AGM Module 1 Lasers & Optical Fibers CSE PDF

Summary

This document provides information on lasers and optical fibers. It covers topics such as the properties of lasers, interaction of radiation with matter, and the principle and structure of optical fibers.

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Dr.Mahesh S. Bannur, AGMRCET, VARUR ENGG PHYSICS CSE Stream MODULE-1
MODULE 1 : LASERS AND OPTICAL FIBERS
Laser and Optical Fibers:
LASER: Characteristic properties of a LASER beam, Interaction of Radiation with Matter, Einstein’s A and
B Coefficients and Expression for Energy Density (Derivation), Laser Action, Population Inversion,
Metastable State, Requisites of a laser system, Semiconductor Diode Laser, Applications: Bar code scanner,
Laser Printer, Laser Cooling (Qualitative), Numerical Problems.

Optical Fiber: Principle and Structure, Propagation of Light, Acceptance angle and Numerical Aperture
(NA), Derivation of Expression for NA, Modes of Propagation, RI Profile, Classification of Optical Fibers,
Attenuation and Fiber Losses, Applications: Fiber Optic networking, Fiber Optic Communication. Numerical
Problems
Pre requisite: Properties of light
Self-learning: Total Internal Reflection

LASER
The term LASER is an acronym for Light Amplification by Stimulated
Emission of Radiation. Laser is a device that produces a highly coherent,
monochromatic, intense beam of light with very small divergence.
The first laser was built by T.H.Maiman in 1960 and since then
extensive research has been carried out on the development of lasers due to
their wide ranging applications.
Coherence: Two waves are said to coherent if the phase difference between
them remains constant.
Einstein’s explanation of interaction of radiation with matter (or)
Explaination of Induced absorption, Spontaneous emission &
Stimulated emission.
Consider a system of energy density E𝜈𝑎𝑛𝑑Let N1& N2 be the
population of the energy states E1& E2 respectively so that (E2− E1) = hν
&E2>E1

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According to Einstein radiation interacts with matter in 3 ways namely:

1) Induced absorption:

Induced absorption is the phenomenon in which an atom(A) in the lower

energy state E1 absorb the incident photon of energy „hν‟ & excite to the

higher energy state E2

If (E2−E1) = hν.
Mathematically it (induced absorption) is represented as

hν +A →𝑨∗or photon + atom→𝑎𝑡𝑜𝑚∗

Also, Rate of induced absorption = 𝐵12𝑁1E𝜈,
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where E𝜈 = E𝑛𝑒𝑟𝑔𝑦𝑑𝑒𝑛𝑠𝑖𝑡𝑦 of radiations &
𝐵12 =𝐸𝑖𝑛𝑠𝑡𝑒𝑖𝑛′𝑠 coefficient for 𝑖𝑛𝑑𝑢𝑐𝑒𝑑𝑎𝑏𝑠𝑜𝑟𝑝𝑡𝑖𝑜𝑛.
2. Spontaneous emission:

Spontaneous emission is the phenomenon in which an atom (A) in the
excited state of energy E2 de-excite to the lower energy state E1 without any
external influence by emitting a photon of energy hν =(E2 −E1).
Mathematically, it is represented as 𝑨∗ → A + hν

Also, Rate of Spontaneous emission = 𝐴21𝑁2
𝑤𝑕𝑒𝑟𝑒𝐴21 =𝐸𝑖𝑛𝑠𝑡𝑒𝑖𝑛′𝑠𝑐𝑜𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑡 for 𝑠𝑝𝑜𝑛𝑡𝑎𝑛𝑒𝑜𝑢𝑠𝑒𝑚𝑖𝑠𝑠𝑖𝑜𝑛.

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3. Stimulated emission:

Stimulated emission is the phenomenon in which an atom (𝑨∗) in the
excited state of energy E2 de-excite to the lower energy state E1 under the
influence of an external photon (hν) by emitting an identical photon of
energy hν =(E2−E1).
Mathematically,𝑠𝑟𝑒𝑝𝑟𝑒𝑠𝑒𝑛𝑡𝑒𝑑𝑎𝑠𝒉𝝂+𝑨∗ → A + hν + hν

Also, Rate of Stimulated emission= 𝐵21𝑁2 E𝜈,
where 𝑈𝜈=𝑒𝑛𝑒𝑟𝑔𝑦𝑑𝑒𝑛𝑠𝑖𝑡𝑦&

𝐵21 =𝐸𝑖𝑛𝑠𝑡𝑒𝑖𝑛′𝑠𝑐𝑜𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑡 for 𝑆𝑝𝑜𝑛𝑡𝑎𝑛𝑒𝑜𝑢𝑠𝑒𝑚𝑖𝑠𝑠𝑖𝑜𝑛.

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Einstein coefficients are mathematical quantities which are a measure of
the probability of absorption or emission of light by an atom or molecule.
Thermodynamic equilibrium is a state in which the energy exchanges due to
emission and absorption processes occur such that the population of each
state remains unaltered.

Derivation of an expression for energy density of radiations in terms of
Einstein’s coefficients (or) Derive the relation between Einstein‟s
coefficients.

Consider a system of energy density E𝜈in thermal equilibrium.

Consider two energy states E1 and E2 of a system of atoms (E2>E1).

Let there be N1 atoms with energy E1

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& N2 be the number density of the energy states E1& E2 respectively,

where
Number density means number of atoms or molecules available per
unit volume of the quantum system.
WKT,

Rate of induced absorption = 𝐵12𝑁1E𝜈,

where 𝐵12 =𝐸𝑖𝑛𝑠𝑡𝑒𝑖𝑛′𝑠𝑐𝑜𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑡 𝑜𝑓 𝑖𝑛𝑑𝑢𝑐𝑒𝑑 𝑎𝑏𝑠𝑜𝑟𝑝𝑡𝑖𝑜𝑛.

Rate of Spontaneous emission = 𝐴21𝑁2

𝑤𝑕𝑒𝑟𝑒𝐴21 =𝐸𝑖𝑛𝑠𝑡𝑒𝑖𝑛′𝑠 𝑐𝑜𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑡 𝑜𝑓 𝑠𝑝𝑜𝑛𝑡𝑎𝑛𝑒𝑜𝑢𝑠 𝑒𝑚𝑖𝑠𝑠𝑖𝑜𝑛 𝑎𝑛𝑑

Rate of Stimulated emission= 𝐵21 𝑁2E ,

where 𝐵21 =𝐸𝑖𝑛𝑠𝑡𝑒𝑖𝑛′𝑠 𝑐𝑜𝑒𝑓𝑓𝑖𝑐𝑖𝑒𝑛𝑡 𝑜𝑓 𝑆𝑡𝑖𝑚𝑢𝑙𝑎𝑡𝑒𝑑 𝑒𝑚𝑖𝑠𝑠𝑖𝑜𝑛.
At thermal equilibrium,
Rate of induced absorption = {𝑅𝑎𝑡𝑒 𝑜𝑓 𝑆𝑝𝑜𝑛𝑡𝑎𝑛𝑒𝑜𝑢𝑠 𝑒𝑚𝑖𝑠𝑠𝑖𝑜𝑛} + {𝑅𝑎𝑡𝑒 𝑜𝑓
𝑆𝑡𝑖𝑚𝑢𝑙𝑎𝑡𝑒𝑑 e𝑚𝑖𝑠𝑠 }

ie: 𝐵12𝑁1E𝜈 = 𝐴21𝑁2+ 𝐵21𝑁2 E𝜈

∴ E( 𝐵12𝑁1− 𝐵21𝑁2) = 𝐴21𝑁2
𝑖𝑒: E𝜈 = 𝐴21𝑁2 (𝐵12𝑁1− 𝐵21𝑁2)

Dividing both Nr & Dr by 𝐵21𝑁2, we get

E = [ ] …….. ……….(1)

( )
According to Boltzmann‟s law, = 𝑒 = 𝑒 …….(2)

From eqns 1 &2 , we get.

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E = [𝐵 ] ……….……..(3)
𝑒
𝐵
But.the energy density of black body radiation is given by Planck‟s law is

E = [ ] ……….……..(4)
𝑒

Comparing eqns 3 & 4, we get = 1or = 𝑩𝟐𝟏

Thus coefficient of Induced absorption = coefficient of stimulated
emission.

And =

Thus, energy density E𝝂 = [ ]
𝑒
This is the expression for energy density in terms of Einstein‟s
coefficients or relation between Einstein‟s coefficients.
Important the terms:
Active medium;
Pumping mechanism ;
Population Inversion ;
Meta stable state and
Laser Cavity( Resonant cavity)
Explanation of the requisites of a laser system.
Requisites of a laser system:

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Requisites of a laser system as discussed above, for the production of laser
beam stimulated emission is essential requirement which is a non-thermal
equilibrium condition. Therefore, to begin stimulated emission, some
requisites are required which is mentioned as below:
1. Active medium is a Solid/Liquid/Gas medium in which pumping
mechanism, lasing, population inversion and stimulated emission of the
radiations takes place.
2. Pumping mechanism is the process in which atoms in the lower states
in order to excite them to higher states with the help of external energy. The
methods of pumping are Optical pumping, Electrical pumping; Forward bias
pumping, chemical pumping, Elastic one-one collisions.
The energy input may be in the form of light energy. This kind of pumping is
called optical pumping and is made use of in the construction of Ruby
laser. If the pumping is achieved by electrical energy input then it is called
electrical pumping.
3. Lasing: The process which leads the emission of stimulates photons after
establishing a population inversion is called lasing action.

4. Population Inversion is condition of system in which the population of
atoms or molecules in higher energy (excited) states exceeds the population
of atoms or molecules in lower (ground) states. N2> N1
When the material is in thermal equilibrium condition, the population
ratio is governed by the Boltzmann factor according to the following
equation:

( )
According to Boltzmann‟s law, = 𝑒 = 𝑒

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It means that the population E2 will be far smaller than the population
N1 at the level E1. The condition in which there are more atoms in the lower
energy level and relatively lesser number of atoms in the higher energy level
is called normal state or equilibrium state.
Thus under thermal equilibrium condition. N 1 > N2

For achievement of laser light stimulated emission should dominate
over absorption. For the stimulated emission to dominate; population of the
upper energy level N2 must exceed the population of the lower energy level
N1, this is called as population inversion. Population inversion is the
condition of the material in which population of the upper energy level N2
far exceeds the population of the lower energy level N1.
N2> N1
This is a non-equilibrium state and exists only for a short time.
Population inversion is obtained by employing pumping technique, which
transfer large number of atoms from lower energy level to higher energy
level.
5. Meta stable state is an intermediate state in which the average life of the
atoms is of the order of 10−2s to 10−3s or milli second.
An atom can be excited to a higher level by supplying energy to it.
Normally excited atoms have short lifetimes and release their energy in a
matter of nanoseconds (10-8 to 10-9 s) through spontaneous emission. It
means that atoms do not stay long enough at the excited state to be
stimulated. As a result, even though the pumping agent continuously raises
the atoms to the excited level, they undergo spontaneous transition and

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rapidly return to the lower energy level. Population inversion cannot be
established under such circumstances. In order to establish the condition of
population inversion, the excited atoms are required to “wait” at the upper
energy level till a large number of atoms accumulate at that level. Such an
opportunity would be provided by metastable states, which is of the order of
10-6 to 10-3 s. This is 103 to 106 times the lifetimes of the ordinary excited
energy levels.
6. Laser Cavity (Resonant Cavity):
It consists of two opposing plane mirrors, with active material placed in
between them. One of the mirrors is partially reflecting while the other is
fully reflecting (100 %). The mirrors reflect the photons to and fro through
the active medium. The mirrors are placed normal to the optic axis of the
material. The spontaneously emitted photons moving along the optic axis
will only stimulate the other atoms from the excited state in the active
medium and the other photons travelling in the other directions will be lost.
So the two mirrors along with the active medium form the laser cavity. Now
a photon moving in a particular direction represents a light wave moving in
the same direction. Inside the cavity two types of waves exist; one type
comprises of waves moving to the right, and the other one, to the left. Two
waves interfere constructively if there is no phase difference between the
two; but their interference becomes destructive if the phase difference is For
constructive interference the distance “L” between the two mirrors should be
such that the cavity should support an integral multiple of half wavelength

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One mirror is highly silvered and the other partially silvered. The distance

between the two reflected mirrors is given by L = ,

where λ = wavelength of incident radiations and
n = number of stationary waves produced.
Semiconductor Diode laser:
Principle, construction and working of Semiconductor Diode laser.

Construction: Metallic contacts are provided to the P and N types in a
heavily doped P-N junction diode. Two opposite faces which are
perpendicular to the plane of the junction are polished and made parallel to
each other. These parallel faces constitute the resonant cavity and laser is
obtained through these faces as shown in Figure. The remaining two faces
are roughened to prevent lasing action in that direction.
1. The schematic diagram of Ga-As semiconductor device is as shown in the
diagram.
2. It consists of heavily doped n-region of Ga-As doped with tellurium and p-
region of Ga-As doped with zinc.
3. The dopants are added in the concentration of the order 1017 to 1019
number of dopants per cm3.
4. The upper and lower surfaces are metalized so that pn-junction is forward
biased.
5. Two surfaces perpendicular to the junction are polished so that they act
as optical resonators and the other two surfaces roughened to prevent
lasing in that direction.
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Principle: Semiconductor diode laser works on the principle of stimulated
emission.
Energy Level Diagram :

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Working:
1. Semi-conductor laser are made up of highly de-generate semi-conductors
having direct band gap like Gallium Arsenide (GaAs).
2. When GaAS diode is forward biased with voltage nearly equal to the
energy gap voltage, electrons from n-region & holes from p-region flow
across the junction creating population inversion in the active jn region.
3. As the voltage is gradually increased due to forward biasing population
inversion is achieved between the valence band and conduction band
which in turn result in stimulated emission.
4. Photons produced are amplified between polished optical resonator
surfaces producing laser beam.
5. GaAs laser produce laser beam of wavelength 8870Å in IR region , GaAsP
produce laser beam of 6500Å in visible region etc.

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Spontaneously emitted photon may trigger stimulated emissions over a
large number of recombinations leading to build of laser radiation of high
power. The energy gap of GaAs is 1.4 eV, the wavelength of emitted light
= 8400A0

Since energy gap is a function of temperature, the wavelength of laser
can be tuned anywhere between 8400A0 to 9000A0.
Advantages of semiconductor laser:
❖ Semiconductor lasers are the smallest and least expensive of all the
lasers available.
❖ The semiconductor lasers find important use in optical
communications since they provide light beams of wavelengths which have
low absorption loss in the optical fibers.

Mention the characteristics of laser beam.
The laser beam characteristics are:
1. They are highly monochromatic.
2. They are highly coherent.
3. They are highly directional.
4. They are highly focusable.
5. They are least divergent.
Applications of lasers:
By the virtue of their high intensity, high degree of
monochromaticity, and coherence, lasers find remarkable applications
in a diverse of fields such as medicine, material processing,
communications, energy resources, 3-D photography etc. They also
find immense applications in defense. Some applications are discussed
below:
Applications of LASER :
LASER has wide range of applications pertaining all disciplines of
engineering. Here in the syllabus only two applications are discussed
relevant to computing.

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LASER Barcode Reader

A barcode scanner, or barcode reader, is a device with lights,
lenses, and a sensor that decodes and captures the information
contained in barcodes. In the early days of 1D codes, codes could
only be read by lasers.
Laser light is shone on the label surface and its reflection is
captured by a sensor (laser photo detector) to read a bar code. A
laser beam is reflected off a mirror and swept left and right to read a
bar code Using laser allows reading of distant and wide bar code labels.

Laser scanners sweep a laser across a barcode to capture the
pattern and decode it. On the flip side, 2D imagers can also read
linear barcodes, though generally not as efficiently or rapidly. But, 2D
imagers can of course read 2D barcodes such as QR Code and Data
Matrix, which laser-based scanners do not do.

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Often, 2D codes are used in conjunction with 1D barcodes in the
production process. However, laser scanners cannot read Data
Matrix or QR codes.
Laser barcode scanners use a visible and repetitive “flashing”
laser light beam, commonly used to track inventory and to enter
purchases into a computerized management system.
Advantages of laser barcode scanner: 1) The laser barcode scanner
is used for non-contact scanning flexibly and efficiently. Normally,
the laser barcode scanner is the only choice when the scanning
distance exceeds 30cm.
The technology improves quality and accuracy, gives
immediate information to help reduce rework, and cuts costs by
up to 50% compared to 2D scanning. It also reduces manual labor
and streamlines coordination and collaboration on site.
A barcode reader or barcode scanner is an optical scanner that
can read printed barcodes, decode the data contained in the barcode to
a computer. Like a flatbed scanner, it consists of a light source, a lens
and a light sensor for translating optical impulses into electrical
signals.
Barcodes encode product information into bars and
alphanumeric characters, making it much faster and easier to ring up
items at a store or track inventory in a warehouse. Besides ease and
speed, bar codes' major business benefits include accuracy, inventory
control and cost savings.

Laser Printing:
Laser printers ware invented at XEROX in 1969 by by researcher
Gary Stark weather.Laser Printers are digital printing devices that are
used to create high quality text and graphics on plain printer. A Diode
Laser is used in the process of printing in LASER Printer.

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Construction:

Laser printing is an electrostatic digital printing process. It produces
high-quality text and graphics (and moderate-quality photographs) by repeatedly
passing a laser beam back and forth over a negatively-charged cylinder called a
"drum" to define a differentially-charged image.
Working Principle:
1. A laser beam projects an image of the page to be printed onto an
electrically charged rotating Photo sensitive drum coated with
selenium.
2. Photo conductivity allows charge to leak away from the areas which
are exposed to light and the area gets positively charged.
3. Toner particles are then electrostatically picked up by the drum‟s
charged areas, which have been exposed to light.
4. The drum then prints the image onto paper by direct contact and
heat, which fuses the ink to the paper.
Advantages
1. Laser printers are generally quiet and fast.
2. Laser printers can produce high quality output on ordinary
papers.
3. The cost per page of toner cartridges is lower than other printers.
Disadvantages
1. The initial cost of laser printers can be high.
2. Laser printers are more expensive than dot-matrix
printers and ink-jet printers
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A laser printer is a popular type of computer printer that uses a non-impact
photocopier technology where there are no keys striking the paper. When a
document is sent to the printer, a laser beam "draws" the document on a selenium-
coated drum using electrical charges.
Laser printers use an electrical charge to attract toner particles to a transfer roller.
Toner particles are pressed onto a piece of paper, while heat and pressure from the
fuser unit permanently fix the image onto the page.

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Common features for laser printers include color printing, copying and or
sorting capabilities, industrial metal housing, user controls, indicators,
application software, and cutters. Laser printers with color printing are capable of
color output in addition to monochrome output.
Types of Laser Printers
 Monochrome Laser Printer. Monochrome laser printers only print in black and white....
 Color Laser Printer. Color laser printers print in cyan, magenta, yellow and black....
 Compact Laser Printer. These printers feature a smaller, compact design....
 Multifunction Laser Printer.
laser, a device that stimulates atoms or molecules to emit light at particular
wavelengths and amplifies that light, typically producing a very narrow beam of
radiation. The emission generally covers an extremely limited range of visible, infrared,
or ultraviolet wavelengths.

Laser Cooling (Qualitative):
Principle of LASER Cooling Laser cooling is the use of dissipative light
forces for reducing the random motion and thus the temperature of
small particles, typically atoms or ions. Depending on the mechanism

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used, the temperature achieved can be in the millikelvin, microkelvin,
or even, nano kelvin regime.

If an atom is traveling toward a laser beam and absorbs a photon
from the laser, it will be slowed by the fact that the photon has
momentum. 𝑝 or P =
It would take a large number of such absorptions to cool the atoms
to near 0K
The following are the types of laser cooling
Doppler Cooling.
Sisyphous Cooling.

Chapter at a Glance
Chapter at a Glance

 The term laser is an acronym for light amplification by stimulated emission of
radiation.
 If the phase difference between two points along any ray remains constant, the
coherence is called temporal coherence.
 If the phase difference between two points in a plane normal to the ray direction
remains constant the coherence is called spatial or lateral coherence.
 Metastable states : These are excited states of an atom with relatively larger life
times of the order of 10– 3 s. As these energy states are neither as stable as ground
state nor as unstable as the other excited states, they are known as metastable
states.
 Spontaneous emission of radiation : When an atom in its excited energy state E2
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makes a transition to the ground state E1on its own, without any external
stimulus, it emits a photon of energy E2– E1. This is known as spontaneous
emission of radiation.
 Stimulated emission of radiation : If a photon having energy E2– E1interacts
with an atom in the energy state E2, the photon forces the atom to undergo
transition to the ground state E1giving rise to another photon of the same energy
E2– E1. This is known as stimulated emission of radiation.
 The light produced by stimulated emission is coherent.
 The rate of absorption of photons is proportional to the number density N1 of the
atoms in ground state and the energy density Ev in the frequency range ν to ν +dν
in incident radiation,i.e,
Rate of absorption = B12 N1 Eν
Where B12is a constant known as Einstein's coefficient of induced absorption.
 Rate of spontaneous emission = A21N2
where A21is a constant known as Einstein's coefficient of spontaneous emission
and N2 is the number of atoms in the excited state.
 Rate of stimulated emission = B21N2E_
where B21 is a constant known as Einstein's coefficient of stimulated emission.
 The state, in which there is a larger number of atoms in the higher energy state
than the lower, is called population inversion. Population inversion ensures
amplification of light.
 The process of raising the atoms from a lower energy state to higher, to create
population inversion, is called pumping.
 Cavities can be constructed using different types of mirrors such that the light
rays return to their original location and orientation after travelling through the
cavity for a certain number of times. Such cavities are known as
resonant cavities.
 The carbon dioxide laser makes use of transitions in the molecular vibrational and
rotational energy levels. Carbon dioxide is the active gas having metastable states.
 In a semiconductor laser, the large forward bias applied to the junction is the
pumping mechanism which produces population inversion.
 Characteristics of laser : Laser is monochromatic, coherent, unidirectional, bright
and can be focussed easily.
 Lasers are used for welding, cutting, drilling, measuring atmospheric pollutants,
surgeries, telecommunication, holography, Laser rangefinder in defense and laser
used in compact disc.

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Important Questions:
1. What is LASER? Enumerate the Characteristics of a LASER Beam.
2. Discuss the three possible ways through which radiation and matter
interaction can take place.
3. Explain the terms, (i) Induced absorption, (ii) Spontaneous emission,
(iii) Stimulated emission, (iv) Population inversion, (v) Meta-stable state
& (vi) Resonant cavity.
4. Explain the rates of absorption and emission and hence derive an
expression for energy density using Einstein‟s A and B coefficients.
5. Explain requisites of LASER system.
6. What is Semiconductor LASER? Describe with energy band diagram
the construction & working of Semiconductor diode LASER along with
applications.
7. Discuss the working of LASER barcode reader.
8. With the help of a sketch describe the principle, construction and
working of the LASER Printer.
9. Explain LASER Cooling and its application.

Numerical Problems:
1. Find the ratio of population of two energy levels in a LASER if the
transition between them produces light of wavelength 6493 A0,
assuming the ambient temperature at 27°C.
2. Find the ratio of population of two energy levels in a medium at thermal
equilibrium, if the wavelength of light emitted at 291 K is 6928 A0.
3. The ratio of population of two energy levels out of which one corresponds
to metastable state is 1.059 × 10−30. Find the wavelength of light emitted
at 330 K.
4. Find the ratio of population of two energy levels in a medium at thermal
equilibrium, if the wavelength of light emitted at 300 K is 10𝜇𝑚. Also find
the effective temperature when energy levels are equally populated.
5. The average power output of a LASER beam of wavelength 6500 A0 is
10 mW. Find the number of photons emitted per second by the LASER
source.
6. The average power of a LASER beam of wavelength 6328 A is 5 mW.
Find the number of photons emitted per second by the LASER source.
7. A pulsed LASER has an average power output 1.5 mW per pulse and
pulse duration is 20 ns. The number of photons emitted per pulse is
estimated to be 1.047 ×108. Find the wavelength of the emitted by the
LASER.

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8. A pulsed LASER with power 1 mW lasts for 10 ns. If the number of
photons emitted per pulse is 5 ×107. Calculate the wavelength of LASER.
9. A Ruby LASER emits a pulse of 20 ns duration with average power per
pulse being 100 kW. If the number of photons in each pulse is
6.981 × 1015, calculate the wavelength of photons.
10. In a LASER system when the energy difference between two energy levels
is 2 × 10−19 J, the average power output of LASER beam is found to be
4 mW. Calculate number of photons emitted per second.

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MODULE I

OPTICAL FIBERS

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What is an Optical Fiber?
Optical Fiber is a transparent di-electric material (like glass/plastic)
which guides/ carry) light along it based on the principle of total reflection of
light.
Optical fiber consists of a cylindrical transparent di-electric material of
high refractive index called core. It is surrounded by another di-electric
transparent material of low refractive index called cladding. Cladding in turn
is surrounded by cylindrical insulator called Sheath, which gives
mechanical strength & protect the fiber from absorption, scattering etc.

Optical fiber is a plastic or transparent fiber that is used to propagate
light. The working principle of this is the total internal reflection from
completely different walls. So light can be transmitted for long distances
because the flexibility of fiber optics is sufficient. So this is used in
microscopes which are in micro size, data communication, in fine
endoscopes design, etc. An optical fiber cable includes three layers like core,
cladding, and jacket. A core layer is enclosed through a cladding.
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Here cladding layer is normally designed with plastic or silica. The
main function of the core within the optical fiber is to transmit an optical
signal while the cladding directs the light in the core. As the optical signal is
guided throughout the fiber, then it is called an optical waveguide. This
article discusses an overview of the numerical aperture of optical fiber.

Total Internal Reflection:
When a ray of light travels from denser to rarer medium it bends away
from the normal. As the angle of incidence increases in the denser medium,
the angle of refraction also increases. For a particular angle of incidence
called the “critical angle”, the refracted ray grazes the surface separating the
media or the angle of refraction is equal to 90°. If the angle of incidence is
greater than the critical angle, the light ray is reflected back to the same
medium. This is called “Total Internal Reflection”.
In total internal reflection, there is no loss of energy. The entire
incident ray is reflected back.
XX1 is the surface separating medium of refractive index n1 and
medium of refractive index n2, n1> n2.
AO and OA1 are incident and refracted rays. θ1 and θ2 are angle of
incidence and angle of refraction, θ2> θ1.
For the ray BO, θc is the critical angle. OB1 is the refracted ray which
grazes the interface. The ray CO incident with an angle greater than θc is
totally reflected back along OC1.

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From Snell‟s law,
n1sinθ1 = n2sinθ2
For total internal reflection,
θ1= θc and θ2 = 90°
n1sinθc = n2 (because sin90°=1)
θc= sin-¹(n2/n1)
In total internal reflection there is no loss or absorption of light energy.
The entire energy is returned along the reflected light. Thus is called Total
internal reflection.
Optical Fibers: They are used in optical communication which on the
principle of total internal reflection (TIR).

Optical fiber is made from transparent dielectrics. It is cylindrical in
shape. The inner cylindrical part is called as core of refractive index n1. The
outer part is called as cladding of refractive index n2, n1 > n2. There is
continuity between core and cladding. Cladding is enclosed inside a
polyurethane jacket. Number of such fibers is grouped to form a cable.

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The light entering through one end of core strikes the interface of the
core and cladding with angle greater than the critical angle and undergoes
total internal reflection. After series of such total internal reflection, it
emerges out of the core. Thus the optical fiber works as a waveguide. Care
must be taken to avoid very sharp bends in the fiber because at sharp
bends, the light ray fails to undergo total internal reflection.

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What is the Numerical Aperture of Optical Fiber?

Definition: The measurement of an optical fiber ability to collect the
occurrence light ray in it is known as the numerical aperture. The short
form of this is NA that illustrates the efficiency with the light which is
collected within the fiber to get propagated. We know that when the light is
propagated through an optical fiber during total internal reflection. So
multiple total internal reflections take place within the fiber to transmit from
one end to another.

Once the light ray is produced from the source of an optical fiber, then
the optical fiber should be very efficient to get the maximum emitted
radiation in it. So we can say that the efficiency of a light which is getting
from the optical fiber is the main character once transmitting a signal
throughout an optical fiber.

The numerical aperture is connected to the acceptance angle because
the acceptance angle is the maximum angle during light travels through the
fiber. Therefore the NA & acceptance angle is associated with each other.

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Derive an expression for acceptance angle or Numerical aperture of an
optical fiber.

Consider a light ray AO incident at an angle „θ0‟ enters into the fiber.
Let „θ1‟ be the angle of refraction for the ray OB. The refracted ray OB
incident at a critical angle (900- θ1) at B grazes the interface between core
and cladding along BC.
If the angle of incidence is greater than critical angle, it undergoes total
internal reflection. Thus θ0 is called the waveguide acceptance angle and
sinθ0 is called the numerical aperture.
Acceptance angle is the maximum angle submitted by the ray with the
axis of the fiber so that light can be accepted and guided along the fiber.

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Let 𝑛1, 𝑛2&𝑛𝑜be the RI of core, cladding and launch medium respectively.
Also OA incident ray, AB refracted ray, BC totally reflected ray, 𝜃𝑖&𝜃𝑟be the
angles of incidence, refraction at A &𝜃&𝜃𝑟be the angle of incidence and
angle of refraction at B respectively.

By Snell‟s law at position “O”,
Let n0, n1 and n2 be the refractive indices of the medium, core and cladding
respectively.
From Snell‟s law,
nosinθ0 = n1sinθ1 → (1)
From Snell‟s law,
At „B‟ the angle of incidence is (900 – θ1)
n1sin(900 – θ1) = n2 sin900
n1cosθ1 = n2
cosθ1 = → (2)
From equation (1), we have
Rearrange the equation (1)
sinθ0 = sinθ1

sinθ0 = √ 𝑐𝑜𝑠 𝜃 ……. (3) ( √ 𝑐𝑜𝑠 𝜃 )

Using eqn. (2) in (3)
Put the value of cos θ1 in equn(3) from equn(2)

sinθ0 = √

𝑛 𝑛
sinθ0 = √
𝑛

sinθ0 = x √𝑛 𝑛

√
sinθ0 = ……… (4)
𝑛

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If the surrounding medium is air 𝑛 , then
sinθ0 = √𝑛 𝑛
Where Sinθo is called numerical aperture (N.A).
N.A = √𝑛 𝑛
Therefore, for any angle of incidence equal to θi equal to or less than θ0,
the incident ray is able to propagate.
θi < θ0
sinθi < sinθ0
sin θi √𝑛 𝑛
sin θi n2
Relation between N.A and Δ:
Consider Δ=

𝑛 𝑛 = 𝑛 ……(1)
We have
Expression for numerical aperture
N.A = √𝑛 𝑛
N.A. = √ 𝑛 𝑛 𝑛 𝑛 ….. (2)
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Using equation (1), we have

N.A. = √ 𝑛 𝑛 𝑛 …… (3)

Usually R.I. of core (n1) is nearly equal to R.I. of cladding (n2)i.e. n1 n2
Hence, we can write n1 + n2 = 2n1
By making this substitution equation 3 becomes
N.A. = √ 𝑛
N.A. = √ 𝑛
N.A. = n1√ ……. (4)
Thus, the numerical aperture can be increased by increasing the fractional
index change.
It appears from the above that an increase in the value of Δ increases the
numerical aperture and thus enhances the light gathering capacity of the
fiber. But we cannot increase Δ to a very large value, since it leads to what is
known as “intermodal dispersion” which causes signal distortion. This
dispersion causes distortion in the signal.

V-number:
“The number of modes supported for propagation in the fiber is
determined by
a parameter called V-number”.
If the surrounding medium is air, then
𝑑
√𝑛 𝑛
Where, „d‟ is the core diameter,
n1 and n2 are refractive indices of core and cladding respectively,
„λ‟ is the wavelength of light propagating in the fiber.

V= (𝑁𝐴)
If the fiber is surrounded by a medium of refractive index n0, then,
√𝑛 𝑛
V=
For V >1, the number of modes supported by the fiber is given by,
Number of modes
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Modes of propagation:

The paths along which the light is guided in the fiber are called modes
of propagation and the number of modes of the fiber is given by N.
Types of optical fibers:
In an optical fiber the refractive index of cladding is uniform and the
refractive index of core may be uniform or may vary in a particular way such
that the refractive index decreases from the axis radialy.
Refractive index profile:
The curve which represents tha variation of R.I. w.r.t. the radial distance
from the axis of the fiber is called refractive index profile.

Following are the different types of fibers:
1. Single mode fiber
2. Step index multimode fiber
3. Graded index multimode fiber
This classification is done depending on the refractive index profile and
the number of modes that the fiber can guide.

1. Single mode fiber:
A single mode fiber has a core material of uniform R.I. value. The cladding
is also of uniform R.I. But the R.I. of cladding is less than that of the core.
This results in a sudden increase in the value of R.I. from cladding to core.
Thus its R.I. profile takes the shape of a step. The diameter value of the core
is about 8 to 10μm and external diameter of cladding is 60 to 70μm.
Because of its narrow core, it can guide just a single mode as shown in
figure. Refractive index of core and cladding has uniform value; there is an
increase in refractive index from cladding to core.
Applications: They are used in submarine. It is used in long hand
communication due to higher bandwidth. They transmit transformation to
longer distance due to negligible dispersion.

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2. Step index multimode fiber: It is similar to single mode fiber but core
has large diameter. The diameter value of the core is about 50 to 200μm
and external diameter of cladding is 100 to 250μm. But the core is
comparatively larger in diameter. It can propagate large number of modes as
shown in figure. Laser or LED is used as a source of light. It has an
application in data links.

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Applications: They are used in submarine. It is used in short distance
communication due to lower bandwidth. They transmit transformation to
shorter distance due to negligible dispersion.

3.Graded index multimode fiber: It is also called GRIN. The geometry of
the GRIN multimode fiber is similar to that of step index multimode fiber. Its
core material has a special feature that its R.I. value decreases in the
radially outwards direction from the axis and becomes equal to that of the
cladding at the interface. But the R.I. of the cladding remains uniform.
The refractive index profile is shown in figure. The incident rays bends and
takes a periodic path along the axis. The rays have different paths with
same period. Laser or LED is used as a source of light. It is the expensive of
all. It is used in telephone trunk between central offices.

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Applications: They are used in the telephone trunk between central offices.
It is used in short distance communication due to lower bandwidth. They
transmit transformation to shorter distance.

Signal distortion in optical fibers:
The propagation of a signal through the optical fiber involves total
internal reflection of light rays many times. Further, the rays are reflected at
various angles. The rays reflected at higher angles travel greater distances
than the rays reflected at lower angles. As a result, all the rays do not arrive
at the end of the fiber simultaneously and the light pulse broadens as it
travels through the fiber. Since the output pulse does not match with the
input pulse, the signal is said to be distorted.
If white light is used instead of monochromatic light, another kind of
distortion occurs. Since radiation of different wavelengths has different
velocities, they do not arrive at the output simultaneously. This distortion is
called chromatic dispersion.
The signal distortion is quite considerable in multimode step index
fibers. In graded index fibers, the light travels with different velocities in
different parts of the core as the refractive index varies radially along the
core. The rays travel faster near the interface. Hence all the rays arrive at
the output almost at the same time and the signal distortion is reduced. In a
single mode step index fiber the distortion is less than that in multimode
step index fibers.
Signal attenuation in optical fibers:
Attenuation is the loss of optical power as light travels through a fiber.
The power loss of optical signal when they propagated through optical
fiber is known as attenuation (PL).
The power loss PL in decibel (dB) is given by

PL = 𝑙𝑜𝑔 ( ) ……..(1)
Pin is the input power and Pout is the output power of signal.
The attenuation constant( ) for optical fibers is defined as the power
loss per unit length and is expressed in dB/km.
It is expressed in decibel/kilometre [dB/km].

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= 𝑙𝑜𝑔 ( ) …….. (2)
Where, L be the length of fiber & is measured in Km.
Attenuation can be caused by three mechanisms.
Type of Attenuation in an Optical fiber:
1. Absorption losses:-
Absorption of photons by impurities like metal ions such as iron,
chromium, cobalt and copper in the silica glass of which the fiber is made
of. During signal processing photons interact with electrons of impurity
atoms. The atoms are excited and de-excite by emitting photons of different
characteristics. Hence it is a loss of energy. The other impurity such as
hydroxyl ions (OH) causes significant absorption loss. The absorption of
photons by fiber material itself is called intrinsic absorption.
2. Scattering losses:
When the wavelength of the photon is comparable to the size of the
particle then the scattering takes place. Because of the non-uniformity in
manufacturing, the refractive index changes with length leads to a
scattering. This type of scattering is called as Rayleigh scattering. It is
inversely proportional to the fourth power of wavelength. Scattering of
photons also takes place due to trapped gas bubbles which are not dissolved
at the time of manufacturing.
3. Radiation losses:
Radiation losses occur due to macroscopic bends and microscopic
bends.
a. Macroscopic bending: All optical fibers are having critical radius of
curvature provided by the manufacturer. If the fiber is bent below that
specification of radius of curvature, the light ray incident on the core
cladding interface will not satisfy the condition of TIR. This causes loss of
optical power.
b. Microscopic bending: Optical power loss in optical fibers is due to non-
uniformity of the optical fibers when they are laid. Non uniformity is due to
manufacturing defects and also lateral pressure built up on the fiber. The
defect due to nonuniformity (microbendings) can be overcome by
introducing optical fiber inside a good strengthen polyurethane jacket.

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Application of optical fiber: (Point to point communication in OF)

In an optical fiber communication system, the input signals (audio,
video or other digital data) are used to modulate light from a source like a
LED or a semiconductor LASER and is transmitted through optical fiber. At
the receiving end the signal is demodulated to reproduce the input signal. If
data transfer takes place between only two devices then, it is called point to
point communication.
A fiber optic communication system is very much similar to a
traditional communication system and has three major components. A
transmitter converts electrical signals to light signals, an optical fibre
transmits the signals and a receiver captures the signals at the other end of
the fiber and converts them to electrical signals.
The transmitter consists of a light source supported by necessary drive
circuits. First voice is converted into electrical signals using a transducer. It
is digitized (converted to binary electrical signals) using a coder. The
digitized signal, which carries the voice information, is fed to an optical
transmitter. The light source in optical transmitter (LED or laser diode)
emits modulated light, which is transmitted through optical fiber. The light
emitted by the source is in the IR range with a wavelength of 850nm,
1300nm or 1550nm.
Optical fiber communication process : The communication using
Optical fiber is as follows. First voice is converted into electrical signal using
a transducer. It is digitized using a Coder. The digitized signal, which carries
the voice information, is fed to an optical transmitter. The light source in
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optical transmitter (LED or LASER Diode) emits modulated light, which is
transmitted through the optical fiber. At the other end the modulated light
signal is detected by a photo detector and is decoded using a decoder.
Finally the information is converted into analog electrical signal and is
fed to a loud speaker, which converts the signal to voice (sound).
On the other end the modulated light signal is detected by a photo
detector is amplified and is decoded using a decoder. The output is fed to a
suitable transducers to convert it into an audio or video form.
Applications of Optical Fibers:

Fiber Optic Networking
Local Area Network
A Local Area Network (LAN) is a type of computer network that interconnects
multiple computers and computer driven devices in a particular physical
location. Traditionally copper coaxial cables are used for for LAN.

Figure : Fiber Optic LAN

Abbreviations:

1. PON - Passive Optical Network
2. ONT - Optical Network Terminal
3. ODN - Optical Distribution Network
4. OLT - Optical Line Terminal
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5. ONU - Optical Network Unit.

Passive Optical LAN:
A passive optical network refers to a fiber-optic network utilizing a
point-to-multipoint topology and optical splitters to deliver data from a
single transmission point to multiple user endpoints.Passive here refers to
the unpowered condition of the fiber and splitting/combining components.
Passive optical LANs are built entirely using Optical fiber cables. The passive
optical LAN works on the concept of optical network terminals (ONT) and
passive optical splitters.
Network switches act as passive splitters and the commercial
media converters act as optical network terminals in a real-time application
of passive optical LAN.

Advantages:
1. High speeds and bandwidth
2. Longer distances are possible
3. Less chance of errors

Advantages
1. Optical fibers can carry very large amounts of information in either digital
or analog form.
2. The raw material for optical fiber is of low cost and abundant.
3. It has low cost /meter/ channel
4. Cables are very compact
5. Signals are protected from radiation from lightning or sparking
6. There is no energy radiation from fiber
7. No sparks are generated.

Disadvantages
1. The optical connectors are very costly
2. Maintenance cost is high
3. They cannot be bent too sharply
4. They under go structural changes with temperature

Advantages of optical communication system:
1) It carries very large amount of information in either digital or analog form
due to its large bandwidth.
2) The materials used for making optical fiber are dielectric nature. So, it
doesn‟t produces or receives any electromagnetic and R-F interferences.
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3) Fibers are much easier to transport because of their compactness and
lightweight.
4) It is easily compatible with electronic system.
5) It can be operated in high temperature range.
6) It does not pick up any conducted noise.
7) Not affected by corrosion and moisture.
8) It does not get affected by nuclear radiations.
9) No sparks are generated because the signal is optical signal.

Model Questions :
1. Define the terms: (i) angle of acceptance, (ii) numerical aperture,
(iii) modes of propagation & (iv) refractive index profile.
2. Obtain an expression for numerical aperture and arrive at the condition
for propagation.
3. Explain modes of propagation and RI profile.
4. What is attenuation? Explain the factors contributing to the fiber loss.
5. Discuss the types of optical fibers based on modes of propagation and
RI profile.
6. Explain attenuation along with the expression for attenuation co-efficient
and also discuss the types of fiber losses.
7. Explain the Fiber Optic Networking and mention its advantages.
8. Discuss point to point optical fiber communication system and mention
its advantages over the conventional communication system.
9. Discuss the advantages and disadvantages of an optical communication.

Numerical Problems :
1. Calculate the numerical aperture and angle of acceptance for an optical
fiber having refractive indices 1.563 and 1.498 for core and cladding
respectively.
2. The refractive indices of the core and cladding of a step index optical fiber
are 1.45 and 1.4 respectively and its core diameter is 45𝜇𝑚. Calculate its
fractional refractive index change and numerical aperture.
3. Calculate numerical aperture, acceptance angle and critical angle of a
fiber having a core RI 1.50 and cladding RI 1.45.
4. An optical fiber has a numerical aperture of 0.32. The refractive index of
cladding is 1.48. Calculate the refractive index of the core, the acceptance
angle of the fiber and the fractional index change.
5. An optical signal propagating in a fiber retains 85% of input power after
traveling a distance of 500 m in the fiber. Calculate the attenuation
coefficient.
I/II SEM B.E BPHYS102/202 ( NEW 2022 CBCS SCHEME ) Mob.9900111638 42 | P a g e
Dr.Mahesh S. Bannur, AGMRCET, VARUR ENGG PHYSICS CSE Stream MODULE-1
6. An optical fiber has core RI 1.5 and RI of cladding is 3% less than the
core index. Calculate the numerical aperture, angle of acceptance
critical angle.
7. The numerical aperture of an optical fiber is 0.2 when surround by air.
Determine the RI of its core, given the RI of the cladding is 1.59. Also find
the acceptance angle when the fiber is in water of RI 1.33.
8. The angle of acceptance of an optical fiber is 300 when kept in air. Find
the angle of acceptance when it is in medium of refractive index 1.33.
9. An optical fiber of 600 m long has input power of 120 mW which emerges
out with power of 90 mW.
10. Find attenuation in fiber. The attenuation of light in an optical fiber is
3.6 dB/km. What fraction of its initial intensity is remains after
i) 1 km and ii) 3 km ?
11. The attenuation of light in an optical fiber is 2.2 dB/km. What fraction
of its initial intensity is remains after i) 2 km and ii) 6 km ?

I/II SEM B.E BPHYS102/202 ( NEW 2022 CBCS SCHEME ) Mob.9900111638 43 | P a g e