Design of a four bit numeric data transceiver using optical free space communication
Table Of Contents
Chapter ONE
INTRODUCTION
- 1.1Introduction
- 1.2Background of Study
- 1.3Problem Statement
- 1.4Objective of Study
- 1.5Limitation of Study
- 1.6Scope of Study
- 1.7Significance of Study
- 1.8Structure of the Research
- 1.9Definition of Terms
Chapter TWO
LITERATURE REVIEW
- 2.1Overview of Optical Free Space Communication
- 2.2Historical Development of Optical Communication
- 2.3Principles of Optical Communication
- 2.4Types of Optical Communication Systems
- 2.5Applications of Optical Free Space Communication
- 2.6Challenges in Optical Free Space Communication
- 2.7Advances in Optical Communication Technologies
- 2.8Optical Transceivers and Their Functions
- 2.9Comparison of Optical Communication with Other Technologies
- 2.10Future Trends in Optical Communication
Chapter THREE
SYSTEM DESIGN AND IMPLEMENTATION
- 3.1Research Design and Methodology
- 3.2Selection of Research Approach
- 3.3Data Collection Methods
- 3.4Sampling Techniques
- 3.5Data Analysis Procedures
- 3.6Research Instrumentation
- 3.7Ethical Considerations
- 3.8Validity and Reliability of Data
Chapter FOUR
SYSTEM TESTING AND EVALUATION
- 4.1Data Analysis and Interpretation
- 4.2Presentation of Findings
- 4.3Comparative Analysis of Results
- 4.4Discussion on Research Findings
- 4.5Implications of Findings
- 4.6Recommendations for Further Research
- 4.7Practical Applications of Research Results
- 4.8Limitations of the Study
Chapter FIVE
SUMMARY, CONCLUSION AND RECOMMENDATIONS
- 5.1Summary of Research Findings
- 5.2Conclusions Drawn from the Study
- 5.3Contribution to Knowledge
- 5.4Practical Implications of the Study
- 5.5Recommendations for Future Research
Project Abstract
Optical free space communication has gained significant interest due to its potential for high-speed data transmission and secure communication. In this research project, a four-bit numeric data transceiver is designed using optical free space communication. The transceiver system consists of four main components a transmitter, a receiver, a data encoder, and a data decoder. The transmitter module is responsible for converting the four-bit numeric data into optical signals. This process involves encoding the numeric data into binary format and modulating the optical signal for transmission through free space. The design of the transmitter includes a laser diode for generating the optical signal and modulating circuitry for encoding the binary data. On the receiver side, a photodetector is used to capture the optical signal transmitted through free space. The receiver module includes a demodulator circuit to decode the received optical signal back into binary data. The decoded binary data is then converted back into the original four-bit numeric format for further processing. The data encoder and decoder play a crucial role in ensuring the accurate transmission and reception of the numeric data. The encoder module is responsible for converting the four-bit numeric data into binary format, which is essential for optical signal modulation. On the other hand, the decoder module decodes the received binary data back into the original numeric format for data processing. The design and implementation of the four-bit numeric data transceiver using optical free space communication involve considerations such as signal modulation techniques, transmission distance, optical alignment, and data encoding/decoding algorithms. The performance of the transceiver system is evaluated based on parameters such as data transmission rate, bit error rate, and signal-to-noise ratio. Overall, the research project aims to demonstrate the feasibility and effectiveness of using optical free space communication for transmitting numeric data. The designed transceiver system serves as a proof-of-concept for implementing high-speed data transmission using optical technology. The findings of this research contribute to the advancement of optical communication systems and pave the way for future developments in data transceiver design and implementation.
Project Overview
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</p><div><b><p><b>1.0 INTRODUCTION</b></p><p><b>1.1 Brief Overview of Free-Space Communication</b></p><p>Telecommunication is a process whereby information is encoded and transmitted over a distance through a channel or a medium by a sender to one or more receiver electronically (Advance English Dictionary). From the above definition the word that is to be emphasis is “distance” gotten from the Greek prefix “tele” meaning “distant”. Distance is a major point to consider when building a telecommunication device or system, therefore scientist over the years have worked and are still working on different means to enhance the efficiency of the distance and data-rate of telecommunication systems. Examples of such works are in the area of Radio and Microwave communications, Light Amplification by Stimulated Emission of Radiation (LASER) or optical communication systems and wired communication technology among others [5].</p><p>Optical communication systems are in various form and have been used for thousands of years. Among the early users of this system are the Ancient Greeks, they polish their shields to sends signals during battle [6]. In modern era, semaphores and wireless solar telegraphs called heliographs have been developed using coded signal to communicate with the receiver.</p><p></p><p>In the past ten to twenty years free-space optical communication (FSO) has attain a state of interest as an alternative to radio frequency communication [1]. Free-space optics also known as free-space photonics (FSP) is a branch of optical communication system that deals with the transmission of modulated visible or infrared (IR) beams through the atmosphere to obtain data or broadband communication. Some of the sources of these beams used are LASER and non-lasing sources like light-emitting diodes or IR-emitting diodes (IREDs) [4]. This technology is useful in areas with high electromagnetic interference (EMI) and therefore can be used for the most demanding industrial and domestic applications [5].</p><p>The growing need for high-speed and tap-proof communication systems to create links to satellites, ground stations, deep-space probes, unmanned aerial vehicles (UVAs), high altitude platforms (HAPs), aircrafts and other mobile or static communication systems makes the improvement and works on free-space optics a very high priority for telecommunication standards societies and space agencies such as; International Telecommunications Union (ITU) and National Aeronautics and Space Administration (NASA) among others. Links created by this technology can be used in both military and professional fields [1]. For example, it will take Radio frequency (RF) systems nine years to transmit a 30cm resolution map of the entire Martian surface (at one bit per pixel), but with an FSO system (such as LASERCOMM) this can be achieved in nine weeks.</p><p>FSO links between much distanced buildings have long been developed and established in developed countries such as the United State of America, but this technology just seems to be lacking in African countries like Nigeria among others [6]. If this technology is implemented in Nigeria it will greatly increase data-rate, and “Last Mile Challenges” can be reduced or completely eliminated.</p><p>Furthermore, free-space optic (FSO) systems are license-free access technologies with high frequency and very short wavelength therefore allowing higher data transmission, with less transmit power. It is a potential alternative or complement solution to common physical layers like fiber optic links. But in spite of the major merits of the FSO technology and diversity of its applications, works is on-going on ways to reduce or eliminate some of the major limitations of the technology such as fading resulting from ‘index-of-refraction turbulence (IRT) and link blockage by clouds, snow and rain [4].</p><p>In this project, a model will be designed to transmit and receive four bit numerical integers over a reasonable distance in free space to illustrate the working principle of the FSO systems.</p><p></p></b></div><b><div><p><b>1.2 Project Motivation</b></p><p>In today’s data rich world, high speed connections has become almost as important as the internet itself, broadband is faster and more accessible than ever before. Almost 60 million people now pay premium to access data all over the world with high speed connection, millions more want to join but cannot [3]. Service providers are always tasked to deliver high-speed internet access to eagerly waiting customers but, lack of infrastructure, long distance challenges, cost, competitive and regulatory issues are a constant problems especially in Nigeria and Africa in general. But with development of (FSO) technology a shortcut to broadband connectivity can be created to link with existing networks such as wired and wireless local area networks (WLANs), fiber optics and even satellite. These networks can then be extended using invisible beams of light (LASER or IR-emitting diodes), resulting in a very fast broadband wireless connections with merits such as no spectrum licenses, no electromagnetic interference (EMI) and highly secured from vandalisation.</p><p><b>1.3 Aims and Objectives</b></p><p>The aim of this project is to design and produce an optical-base system for transmission of 4-bits single digit numeric data from one point to another using free-space optical communication to illustrate the working principle of an (FSO) system.</p><p>The objectives of this project are:</p><p>1. To design an optical-base transceiver system using free-space optics.</p><p>2. To design the model using infrared (IR) beams.</p><p>3. To achieve a reasonable distance of at least 10 meters.</p><p>4. To illustrate the basic fundamental principle of the (FSO) systems.</p><p><b>1.4 Methodology</b></p><p>The implementation of this project uses a digital serial transmission system where single numeric integers are sent using 4-bits coding system over an optical path sequentially. This system is efficient because it requires less signal processing thereby less chance of error compared to parallel transmission and thus a faster transfer rate. The model uses a transmitter which encodes the integers into 4-bit codes then to a binary-to-frequency converter, next is to an optical emitter over free-space and a receiver, which reproduces the numeric integer from the received optical signal using a seven segment display.</p><p><b>1.5 Scope of Study</b></p><p>This project seeks to cover the design and implementation of a 4-bit transceiver using optical transmission channel. The maximum range of communication between the optical transmitter and receiver is between 10 to 20 meters. Intercommunication link between both the transmitter and receiver systems is completely based on line of sight.</p><p><b>1.6 Project Outline</b></p><p>The Chapter one of this project introduce the entire work. Chapter two reviews LASER in free-space optical and modulation in data transmission, Chapter three deals with the design procedure, Chapter four covers the construction, testing and result analysis. Chapter five is the summery which consist of the conclusion, recommendation and references</p></div></b>
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