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Analysis on Optical Waveguide (Free Space Optics) via Beam Propagation Method

(BPM)

TAN XIN MEI

This report is submitted in partial fulfillment of the requirement for the award of

Bachelor of Electronic Engineering (Wireless Communication) With Honors

Faculty of Electronic and Computer Engineering

Universiti Teknikal Malaysia Melaka

APRIL 2011

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UNIVERSTI TEKNIKAL MALAYSIA MELAKA FAKULTI KEJURUTERAAN ELEKTRONIK DAN KEJURUTERAAN KOMPUTER

BORANG PENGESAHAN STATUS LAPORAN

PROJEK SARJANA MUDA II

Tajuk Projek :

Analysis on Optical Waveguide (Free Space Optics) via

Beam Propagation Method (BPM).

Sesi

Pengajian : 1 0 / 1 1

Saya ……………………………………TAN XIN MEI……………………………

(HURUF BESAR)

mengaku membenarkan Laporan Projek Sarjana Muda ini disimpan di Perpustakaan dengan

syarat-syarat kegunaan seperti berikut:

1. Laporan adalah hakmilik Universiti Teknikal Malaysia Melaka.

2. Perpustakaan dibenarkan membuat salinan untuk tujuan pengajian sahaja.

3. Perpustakaan dibenarkan membuat salinan laporan ini sebagai bahan pertukaran antara

institusi pengajian tinggi.

4. Sila tandakan ( √ ) :

SULIT*

*(Mengandungi maklumat yang berdarjah keselamatan atau

kepentingan Malaysia seperti yang termaktub di dalam AKTA

RAHSIA RASMI 1972)

TERHAD**

**(Mengandungi maklumat terhad yang telah ditentukan oleh

organisasi/badan di mana penyelidikan dijalankan)

TIDAK TERHAD

Disahkan oleh:

__________________________ ___________________________________

(TANDATANGAN PENULIS) (COP DAN TANDATANGAN PENYELIA)

Tarikh: ……………………….. Tarikh: ………………………..

√

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“I hereby declare that this report is the result of my own work except for quotes as

cited in the references.”

Signature : ………………………………

Author : ……TAN XIN MEI…….......

Date : ……29 APRIL 2011…..........

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“I hereby declare that I have read this report and in my opinion is sufficient in terms

of the scope and qualify for the award of Bachelor of Electronic Engineering

(Wireless Communication) With Honors.”

Signature : …………………………………………

Supervisor’s name : ……DAVID YAP FOOK WENG…….

Date : …………29 APRIL 2011…..................

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To my beloved family and friends

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ACKNOWLEGDEMENT

I would like to express my gratitude and appreciation to Mr David Yap Fook

Weng as my project supervisor for his guidance and advices throughout the project

period. I truly appreciate those who have helped me toward the completion of this

project.

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ABSTRACT

This project presents the study and simulation of Free Space Optics (FSO)

communication link and analysis of FSO system performance. Free Space Optics

(FSO) also called Optical Wireless (OW) is regarded as high speed wireless

communication technology due to the security and high data rates. FSO

communication system involves the transmission of modulated optical signal through

the atmosphere to obtain broadband communications. FSO systems can function over

distances of several kilometers. As long as there is a clear line of sight between the

source and the destination, and enough transmitter power, communication is

theoretically possible. It offers an attractive alternative for transferring high-

bandwidth data when fiber optic cable is neither practical nor feasible. However the

performance of a FSO link is primarily dependent upon the atmospheric weather

effects such as atmospheric attenuation, scintillation, window attenuation, alignment

or building motion, solar interference and line-of-sight obstruction. OptiSystem and

MATLAB are used as simulation tool to simulate the atmospheric weather effects.

The result of simulation shows these effects attenuate the FSO signal as it travels

through a certain distances.

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ABSTRAK

Projek ini menyajikan kajian dan simulasi link Free Space Optics (FSO)

komunikasi dan analisa prestasi sistem FSO. Free Space Optics (FSO) juga disebut

Optical Wireless (OW) dianggap sebagai teknologi komunikasi wayarles kelajuan

tinggi kerana keselamatan dan kelajuan data yang tinggi. Sistem komunikasi FSO

melibatkan penghantaran isyarat optik termodulasi melalui atmosfera untuk

mendapatkan komunikasi jalur lebar. Sistem FSO boleh berfungsi lebih dari jarak

beberapa kilometer. Selama ada garis yang jelas kelihatan antara sumber dan tujuan,

dan kekuatan pemancar yang cukup, komunikasi secara teoritis boleh berlaku. Ini

menawarkan alternatif yang menarik untuk memindahkan data bandwidth tinggi

ketika kabel fiber optik tidak praktikal. Namun prestasi link FSO adalah terutama

bergantung pada kesan cuaca atmosfera seperti redaman atmosfera, kilau, redaman

tetingkap, keselarasan atau gerakan bangunan, gangguan matahari dan halangan

antara sumber dan tujuan. OptiSystem dan MATLAB digunakan sebagai alat

simulasi untuk mensimulasi kesan cuaca atmosfera. Hasil daripada simulasi

menujukkan bahawa kesan-kesan tersebut melemahkan isyarat FSO setelah ia

berjalan ke satu jarak yang tertentu.

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TABLE OF CONTENTS

CHAPTER TITLE PAGE

PROJECT TITLE i

PROJECT STATUS VERIFICATION FORM ii

DECLARATION iii

VERIFICATION OF SUPERVISOR iv

DEDICATION v

ACKNOWLEDGEMENT vi

ABSTRACT vii

ABSTRAK vii

TABLE OF CONTENTS ix

LIST OF TABLES xii

LIST OF FIGURES xiii

LIST OF ABBREVIATION xv

LIST OF APPENDIXES xvi

I INTRODUCTION

1.1 Introduction of FSO 1

1.2 Project Objective 2

1.3 Problem Statement 3

1.4 Project Scope 3

1.5 Brief Explanation of Methodology 4

1.6 Report Structure 4

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II LITERATURE REVIEW

2.1 What is Free Space Optics 5

2.2 History of FSO 6

2.3 How FSO Works 8

2.4 Advantages of FSO 12

2.5 Limitations of FSO 13

III METHODOLOGY

3

3.1 Project Methodology

16

3.2 Simulation-assisted Design of FSO Communication

Link

18

3.2.1 OptiSystem Software 18

3.2.2 FSO Link Design 20

3.2.3 Information Obtained

1. Transmit Power 23

2. Optical Spectrum of Directly

Modulated Laser

23

3. Optical Spectrum of FSO Channel 24

4. Optical Power Meter at FSO Channel 25

5. Received Signal 26

6. Eye Diagram 27

IV RESULT AND DISCUSSION

3.3 Nonlinear Schrödinger Equation 28

3.4 Rainfall Attenuation 29

3.5 Scattering Effect 36

3.6 Scintillation Effect 40

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3.7 Atmospheric Effect 43

3.8 Sum up all Effects 45

3.9 Result Analysis 48

V CONCLUSION

3.10 Conclusion 50

3.11 Recommendation 51

REFERENCES 52

APPENDIX 54

xii

LIST OF TABLES

NO TITLE PAGE

3.1 Equipments and parameters used in FSO link simulation 21

3.2 Analysis tools used in FSO link simulation 22

4.1 Rainfall distribution 29

4.2 Rainfall attenuation comparison 35

4.3 Particle size distribution 37

4.4 Atmospheric Condition 43

4.5 Comparison of attenuation and power transmit required under

different weather effects

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xiii

LIST OF FIGURES

NO TITLE PAGE

2.1 Historical photos of FSO 7

2.2 FSO transceiver device, old and new design 8

2.3 Basic FSO Principle 9

2.4 Electromagnetic Spectrum and Visible Spectrum 10

2.5 FSO Application 11

2.6 Rain droplet 14

2.7 Fog effect 14

2.8 FSO Limitation Factors 15

3.1 Portion of OptiSystem library devices 19

3.2 Simulation setup of FSO link using OptiSystem 20

3.3 Transmitted signal 23

3.4 Optical Spectrum of Directly Modulated Laser 24

3.5 Optical Spectrum of FSO channel 25

3.6 Optical Power Meter 25

3.7 Received signal 26

3.8 Eye Diagram 27

4.1 Weak rain attenuation simulation result 30

4.2 Weak rain attenuation= 2.9dB/km 31

4.3 Relationship between signal power and range (Rain effect) 32

4.4 Distorted eye diagram caused by rain attenuation 33

4.5 Clear eye diagram with minimum Pt ≥ 25dBm 33

4.6 Normal rain simulation result 34

4.7 Strong rain simulation result 35

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4.8 Scattering effect simulation result 37

4.9 Relationship between signal power and range (Scattering Effect) 38

4.10 Clear eye diagram with minimum Pt ≥20dBm 39

4.11 Scintillation as a result of variation of refractive index of air 40

4.12 Scintillation effect simulation result 41

4.13 Clear eye diagram with minimum Pt ≥28dBm 42

4.14 Clear air condition simulation result 44

4.15 Clear eye diagram with minimum Pt ≥19dBm 45

4.16 All effects simulation result 46

4.17 Relationship between signal power and range (Overall effect) 47

4.18 Clear eye diagram with minimum Pt ≥40dBm 47

xv

LIST OF ABBREVIATION

BER - Bit error rates

FSO - Free Space Optics

IrDA - Infrared Data Association

LAN - Local Area Network

LED - Light-emitting diodes

Pt - Power transmit

xvi

LIST OF APPENDIX

NO TITLE PAGE

A MATLAB Code Used for Simulation 54

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CHAPTER I

INTRODUCTION

This chapter includes an introduction of Free Space Optics (FSO), project

objectives, problem statement, and project scope, as well as brief explanation of

methodology and report structure.

1.1 Introduction of FSO

Free-space optical (FSO) has been used for more than a decade as a

short/medium distance point-to-point (building-to-building) connectivity solution.

The license free nature of this technology combined with its high-speed bandwidth

capabilities, comparable to optical fiber make it becomes the most promising high

data rate communication technology. FSO communication involves the use of optical

links across the space between two points, either within the Earth's atmosphere, or in

outer space. The transmitter made up of optical source and telescope to direct the

beam toward the receiver. The photo detector in the receiver processes the received

optical signal. The optical links usually use laser light, although low-data-rate

communication over short distances is possible using light-emitting diodes (LEDs).

Infrared Data Association (IrDA) in most laptop/palmtop computer is a very simple

form of free-space optical communications using LEDs.

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Free-space optical communications has a number of applications, such as to

become a last (or first) mile telecommunications link, as a LAN link between

buildings, as a LAN link within a room using diffusive optic, for communications

between spacecraft, including elements of a satellite constellation and for interstellar

communication.

However there are a variety of deleterious features of the atmospheric

channel that may lead to serious signal fading and even complete loss of signal. This

results in increased system bit error rates (BERs). The primary factors affecting

performance include atmospheric attenuation, scintillation, building motion, and

physical obstructions. Several simulations using simulation tools are carried out to

further investigate FSO system performance.

1.2 Objectives

The first objective of the project is to study and understand the performance

of FSO communication system as a point to point wireless communication. This

includes studying of how the system works and clarifying its advantages’ and

disadvantages in the daily application.

The second objective is to study the atmospheric weather effects on the

propagation of optical beam in the waveguide (or FSO). These effects are rain

attenuation, scattering effect, scintillation effect and atmospheric effect which

limiting the maximum data rate of the system. Define the realistic performance

limitations of FSO regard to atmospheric considerations is important.

The third objective is to perform simulation of FSO system under different

weather conditions using OptiSystem and MATLAB to evaluate and predict pulse

propagation in the atmosphere. The simulation is done in order to show the effect of

transmission medium (atmosphere) to a signal along the propagation path and relate

the outcome on the pulse behavior as well as the quality of the communication link.

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1.3 Problem Statement

While fiber-optic cable and FSO technology share many of the same

attributes, they face different challenges due to the way they transmit information.

While fiber is subject to outside disturbances from wayward construction backhoes,

and even sharks when deployed under sea, FSO technology is subject to its own

potential outside disturbances.

Optical wireless networks based on FSO technology must be designed to

combat changes in the atmosphere, which can affect FSO system performance

capacity. And because FSO is a line-of-sight technology, the interconnecting points

must be free from physical obstruction and able to "see" each other. Among the

issues to be considered when deploying FSO-based optical wireless systems are fog

which leads to absorption and scattering, scintillation, atmospheric turbulences,

physical obstructions and building sway.

These effects degrade the quality of communication link and resulting of

increasing BER. Therefore there exists the need for accurate channel characterization

in order to understand and mitigate the problem.

1.4 Project Scope

A few guidelines are proposed so that this project is narrowed to a certain

boundaries. This will ensure that this project achieves its objectives. First part of the

project is focused on literature review and study of FSO communication system, the

technology deployed, and the advantages and limitation of FSO as high bandwidth

wireless communication technology.

The second part of the project is focused on the simulation of different

atmospheric weather effects on FSO pulse propagation in the atmosphere. This

project utilized OptiSystem to design the FSO communication link and MATLAB to

simulate pulse propagation in the atmosphere for 3km distance. The signal

attenuation is observed and analyzed from the result of simulation.

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1.5 Brief Explanation of Methodology

Firstly all the information gathered for this project is through research via

internet and library, the material includes journal paper, articles from books, thesis

paper, and internet references.

OptiSystem and MATLAB software are introduced as simulation tool in this

project. OptiSystem is used to design the FSO communication link while Matlab is

used to simulate different atmospheric weather effects on FSO signal propagation.

1.6 Report Structure

First chapter of the report is about project introduction. FSO has been of

interest in recent years due to the increase in demand for high data link speed,

especially in urban area. However it suffers from adverse weather conditions such as

fog and rain. Therefore the objective of the project is to study and simulate an

accurate FSO model to show the weather effects on propagation of optical signal.

Second chapter covers the literature review of FSO system, the development

of FSO communication, the technology used and also benefits and limitation of this

emerging technology. Understanding on this chapter helps in the simulation in the

chapter later.

Research methodology is explained detail in the third chapter. The chapter

shows how the simulations tools are being utilized in doing the simulation. It

includes the simulation specification.

Results from simulation are presented in the fourth chapter. Comparison and

analysis are made regarding to the result obtained.

Conclusion of the entire project is made in chapter five and some

recommendations are suggested for future study.

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CHAPTER II

LITERATURE REVIEW

This chapter will describe details about Free Space Optics (FSO), literature

review on the history of FSO, basic principles, how does FSO works, advantages and

performance limitation of FSO.

2.1 What is Free Space Optics (FSO)

Free-Space Optics (FSO), also called Optical Wireless OW) is a line-of-sight

technology that uses lasers to provide optical bandwidth connections. It refers to the

transmission of modulated visible or infrared (IR) beams through the atmosphere to

obtain broadband communications. FSO systems can function over distances of

several kilometers. As long as there is a clear line of sight between the source and the

destination and enough power transmitted, communication is theoretically possible.

Currently, FSO offers capacities in the range of 100Mbps to 2.5Gbps of data,

voice and video communications through the air, allowing optical connectivity

without requiring fiber-optic cable or securing spectrum licenses. These systems are

compatible with a wide range of applications and markets since they are sufficiently

flexible as to be easily implemented.

FSO requires light, which can be focused by using either light emitting diodes

(LEDs) or lasers (light amplification by stimulated emission of radiation). The use of

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lasers is a simple concept similar to optical transmissions using fiber-optic cables;

the only difference is the medium. Light travels through air faster than it does

through glass, so it is fair to classify FSO as optical communications at the speed of

light. FSO is all-optical without the labor of digging up sidewalk to install a fiber

link and it requires no government licensing and can be readily deployed within

hours of the availability of line-of-sight access. This means no hassles, no backlog,

and no intermediary devices to the fiber backbone.

FSO technology is relatively simple. It's based on connectivity between FSO

units, each consisting of an optical transceiver with a laser transmitter and a receiver

to provide full duplex (bi-directional) capability. Each FSO unit uses a high-power

optical source (i.e. laser), plus a lens that transmits light through the atmosphere to

another lens receiving the information. The receiving lens connects to a high-

sensitivity receiver via optical fiber. FSO technology requires no spectrum licensing.

FSO is easily upgradeable, and its open interfaces support equipment from a variety

of vendors, which helps service providers protect their investment in embedded

telecommunications infrastructure.

2.2 History of Free Space Optics (FSO)

The engineering maturity of Free Space Optics (FSO) is often underestimated,

due to a misunderstanding of how long Free Space Optics (FSO) systems have been

under development. Historically, Free Space Optics (FSO) or optical wireless

communications was first demonstrated by Alexander Graham Bell in the late

nineteenth century (prior to his demonstration of the telephone!). Bell’s Free Space

Optics (FSO) experiment converted voice sounds into telephone signals and

transmitted them between receivers through free air space along a beam of light for a

distance of some 600 feet. He named his experimental device the “photo phone,” as

shown in Figure 2.1. Bell considered this optical technology – and not the telephone

– his pre-eminent invention because it did not require wires for transmission [1].

Although Bell’s photo phone never became a commercial reality, it

demonstrated the basic principle of optical communications. Essentially all of the

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engineering of today’s Free Space Optics (FSO) or free space optical

communications systems was done over the past 40 years or so, mostly for defense

applications. By addressing the principal engineering challenges of Free Space

Optics (FSO), this aerospace/defense activity established a strong foundation upon

which today’s commercial laser-based Free Space Optics (FSO) systems are based.

In the mid-1960’s, the military and NASA initiated experiments to utilized

the laser as a means of communication between the Goddard Space Flight Center and

the Gemini-7 orbiting space capsule. FSO has been used for more than 30 years to

provide fast communication links in remote locations. While fiber-optic

communications has gained acceptance in the telecommunications industry, FSO

communications is still relatively new. FSO technology enables bandwidth

transmission capabilities that are similar to fiber optics, using similar optical

transmitters and receivers and even enabling WDM-like technologies to operate

through free space.

Figure 2.1: Historical photos of FSO

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Figure 2.2: FSO transceiver device, old and new design

2.3 How Free Space Optics (FSO) Works?

FSO involves the optical transmission of voice, video, and data using air as

the medium of transmission as opposed to fiber optic cable. FSO technology is

relatively simple. It's based on connectivity between FSO-based optical wireless

units, each consisting of an optical transceiver with a laser transmitter and a receiver

to provide full-duplex (bi-directional) capability, as shown in Figure 2.3.

In order to transmit any information, network traffic is first converted into

pulses of invisible light representing 1’s and 0’s with the presence or absence of

pulses. Transmitter projects the carefully aimed light pulses into the air toward the

receiver. A receiver at the other end of the link collects the light using lenses and/or

mirrors. Received signal converted back into fiber or copper and connected to the