Zhongmin Yang, Can Li, Shanhui Xu, Changsheng Yang.
.PUBLICATION, DISTRIBUTION, ETC
Place of Publication, Distribution, etc.
Singapore :
Name of Publisher, Distributor, etc.
Springer,
Date of Publication, Distribution, etc.
2019.
PHYSICAL DESCRIPTION
Specific Material Designation and Extent of Item
1 online resource (vii, 170 pages) :
Other Physical Details
illustrations (some color)
SERIES
Series Title
Optical and fiber communications reports,
Volume Designation
volume 8
ISSN of Series
1619-1447 ;
INTERNAL BIBLIOGRAPHIES/INDEXES NOTE
Text of Note
Includes bibliographical references.
CONTENTS NOTE
Text of Note
Intro; Contents; Chapter 1: Introduction; 1.1 Brief History of Fiber Lasers; 1.2 Main Components of Fiber Lasers; 1.3 Current Development Status of Fiber Lasers; 1.4 The Importance of Single-Frequency Fiber Lasers; References; Chapter 2: Fundamental Principle and Enabling Technologies of Single-Frequency Fiber Lasers; 2.1 Principle of Single-Frequency Lasing; 2.2 Properties of Single-Frequency Lasers; 2.2.1 Single Longitudinal Mode Operation; 2.2.2 Intensity Noise; 2.2.3 Frequency Noise; 2.2.4 Linewidth; 2.3 Cavity Design of Single-Frequency Fiber Lasers; 2.3.1 Typical Cavity Structures
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2.3.2 Other Schemes to Achieve Single-Frequency Lasing2.4 Single-Frequency Fiber Laser Design with Advanced Performances; 2.4.1 Linearly Polarized Operation; 2.4.2 Linewidth Suppression; 2.4.3 Frequency and Intensity Noise Suppression; 2.4.4 Continuous Wavelength Tuning; 2.4.5 Fast Frequency Modulation; References; Chapter 3: Single-Frequency Active Fiber Lasers; 3.1 Introduction of Rare-Earth Ions Doped Multicomponent Glass Fiber; 3.2 High-Power Operation from Fiber Oscillator; 3.3 Thermal Effects in High-Gain Single-Frequency Fiber Lasers
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3.4 Noise Properties of High-Gain Single-Frequency Fiber Lasers3.4.1 Self-Heating Noise; 3.4.2 Coupling Between Frequency and Intensity Noise; 3.4.3 Amplified Spontaneous Emission Noise; References; Chapter 4: Fiber Nonlinear Single-Frequency Lasers; 4.1 Nonlinear Effects in Optical Fibers; 4.2 Raman and Brillouin Fiber Lasers; 4.3 Random Distributed Feedback Fiber Lasers; 4.4 Fiber Optical Parametric Oscillator; References; Chapter 5: Single-Frequency Pulsed Fiber Lasers; 5.1 Principle of Q-Switching; 5.2 Q-Switched Single-Frequency Fiber Lasers
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5.3 Other Single-Frequency Pulsed Fiber LasersReferences; Chapter 6: Amplification Technologies of Single-Frequency Lasers; 6.1 The Significance of Amplifying Single-Frequency Lasers; 6.2 Basic Principles of MOPA Fiber Laser; 6.3 Structure of MOPA Fiber Laser; 6.3.1 Double-Clad Fiber Technology; 6.3.2 Cladding Pump Coupling Technology; 6.3.2.1 End-Face Coupling via Lens Group; 6.3.2.2 V-Groove Side-Pump Coupling; 6.3.2.3 Embedded Prism Side-Pump Coupling; 6.3.2.4 Fused Fiber Bundle Coupler; 6.4 Limitation Factors of High-Power Single-Frequency MOPA Laser; 6.4.1 Nonlinear Effects
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SUMMARY OR ABSTRACT
Text of Note
This book gives a contemporary overview of the technologies of single-frequency fiber lasers. The development of single-frequency fiber lasers is one of the most significant achievements in the field of laser photonics over the past two decades. Owing to the crucial demands of a laser sources with highly stable single-frequency operation, narrow linewidth, low noise, scalable to high output power, compact and robustness structure, fiber lasers have been intensively studied since its introduction to the single-frequency laser community and they still continuously proceed to trigger the emergence of new technologies and applications. This book systematically demonstrates the single-frequency fiber laser technologies from fundamental principles to state-of-the-art progress. Details of selected typical applications of single-frequency fiber lasers are also given and discussed. The reader will acquire a good knowledge of the current situation within this important field.