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Output coupling in optical cavities and lasers [[electronic resource] ] : a quantum theoretical approach / / Kikuo Ujihara
| Output coupling in optical cavities and lasers [[electronic resource] ] : a quantum theoretical approach / / Kikuo Ujihara |
| Autore | Ujihara Kikuo |
| Pubbl/distr/stampa | Weinheim, : Wiley, c2010 |
| Descrizione fisica | 1 online resource (410 p.) |
| Disciplina |
621.366
621.3661 |
| Soggetto topico |
Lasers
Optical communications |
| Soggetto genere / forma | Electronic books. |
| ISBN |
1-282-55034-9
9786612550348 3-527-63049-X 3-527-63050-3 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Output Coupling in Optical Cavities and Lasers; Contents; Preface; Acknowledgments; 1 A One-Dimensional Optical Cavity with Output Coupling: Classical Analysis; 1.1 Boundary Conditions at Perfect Conductor and Dielectric Surfaces; 1.2 Classical Cavity Analysis; 1.2.1 One-Sided Cavity; 1.2.2 Symmetric Two-Sided Cavity; 1.3 Normal Mode Analysis: Orthogonal Modes; 1.3.1 One-Sided Cavity; 1.3.2 Symmetric Two-Sided Cavity; 1.4 Discrete versus Continuous Mode Distribution; 1.5 Expansions of the Normalization Factor; 1.6 Completeness of the Modes of the ''Universe''
2 A One-Dimensional Optical Cavity with Output Coupling: Quantum Analysis2.1 Quantization; 2.2 Energy Eigenstates; 2.3 Field Commutation Relation; 2.4 Thermal Radiation and the Fluctuation-Dissipation Theorem; 2.4.1 The Density Operator of the Thermal Radiation Field; 2.4.2 The Correlation Function and the Power Spectrum; 2.4.3 The Response Function and the Fluctuation-Dissipation Theorem; 2.4.4 Derivation of the Langevin Noise for a Single Cavity Resonant Mode; 2.4.5 Excitation of the Cavity Resonant Mode by a Current Impulse; 2.5 Extension to an Arbitrarily Stratified Cavity 2.5.1 Description of the Cavity Structure2.5.2 The Modes of the ''Universe''; 3 A One-Dimensional Quasimode Laser: General Formulation; 3.1 Cavity Resonant Modes; 3.2 The Atoms; 3.3 The Atom-Field Interaction; 3.4 Equations Governing the Atom-Field Interaction; 3.5 Laser Equation of Motion: Introducing the Langevin Forces; 3.5.1 The Field Decay; 3.5.2 Relaxation in Atomic Dipole and Atomic Inversion; 4 A One-Dimensional Quasimode Laser: Semiclassical and Quantum Analysis; 4.1 Semiclassical Linear Gain Analysis; 4.2 Semiclassical Nonlinear Gain Analysis; 4.3 Quantum Linear Gain Analysis 4.4 Quantum Nonlinear Gain Analysis5 A One-Dimensional Laser with Output Coupling: Derivation of the Laser Equation of Motion; 5.1 The Field; 5.2 The Atoms; 5.3 The Atom-Field Interaction; 5.4 Langevin Forces for the Atoms; 5.5 Laser Equation of Motion for a Laser with Output Coupling; 6 A One-Dimensional Laser with Output Coupling: Contour Integral Method; 6.1 Contour Integral Method: Semiclassical Linear Gain Analysis; 6.2 Contour Integral Method: Semiclassical Nonlinear Gain Analysis; 6.3 Contour Integral Method: Quantum Linear Gain Analysis 6.4 Contour Integral Method: Quantum Nonlinear Gain Analysis7 A One-Dimensional Laser with Output Coupling: Semiclassical Linear Gain Analysis; 7.1 The Field Equation Inside the Cavity; 7.2 Homogeneously Broadened Atoms and Uniform Atomic Inversion; 7.3 Solution of the Laser Equation of Motion; 7.3.1 The Field Equation for Inside the Cavity; 7.3.2 Laplace-Transformed Equations; 7.3.3 The Field Inside the Cavity; 7.3.4 The Field Outside the Cavity; 8 A One-Dimensional Laser with Output Coupling: Semiclassical Nonlinear Gain Analysis; 8.1 The Field Equation Inside the Cavity 8.2 Homogeneously Broadened Atoms and Uniform Pumping |
| Record Nr. | UNINA-9910139354003321 |
Ujihara Kikuo
|
||
| Weinheim, : Wiley, c2010 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Output coupling in optical cavities and lasers [[electronic resource] ] : a quantum theoretical approach / / Kikuo Ujihara
| Output coupling in optical cavities and lasers [[electronic resource] ] : a quantum theoretical approach / / Kikuo Ujihara |
| Autore | Ujihara Kikuo |
| Pubbl/distr/stampa | Weinheim, : Wiley, c2010 |
| Descrizione fisica | 1 online resource (410 p.) |
| Disciplina |
621.366
621.3661 |
| Soggetto topico |
Lasers
Optical communications |
| ISBN |
1-282-55034-9
9786612550348 3-527-63049-X 3-527-63050-3 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Output Coupling in Optical Cavities and Lasers; Contents; Preface; Acknowledgments; 1 A One-Dimensional Optical Cavity with Output Coupling: Classical Analysis; 1.1 Boundary Conditions at Perfect Conductor and Dielectric Surfaces; 1.2 Classical Cavity Analysis; 1.2.1 One-Sided Cavity; 1.2.2 Symmetric Two-Sided Cavity; 1.3 Normal Mode Analysis: Orthogonal Modes; 1.3.1 One-Sided Cavity; 1.3.2 Symmetric Two-Sided Cavity; 1.4 Discrete versus Continuous Mode Distribution; 1.5 Expansions of the Normalization Factor; 1.6 Completeness of the Modes of the ''Universe''
2 A One-Dimensional Optical Cavity with Output Coupling: Quantum Analysis2.1 Quantization; 2.2 Energy Eigenstates; 2.3 Field Commutation Relation; 2.4 Thermal Radiation and the Fluctuation-Dissipation Theorem; 2.4.1 The Density Operator of the Thermal Radiation Field; 2.4.2 The Correlation Function and the Power Spectrum; 2.4.3 The Response Function and the Fluctuation-Dissipation Theorem; 2.4.4 Derivation of the Langevin Noise for a Single Cavity Resonant Mode; 2.4.5 Excitation of the Cavity Resonant Mode by a Current Impulse; 2.5 Extension to an Arbitrarily Stratified Cavity 2.5.1 Description of the Cavity Structure2.5.2 The Modes of the ''Universe''; 3 A One-Dimensional Quasimode Laser: General Formulation; 3.1 Cavity Resonant Modes; 3.2 The Atoms; 3.3 The Atom-Field Interaction; 3.4 Equations Governing the Atom-Field Interaction; 3.5 Laser Equation of Motion: Introducing the Langevin Forces; 3.5.1 The Field Decay; 3.5.2 Relaxation in Atomic Dipole and Atomic Inversion; 4 A One-Dimensional Quasimode Laser: Semiclassical and Quantum Analysis; 4.1 Semiclassical Linear Gain Analysis; 4.2 Semiclassical Nonlinear Gain Analysis; 4.3 Quantum Linear Gain Analysis 4.4 Quantum Nonlinear Gain Analysis5 A One-Dimensional Laser with Output Coupling: Derivation of the Laser Equation of Motion; 5.1 The Field; 5.2 The Atoms; 5.3 The Atom-Field Interaction; 5.4 Langevin Forces for the Atoms; 5.5 Laser Equation of Motion for a Laser with Output Coupling; 6 A One-Dimensional Laser with Output Coupling: Contour Integral Method; 6.1 Contour Integral Method: Semiclassical Linear Gain Analysis; 6.2 Contour Integral Method: Semiclassical Nonlinear Gain Analysis; 6.3 Contour Integral Method: Quantum Linear Gain Analysis 6.4 Contour Integral Method: Quantum Nonlinear Gain Analysis7 A One-Dimensional Laser with Output Coupling: Semiclassical Linear Gain Analysis; 7.1 The Field Equation Inside the Cavity; 7.2 Homogeneously Broadened Atoms and Uniform Atomic Inversion; 7.3 Solution of the Laser Equation of Motion; 7.3.1 The Field Equation for Inside the Cavity; 7.3.2 Laplace-Transformed Equations; 7.3.3 The Field Inside the Cavity; 7.3.4 The Field Outside the Cavity; 8 A One-Dimensional Laser with Output Coupling: Semiclassical Nonlinear Gain Analysis; 8.1 The Field Equation Inside the Cavity 8.2 Homogeneously Broadened Atoms and Uniform Pumping |
| Record Nr. | UNINA-9910830282703321 |
|
Ujihara Kikuo
|
||
| Weinheim, : Wiley, c2010 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||