Program: B. Sc in Civil Engineering
Course
Title:
Mechanics,
Heat, Thermodynamics, Waves, Oscillations and Physical Optics- Lab
Course
code: PHY 103
Assignment
Experiment
No-01 Experiment Done Date: 28.01.2015
Name
of the Experiment:
To
determine the focal length and hence the power of a convex lens by displacement
method with the help of an optical bench.
Submitted
by:
Name: Mohammed Abdur Razzak
Roll No: 3326, Registration No: WUB/10/13/60/3326,
Batch No: 60/C, Semester
No: Fourth, Year: Second.
Submitted
To:
Name: Md. Shohel Rana
Designation: Lecturer in physics, Basic science Division
(WUB) Date of Submission:
Experiment No.:04
Experiment Name: Determine
the focal length and hence the power of a convex lens by displacement method
with the help of an optical bench.
Theory: If the object and the image screen be so placed on an
optical bench that the distance between them is greater than four times the
focal length (f) of a given convex lens, then there will be two different
positions of the lens which for which an equal sharp image will be obtained on
the image screen.
The
fig represent respectively the positions of the object and the image screen and
the two different positions of the lens for which an equally sharp image is
obtained.
Let
the distance Ol =D and L1 – L2 = x.
From the lens equation , we have
Or,
(since u + v =D)
Applying
sign convention, u is negative.
Or,
Or, u2 – ud =df = 0
Solving the above equation which is quartic, we
have two values of u corresponding to the two positions of the lens. These are
u1 =
-
position L1 of the lens
And u2 =
+
position L2 of the lens
Then x = L1
L2
= u1
u2
=
Or x2 = D2 – 4Df
Or f =
……………….. (1)
Where D is the distance between
the object and the image and must be greater than 4f and x is the distance
between two different positions of the lens.
The power P of the lens s as
usual given by the relation,
P =
diopters
Results:
Table I
|
No. of obs.
|
Position of
|
Displacement
of Lens
X = L1
– L2
(cm)
|
Apparent
distance between object and image
D’ = O
|
Corrected
distance between object and image
D = D’ +
|
|||
|
Object
(O)
|
Image
(I)
|
Lens at
|
|||||
|
L1
|
L2
|
||||||
|
1
|
0
|
45
|
16
|
28.2
|
12.20
|
45
|
|
|
2
|
0
|
50
|
14.4
|
34.4
|
20.00
|
50
|
|
|
3
|
0
|
55
|
14
|
40.30
|
26.30
|
55
|
|
|
4
|
0
|
60
|
12.4
|
46.00
|
33.60
|
60
|
|
|
5
|
0
|
65
|
12.1
|
51.00
|
38.90
|
65
|
|
Table II:
|
No. of obs.
|
Lens
displacement (x) from Tab. II
|
Corrected
Distance (d) from Tab. II
|
Focal
length
|
Mean focal
length (f) cm
|
Power
P =
|
|
1
|
45
|
10.42
|
10.45
|
9.56
|
|
|
2
|
20.00
|
50
|
10.50
|
||
|
3
|
26.30
|
55
|
10.60
|
||
|
4
|
33.60
|
60
|
10.30
|
||
|
5
|
38.90
|
65
|
10.43
|
