Content Networking: Architecture, Protocols, and PracticeElsevier, 2005. gada 24. marts - 352 lappuses As the Internet has grown, so have the challenges associated with delivering static, streaming, and dynamic content to end-users. This book is unique in that it addresses the topic of content networking exclusively and comprehensively, tracing the evolution from traditional web caching to today's open and vastly more flexible architecture. With this evolutionary approach, the authors emphasize the field's most persistent concepts, principles, and mechanisms--the core information that will help you understand why and how content delivery works today, and apply that knowledge in the future.
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No grāmatas satura
1.–5. rezultāts no 35.
15. lappuse
... packet loss on the path, or even geographic distance. Even if a Web server has enough resources to handle all incoming requests in a timely manner, the distance between server and clients can lead to noticeable delays. In the example ...
... packet loss on the path, or even geographic distance. Even if a Web server has enough resources to handle all incoming requests in a timely manner, the distance between server and clients can lead to noticeable delays. In the example ...
16. lappuse
... packets in the best-effort model of the Internet. Evolutionary Steps in Overcoming the Web Slowdown Adding more bandwidth, more processing power and other mechanisms to improve quality-of-service (QoS) to the Internet infrastructure is ...
... packets in the best-effort model of the Internet. Evolutionary Steps in Overcoming the Web Slowdown Adding more bandwidth, more processing power and other mechanisms to improve quality-of-service (QoS) to the Internet infrastructure is ...
20. lappuse
... packet networks. Whereas packet networks traditionally have processed information at the protocol Layers 1–3, content networks include communication components operating on protocol Layers 4–7. The units of transported data in content ...
... packet networks. Whereas packet networks traditionally have processed information at the protocol Layers 1–3, content networks include communication components operating on protocol Layers 4–7. The units of transported data in content ...
27. lappuse
... packet loss, and congestion control. The most important transport protocols on the Internet are the Transmission Control Protocol (TCP), which provides loss-less and ordered packet delivery, and the User Datagram Protocol (UDP), which ...
... packet loss, and congestion control. The most important transport protocols on the Internet are the Transmission Control Protocol (TCP), which provides loss-less and ordered packet delivery, and the User Datagram Protocol (UDP), which ...
28. lappuse
... packet loss is caused by network congestion. While this assumption meets the characteristics of traditional wireline networks, packet loss on wireless and satellite links can very well be caused by bit errors rather than congestion. As ...
... packet loss is caused by network congestion. While this assumption meets the characteristics of traditional wireline networks, packet loss on wireless and satellite links can very well be caused by bit errors rather than congestion. As ...
Saturs
1 | |
25 | |
53 | |
Chapter 4 Caching Techniques for Streaming Media | 81 |
Chapter 5 Navigating Content Networks | 109 |
Chapter 6 PeertoPeer Content Networks | 147 |
Chapter 7 Interactive Content Delivery Instant Messaging | 179 |
Chapter 8 Beyond Web Surfing Content Services | 217 |
Chapter 10 Standards Efforts | 279 |
Chapter 11 Summary and Outlook | 299 |
AppendixXML Basics | 311 |
Glossary | 313 |
RFC References | 325 |
References | 331 |
Index | 345 |
Chapter 9 Building Content Networks | 263 |
Citi izdevumi - Skatīt visu
Content Networking: Architecture, Protocols, and Practice Markus Hofmann,Leland R. Beaumont Ierobežota priekšskatīšana - 2005 |
Content Networking: Architecture, Protocols, and Practice Markus Hofmann (Computer scientist),Leland R. Beaumont Priekšskatījums nav pieejams - 2005 |
Bieži izmantoti vārdi un frāzes
allows application message architecture audio bandwidth browser cache callout protocol callout server Chapter client request communication connection content consumer content delivery content delivery network content networking content providers content services cookie defined described device distributed document Domain Name Domain Name System endpoints Ethernet example Figure format Global Gnutella header host ICAP ICAP client ICAP server identified IETF implement instant messaging interactive interception proxies Internet IP address Layer load MSRP multicast multimedia name server Napster network provider object operation OPES processor origin server packet peer-to-peer peer-to-peer networks peers port presence information Profile resource response retrieve reverse proxy Router RTSP scalability sends servent service activation point service node session specification standards streaming media switch tion traffic transaction transport protocol typically UDDI VoiceXML Web cache Web server wireless WSDL XMPP