Lenses can be either convex or concave depending on their thickness. A convex lens is thicker in the center and converges light rays, forming a real or virtual image. A concave lens is thinner in the center and diverges light rays, always forming a virtual image. The location and properties of an image formed by a lens depends on the position of the object relative to the lens's focal points, which can be determined using lens formulas and ray diagrams. Lenses are used in optical systems to focus and manipulate light in applications like cameras, microscopes, and eyeglasses.
2. Lenses
Lenses are made of transparent
materials, like glass or plastic.
Each of a lens’ two faces is part of a
sphere and can be convex or concave
If a lens is thicker at the center than the
edges, it is a convex, or converging, lens
since parallel rays will be converged to
meet at the focus.
A lens which is thinner in the center
than the edges is a concave, or diverging,
lens since rays going through it will be
spread out.
Convex
(Converging) Lens
Concave
(Diverging) Lens
3. 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.
5. 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.
6. A converging lens can also form a real image.
In a real image, light rays from the object actually come back
together.
The image formed by a lens
7. 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).
8. Convex Lens: Object Beyond 2F
•• • •F F 2F2F
object
image
The image formed when
an object is placed
beyond 2F is located
behind the lens between
F and 2F. It is a real,
inverted image which is
smaller than the object
itself.
Experiment with this diagram
9. Convex Lens: Object Between 2F and F
•• • •F F 2F2F
object
image
The image formed
when an object is
placed between 2F and
F is located beyond 2F
behind the lens. It is a
real, inverted image,
larger than the object.
10. Convex Lens: Object within F
•• • •F F 2F2F
object
image
The image formed when an object is placed in front of F is
located somewhere beyond F on the same side of the lens as
the object. It is a virtual, upright image which is larger than
the object.
convex lens used as a magnifier
11. Concave Lens Diagram
•• • •F F 2F2F
object
image
No matter where the object is placed, the image will be on the same
side as the object. The image is virtual, upright, and smaller than
the object with a concave lens.
Experiment with this diagram
12. Sign convention for spherical lenses
The sign convention for spherical lenses is the same as in
spherical mirrors except that the distances are measured from the
optical centre (O).
The focal length of a convex lens is positive ( + ve ) and the
focal length of a concave lens is negative ( - ve ).
Direction of incident light
Distance towards the left (- ve )
Height
downwards ( - ve )
Height
upwards ( + ve )
Convex lens
Object
Image
O
Distance towards the right ( + ve )
13. 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
o i f
focal
length (cm)
Image distance
(cm)
Object
distance
(cm)
15. Derivation of Lens Formula (Convex Lens)
Let AB represent an object placed at right angles to the principal
axis at a distance greater than the focal length f of the convex lens.
The image A1B1 is formed beyond 2F2 and is real and inverted.
OA = Object distance = u
OA1 = Image distance = v
OF2 = Focal length = f
C C
16. OAB and OA1B1 are similar
A1B1
A B
=
O A1
O A
------------------- (1)
Similarly , OCF2 and F2A1B1 are similar
A1B1
O C
=
F2A1
O F2
C C
But we know that OC = AB
the above equation can be written as
17. C C
A1B1
A B
=
F2A1
O F2
------------------- (2)
From equation (1) and (2), we get
O A1
O A
= F2A1
O F2
= OA1 – OF2
O F2
v
-u
= v – f
f
Or
v f = - u v + u f ------------------- (3) Dividing Both side by uvf
1
u
=
-1
f
+
1
v
Or
1
f
=
1
v
1
u
–
18. The magnification M of an image is the ratio of the height of
the image to the height of the object:
M =
Image height
Object height
This number is a dimensionless ratio (a length over a length)
and does not have any units
Rule: The magnification factor M of a lens is always positive
and given by:
M =
v
u
Image height
Object height
Magnification of a lens
19. Power of a lens
The power of a lens is the reciprocal of its focal length
The SI unit of power is dioptre (D).
1 dioptre is the power of a lens whose focal length is 1 meter.
The power of a convex lens is positive ( + ve ) and the power of a
concave lens is negative ( - ve ).
)(
1
mf
P
P
f
1
0r
20. 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.
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