书籍详情
光纤通信系统
作者:美Govind P.Agrawal著
出版社:清华大学出版社
出版时间:2004-07-01
ISBN:9787302087496
定价:¥54.00
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内容简介
自从197年低损耗的石英光纤和在室温下连续工作的半导体激光器取得突破性进展以来,光纤通信技术进入了一个迅猛发展的阶段。近3年来,光纤通信系统从1975年的速率为45Mb/s、传输距离为1km左右发展到如今单纤中最高累计速率为1.92Tb/s、最长实验传输距离达到近3万km,系统的速率与传输距离的乘积(BL)一直以每年翻一番的趋势增长,增长速度超过了著名的摩尔定律。光纤系统性能的巨大进展极大地提高了全球通信网络的容量和覆盖范围,在“信息高速公路”的建设乃至全球信息化的进程中发挥了关键的作用。因此,目前国内外许多大学的电子工程、物理和光学等领域的有关专业中都开设光纤通信课程,相应的教材、参考书和专著己不胜枚举。美国罗彻斯特大学的GovindPAgrawal教授的《光纤通信系统》一书在国内外享有盛誉。本书于1992年问世,1多年来一直受到光通信界的认可,许多大学将它作为教材或参考书。本书再版于1997年。由于近年来光纤通信技术的快速发展,作者又于22年推出了目前的第三版。其主要目标依然与前两版一样,即一方面能够作为教科书使用,同时又能供光通信界科技工作者作参考。因此,物理的理解是本书的重点,但工程方面内容的讨论也贯穿各章的始终。概括起来,本书有如下特点:(1)内容系统全面。本书从最基本的光纤、光发射和光接收机讲起,随后按章节分别讨论了系统设计、光纤损耗和色散管理所涉及的先进技术、光网络中的波分复用、时分复用及码分复用技术。光孤子,以及相干光通信系统等。书中内容反映了到21年为止光纤通信系统最新和全面的状况。·(2)注重概念方法。从内容的整体编排到具体内容的叙述,都体现了突出物理概念、强调基本分析方法的指导思想。为了便于读者理解概念,本书采用了大量清晰的插图和内容详实的表格。(3)例题习题丰富。书中有大量的例题和习题。书后并附有一张由Optiwave公司提供的CD光盘,其中包含了一个光纤通信系统设计用的软件包。光盘中有大量的例题,读者能够利用这些例题了解该软件包的各种功能,然后可使用该软包求解本书各章结尾部分提供的习题,这将有助于读者加深对光通信系统设计重要难点的理解。本书的作者从1989年起在美国罗彻斯特大学光学院讲授光纤通信系统课程,且与工业界合作密切,因此本书的内容不仅适合教学,而且反映了工业界的最新发展。本书的主要用途是作为光通信专业研究生的教材,内容经适当筛选后也能用于高年级的本科生。书中的主干内容与国内教材基本一致,因此很适合作为国内光纤通信和光电子技术应用等相关课程的教学参考书。在当前高校中正大力推进采用外语讲学的形势下,本书更是英文版教材中一个较好的选择。谢世钟教授清华大学电子工程系光通信研究所24年5月
作者简介
暂缺《光纤通信系统》作者简介
目录
Contents
1,introduction
1.1 historical perspective
1.2 basic concepts
1.3 optical communication systems
1.4 lightwave system components
2,optical fibers
2.1 geometrical-optics description
2.2 wave propagation
2.3 dispersion in single-mode fibers
2.4 dispersion-induced limitations
2.5 fiber losses
2.6 nonlinear optical effects
2.7 fiber manufacturing
3,optical transmitters
3.1 basic concepts
3.2 light-emitting diodes
3.3 semiconductor lasers
3.4 control of longitudinal modes
3.5 laser characteristics
3.6 transmitter design
4,optical receivers
4.1 basic concepts
4.2 common photodetectors
4.3 receiver design
4.4 receiver noise
4.5 receiver sensitivity
4.6 sensitivity degradation
4.7 receiver performance
5,lightwave systems
5.1 system architectures
5.2 design guidelines
5.3 long-haul systems
5.4 sources of power penalty
5.5 comprter-aided design
6,optical amplifiers
6.1 basic concepts
6.2 semiconductor optical amplifiers
6.3 raman amplifiers
6.4 erbium-doped fiber amplifiers
6.5 system applications
7,dispersion management
7.1 need for dispersion management
7.2 precompensation schemes
7.3 postcompensation techniques
7.4 optical filters
7.5 optical filters
7.6 fiber bragg gratings
7.7 optical phase conjugation
7.8 long-haul lightwave systems
7.9 high-capacity systems
8,multichannel systems
8.1 WDM lightwave systems
8.2 WDM components
8.3 system performance issues
8.4 time division multiplexing
8.5 subcarrier multiplexing
8.6 code division multiplexing
9,soliton systems
9.1 fiber solitons
9.2 soliton based communications
9.3 loss managed solitons
9.4 dispersion managed solitons
9.5 impact of amplifier noise
9.6 high speed soliton systems
9.7 WDMsoliton systems
10,coherent lightwave systems
10.1 basic concepts
10.2 modulation formats
10.3 demodulation formats
10.4 bit error rate
10.5 sensitivity degradation
10.6 system performance
appendixA system of units
appendixB acronyms
appendixC general formula for pulse broadening
appendixD ultimate system capacity
appendixE sofyware package
index
1,introduction
1.1 historical perspective
1.2 basic concepts
1.3 optical communication systems
1.4 lightwave system components
2,optical fibers
2.1 geometrical-optics description
2.2 wave propagation
2.3 dispersion in single-mode fibers
2.4 dispersion-induced limitations
2.5 fiber losses
2.6 nonlinear optical effects
2.7 fiber manufacturing
3,optical transmitters
3.1 basic concepts
3.2 light-emitting diodes
3.3 semiconductor lasers
3.4 control of longitudinal modes
3.5 laser characteristics
3.6 transmitter design
4,optical receivers
4.1 basic concepts
4.2 common photodetectors
4.3 receiver design
4.4 receiver noise
4.5 receiver sensitivity
4.6 sensitivity degradation
4.7 receiver performance
5,lightwave systems
5.1 system architectures
5.2 design guidelines
5.3 long-haul systems
5.4 sources of power penalty
5.5 comprter-aided design
6,optical amplifiers
6.1 basic concepts
6.2 semiconductor optical amplifiers
6.3 raman amplifiers
6.4 erbium-doped fiber amplifiers
6.5 system applications
7,dispersion management
7.1 need for dispersion management
7.2 precompensation schemes
7.3 postcompensation techniques
7.4 optical filters
7.5 optical filters
7.6 fiber bragg gratings
7.7 optical phase conjugation
7.8 long-haul lightwave systems
7.9 high-capacity systems
8,multichannel systems
8.1 WDM lightwave systems
8.2 WDM components
8.3 system performance issues
8.4 time division multiplexing
8.5 subcarrier multiplexing
8.6 code division multiplexing
9,soliton systems
9.1 fiber solitons
9.2 soliton based communications
9.3 loss managed solitons
9.4 dispersion managed solitons
9.5 impact of amplifier noise
9.6 high speed soliton systems
9.7 WDMsoliton systems
10,coherent lightwave systems
10.1 basic concepts
10.2 modulation formats
10.3 demodulation formats
10.4 bit error rate
10.5 sensitivity degradation
10.6 system performance
appendixA system of units
appendixB acronyms
appendixC general formula for pulse broadening
appendixD ultimate system capacity
appendixE sofyware package
index
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