Showing posts with label optical fiber. Show all posts
Showing posts with label optical fiber. Show all posts

9 Feb 2020

Optical Fiber Communication Notes (PPT) | Optical Fiber Structure, Working, Types, Benefits, Losses

Here you will find the Handwritten Notes (PPT) of Optical Fiber communication. This video covers, what is an optical fiber, structure and working principle of The Optical Fiber, optical Fiber types based on modes (single mode optical fiber and Multimode optical fiber) and refractive index profile (step index fiber and graded index fiber).
This video also discusses what are different types of losses in optical fibers along with advantages of optical fiber.

Optical Fiber Communication Notes (PPT) Video


24 Dec 2018

Dispersion in Optical Fiber - Intramodal Dispersion (Chromatic Dispersion) and Intermodal Dispersion

Dispersion in optical fibres

Broadening of the transmitted light pulses take place as the light rays move along the optical fibre. This broadening of light pulses is known as dispersion.


Intersymbol Interference (ISI) in Optical Fibers

Let's understand the dispersion with help of diagram given below-


Dispersion in Optical Fiber, Intersymbol Interference in optical fiber, ISI in optical fiber
Dispersion in Optical Fiber (Intersymbol Interference ISI)

You can see in this diagram that the light pulses that are sharp before transmission, gets broadened after travelling through the optical fibre. This Increase in width of the pulses makes it very difficult to distinguish them at the receiving end. Because of this light pulse broadening, these pulses overlap with its neighboring light pulses and it becomes hard to identify them as separate pulses at the receiving side. This effect is known as the Intersymbol Interference (ISI).
Now observe the same diagram carefully. Due to this dispersion effect (broadening of light pulses) the digital bit pattern 1011 at the input side is not indistinguishable at the output side as the same bit pattern. Because of this effect, '0' level is missing at the output side.

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Optical fiber communication (Complete)


Types of Dispersion in optical fibers

Dispersion in optical fibers can be categorized into two parts -
#Intramodal Dispersion (Chromatic dispersion) and
#Intermodal Dispersion (Modal or Mode dispersion)

Intramodal Dispersion (Chromatic Dispersion)

Intramodal dispersion may occur in all types of optical fibers. As we know that optical sources emit a band of frequencies so do not emit just a single frequency. Therefore different spectral components present in the optical source take different propagation delay while travelling through the optical fiber. This phenomena results in the broadening of each transmitted mode and is responsible for the intramodal dispersion. Intramodal dispersion is also popular by another name 'chromatic dispersion'.
Intramodal dispersion (chromatic dispersion) is found more in LED sources in comparison to LASER sources.
This delay difference may be caused by the dispersive properties of the material of the waveguide (material dispersion) and also guidance effects within the fibre structure (waveguide dispersion). 

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STEP INDEX OPTICAL FIBER (MULTIMODE AND SINGLE MODE STEP INDEX FIBERS)


Material Dispersion

Pulse broadening because of material dispersion is caused due to different group velocities of various spectral components that are launched into the fibre from the optical source.
It occurs when the phase velocity of a plane wave that is propagating in the dielectric medium varies non-linearly with wavelength.


Waveguide Dispersion

Intramodal dispersion may also be caused due to waveguiding of the optical fibre. As the group velocity varies with change in wavelength for a particular mode, the waveguide dispersion takes place.
When the angle between the ray and the fibre axis varies with wavelength then it results in different transmission times for the rays which is responsible for dispersion.
Now we will discuss another kind of dispersion known as intermodal dispersion.

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OPTICAL FIBER: STRUCTURE AND WORKING PRINCIPLE


Intermodal Dispersion (Modal or Mode Dispersion)

Intermodal dispersion is found in multimode optical fibres. Multimode fiber are the fibres that allow various modes to propagate through it. Therefore it is not observed in single mode fibers as only a single mode is allowed to propagate through the single mode fibre. But single mode fibres suffer from the intramodal dispersion (chromatic dispersion). 
The intermodal dispersion results due to propagation delay difference between various modes propagating through the optical fibre.


Intermodal Dispersion in Step Index Fibers, Intermodal Dispersion, Dispersion in Step Index Fibers
Intermodal Dispersion in Step Index Fibers  

Intermodal dispersion is found more in case of multimode step index fibres in comparison to graded index fibres. As in case of multimode step index fibres, the refractive index of the core is uniform. Because of this same refractive index throughout the core of the multimode step index fibre, different modes propagating through the core travel with same speed. Because of this same speed, different light rays launched into the optical fibre at different angles at the transmitting end takes different times to reach to the other end of the optical fibre as their propagation path (path length) changes with change in angle while launching.

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OPTICAL FIBER SOURCES (DESIRABLE PROPERTIES)

You can observe this phenomena in the diagram shown above. Because of this, intermodal dispersion is found more in multimode step index fibres.


Propagation of Light Ray inside Graded Index Fibers, Total Internal Reflection in optical fiber
Propagation of Light Ray inside Graded Index Fibers (Total Internal Reflection)

On the other hand, graded index fibres offer less intermodal dispersion as the refractive index of the core is not uniform in it. Refractive Index is maximum at the core axis and decreases as we move away from the core axis. So the refractive index is maximum at the core axis in case of graded index fibers. The refractive index of the cladding is uniform.
But how does this non-uniform refractive index of the core in graded index fibres help in reducing intermodal dispersion?
To understand it, carefully observe the diagram shown below.


Intermodal Dispersion in Graded Index Fibers, Dispersion in optical Fibers
Intermodal Dispersion in Graded Index Fibers 

As the light rays travel slower in denser mediums (high refractive index) and we also know that refractive index in case of graded index fibers is maximum at the core axis and decreases as we move radially away from the core axis towards the core-cladding interface. 

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ADVANTAGES OF OPTICAL FIBER COMMUNICATION

We can transmit light rays at different angles into the optical fibre. So the light rays that travel near the core axis move slower in comparison to the light rays that travel near the core-cladding interface. 

You can easily understand this, that the light rays that travel near the core axis have to cover smaller distance in comparison to the rays that are close to the core-cladding interface. This creates a compensating effect in dispersion of light rays.

This phenomena is responsible for lower dispersion (broadening of light pulses) in case of graded index fibres in comparison to step index fibres because the light rays travelling at different angles in graded index fiber reach at the receiving end, almost at the same time. Because the light rays that need to travel longer distances (moving close to core-cladding interface) propagate at high speed because of lower refractive index (rarer medium) near the core-cladding interface. This reduces broadening (dispersion) of the light pulses.

Read More-

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FREQUENCY SPECTRUM OF AMPLITUDE MODULATION (WAVEFORMS AND EQUATIONS DERIVATION)

AMPLITUDE MODULATION (TIME DOMAIN EQUATIONS AND WAVEFORMS)

ADVANTAGES AND DISADVANTAGES OF DIGITAL COMMUNICATION SYSTEM

ADVANTAGES OF OPTICAL FIBER COMMUNICATION

STEP INDEX OPTICAL FIBER (MULTIMODE AND SINGLE MODE STEP INDEX FIBERS)

PULSE MODULATION TECHNIQUES (PAM, PWM, PPM, PCM)

OPTICAL FIBER: STRUCTURE AND WORKING PRINCIPLE

PULSE AMPLITUDE MODULATION (PAM)

COMPARISON OF PAM, PWM, PPM MODULATION TECHNIQUES

PULSE WIDTH MODULATION (PWM)

CONTINUOUS TIME AND DISCRETE TIME SIGNALS (C.T. AND D.T. SIGNALS)

NEED AND BENEFITS OF MODULATION

PULSE POSITION MODULATION (PPM)

OPTICAL FIBERS IN COMMUNICATION: COVERS ALL IMPORTANT POINTS

OPTICAL FIBER SOURCES (DESIRABLE PROPERTIES)

AMPLITUDE MODULATION Vs FREQUENCY MODULATION (ADVANTAGES AND DISADVANTAGES)

PULSE CODE MODULATION (PCM) [ADVANTAGES AND DISADVANTAGES]

SAMPLING THEOREM AND RECONSTRUCTION (SAMPLING AND QUANTIZATION)

SUPERPOSITION THEOREM (BASICS, SOLVED PROBLEMS, APPLICATIONS AND LIMITATIONS)

Digital Modulation Techniques (ASK, FSK, PSK, BPSK)/ Amplitude, Frequency and Phase Shift Keying

Conventional AM Vs DSB-SC Vs SSB-SC Vs VSB (Comparison of AM Systems)

Quadrature Amplitude Modulation (QAM)/ QAM Transmitter and QAM Receiver Block Diagram

Single-Mode Optical Fiber Advantages

What are Microwaves and their Applications (Uses) in various fields

Microwaves Properties and Advantages (Benefits)

Basic Structure of Bipolar Junction Transistor (BJT) - BJT Transistor - Working and Properties

Polar Plots of Transfer Functions in Control Systems (How to Draw Nyquist Plot Examples)

Generation of Binary Phase Shift Keying (BPSK Generation) - Block Diagram of Binary Phase Shift Keying (BPSK)

Low Level and High Level Modulation Block Diagram (AM Transmitter Block Diagram)

Block Diagram of CRO (Cathode Ray Oscilloscope), Components of CRO and CRT with Structure and Working

Slope Overload Distortion and Granular (Idle Noise), Quantization Noise in Delta Modulation

Frequency Translation/Frequency Mixing/Frequency Conversion/Heterodyning (Basic Concepts and Need)

Quadrature Phase Shift Keying Modulation (QPSK) Basics, Waveform and Benefits

Pulse Code Modulation (PCM) Vs Differential Pulse Code Modulation (DPCM)




Meridional and Skew Rays (Optical Fiber Communication)

There are two types of light rays on the basis of propagation inside the optical fiber- 
#Meridional Rays and
#Skew Rays (Helical Rays)

Here we will discuss propagation of both types of rays-

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Optical Fiber Communication (Complete)

Meridional Rays

*Meridional rays enter into the optical fiber through it's axis. 
*These rays cross the fiber axis at each reflection.


Meridional Rays, Propagation Inside Optical Fiber
Meridional Rays Propagation Inside Optical Fiber

The two diagrams given above show the propagation of meridional rays inside the optical fiber. The first diagram provides the ray path view along the fiber axis. It is clear from the diagram that the light ray is crossing the fiber axis at each reflection. These reflections are marked as 1, 2 and 3.

Meridional and Skew Rays Video

 

Another diagram is also of meridional ray propagation but with a different view. It is ray path view along the plane normal to the fiber axis.

Now let's discuss another kind of light ray propagation inside optical fibers i.e. Skew rays.


Skew Rays (Helical Rays)

*Skew rays are also known as helical rays as they move on helical path inside the optical fiber. 
*Skew rays do not cross the fibre axis and propagate around the optical fiber axis on zigzag path.
*Skew rays greatly outnumber the meridional rays. *Skew rays enter the optical fiber off the fiber axis.
It should be noted here that, in case of skew rays, the point of emergence from the fiber in air depends upon the number of reflections inside the optical fibre. It does not depend upon the input conditions to the fiber.

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OPTICAL FIBER: STRUCTURE AND WORKING PRINCIPLE

This concept is made clear with the help of two diagrams given below. 
Skew Rays, Helical Rays, Propagation Inside Optical Fiber
Skew Rays (Helical Rays) Propagation Inside Optical Fiber

The first diagram of skew ray shows the ray path view along the fiber axis and the second diagram shows the ray path view along the plane normal to the fiber axis.
It is clear from the second diagram that the skew ray (helical ray) is not crossing the optical fiber axis and propagating around the axis.

Read More-

Go To HOME Page
   
FREQUENCY SPECTRUM OF AMPLITUDE MODULATION (WAVEFORMS AND EQUATIONS DERIVATION)

AMPLITUDE MODULATION (TIME DOMAIN EQUATIONS AND WAVEFORMS)

ADVANTAGES AND DISADVANTAGES OF DIGITAL COMMUNICATION SYSTEM

ADVANTAGES OF OPTICAL FIBER COMMUNICATION

STEP INDEX OPTICAL FIBER (MULTIMODE AND SINGLE MODE STEP INDEX FIBERS)

PULSE MODULATION TECHNIQUES (PAM, PWM, PPM, PCM)

OPTICAL FIBER: STRUCTURE AND WORKING PRINCIPLE

PULSE AMPLITUDE MODULATION (PAM)

COMPARISON OF PAM, PWM, PPM MODULATION TECHNIQUES

PULSE WIDTH MODULATION (PWM)

CONTINUOUS TIME AND DISCRETE TIME SIGNALS (C.T. AND D.T. SIGNALS)

NEED AND BENEFITS OF MODULATION

PULSE POSITION MODULATION (PPM)

OPTICAL FIBERS IN COMMUNICATION: COVERS ALL IMPORTANT POINTS

OPTICAL FIBER SOURCES (DESIRABLE PROPERTIES)

AMPLITUDE MODULATION Vs FREQUENCY MODULATION (ADVANTAGES AND DISADVANTAGES)

PULSE CODE MODULATION (PCM) [ADVANTAGES AND DISADVANTAGES]

SAMPLING THEOREM AND RECONSTRUCTION (SAMPLING AND QUANTIZATION)

SUPERPOSITION THEOREM (BASICS, SOLVED PROBLEMS, APPLICATIONS AND LIMITATIONS)

Digital Modulation Techniques (ASK, FSK, PSK, BPSK)/ Amplitude, Frequency and Phase Shift Keying

Conventional AM Vs DSB-SC Vs SSB-SC Vs VSB (Comparison of AM Systems)

Quadrature Amplitude Modulation (QAM)/ QAM Transmitter and QAM Receiver Block Diagram

Single-Mode Optical Fiber Advantages

What are Microwaves and their Applications (Uses) in various fields

Microwaves Properties and Advantages (Benefits)

Basic Structure of Bipolar Junction Transistor (BJT) - BJT Transistor - Working and Properties

Polar Plots of Transfer Functions in Control Systems (How to Draw Nyquist Plot Examples)

Generation of Binary Phase Shift Keying (BPSK Generation) - Block Diagram of Binary Phase Shift Keying (BPSK)

Low Level and High Level Modulation Block Diagram (AM Transmitter Block Diagram)

Block Diagram of CRO (Cathode Ray Oscilloscope), Components of CRO and CRT with Structure and Working

Slope Overload Distortion and Granular (Idle Noise), Quantization Noise in Delta Modulation

Frequency Translation/Frequency Mixing/Frequency Conversion/Heterodyning (Basic Concepts and Need)

Quadrature Phase Shift Keying Modulation (QPSK) Basics, Waveform and Benefits

Pulse Code Modulation (PCM) Vs Differential Pulse Code Modulation (DPCM)




12 Dec 2018

Graded Index Fiber - Basics, Mathematical Formula, Structure, Working, Basic Principle, Dispersion and Benefits in Graded Index Optical Fiber

We have already discussed step index fibers. The other type of optical fiber based on the refractive index profile is the graded index fibre.
As we know that step index fibres make step (sudden) change in the refractive index at the core-cladding interface. The core has a constant refractive index that changes to a lower (constant) refractive index in the cladding.

Step Index Vs Graded Index optical fiber (Read more)

Now let's discuss the graded index fibres-



What is Graded Index Optical Fibre?
In graded index fibre the core has maximum value of the refractive index at it's axis and this value decreases on radially moving away from the core axis and has a constant value of refractive index in the cladding. Now let's see the mathematical representation of the Graded index fiber- 


Mathematical representation of Graded Index Fibre

Graded index fibers refractive index formula, graded index fibers
Graded index fibers refractive index formula

Refractive Index Profile Graph for Optical Fibers

Graded index fiber structure, working and refractive index profile graph
Graded index fiber structure, working and refractive index profile graph

This graph shows how the refractive index of graded index fiber varies as we move away from the core axis.
This graph shows different kinds of refractive index profiles like- step index profile, triangular profile and parabolic profile.
Here we will use the refractive index profile (alpha= 2) for the graded index fibre.
The diagram above shows, how the light rays travel inside the graded index fibre-

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Optical Fiber Communication (Complete)

As you can see in this diagram, that the optical fiber has two layers, core (shown in blue colour) and cladding (shown in green colour).
The propagation of light rays inside the graded index fibers also, takes place by the Total Internal Reflection (TIR) phenomena like step index fibres. But the propagation path of light is not exactly same as in case of step index fibres.

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Structure and Working of optical Fiber

The graph given in this diagram also shows how the refractive index of the core and cladding changes as we move away from the core axis. You can observe here that the refractive index of the cladding is constant (n2) while that of core varies parabolically.
As you now know that the refractive index of the core in graded index fibre varies smoothly therefore the propagation path of light also has a smooth path.


Propagation of light inside Graded Index Fiber (Dispersion in optical Fibers)

By the following Diagram you will clearly and easily understand how the light ray moves inside the graded index fibre and why it has a smooth propagation path.


Propagation of light inside graded index optical fiber
Propagation of light inside graded index optical fiber

The diagram shows only the core layer of the graded index fibre. As we know that as we move away from the core axis, the refractive index decreases until we reach the core-cladding interface. Therefore the refractive index has its maximum value at the core axis. So as the light ray moves from the core axis towards the core-cladding interface, it gets refracted continuously. As the light ray is moving continuously from a denser medium to rarer medium, it continuously deviates away from the normal when it goes away from the core axis and at some point this continuous deviation away from the normal causes the direction of the light ray turn back towards the core axis.
But when it returns back towards the core axis it continuously moves from rarer medium to denser medium and moves continuously towards the normal.

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Benefits of optical fibers

The light rays keep propagating in this way inside the core. This is known as the Total Internal Reflection (TIR). The total internal reflection is sharp (sudden) in case of step index fibre because the change in refractive index is sharp (sudden).


Benefits of graded index fiber and Dispersion

Observe the figure shown above. As the light rays travel slower in denser mediums (high refractive index) and we also know that refractive index in case of graded index fibers is maximum at the core axis and decreases as we move radially away from the core axis towards the core-cladding interface. 
We can transmit light rays at different angles into the optical fibre. So the light rays that travel near the core axis move slower in comparison to the light rays that travel near the core-cladding interfaces. 
You can easily understand this, that the light rays that travel near the core axis have to cover smaller distance in comparison to the rays that are close to the core-cladding interface. This creates a compensating effect in dispersion of light rays.

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Acceptance angle and Numerical Aperture (NA) in optical fibers

This phenomena is responsible for lower dispersion (broadening of light pulses) in case of graded index fibres in comparison to step index fibres because the light rays travelling at different angles reach at the receiving end almost at the same time. Because the light rays that need to travel longer distances (moving close to core-cladding interface) propagate at high speed because of lower refractive index (rarer medium) near the core-cladding interface. This reduces broadening (dispersion) of the light pulses.

Read More-

Go To HOME Page
   
FREQUENCY SPECTRUM OF AMPLITUDE MODULATION (WAVEFORMS AND EQUATIONS DERIVATION)

AMPLITUDE MODULATION (TIME DOMAIN EQUATIONS AND WAVEFORMS)

ADVANTAGES AND DISADVANTAGES OF DIGITAL COMMUNICATION SYSTEM

ADVANTAGES OF OPTICAL FIBER COMMUNICATION

STEP INDEX OPTICAL FIBER (MULTIMODE AND SINGLE MODE STEP INDEX FIBERS)

PULSE MODULATION TECHNIQUES (PAM, PWM, PPM, PCM)

OPTICAL FIBER: STRUCTURE AND WORKING PRINCIPLE

PULSE AMPLITUDE MODULATION (PAM)

COMPARISON OF PAM, PWM, PPM MODULATION TECHNIQUES

PULSE WIDTH MODULATION (PWM)

CONTINUOUS TIME AND DISCRETE TIME SIGNALS (C.T. AND D.T. SIGNALS)

NEED AND BENEFITS OF MODULATION

PULSE POSITION MODULATION (PPM)

OPTICAL FIBERS IN COMMUNICATION: COVERS ALL IMPORTANT POINTS

OPTICAL FIBER SOURCES (DESIRABLE PROPERTIES)

AMPLITUDE MODULATION Vs FREQUENCY MODULATION (ADVANTAGES AND DISADVANTAGES)

PULSE CODE MODULATION (PCM) [ADVANTAGES AND DISADVANTAGES]

SAMPLING THEOREM AND RECONSTRUCTION (SAMPLING AND QUANTIZATION)

SUPERPOSITION THEOREM (BASICS, SOLVED PROBLEMS, APPLICATIONS AND LIMITATIONS)

Digital Modulation Techniques (ASK, FSK, PSK, BPSK)/ Amplitude, Frequency and Phase Shift Keying

Conventional AM Vs DSB-SC Vs SSB-SC Vs VSB (Comparison of AM Systems)

Quadrature Amplitude Modulation (QAM)/ QAM Transmitter and QAM Receiver Block Diagram

Single-Mode Optical Fiber Advantages

What are Microwaves and their Applications (Uses) in various fields

Microwaves Properties and Advantages (Benefits)

Basic Structure of Bipolar Junction Transistor (BJT) - BJT Transistor - Working and Properties

Polar Plots of Transfer Functions in Control Systems (How to Draw Nyquist Plot Examples)

Generation of Binary Phase Shift Keying (BPSK Generation) - Block Diagram of Binary Phase Shift Keying (BPSK)

Low Level and High Level Modulation Block Diagram (AM Transmitter Block Diagram)

Block Diagram of CRO (Cathode Ray Oscilloscope), Components of CRO and CRT with Structure and Working

Slope Overload Distortion and Granular (Idle Noise), Quantization Noise in Delta Modulation

Frequency Translation/Frequency Mixing/Frequency Conversion/Heterodyning (Basic Concepts and Need)

Quadrature Phase Shift Keying Modulation (QPSK) Basics, Waveform and Benefits

Pulse Code Modulation (PCM) Vs Differential Pulse Code Modulation (DPCM)



Step Index and Graded Index Fibre - Comparison between Step Index and Graded Index Fibre (Optical Fiber Cable)

Here is the comparison between step index and graded index fibres on the basis of various parameters like basic structure, working principle, types, refractive index profile, propagation of light inside fibers, dispersion in optical fibers, advantages and disadvantages-

1. In step index fibers, sudden (step) change takes place in the refractive index at the core-cladding interface. The refractive index of the core is uniform
While in case of graded index fibers, refractive index of the core is non-uniform. It is maximum at the core axis and then it decreases (generally parabolically) with increasing distance from the core axis.

2. Step index fibers are of two types on the basis of modes-
#Single mode step index fiber
#Multimode step index fiber


Multimode Step Index Fiber, Single Mode Step Index Fibers
Multimode and Single Mode Step Index Fibers

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Optical fiber communication (Complete)

While on the basis of modes, only one type of graded index fibre is present i.e. Multimode graded index fibre.


Graded Index Fiber, Refractive Index Profile, Propagation of Light with TIR
Graded Index Fiber (Refractive Index Profile and Propagation of Light with TIR)

3. In step index fibres, light rays propagate in a zigzag manner (on zigzag path) inside the fiber Core. These rays travel as meridional rays. It means that the rays cross the axis of fibre for each reflection while propagating.

Step Index and Graded Index Fiber Video

 

But in case of graded index fibres, the light rays propagate as skew rays or helical rays. It means that while travelling inside the core these days do not cross the fibre axis.

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Optical fiber structure and working


4. In case of step index fibers the refractive index profile may be defined as-


 Refractive Index Profile of Step Index Fiber
Refractive Index Profile of Step Index Fiber

And in case of graded index fibers, the refractive index profile is defined as -


Refractive Index Profile of Graded Index Fiber
Refractive Index Profile of Graded Index Fiber

5. Modal dispersion is present that affects signal quality in case of step index fibres.
But the graded index fibres have very low or zero dispersion as the time taken by each mode to propagate is same. As the velocity of each mode is different due to change in refractive index.

Read More-

Go To HOME Page
   
FREQUENCY SPECTRUM OF AMPLITUDE MODULATION (WAVEFORMS AND EQUATIONS DERIVATION)

AMPLITUDE MODULATION (TIME DOMAIN EQUATIONS AND WAVEFORMS)

ADVANTAGES AND DISADVANTAGES OF DIGITAL COMMUNICATION SYSTEM

ADVANTAGES OF OPTICAL FIBER COMMUNICATION

STEP INDEX OPTICAL FIBER (MULTIMODE AND SINGLE MODE STEP INDEX FIBERS)

PULSE MODULATION TECHNIQUES (PAM, PWM, PPM, PCM)

OPTICAL FIBER: STRUCTURE AND WORKING PRINCIPLE

PULSE AMPLITUDE MODULATION (PAM)

COMPARISON OF PAM, PWM, PPM MODULATION TECHNIQUES

PULSE WIDTH MODULATION (PWM)

CONTINUOUS TIME AND DISCRETE TIME SIGNALS (C.T. AND D.T. SIGNALS)

NEED AND BENEFITS OF MODULATION

PULSE POSITION MODULATION (PPM)

OPTICAL FIBERS IN COMMUNICATION: COVERS ALL IMPORTANT POINTS

OPTICAL FIBER SOURCES (DESIRABLE PROPERTIES)

AMPLITUDE MODULATION Vs FREQUENCY MODULATION (ADVANTAGES AND DISADVANTAGES)

PULSE CODE MODULATION (PCM) [ADVANTAGES AND DISADVANTAGES]

SAMPLING THEOREM AND RECONSTRUCTION (SAMPLING AND QUANTIZATION)

SUPERPOSITION THEOREM (BASICS, SOLVED PROBLEMS, APPLICATIONS AND LIMITATIONS)

Digital Modulation Techniques (ASK, FSK, PSK, BPSK)/ Amplitude, Frequency and Phase Shift Keying

Conventional AM Vs DSB-SC Vs SSB-SC Vs VSB (Comparison of AM Systems)

Quadrature Amplitude Modulation (QAM)/ QAM Transmitter and QAM Receiver Block Diagram

Single-Mode Optical Fiber Advantages

What are Microwaves and their Applications (Uses) in various fields

Microwaves Properties and Advantages (Benefits)

Basic Structure of Bipolar Junction Transistor (BJT) - BJT Transistor - Working and Properties

Polar Plots of Transfer Functions in Control Systems (How to Draw Nyquist Plot Examples)

Generation of Binary Phase Shift Keying (BPSK Generation) - Block Diagram of Binary Phase Shift Keying (BPSK)

Low Level and High Level Modulation Block Diagram (AM Transmitter Block Diagram)

Block Diagram of CRO (Cathode Ray Oscilloscope), Components of CRO and CRT with Structure and Working

Slope Overload Distortion and Granular (Idle Noise), Quantization Noise in Delta Modulation

Frequency Translation/Frequency Mixing/Frequency Conversion/Heterodyning (Basic Concepts and Need)

Quadrature Phase Shift Keying Modulation (QPSK) Basics, Waveform and Benefits

Pulse Code Modulation (PCM) Vs Differential Pulse Code Modulation (DPCM)