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Fundamentals Of Photonics 2nd Ed - B. Saleh, M. Teich (Wiley, 20 Megal)

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If you are looking for a comprehensive, up-to-date, and full-color textbook that covers all aspects of photonics, then you should check out Fundamentals Of Photonics 2nd Ed - B. Saleh, M. Teich (Wiley, 20 Megal). This book is written by two renowned experts in the field, Bahaa E. A. Saleh and Malvin Carl Teich, who have decades of experience in teaching and research in photonics. In this article, I'll give you an overview of what photonics is, why it is important, what are the main topics covered in the book, and how to use the book effectively for learning or teaching photonics.

Fundamentals Of Photonics 2nd Ed - B. Saleh, M. Teich (Wiley, 20 Megal

What is Photonics?

Photonics is the science and engineering of light. It deals with the generation, transmission, manipulation, detection, and utilization of light and its interaction with matter. Photonics encompasses a wide range of disciplines, such as optics, laser, fiber optics, optoelectronics, quantum optics, nanophotonics, biophotonics, and more. Photonics is based on the fundamental principles of physics, such as Maxwell's equations, quantum mechanics, and statistical mechanics.

Why is Photonics Important?

Photonics is important because it has many applications and benefits in various domains, such as communication, information processing, sensing, imaging, metrology, medicine, energy, security, and entertainment. For example:

• Photonics enables high-speed, high-capacity, and low-cost optical communication networks that connect the world through fiber-optic cables and wireless links.

• Photonics enables advanced information processing technologies that use light to perform computation, encryption, storage, and display.

• Photonics enables precise and sensitive sensing and measurement techniques that use light to detect physical, chemical, biological, and environmental parameters.

• Photonics enables high-resolution and high-contrast imaging and microscopy techniques that use light to visualize structures and processes at various scales.

• Photonics enables accurate and reliable metrology and calibration techniques that use light to define standards and units of measurement.

• Photonics enables innovative and effective medical and biomedical techniques that use light to diagnose, treat, and monitor diseases and disorders.

• Photonics enables efficient and sustainable energy technologies that use light to generate, convert, store, and distribute energy.

• Photonics enables secure and robust security technologies that use light to identify, authenticate, protect, and monitor people and objects.

• Photonics enables entertaining and creative entertainment technologies that use light to create, manipulate, and display images and sounds.

What are the Main Topics Covered in the Book?

The book covers the main topics of photonics in a logical and systematic way. It consists of 22 chapters that are organized into four parts: Part I: Basic Concepts; Part II: Optical Devices; Part III: Quantum Optics; Part IV: Applications. Each chapter contains summaries, highlighted equations, exercises, problems, and selected reading lists. Here is a summary of the main topics covered in each chapter:

Ray Optics

This chapter reviews the basic concepts and laws of ray optics. It covers topics such as reflection and refraction at plane and curved surfaces; Snell's law; Fermat's principle; lenses; mirrors; prisms; optical systems; aberrations; ray tracing; matrix methods; Gaussian optics; cardinal points; magnification; optical instruments.

Wave Optics

This chapter reviews the basic concepts and laws of wave optics. It covers topics such as scalar waves; wave equation; wave propagation; phase velocity; group velocity; dispersion relation; superposition principle; interference; coherence; Young's experiment; Michelson interferometer; diffraction; Fraunhofer diffraction; Fresnel diffraction; Huygens-Fresnel principle;

Beam Optics

This chapter reviews the basic concepts and laws of beam optics. It covers topics such as paraxial approximation; Gaussian beams; beam parameters; beam waist; Rayleigh range; beam divergence; beam propagation factor (M2); beam quality factor (Q); ABCD law for Gaussian beams; transformation of Gaussian beams by optical elements;

Fourier Optics

This chapter reviews the basic concepts and laws of Fourier optics. It covers topics such as Fourier transform; convolution theorem; correlation theorem; sampling theorem; spatial frequency spectrum; spatial filtering; optical transfer function (OTF); modulation transfer function (MTF); point spread function (PSF); impulse response function (IRF); coherent imaging system;

Electromagnetic Optics

Polarization and Crystal Optics

This chapter reviews the basic concepts and laws of polarization and crystal optics. It covers topics such as polarization states; Jones vectors; Stokes parameters; Poincaré sphere; polarization devices; polarizers; wave plates; retarders; rotators; optical activity; circular dichroism; birefringence; double refraction; phase retardation; Jones matrices; Mueller matrices;

Guided-Wave Optics

This chapter reviews the basic concepts and laws of guided-wave optics. It covers topics such as waveguides; slab waveguides; modes; propagation constants; effective refractive index; cut-off frequency; dispersion; modal analysis; planar waveguides; channel waveguides; strip waveguides; rib waveguides;

Fiber Optics

This chapter reviews the basic concepts and laws of fiber optics. It covers topics such as optical fibers; fiber structure; fiber fabrication; fiber types; step-index fibers; graded-index fibers; single-mode fibers; multimode fibers; fiber modes; mode field diameter (MFD); numerical aperture (NA); V-number (normalized frequency); fiber losses; attenuation coefficient;

Resonator Optics

This chapter reviews the basic concepts and laws of resonator optics. It covers topics such as optical resonators; Fabry-Perot resonator (etalon); cavity finesse (F); cavity quality factor (Q); free spectral range (FSR); cavity linewidth (Δν); mode spacing (δν); longitudinal modes (m); transverse modes (n); mode volume (V); mode matching;

Statistical Optics

This chapter reviews the basic concepts and laws of statistical optics. It covers topics such as random variables and processes; probability density function (PDF); cumulative distribution function (CDF); mean value and variance; moments and cumulants; correlation functions and spectra; ergodicity and stationarity; Gaussian processes and fields;

Photon Optics

This chapter reviews the basic concepts and laws of photon optics. It covers topics such as photons and light quanta; Planck's law of blackbody radiation; Einstein's coefficients of spontaneous and stimulated emission and absorption; photon statistics and distributions;

Photons and Atoms

This chapter reviews the basic concepts and laws of photons and atoms. It covers topics such as atomic energy levels and transitions; selection rules and transition probabilities; line broadening mechanisms and linewidths;

Laser Amplifiers

This chapter reviews the basic concepts and laws of laser amplifiers. It covers topics such as laser amplification process and principles; gain coefficient and saturation intensity; small-signal gain and gain bandwidth; amplified spontaneous emission (ASE) and noise figure; optical parametric amplification (OPA) and oscillation (OPO); Raman amplification and oscillation; Brillouin amplification and oscillation;

How to Use the Book Effectively?

The book is designed to be used effectively for learning or teaching photonics at various levels. Here are some tips on how to use the book effectively:

Prerequisites and Level

The book assumes that the reader has a basic background in physics, mathematics, and engineering. The book is suitable for advanced undergraduate or graduate students, as well as researchers and professionals who want to learn or refresh their knowledge of photonics. The book covers both fundamental concepts and advanced topics, with varying levels of difficulty. The reader can choose the topics that suit their interests and needs.

Features and Organization

The book has many features that make it easy to follow and understand. The book is organized into four parts, each containing several chapters that cover a specific topic in photonics. Each chapter has a clear structure, with an introduction, a main body, a summary, highlighted equations, exercises, problems, and selected reading lists. The book also has many figures, tables, examples, and applications that illustrate and demonstrate the concepts and laws of photonics. The book uses a consistent notation and terminology throughout.

Resources and Supplements

The book has many resources and supplements that enhance the learning or teaching experience. The book has a companion website that provides additional materials, such as solutions to selected problems, MATLAB codes, animations, simulations, videos, slides, and links to relevant websites. The book also has a bibliography that lists the references cited in the book, as well as a comprehensive index that helps the reader to find the topics of interest.

Conclusion

In conclusion, Fundamentals Of Photonics 2nd Ed - B. Saleh, M. Teich (Wiley, 20 Megal) is a complete, thoroughly updated, full-color textbook that thoroughly surveys the rapidly expanding area of photonics. The book covers all aspects of photonics, from basic concepts to advanced topics, from theory to applications, from classical to quantum optics. The book is written by two renowned experts in the field, who have decades of experience in teaching and research in photonics. The book is suitable for advanced undergraduate or graduate students, as well as researchers and professionals who want to learn or refresh their knowledge of photonics. The book has many features, resources, and supplements that make it easy to follow and understand. The book is available online or in print from Wiley or other retailers. If you are interested in photonics, you should definitely get this book!

FAQs

Here are some frequently asked questions about the book:

• Q: How can I access the companion website of the book?A: You can access the companion website of the book by visiting https://onlinelibrary.wiley.com/doi/book/10.1002/0471213748. You will need to register or log in with your Wiley account to access the materials.

• Q: How can I get the solutions to the problems in the book?A: You can get the solutions to selected problems in the book by visiting the companion website of the book. The solutions are available in PDF format for download.

• Q: How can I contact the authors of the book?A: You can contact the authors of the book by sending an email to bsaleh@bu.edu (Bahaa E. A. Saleh) or mcteich@columbia.edu (Malvin Carl Teich).

• Q: How can I get a copy of the book?A: You can get a copy of the book by ordering online or in print from Wiley or other retailers. The ISBN of the book is 978-0-471-23365-1.

• Q: How can I give feedback on the book?A: You can give feedback on the book by writing a review on Amazon or other platforms, or by contacting Wiley or the authors directly.

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