描述
开 本: 16开纸 张: 胶版纸包 装: 精装是否套装: 否国际标准书号ISBN: 9787302349518
内容简介
《激光器的正交偏振(物理效应和工程应用)(精)》是一本全面介绍激光器正交偏振的专著,有4个部分共18章。第1部分包括3章,介绍激光器的基本知识,包括激光器的基本物理效应,可以产生正交偏振光的激光器类型,激光和正交偏振光束的黑盒子理论。第2部分包括3章,介绍各种正交偏振激光器,包括塞曼双频激光器、两频和四频环形激光器、双折射双频激光器等,以及各向异性激光腔的矩阵理论。第3部分包含3章,讨论激光器内的正交偏振光的形成和物理行为,腔调谐(长度改变)揭示的物理现象,正交偏振光回馈大量物理效应,正交偏振激光器的半经典理论。第4部分包括9章,介绍激光正交偏振效应的新应用,例如高分辨率位移传感,光学元件相位延迟的精密测量,精密、大动态范围的力和压力测量,角度测量及同时测量磁场和转角的四频环形激光器。
《激光器的正交偏振(物理效应和工程应用)(精)》提供了系统的知识,适合科学家、工程师、教授以及大学本科生和研究生参考。
目 录
Foreword
Foreword
Preface
Introduction
Part One FUNDAMENTALS OF LASERS AND BEAM POLARIZATIONS
1 Rigorous Introduction to Lasers and Beam Polarizations
1.1 The Basic Amplifier1Cavity Configuration
1.2 Optical Waves of a Laser
1.3 Cavity Closed-Loop and Laser Threshold
1.3. 1 The System Acts as a Closed-Loop Amplifier
1.3.2 The Closed-Loop System Acts as a Steady State Oscillator
1.4 Survey of Techniques for Generating and Converting Laser Polarization States
1.4.1 Survey of Light Polarization States
1.4.2 Polarization Conversion by Anisotropic Components
1.4.3 Laser Polarization States at a Glance
1.4.4 Anisotropic Elements Modulated by Electric1Magnetic Fields or Tactile Forces
1.4.5 Outlook
References
2 Basic Physical Effects Inside Lasers
2.1 Interaction between Light and Particles
2.1.1Spontaneous Emission
2.1.2Stimulated Transitions
2.1.3 Relationships among Einstein Coefficients
2.1.4 Intensities by Spontaneous Emission and Induced Emission
2.1.5 Boltzmann Distribution 1aw
2.1.6 Population Inversion and Light Amplification
2.2 Line Shape Function and the Line Broadening Mechanism
2.2.1 Line Form Function and Luminescence Line Bandwidth
2.2.2 Probability of Spontaneous and Induced Transitions
2.2.3 Mechanisms of Line Broadening
2.3 Gain Coefficient of Light in an Active Medium
2.3.1 Amplification Factor Gain, and Gain Coefficient
2.3.2 Some Remarks on the Gain Coefficient
2.4 Saturation of Gain in the Laser Active Medium
2.4.1 Saturation in a Homogeneously Broadened Medium
2.4.2 Saturation in an Inhomogeneously Broadened Medium
2.4.3 Saturation in an Integrative Broadened Medium
2.5 Threshold Condition, Gain for Stationary Operation, and Lasing Bandwidth
2.5.1 Losses of a Laser and the Threshold Condition
2.5.2 Stationary Gain of a Laser in Continuous Operation
2.6 Optical Cavities and Laser Modes
2.6.1 Optical Cavity and Its Stability Condition
2.6.2 Longitudinal Modes of a Laser
2.6.3 Laser Frequency Shift
2.6.4 La.ser Transverse Modes
2.6.5 Self Consistent Condition of Laser Oscillation
2.7 Laser Mode Competition
2.7.1 Mode Competition in a Laser with a Homogeneously Broadened Medium
2.7.2 Mode Competition in an Integratively Broadened Medium
2.8 Mode Push1Pull and Locking Effects
2.8.1 Frequency Pulling and Pushing Effects
2.8.2 Mode Locking
2.9 Power Tuning Properties of Lasers
2.9.1 Experimental Study of the Power Tuning Properties in Single-Mode Lasers
2.9.2 Power Tuning Curve of a Laser with a Homogeneously Broadened Medium
2.9.3 Tuning Properties of a La.ser with an Integratively Broadened Medium
References
3 Specific Laser Technologies Applicable for Orthogonally
Polarized Beam Generation
3.1 Background
3.2 He-Ne lasers
3.2.1 He-Ne Laser Configurations
3.2.2 Gas Discharge Excitation Mechanism (0.6328 μm)
3.2.3 Light Generation Process
3.2.4 Factors Injluencing Output Power of Laser Radiation
3.2.5 Polarization and Radiation Properties of He-Ne Lasers
……
Part Two GENERATION OF ORTHOGONAL LASER POLARIZATIONS
Part Three NONLINEAR BEHAVIOR OF ORTHOGONALLY POLARIZED LASERS
Part Four APPLICATIONS OF ORTHOGONALLY POLARIZED LASERS
Foreword
Preface
Introduction
Part One FUNDAMENTALS OF LASERS AND BEAM POLARIZATIONS
1 Rigorous Introduction to Lasers and Beam Polarizations
1.1 The Basic Amplifier1Cavity Configuration
1.2 Optical Waves of a Laser
1.3 Cavity Closed-Loop and Laser Threshold
1.3. 1 The System Acts as a Closed-Loop Amplifier
1.3.2 The Closed-Loop System Acts as a Steady State Oscillator
1.4 Survey of Techniques for Generating and Converting Laser Polarization States
1.4.1 Survey of Light Polarization States
1.4.2 Polarization Conversion by Anisotropic Components
1.4.3 Laser Polarization States at a Glance
1.4.4 Anisotropic Elements Modulated by Electric1Magnetic Fields or Tactile Forces
1.4.5 Outlook
References
2 Basic Physical Effects Inside Lasers
2.1 Interaction between Light and Particles
2.1.1Spontaneous Emission
2.1.2Stimulated Transitions
2.1.3 Relationships among Einstein Coefficients
2.1.4 Intensities by Spontaneous Emission and Induced Emission
2.1.5 Boltzmann Distribution 1aw
2.1.6 Population Inversion and Light Amplification
2.2 Line Shape Function and the Line Broadening Mechanism
2.2.1 Line Form Function and Luminescence Line Bandwidth
2.2.2 Probability of Spontaneous and Induced Transitions
2.2.3 Mechanisms of Line Broadening
2.3 Gain Coefficient of Light in an Active Medium
2.3.1 Amplification Factor Gain, and Gain Coefficient
2.3.2 Some Remarks on the Gain Coefficient
2.4 Saturation of Gain in the Laser Active Medium
2.4.1 Saturation in a Homogeneously Broadened Medium
2.4.2 Saturation in an Inhomogeneously Broadened Medium
2.4.3 Saturation in an Integrative Broadened Medium
2.5 Threshold Condition, Gain for Stationary Operation, and Lasing Bandwidth
2.5.1 Losses of a Laser and the Threshold Condition
2.5.2 Stationary Gain of a Laser in Continuous Operation
2.6 Optical Cavities and Laser Modes
2.6.1 Optical Cavity and Its Stability Condition
2.6.2 Longitudinal Modes of a Laser
2.6.3 Laser Frequency Shift
2.6.4 La.ser Transverse Modes
2.6.5 Self Consistent Condition of Laser Oscillation
2.7 Laser Mode Competition
2.7.1 Mode Competition in a Laser with a Homogeneously Broadened Medium
2.7.2 Mode Competition in an Integratively Broadened Medium
2.8 Mode Push1Pull and Locking Effects
2.8.1 Frequency Pulling and Pushing Effects
2.8.2 Mode Locking
2.9 Power Tuning Properties of Lasers
2.9.1 Experimental Study of the Power Tuning Properties in Single-Mode Lasers
2.9.2 Power Tuning Curve of a Laser with a Homogeneously Broadened Medium
2.9.3 Tuning Properties of a La.ser with an Integratively Broadened Medium
References
3 Specific Laser Technologies Applicable for Orthogonally
Polarized Beam Generation
3.1 Background
3.2 He-Ne lasers
3.2.1 He-Ne Laser Configurations
3.2.2 Gas Discharge Excitation Mechanism (0.6328 μm)
3.2.3 Light Generation Process
3.2.4 Factors Injluencing Output Power of Laser Radiation
3.2.5 Polarization and Radiation Properties of He-Ne Lasers
……
Part Two GENERATION OF ORTHOGONAL LASER POLARIZATIONS
Part Three NONLINEAR BEHAVIOR OF ORTHOGONALLY POLARIZED LASERS
Part Four APPLICATIONS OF ORTHOGONALLY POLARIZED LASERS
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