This Third Edition of the popular text, while retaining nearly all the material of the previous edition, incorporates material on important new developments in lasers and quantum electronics. Covers phase-conjugate optics and its myriad applications, the long wavelength quaternary semiconductor laser, and our deepened understanding of the physics of semiconductor lasers--especially that applying to their current modulations and limiting bandwidth, laser arrays and the related concept of supermodes, quantum well semiconductor lasers, the role of phase amplitude coupling in laser noise, and free-electron lasers. In addition, the chapters on laser noise and third-order nonlinear effects have been extensively revised.
55 pages matching electric field in this book
Results 1-3 of 55
absorption according acoustic amplifier amplitude angle assume atoms axis Brillouin scattering Chapter coefficient component condition conjugate consider corresponding coupling crystal defined density density matrix derived dielectric diffraction direction eigenfunctions eigenvalues electric field electromagnetic electron electrooptic energy equal example factor fiber follows frequency function gain Gaussian beam given Hamiltonian IEEE index ellipsoid index of refraction input integral intensity interaction inversion laser oscillation linewidth loss matrix medium mirror mode locking modulation molecule momentum noise nonlinear nonlinear optical normal obtain operator optical field optical resonator output perturbation phase phase-conjugate photon Phys plane plot polarization problem propagation constant pulse pump quantum mechanical radiation Raman Reference region relation result scattering Section semiconductor laser shown in Figure shows signal solution spectrum spontaneous emission supermodes symmetry threshold tion transition transverse valence band vector velocity vibrational wave equation wavefunction waveguide wavelength width Yariv zero