Muutke küpsiste eelistusi

Integrated Micro-Ring Photonics: Principles and Applications as Slow Light Devices, Soliton Generation and Optical Transmission [Pehme köide]

(Photonics Research Centre, University of Malaya, Kuala Lumpur, Malaysia), (Photonics Research Centre, University of Malaya, Kuala Lumpur, Malaysia), (University of Larestan, Lar, Iran)
  • Formaat: Paperback / softback, 164 pages, kõrgus x laius: 246x174 mm, kaal: 340 g
  • Ilmumisaeg: 12-Dec-2019
  • Kirjastus: CRC Press
  • ISBN-10: 0367873702
  • ISBN-13: 9780367873707
Teised raamatud teemal:
Integrated Micro-Ring Photonics: Principles and Applications as Slow Light Devices, Soliton Generation and Optical TransmissionSuurem pilt
  • Formaat: Paperback / softback, 164 pages, kõrgus x laius: 246x174 mm, kaal: 340 g
  • Ilmumisaeg: 12-Dec-2019
  • Kirjastus: CRC Press
  • ISBN-10: 0367873702
  • ISBN-13: 9780367873707
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9780367873707.html
Märksõnad:

Micro-ring resonators (MRRs) are employed to generate signals used for optical communication applications, where they can be integrated in a single system. These structures are ideal candidates for very large-scale integrated (VLSI) photonic circuits, since they provide a wide range of optical signal processing functions while being ultra-compact. Soliton pulses have sufficient stability for preservation of their shape and velocity. Technological progress in fields such as tunable narrow band laser systems, multiple transmission, and MRR systems constitute a base for the development of new transmission techniques. Controlling the speed of a light signal has many potential applications in fiber optic communication and quantum computing. The slow light effect has many important applications and is a key technology for all optical networks such as optical signal processing. Generation of slow light in MRRs is based on the nonlinear optical fibers. Slow light can be generated within the micro-ring devices, which will be able to be used with the mobile telephone. Therefore, the message can be kept encrypted via quantum cryptography. Thus perfect security in a mobile telephone network is plausible. This research study involves both numerical experiments and theoretical work based on MRRs for secured communication.



This book presents theoretically and experimentally gained data on novel techniques in optical communication applications, signals transmission and multi-ring resonator passive systems used for secured and high capacity optical communication.



It focussed on readers and researchers in the field of nonlinear physics, Photonics, op

Arvustused

"The phenomenon of slow light has received considerable attention over the last few years. The term slow light refers to the propagation of an optical signal through a medium with a speed considerably less than speed of light in vacuum. Controlling the speed of light is important for many applications such as optical communication systems, optical buffering, data synchronization, optical memories etc. Recent research has established that the velocity of light pulses can be controlled through micro-ring resonators (MRRs). This book is basically a research-based study on MRR systems and their utilization and application in optical communications. [ ...]

This book cannot be used as a textbook, but can be used as a reference for undergraduate and graduate researchers and for professional engineers with prior knowledge of applied optics and optical communication."

Book review by Ishtiaque Ahmed, Member of OSA, IEEE, APS in "Optics and Photonics News", August 2017

Preface ix
Acknowledgements xi
List of figures
xiii
List of tables
xvii
1 Soliton signals propagating in fiber waveguides and slow light generation
1(14)
1.1 Fiber waveguides
1(1)
1.2 Optical soliton
1(2)
1.3 Ring resonators
3(1)
1.4 Applications of ring resonator systems
3(3)
1.5 Introduction of slow light
6(1)
1.6 Slow light
7(1)
1.7 Background of slow light generation
8(1)
1.8 Problem statement
8(1)
1.9 Research achievements
8(1)
1.10 Scope of research
9(1)
1.11 Significance of study
9(1)
1.12 History of slow light generation
10(1)
1.13 History of slow light
11(4)
2 MRR systems and soliton propagating in optical fiber communication
15(32)
2.1 Soliton properties
15(2)
2.2 Evaluation of soliton signals
17(2)
2.3 MRR used to generate chaotic signals
19(3)
2.4 Resonance bandwidth of soliton
22(1)
2.5 Finesse of soliton
22(1)
2.6 Free Spectral Range (FSR) of soliton
22(1)
2.7 Quality factor of soliton
23(1)
2.8 Chaotic soliton signal generator
24(1)
2.9 Add/Drop filter system
25(3)
2.10 Half panda ring resonator function
28(2)
2.11 PANDA ring resonators
30(3)
2.12 Fiber nonlinearities
33(1)
2.13 Calculation of nonlinear refractive index
34(1)
2.14 Nonlinear Schrodinger equation (NLS equation)
35(2)
2.15 Temporal soliton
37(2)
2.16 Gaussian beam
39(1)
2.17 Dispersion
39(1)
2.18 Group velocity dispersion
40(1)
2.19 Self Phase Modulation (SPM)
41(1)
2.20 Chaotic phenomena
42(1)
2.21 Kramers-Kronig relations
42(1)
2.22 Scattering matrix method for ring resonator
43(1)
2.23 Theory of slow light
43(2)
2.24 Optical buffer
45(2)
3 Analysis of single Micro-Ring Resonators (MRR), add/drop filter MRR and cascaded MRR
47(16)
3.1 Single Micro-Ring Resonator (MRR)
47(1)
3.2 Analysis of Single Micro-Ring Resonator (SMRR)
47(2)
3.3 Soliton roundtrip and add/drop system
49(2)
3.4 Characteristics of the ring resonator
51(1)
3.5 Free Spectral Range (FSR)
51(1)
3.6 Full Width at Half Maximum (FWHM)
52(1)
3.7 Finesse
52(1)
3.8 Quality factor (Q factor)
53(1)
3.9 Group velocity and phase velocity
53(1)
3.10 Semiconductor cascaded MRR analysis and characterization
54(1)
3.10.1 Introduction of optical filters MRRs
54(1)
3.11 Theoretical background of cascaded MRR system
55(3)
3.12 Phase and dispersion responses and group delay analysis of the cascaded MRR system
58(5)
4 Physics and fabrication of Micro-Ring Resonator (MRR) structure devices
63(10)
4.1 Introduction
63(2)
4.2 Physical of micro-ring resonators
65(8)
5 Micro-ring modulators
73(6)
5.1 Introduction
73(1)
5.2 Micro-ring used as modulator
74(2)
5.3 Frequency-dependent micro-ring transmission
76(1)
5.4 Optical modulator based on MRRS integrated with Mach-Zehnder Interferometer (MZI)
76(3)
6 Micro-Ring Resonator (MRR) in optical transmission systems
79(8)
6.1 Micro-ring resonator systems in optical communication systems
79(1)
6.2 Theoretical background of soliton propagation in nonlinear Kerr medium
80(1)
6.3 Result and discussion
81(6)
7 Methods of slow light generation
87(14)
7.1 Introduction
87(2)
7.2 Dispersion in optical waveguide
89(1)
7.3 Slow light generation using nonlinear waveguide
90(4)
7.4 Slow light generation using linear waveguide
94(2)
7.5 Examine of dispersion waveguides
96(3)
7.6 Applications
99(2)
8 Soliton generation and transmission in optical fiber link
101(32)
8.1 Soliton chaotic signal generation using the MRRs
101(1)
8.2 Single dark and bright soliton generation
102(2)
8.3 Soliton comb generation using the add/drop system
104(1)
8.4 Add/drop filter system incorporating with series of ring resonator
104(6)
8.5 Ring resonator system analysis to optimize the soliton transmission
110(6)
8.6 Ring resonator for communication applications
116(6)
8.6.1 System setup
119(1)
8.6.2 Wimax signal generation
119(3)
8.7 Highly chaotic signal generation and transmission using PANDA ring resonator
122(2)
8.8 Dark soliton generation and tweezers transmission using fiber optic link
124(3)
8.9 Quantum entangled photons generation by tweezers and transmission using the wireless access point system
127(6)
9 Conclusion
133(2)
References 135(20)
Appendices 155
Dr. I.S. Amiri received his B. Sc (Hons, Applied Physics) from Public University of Oroumiyeh, Iran in 2001 and a gold medalist M. Sc. from Universiti Teknologi Malaysia (UTM), in 2009. He was awarded a PhD degree in nanophotonics in 2014. He has published more than 260 journals/conferences and books in Optical Soliton Communications, Nano photonics, Nonlinear Fiber Optics, Quantum Cryptography, Optical Tweezers, Nanotechnology, Biomedical Physics and Biotechnology Engineering.

Dr. Abdolkarim Afroozeh completed his MSc in the field of Astronomy at Shiraz University, Iran, in 2001. He was awarded a PhD degree in photonics from Universiti Teknologi Malaysia (UTM) in 2014. He has published more than 70 journals/conferences papers and books/chapters in Optical Soliton Communications, Laser Physics, photonics, Nonlinear fiber optics, Quantum Cryptography, Nanotechnology, Biomedical Physics and Biotechnology Engineering. Now, He is working in Young Researchers and Elite Club, Jahrom Branch, Islamic Azad University, Jahrom, Iran and The Department General of Fars Province Education, Iran.





Dr. Harith Ahmad received the PhD degree in laser technology from the University of Wales, Swansea, UK, 1983. He is a Professor with the Department of Physics, University of Malaya where he has actively pursued research activities in the field of photonics since 1983. Currently he is also the Director of Photonics Research Centre, University of Malaya. He is the author of more than 850 papers in international journals. His research interest is in lasers, fiber-based devices for telecommunications, and fiber-based sensor devices. Dr. Ahmad is a Fellow of the Academy of Sciences, Malaysia.