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E-grāmata: Photonics Modelling and Design

(The University of Nottingham, UK)
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Photonics Modelling and DesignPalielināt
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Photonics Modeling and Design delivers a concise introduction to the modeling and design of photonic devices. Assuming a general knowledge of photonics and the operating principles of fibre and semiconductor lasers, this book:





Describes the analysis of the light propagation in dielectric media Discusses heat diffusion and carrier transport Applies the presented theory to develop fibre and semiconductor laser models Addresses the propagation of short optical pulses in optical fibres Puts all modeling into practical context with examples of devices currently in development or on the market

Providing hands-on guidance in the form of MATLAB® scripts, tips, and other downloadable content, Photonics Modeling and Design is written for students and professionals interested in modeling photonic devices either for gaining a deeper understanding of the operation or to optimize the design.

Recenzijas

"I think the main strength of this book is the detailed discussion of fundamental equations as well as the in-depth comparison of numerical methods. The author obviously knows what he is writing about from first-hand experience with advanced modeling and practical design of modern devices." Joachim Piprek, NUSOD Institute, Newark, Delaware, USA

"I like the use of MATLAB®-based example codes. ... I like the fact that the material is all based on the authors own personal research. This brings a level of detail and understanding. ... The author has considerable experience in developing original BPM and thermal models in the context of high-power laser diodes simulation. He brings both subjects to light with his considerable insight. ... The book draws upon the authors wide experience in photonics modelling and simulation. It is rigorous in approach, insightful, and very well written." Prof. Trevor Benson, University of Nottingham, UK

"Design and modeling of photonic components is of great importance to the continued expansion of the utilization of photonics devices and systems...the author makes a strong play for a hands on approach to modeling by eschewing detailed theoretical foundations in favor of practical content, including sample MATLAB code."

K. Alan Shore, Bangor University, UK "I think the main strength of this book is the detailed discussion of fundamental equations as well as the in-depth comparison of numerical methods. The author obviously knows what he is writing about from first-hand experience with advanced modeling and practical design of modern devices." Joachim Piprek, NUSOD Institute, Newark, Delaware, USA

"I like the use of MATLAB®-based example codes. ... I like the fact that the material is all based on the authors own personal research. This brings a level of detail and understanding. ... The author has considerable experience in developing original BPM and thermal models in the context of high-power laser diodes simulation. He brings both subjects to light with his considerable insight. ... The book draws upon the authors wide experience in photonics modelling and simulation. It is rigorous in approach, insightful, and very well written." Prof. Trevor Benson, University of Nottingham, UK

"Design and modeling of photonic components is of great importance to the continued expansion of the utilization of photonics devices and systems...the author makes a strong play for a hands on approach to modeling by eschewing detailed theoretical foundations in favor of practical content, including sample MATLAB code."

K. Alan Shore, Bangor University, UK

Preface xi
Biography xiii
Chapter 1 Introduction 1(10)
Optical Model
1(3)
Active Medium Model
4(1)
Heat Diffusion and Stress—Strain Models
5(1)
Photonic Device Models
6(3)
References
9(2)
Chapter 2 Light Propagation in Homogenous Media 11(44)
Fourier Method
11(16)
Optical Beam Reflection and Refraction
27(9)
Paraxial and Wide Angle Approximations
36(8)
Transmission through Thin Optical Elements
44(8)
References
52(3)
Chapter 3 Optical Waveguides 55(76)
Introduction to Optical Waveguide Theory
55(10)
Planar Optical Waveguides
65(29)
Waveguiding in Planar Optical Waveguides
66(4)
Index Guiding Planar Optical Waveguides
66(4)
Low Loss Leaky and Gain Guided Planar Optical Waveguides
70(1)
Examples of Planar Optical Waveguides
70(3)
Slab Optical Waveguide
73(10)
Effective Index Method
83(2)
Propagation Constant Calculation Techniques for Planar Optical Waveguides
85(5)
Comparison of Polarised, Scalar, and Effective Index Approximations
90(4)
Optical Fibres
94(27)
Waveguiding in Optical Fibres
94(3)
Examples of Optical Fibres
97(3)
Step Index Circular Optical Fibre
100(11)
A "Poor Man's Approach" to Modelling MOFs
111(7)
Propagation Constant Calculation Techniques for MOFs
118(3)
References
121(10)
Chapter 4 Beam Propagation Method 131(62)
Introduction
133(5)
BPM Algorithms
138(6)
Split Operator BPM
139(1)
Eigenmode Expansion BPM
140(2)
Matrix Expansion BPM
142(2)
Bidirectional BPM
144(7)
Handling Abrupt Discontinuities
145(4)
Handling Multiply Reflected Waves
149(2)
Numerical Implementation of BPM
151(19)
Boundary Condition
157(2)
Dispersion Characteristics
159(7)
Staircasing Approximation
166(4)
Selected Examples of BPM Application
170(10)
Optical Taper
171(2)
Oblique and Bent Waveguides
173(4)
Y Junction
177(3)
Time Domain Analysis
180(2)
Time Domain BPM
180(1)
Travelling Wave Approach
181(1)
References
182(11)
Chapter 5 Thermal Modelling of Photonic Devices 193(44)
Heat Flow
194(3)
Heat Flow in Photonic Devices
197(6)
Finite Difference Analysis of Heat Flow in Homogenous Media
203(22)
Finite Difference Analysis of Heat Flow in Inhomogeneous Media
225(7)
Heat Sources, Boundary Conditions, and Thermal Boundary Resistance
232(2)
References
234(3)
Chapter 6 Flow of Current in Semiconductor Photonic Devices 237(40)
Introduction
237(5)
Potential Distribution in Unbiased p—n Junction
242(9)
Potential and Quasi-Fermi Level Distribution in Biased p—n Junction
251(19)
Modelling of Current Flow in Photonic Semiconductor Devices
270(3)
References
273(4)
Chapter 7 Fibre Amplifiers and Lasers 277(48)
Photons and Atoms
277(5)
Silica Glass—Doped with Erbium Ions
282(3)
Fibre Amplifier Modelling
285(17)
Copropagating and Counterpropagating Pump Fibre Amplifier Models
286(14)
Amplified Spontaneous Emission
300(2)
Fibre Laser Modelling
302(7)
Time Domain Models
309(1)
Extraction of Modelling Parameters
310(12)
Lanthanide Ion Interaction Effects
320(2)
References
322(3)
Chapter 8 Laser Diode Modelling 325(50)
Introduction
325(3)
OD LD Models
328(30)
OD CW Model
332(8)
OD Time Domain Model
340(3)
OD Spectral Model
343(9)
1D Laser Diode Models
352(6)
Multidimensional LD Models
358(11)
References
369(6)
Chapter 9 Pulse Propagation in Optical Fibres 375(18)
Introduction
375(1)
Propagation of Optical Pulses in Fibres
376(7)
Split-Step Fourier Method
383(8)
References
391(2)
Index 393
Slawomir Sujecki is associate professor at the University of Nottingham, UK. He holds a Ph.D and D.Sc from the Warsaw University of Technology, Poland. Previously he was lecturer and research assistant at the University of Nottingham; researcher at the National Institute of Telecommunications, Warsaw, Poland; and lecturer at the Kielce University of Technology, Poland. An IEEE senior member, OSA life member, and NUSOD Conference Program Committee member, Dr. Sujecki has participated in research projects funded by the European Community, including Ultrabright, Bright.EU, Brighter.EU, FastAccess, Copernicus, and MINERVA, and has received fellowships from Deutscher Akademischer Austauschdienst, British Council, Royal Society, and Wolfson Foundation.
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