Advances in All-Optical Communication.

Format:

Book

Author/Creator:

Dhanabalan, Shanmuga Sundar.

Contributor:

Thirumurugan, Arun.

Thirumaran, Sridarshini.

Series:

IOP Ebooks Series

Language:

English

Subjects (All):

Optical communications.

Photonic crystals.

Physical Description:

1 online resource (249 pages)

Edition:

1st ed.

Place of Publication:

Bristol : Institute of Physics Publishing, 2024.

Summary:

This book will provide an overview of the recent developments in all-optical communication technology, relevant and critical materials, and recent and emerging applications in various domains. It focuses on all-optical communication technology and applications in the most critical domains: microwaves, Meta surface, Optoelectronics, and photonic fibers.

Contents:

Intro

Acknowledgments

Editor biographies

Shanmuga Sundar Dhanabalan

Arun Thirumurugan

T Sridarshini

List of contributors

Chapter Highly efficient materials for photonic crystal-based optical components

1.1 Introduction

1.1.1 Light as a carrier for data transmission

1.1.2 Optical processing

1.1.3 Optical communication

1.1.4 Photonic crystal structure

1.2 Photonic crystal and light propagation

1.3 Photonic crystal-based devices

1.3.1 Demultiplexer/multiplexer

1.3.2 Flip-flop

1.3.3 Comparator

1.4 Materials used in photonic crystal structures

References

Chapter Unidirectional bulk growth of 1,3,5-triphenylbenzene single crystal and doping effect on its optical properties

2.1 Introduction

2.2 Experiment

2.2.1 Conventional crystal growth

2.2.2 Bulk growth of stilbene-doped 3PB

2.2.3 Characterization techniques

2.3 Result and discussion

2.3.1 X-ray diffraction analysis

2.3.2 UV-visible NIR spectra analysis

2.3.3 Fluorescence emission spectrum analysis

2.3.4 Lifetime measurement

2.3.5 FTIR spectral studies

2.3.6 NMR spectra analysis

2.4 Conclusions

Chapter Performance analysis of SOA-based all-optical logic gates over FSO channel

3.1 Introduction

3.2 Applications, advantages, challenges, and models of FSO

3.3 Related works

3.4 Basics of semiconductor optical amplifiers

3.4.1 Types of SOA

3.4.2 Principal operation of SOA and design of XOR gate

3.5 Design of OR gate using RSOA

3.6 All-optical device design using SOA and RSOA

3.7 Simulation setup of encoded inputs over wired and wireless optical channel

3.8 Conclusion

Chapter Switching characteristics of optical solitons through inelastic interactions

4.1 Introduction

4.1.1 Telecommunication windows.

4.1.2 Optical soliton formation in an optical fiber

4.1.3 Nonlinearity

4.1.4 Group velocity dispersion

4.1.5 Attenuation

4.2 Governing theoretical model

4.3 Lax pair for the system (4.10)

4.4 Two soliton solutions through Darboux method

4.5 Discussion on switching characteristics of femtosecond solitons

4.6 Conclusions

Chapter Silicon photonic modulators for high-speed applications-a review

5.1 Introduction

5.2 Phase shifters

5.2.1 Silicon-based phase shifter

5.2.2 Hybrid phase shifters

5.3 Mach-Zehnder modulator (MZM)

5.4 Ring modulator

5.5 Modulator performance metrics

5.6 Data centre requirements

5.7 Conclusion

Chapter MIMO-FSO system for various weather conditions

6.1 Introduction to free-space optical communication

6.1.1 Free-space optical communication

6.2 FSO communication principles

6.2.1 FSO transceiver

6.2.2 FSO classifications

6.2.3 FSO applications

6.3 Performance evaluation of the FSO system

6.3.1 Link budget

6.3.2 FSO received optical power

6.3.3 Data rate

6.3.4 Signal-to-noise ratio and BER

6.3.5 Channel models

6.4 Introduction to MIMO system

6.4.1 From SISO to MIMO to mMIMO

6.4.2 mMIMO

6.4.3 Benefits of mMIMO

6.4.4 mMIMO FSO system

6.5 Result analysis

6.6 Conclusions

Chapter AI in optics and photonics

7.1 Introduction

7.1.1 Introduction to optics and photonics

7.1.2 Introduction to AI

7.2 Intersection of AI/ML in optics

7.2.1 Major applications

7.2.2 Major challenges

7.3 Intersection of AI in photonics

7.3.1 Major applications

7.3.2 Major challenges

7.4 Conclusion and future scope of AI/ML in optics and photonics

Chapter Blood components detection in octagonal-cored photonic crystal fiber biosensor for healthcare applications.

8.1 Introduction

8.2 Design

8.3 Methodology

8.4 Results and discussion

8.5 Conclusion

Chapter Photonic biosensors for healthcare applications

9.1 Introduction

9.2 Biosensors: plasmonic and photonic platforms

9.3 Overview of biosensing technologies and plasmonics for healthcare applications

9.4 Overview of nanophotonics and plasmonics for healthcare applications: introducing SPCE and PCCE technology

9.5 CryoSoret nano-engineering techniques for SPCE-based biosensing applications

9.6 Surface plasmon-coupled emission (SPCE): applications in early diagnostics

9.6.1 Utility of chromaticity plot for tyrosine and spermidine sensing

9.6.2 Utility of luminosity plot for the mercury ion sensing

9.7 Ferroplasmon-on-Mirror (FPoM): applications in early diagnostics

9.8 Photonic crystal-coupled emission: applications in early diagnostics

9.9 Futuristic scope and opportunities

9.10 Conclusions

9.11 Exercises

Chapter Integrated photonic devices for cancer detection

10.1 Introduction

10.2 Surface plasmon resonance (SPR)-based biosensors

10.2.1 Principle of SPR

10.3 Grating-based biosensors

10.3.1 Bragg principle

10.4 2D photonic crystal-based biosensors

10.4.1 Basics of 2D PhC

10.4.2 Types of PhCs

10.4.3 Numerical methods

10.4.4 Performance parameters of sensor

10.4.5 Schematic representation of 2D PhC-based biosensing

10.4.6 Inference of advance technologies

10.5 Conclusion

Chapter Absorbers as biosensors: leveraging absorption phenomena for enhanced biosensing

11.1 Introduction

11.2 Factors influencing sensing performance

11.2.1 Metamaterial design's composition and geometry

11.2.2 Frequency range

11.2.3 Electromagnetic properties

11.2.4 Sensitivity and selectivity.

11.2.5 Integration with other materials/devices

11.2.6 Fabrication techniques

11.2.7 Environmental factors

11.2.8 Signal processing

11.2.9 Application-specific considerations

11.2.10 Power usage

11.3 Materials employed for designing biosensor absorbers

11.3.1 Importance of metal layer and various metals used in metamaterial-based biosensor

11.4 Popular designs of absorbers for biosensing

11.5 Fabrication techniques

11.5.1 Substrate preparation

11.5.2 Catalyst deposition

11.5.3 Graphene growth

11.5.4 Transfer process

11.5.5 Evaluation and optimization

11.6 Conclusion

References.

Notes:

Description based on publisher supplied metadata and other sources.

Part of the metadata in this record was created by AI, based on the text of the resource.

ISBN:

9780750356237

0750356235

OCLC:

1472497027