《现代通信光电子学》 第六版,大名鼎鼎的雅里夫就不用多介绍了吧,希望觉得好的XD们顶一下 IdYzgDH
Photonics: Optical Electronics in Modern Communications ,fK3ZC
Hardcover: 848 pages s]m o$ _na
Publisher: Oxford University Press, USA; 6 edition (January 26, 2006) F:*W5xX
Language: English QK0h6CX
ISBN-10: 0195179463 Q-ni|
ISBN-13: 978-0195179460 G+B~Ix-
Product Dimensions: 9.3 x 7.7 x 1.4 inches ;^*Unyt[4]
[ post]Product Description hjaT^(Y
Due to its central role in modern communications technologies, photonics--or optical electronics--has evolved dynamically over the last ten years. Photonics by Amnon Yariv and Pochi Yeh is extensively revised and updated to keep pace with this unprecedented development. Now more tailored to optical communication, the sixth edition integrates material on generating and manipulating optical radiation and designing photonic components for the transmission of information. It also presents a broader theoretical underpinning and more explanations of mathematical derivations than the previous edition. ]\/tVn.'
The text describes the basic physics and principles of operation of major photonic components in optical communications and electronics. These components include optical resonators, various lasers, waveguides, optical fibers, gratings, and photonic crystals. photonics, Sixth Edition, also covers the transmission, modulation, amplification, and detection of optical beams in optical networks, as well as nonlinear optical effects in fibers. It assumes a background in electromagnetic theory, Maxwell's equations, and electromagnetic wave propagation. !d<"nx[2`
Including numerous examples throughout, Photonics, Sixth Edition, is ideal for advanced undergraduate and graduate courses in photonics, optoelectronics, or optical communications. It is also a useful reference for practicing engineers and scientists. aQI^^$9g
New Material in the Sixth Edition ,Jc m+Wb
Stokes Parameters and Poincare Sphere: polarization states in birefringent optical networks, principal states of polarization m(], r})
Fermat's Principle: rays, beam propagation, and the Fresnel diffraction integral `_b`kzJ
Matrix Formulation: wave propagation in multi-cavity etalons, multi-layer structures, mode coupling, and supermodes in mode-locked lasers uwRr LF
Dispersion: chromatic dispersion and polarization mode dispersion (PMD) in fibers and their compensation <0yE
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Coupled Resonators Optical Waveguides (CROWs): matrix formulation, critical coupling and dispersion relation 1;Pv0&[q/
Nonlinear Optical Effects in Fibers: self-phase modulation, cross-phase modulation, stimulated Brillouin scattering (SBS), stimulated Raman scattering (SRS), optical four-wave mixing, and spectral reversal (phase conjugation) R'kyrEO
Electroabsorption: waveguide electro-optic Mach-Zehnder modulators O+%WR
Photonic Crystals: Bloch wave formulation, photonic bands, photonic bandgaps, periodic layered media, fiber Bragg gratings, and Bragg reflection waveguides uB!kM
Optical Amplifiers: SOA, EDFA, and Raman |F9z,cc"
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About the Author Yvn\xph3
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Amnon Yariv is Martin and Eileen Summerfeld Professor of Applied Physics at the California Institute of Technology. SQeRSz8bK4
Pochi Yeh is Professor of Electrical & Computer Engineering at the University of California, Santa Barbara. sp@E8G%xO
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1. Electromagnetic Fields and Waves gN)c
2. Rays and Optical Beams A
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3. Guided waves in Dielectric Slabs and Fibers Ed9Z9
4. Optical Resonators Lm@vXgMD
5. Interaction of Radiation and Atomic Systems )'*5R <#
6. Theory of Laser Oscillation and Some Specific Laser Systems b;)~wU=
7. Chromatic Dispersion and Polarization Mode Dispersion in Fibers LH:i| I
8. Nonlinear Optics >~K
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9. Electro-Optic Modulation of Laser Beams oI^4pwn h
10. Noise in Optical Detection and Generation Oy 2+b1{
11. Detection of Optical Radiation tzy'G"P|
12. wave propagation in Periodic Media `/HUV&i"S
13. Waveguide Coupling %pXAeeSY`;
14. Nonlinear Optical Effects in Fibers cBo{/Tn:
15. Semiconductor Lasers-Theory and Applications 97K[(KE
16. Advanced Semiconductor Lasers 0rGSH*(
17. Optical Amplifiers JHf
18. Classical Treatment of Quantum Noise and Squeezed States Q,&