close to your eye, it will appear blurred.
The minimum distance, at which objects can be seen most distinctly
without strain is called the 'Least Distance of Distinct Vision' or
the 'Near point of the eye'. For a young adult with normal vision, the
near point is about 25cm.
The farthest point up to which the eye can see objects clearly is called
the 'Far point of the eye'. For a normal eye, it is infinity.
Q. What happens to the image distance in the eye when we increase the
distance of object from the eye?
In human eye the image distance (distance between lens and retina) is
fixed. Therefore no change happens when we increase the distance of
the object from the lens.

DEFECTS OF VISION AND THEIR CORRECTIONS.
When the eye loses it’s power of accommodation ,the person cannot see
the objects clearly. There are three major refractive defects of vision.
1.MYOPIA
Refer fig.10.2
This is also known as nearsightedness.
A person with myopia can see nearby objects clearly but cannot see
distant objects distinctly. The far point is nearer than infinity.
Image of a distant object is formed in front of the retina
Causes:-
1.Excessive curvature of the eye lens
Or
2.Elongation of the eye ball.
Correction
A concave lens of suitable power is used for correction.
2. HYPERMETROPIA OR HYPEROPIA
Refer fig 10.3
Hypermetropia is also known as far- sightedness.
A person with hypermetropia can see distant objects clearly but cannot
see nearby objects distinctly.
Image of nearby objects is formed behind the retina.
Causes:-
1.Focal length of the eye lens is too long.
OR
2. The eyeball has become too small
Correction
A convex lens of suitable power is used for correction.

3.PRESBYOPIA progressive form of farsightedness that affect most
people by old age.
The power of accommodation of the eye decreases with ageing.
Most people find their near point receding gradually.
Causes:
Gradual weakening of ciliary muscles and diminishing flexibility of the
eye lens.
Correction:-
It can be corrected using a convex lens.
Some people who suffer from myopia develop hypermetropia too as they
age.
This can be corrected using BIFOCAL LENS.
The common bifocal lenses consist of both concave and convex lenses.
The upper portion consists of concave lens to facilitate the vision of
faraway objects.
The lower part is a convex lens to facilitate the vision of nearby objects.

CATARACT: The medical condition in which the eye lens of a person
progressively becomes cloudy ( or even opaque), resulting in blurred
vision is called cataract.
Correction:-
The opaque lens is removed surgically and a new artificial lens is
inserted in its place.
NUMERICALS
1. A person cannot see objects nearer than 75 cms from his eyes, while a
person with normal vision can see objects upto 25 cms from his eyes.
Find the nature, the focal length and the power of the correcting lens
used for the defective vision. Name the defect.
Here the defect is hypermetropia,
u = −𝟐𝟓cm
v = −𝟕𝟓𝒄𝒎
f =? P=?
𝟏 𝟏 𝟏
For lens, 𝒇 = 𝒗 − 𝒖
𝟏 𝟏 𝟏
= −𝟕𝟓 + 𝟐𝟓
𝒇

𝟏 +𝟐
=
𝒇 𝟕𝟓
𝟕𝟓
𝒇= = +37.5cm ( the corrective lens is convex lens)
𝟐
𝟏 𝟏𝟎𝟎 𝟖
P = 𝒇 = 𝟕𝟓/𝟐 = 𝟑 = +𝟐. 𝟔𝟕𝑫
2. A person with myopic eye is not able to see objects beyond 2 m from
him. Determine the nature, focal length and power of the lens used to
correct the defect.

Here,
u = -∞
v = -2m
f =? P=?
𝟏 𝟏 ⬚ 𝟏 𝟏 𝟏
For lens,𝒇 = 𝒗 − = −𝟐 + ∞
𝒖 𝒇
𝟏 −𝟏 −𝟏
= + 0=
𝒇 𝟐 𝟐
 f = -2 m (the corrective lens is concave lens)
𝟏 −𝟏
P = 𝒇 = = −𝟎. 𝟓𝑫
𝟐

REFRACTION OF LIGHT THROUGH A TRIANGULAR PRISM

Refer fig 10.4
It has two triangular bases and three rectangular lateral surfaces.
These surfaces are inclined to each other. When a ray of light passes
through a glass prism it refracts twice at air-glass interface as well as
at the glass air interface.
At the first face PQ the ray of light bends towards the normal,
whereas at the other face RS, ray of light bends away from the
normal. Since the two refracting surfaces of the prism are not
parallel, the emergent ray and the incident ray are not parallel to one
another. In this case, the ray of light passing through the prism is
found to bend towards the base of the prism.
The angle between the incident ray and emergent ray is called
ANGLE OF DEVIATION.
The angle between its two lateral faces is called ANGLE OF
PRISM.

DISPERSION OF LIGHT

REFER FIG 10.5
The phenomenon of splitting of white light into seven constituent
colors on passing through a glass prism is known as dispersion of
light.
 Different colors deviate through different angles with respect to
incident ray as they pass through the prism. The red light deviates
the least and violet light maximum.

REASON FOR DISPERSION
1.The refractive index of the glass is different for different colours &
hence they refract at different angles. Violet has the shortest
wavelength so it is most deviated and red has the longest wavelength
so the least deviated.
2.The two refractive surfaces are not parallel.

RECOMBINATION OF SPECTRUM OF LIGHT

REFER FIG 10.6
The components of white light can be recombined to give back white
light. The first prism P1 splits the white light into seven colors and the
second prism P2 is in inverted position w.r.t to P1, again recombines
all the colors to produce white light. It happens because the
dispersion in the first prism is reversed by the second prism.

RAINBOW FORMATION:

Refer fig 10.8
It is a natural spectrum appearing in the sky after a rain shower. A
rainbow is always formed in the direction opposite to that of Sun.
Tiny water droplets present in the atmosphere act as prisms and
disperse sunlight. They refract and disperse the incident sunlight
and reflect it internally and finally refract it again when it comes out
of the droplet. Due to dispersion of light and internal reflection
different colors reach our eyes.
Two conditions necessary to observe a rainbow:
1.It is seen in the sky only after a rain shower.
2.The position of sun should be always behind the observer.

ATMOSPHERIC REFRACTION
When light passes through the different layers of the atmosphere
refraction takes place. This is called atmospheric refraction.
The air in the atmosphere is not at the same temperature.
 The refractive index of the atmosphere gradually increases as we
come down towards the earth.
The refractive index depends on various factors such as temperature,
composition of air, dust particles etc.
All these factors keep fluctuating which causes the fluctuation in the
refractive index of the atmosphere.
Q. Why do stars twinkle?
The twinkling of a star is due to atmospheric refraction of starlight.
Stars appear as point size in the sky, because they are very far away
from us. The star light on entering the earth atmosphere undergoes
refraction due to the difference in the refractive index of the various
layers of the atmosphere. So the star light entering the eye fluctuates
with time. Due to this, at times the star appear brighter and at some
other time fainter. Thus the fluctuating brightness of the star gives
rise to the twinkling effect of the star to the eye.

Q. Why planets do not twinkle?

This is because they are of larger size and much closer to the Earth so
it can be taken as a collection of large number of point
sized(extended) source of light. The dimming effect of one part of the
planet is nullified by the brighter effect in its other parts. On the
whole planets remains brighter and does not appear to twinkle.

Q. Apparent position of star is slightly higher than the actual position. Give
reason.
Ref fig 10.9
Due to atmospheric refraction the stars seem higher than they
actually are. A star light is refracted as soon as it enters the earth’s
atmosphere. Air higher up in the sky is rarer but near the earth’s
surface is denser. So the star light bends more. Though the actual
position of star seems higher in the sky.

ADVANCE SUNRISE AND DELAYED SUNSET
 Refer fig 10.10
Light from the sun on entering the earth’s atmosphere passes from
rarer to denser layers bending towards the normal every time.
Therefore the sun appears to be raised while it is actually below the
horizon. We can see the apparent rising sun about 2 min before it is
actually above the horizon.
Light from the sun on entering earth’s atmosphere passes from rarer
to denser layers bends towards the normal every time. Therefore the
sun appears raised while it is actually below the horizon. So we can
see still the sun 2 minutes even after the sun has set below the horizon

So time from sunrise to sunset is lengthened by about by 2 + 2= 4min
because of atmospheric refraction.
Q. Sun appears bigger during sunrise and sunset. Give reason.
The apparent flattening of the Sun’s disc at sunset and sunrise is also
due to the atmospheric refraction.

SCATTERING OF LIGHT
Light is scattered when it falls on various types of suspended particles in its
path. The spreading of light by particles in a medium is termed as
scattering of light.
TYNDALL EFFECT
The scattering of light by colloidal particles in the medium and the path of
light becomes visible. This is known as Tyndall effect.
SOME NATURAL APPLICATIONS OF TYNDALL EFFECT
1. When sunlight enters a dusty room through a small hole, the
scattering of light by the dust particles in the air make the particles
visible.
2. When sunlight passes through the canopy of dense forest the tiny
water droplets in the mist scatter light and the path of light becomes
visible.
FACTORS ON WHICH THE COLOUR OF SCATTERED
LIGHTDEPENDS:
 1. The colour of scattered light depends on the size of the suspended
particles in the medium such as dust, water droplets etc.
Very fine particles scatter mainly blue light of shorter
wavelength.
Large size particles scatter red light of longer wavelength.
If the size of particle is large enough, then the scattered light
may appear even white.
2. Wave length: The rate of scattering depends the wavelength of the
light.
Blue light has shorter wavelength , therefore it scatters much more
than the red light which has longer wave length.

Q. Why does the sky appear blue?
The particles in the air have size smaller than the wavelength of
visible light. They scatter blue light of shorter wavelength more strongly
than red light. Therefore the scattered blue light enters our eye and the sky
appears blue.

Q. Why does the sky appears dark instead of blue to an astronaut?
Since there is no atmosphere in the outer space, scattering of light does
not take place.Therefore the sky appears dark to an astronaut.

Q. Why are danger signals lights red in colour?
Danger signals are red in colour as red colour has greater
wavelength and it is least scattered by fog or smoke. It can be seen in the
same colour for a long distance.