Beschreibung:
Thomas G. Robertazzi received the Ph.D from Princeton University, Princeton, NJ, in 1981 and the B.E.E. from the Cooper Union, New York, NY in 1977. A Fellow of the IEEE, he is presently a Professor in the Dept. of Electrical and Computer Engineering at Stony Brook University, Stony Brook N.Y. He has published extensively in the areas of parallel processor scheduling, ad hoc radio networks, telecommunications network planning, switching, queueing and Petri networks. Prof. Robertazzi has also authored, co-authored or edited six books in the areas of networking, performance evaluation, scheduling and network planning. For thirteen years Prof. Robertazzi was the faculty director of the Stony Brook Living Learning Center in Science and Engineering. Since 2008 he has been co-chair of the Stony Brook University Senate Research Committee.
Features a concise, accessible treatment of computer networking, focusing on new technological topics;
1 Introduction to Networks1.1 Introduction1.2 Achieving Connectivity1.2.1 Coaxial Cable1.2.2 Twisted Pair Wiring1.2.3 Fiber Optics1.2.4 Microwave Line of Sight1.2.5 Satellites1.2.6 Cellular Systems1.2.7 Ad Hoc Networks1.2.8 Wireless Sensor Networks1.3 Multiplexing1.3.1 Frequency Division Multiplexing (FDM)1.3.2 Time Division Multiplexing (TDM)1.3.3 Frequency Hopping1.3.4 Direct Sequence Spread Spectrum1.4 Circuit Switching Versus Packet Switching1.5 Layered Protocols2 Ethernet2.1 Introduction2.2 10 Mbps Ethernet2.3 Fast Ethernet2.4 Gigabit Ethernet2.5 10 Gigabit Ethernet2.6 40/100 Gigabit Ethernet2.6.1 40/100 Gigabit Technology2.7 Higher Ethernet Speeds2.7.1 Introduction2.7.2 The Road to Higher Speeds2.8 Conclusion3 InfiniBand3.1 Introduction3.2 A First Look3.3 The InfiniBand Protocol3.4 InniBand for HPC3.5 Other RDMA Implementations3.6 Conclusion4 Wireless Networks4.1 Introduction4.2 802.11 WiFi4.2.1 The Original 802.11 Standard4.2.2 Foundational 802.11 Versions4.2.3 More Recent 802.11 Versions4.3 802.15 Bluetooth4.3.1 Technically Speaking4.3.2 Ad Hoc Networking4.3.3 Versions of Bluetooth4.3.4 802.15.4, ZigBee and 802.15.4e4.3.5 Wireless Body Area Networks and 802.15.64.3.6 Bluetooth Security4.4 802.16 WiMax4.5 LTE: Long Term Evolution4.5.1 Introduction4.5.2 LTE4.5.3 LTE Advanced4.5.4 Towards 5G4.6 Conclusion5 Multiprotocol Label Switching (MPLS)5.1 Introduction5.2 Technical Details5.3 Traffic Engineering5.4 Fault Management5.5 GMPLS5.6 MPLS-TP6 Optical Networks for Telecommunications<6.1 SONET6.1.1 SONET Architecture6.1.2 Self-Healing Rings6.2 Wavelength Division Multiplexing (WDM)6.2.1 History and Technology6.2.2 Switching6.3 Optical Transport Networks6.4 Flexible/Elastic Optical Networks6.4.1 Numerical Examples6.4.2 Network Characteristics6.4.3 Routing and Spectrum Allocation6.5 Passive Optical Networks (PONs)6.5.1 Time Division Multiplexing PON6.5.2 Wavelength Division Multiplexing PON6.5.3 OFDM PON6.6 Orbital Angular Momentum7 Software-Defined Networking7.1 Introduction7.2 Classic Internet Architecture7.3 SDN Architecture7.4 Development of SDN7.5 OpenFlow7.6 Two Issues7.7 Standards8 Networks on Chips8.1 Introduction8.2 A Network on Chip: The Mesh8.2.1 Switching Alternatives8.3 Other NOC Interconnection Networks8.3.1 Introduction8.3.2 Mesh, Toroidal and Related Networks8.3.3 Some Other Interconnection Networks9 Space Networking9.1 SpaceWire9.1.1 Background9.1.2 SpaceWire in Detail9.1.3 Some Configurations9.2 SpaceFibre9.2.1 Background9.2.2 SpaceFibre in More Detail9.2.3 Protocol Stack9.3 Space Communications9.3.1 Background9.3.2 Deep Space Networks9.3.3 Delay/Disruption Tolerant Networks10 Grids, Clouds and Data Centers10.1 Introduction10.2 Grids10.2.1 Introduction10.2.2 Grid Issues10.2.3 Grid Architecture and More10.3 Clouds10.3.1 Introduction10.3.2 Trade-offs for Cloud Computing10.3.3 Cloud Principles10.3.4 Cloud Monitoring10.3.5 Resource Provisioning10.3.6 Mobile Cloud Computing10.3.7 Cloud Reliability/Resilency10.3.8 Cloud Security10.4 Data Centers10.4.1 Introduction10.4.2 Racks10.4.3 Networking Support10.4.4 Storage10.4.5 Electrical and Cooling Support10.4.6 Management Support10.4.7 Security10.5 Conclusion11 AES and Quantum Cryptography11.1 Introduction11.2 AES11.2.1 Introduction11.2.2 DES11.2.3 Choosing AES11.2.4 The AES Algorithm11.2.5 AES Issues11.3 Quantum Cryptography11.3.1 Introduction11.3.2 Quantum Physics11.3.3 Quantum Communication11.3.4 Quantum Key Distribution (QKD)11.3.5 Post-Quantum Cryptography11.4 Conclusion12 Bibliography
This book gives a broad look at both fundamental networking technology and new areas that support it and use it. It is a concise introduction to the most prominent, recent technological topics in computer networking. Topics include network technology such as wired and wireless networks, enabling technologies such as data centers, software defined networking, cloud and grid computing and applications such as networks on chips, space networking and network security. The accessible writing style and non-mathematical treatment makes this a useful book for the student, network and communications engineer, computer scientist and IT professional.
