Optical Communications from a Fourier Perspective: Fourier Theory and Optical Fiber Devices and Systems covers Fourier theory and signal analysis over photonic components, including time lenses in optical communication. Sections cover wave propagation in optical waveguides based on Maxwell equations and the nonlinear Schrödinger equation. Optical Fourier transform in the form of time lens is covered, for example in modulation format conversion and spectrum magnification, and couplers and their use for optical discrete Fourier transformation are also discussed. Other important subjects are discussed such as shot noise, thermal noise and also the basics of four wave mixing in relation to time lenses. Detailed derivations and a deeper background for the chapters are provided in appendices where appropriate. Some of the theory is more generally applicable beyond optical communication and is of relevance also for communications engineering. The Fourier theory dimension of the book presents the relationship between Fourier series and Fourier integrals and also the related Laplace transform.
Arvustused
"...the book contains a short discussion on the basic relations for the wave propagation in optical fibers but a detailed discussion of the specific propagating modes is outside the scope of this book An important focus of the book is related to all-optical signal processing... This book covers a vast amount of material and it impresses by a very thorough analysis with extensive appendices... The book is thus very well suited for an advanced undergraduate student with respect to the first part of the book and for a graduate student with respect to the second part of the book. It is also very helpful that each chapter is concluded with a short summary at its end... represents a valuable extension to the existing literature providing the reader with a very deep knowledge for better understanding advanced optical communication systems." --Klaus Petermann, Technische Universität Berlin, Germany, IEEE Photonics Society News
1. The Dirac delta function and Heaviside step function
2. Fourier series, Parseval's theorem, FFT and Cooley-Tukey algorithm
3. Fourier integrals and Fourier series
4. Properties of the Fourier transform and Heaviside's step function
5. Complex signal, complex envelope and Hilbert transform
6. Correlation functions, spectral density, Wiener-Khinchine theorem
7. Linear, time-invariant systems
8. Transfer matrices and frequency filters
9. Laplace transforms, transfer functions, Nyquist criterion
10. Maxwell's equations, optical waveguides and Poynting's vector
11. Pulse propagation in optical fibers
12. Split step Fourier method and nonlinear Schrodinger equation
13. Introduction to modulation formats
14. Required bandwidth for heterodyne and homodyne detection
15. Bandpass noise
16. Bit error rate
17. Pulse shaping using optical Fourier transform
18. Spectrum magnification
19. Optical Fourier transformation, dispersion compensation, jitter suppression
20. Regeneration of WDM phase-modulated signals
21. Time-space duality, dispersion and diffraction, time lens
22. Couplers and their use for optical DFT
23. Multicarrier modulation, OFDM, DFT, Nyquist modulation
24. Optical orthogonal frequency division modulation
Palle Jeppesen is professor emeritus at the Technical University of Denmark (DTU) and a researcher with many years experiences in optical fiber communications, lasers, fibers, systems, and ultra-high-speed optical communications. He has been a member of the Danish Technical Research Council, the Scientific Council for the Danish National Encyclopedia, and on the boards of a number of large corporate entities. His current research interests are optical signal processing, optical multi-level modulation formats, and terabit optical communication.
Bjarne Tromborg was formerly a research and teaching professor at the Technical University of Denmark (DTU) best known for his work in particle physics and photonics. He has been a member of the Danish Natural Science Research Council and many technical program committees. He has published widely on the topics of optoelectronics, semiconductor lasers, and optical communications
