Muutke küpsiste eelistusi

Handbook of IPv4 to IPv6 Transition: Methodologies for Institutional and Corporate Networks [Kõva köide]

(Alcatel-Lucent, Murray Hill, New Jersey, USA), (SES Engineering, Princeton, New Jersey, USA)
  • Formaat: Hardback, 248 pages, kõrgus x laius: 234x156 mm, kaal: 476 g
  • Ilmumisaeg: 06-Dec-2007
  • Kirjastus: Auerbach
  • ISBN-10: 0849385164
  • ISBN-13: 9780849385162
Teised raamatud teemal:
  • Kõva köide
  • Hind: 91,34 €*
  • * hind on lõplik, st. muud allahindlused enam ei rakendu
  • Tavahind: 121,79 €
  • Säästad 25%
  • Raamatu kohalejõudmiseks kirjastusest kulub orienteeruvalt 3-4 nädalat
  • Kogus:
  • Lisa ostukorvi
  • Tasuta tarne
  • Tellimisaeg 2-4 nädalat
  • Lisa soovinimekirja
Handbook of IPv4 to IPv6 Transition: Methodologies for Institutional and Corporate NetworksSuurem pilt
  • Formaat: Hardback, 248 pages, kõrgus x laius: 234x156 mm, kaal: 476 g
  • Ilmumisaeg: 06-Dec-2007
  • Kirjastus: Auerbach
  • ISBN-10: 0849385164
  • ISBN-13: 9780849385162
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9780849385162.html
Märksõnad:
The implementation of IPv6 is essential to the continued growth of the Internet and the development of new applications. The Handbook of IPv4 to IPv6 Transition Methodologies provides a wealth of best practices and procedures that will help corporations plan and implement a smooth transition to IPv6.





A blueprint for successful transition, the Handbook of IPv4 to IPv6 Transition



















Provides a tutorial of IPv6 addressing capabilities





Looks at IPv6 network constructs, specifically key routing processes





Examines IPv6 autoconfiguration techniques and the suite of IPv6-related protocols





Discusses all the major IPv6 enterprise/institutional network migration mechanisms as well as coexistence issues





Identifies the various elements in the network and what migration role they will need to play in order to support the transition





Surveys the application and security aspects of the IPv6 transition





Offers the first reference in many years to address the migration and macro-level scalability requirements to support the DoD/DISA/GAO drive for an IPv6-based U.S. Government
Foreword xiii
Preface xv
Authors xvii
Introduction and Overview
1(22)
Opportunities Offered by IPv6
1(3)
Introductory Overview of IPv6
4(13)
IPv6 Benefits
5(1)
Traditional Addressing Classes for IPv4
6(2)
Network Address Translation Issues in IPv4
8(1)
IPv6 Address Space
9(1)
Basic Protocol Constructs
10(4)
IPv6 Autoconfiguration
14(3)
Migration and Coexistence
17(3)
Course of Investigation
20(3)
References
20(3)
IPv6 Addressing
23(20)
Introduction
23(1)
IPv6 Addressing Mechanisms
23(7)
Addressing Conventions
23(2)
Addressing Issues/Reachability
25(3)
Scope/Reachability
28(2)
Address Types
30(7)
Unicast IPv6 Addresses
30(1)
Aggregatable Global Unicast Addresses
30(2)
Link-Local (Unicast) Addresses
32(1)
Site-Local (Unicast) Addresses
32(1)
Unspecified (Unicast) Address
33(1)
Loopback (Unicast) Address
33(1)
Compatibility (Unicast) Addresses
34(1)
Multicast IPv6 Addresses
34(3)
Anycast IPv6 Addresses
37(1)
Addresses for Hosts and Routers
37(6)
Interface Determination
38(1)
Mapping EUI-64 Addresses to IPv6 Interface Identifiers
38(2)
Mapping IEEE 802 Addresses to IPv6 Interface Identifiers
40(1)
Randomly Generated Interface Identifiers
40(1)
References
41(2)
IPv6 Network Constructs
43(10)
Introduction
43(1)
IPv6 Infrastructure
43(5)
Protocol Mechanisms
43(2)
Protocol Support Mechanisms
45(3)
Routing and Route Management
48(5)
References
50(3)
IPv6 Autoconfiguration Techniques
53(8)
Introduction
53(1)
Configuration Methods
53(2)
Dynamic Host Configuration Protocol for IPv6
55(6)
References
60(1)
IPv6 and Related Protocols (Details)
61(46)
Introduction
61(1)
Terminology
62(1)
IPv6 Header Format
63(1)
IPv6 Extension Headers
64(15)
Extension Header Order
66(1)
Options
66(2)
Hop-by-Hop Options Header
68(1)
Routing Header
69(4)
Fragment Header
73(5)
Destination Options Header
78(1)
No Next Header
79(1)
Packet Size Issues
79(1)
Flow Labels
80(1)
Traffic Classes
81(1)
Upper-Layer Protocol Issues
81(3)
Upper-Layer Checksums
81(2)
Maximum Packet Lifetime
83(1)
Maximum Upper-Layer Payload Size
83(1)
Responding to Packets Carrying Routing Headers
83(1)
Semantics and Usage of the Flow Label Field
84(1)
Formatting Guidelines for Options
85(2)
Introduction to Addressing
87(13)
IPv6 Addressing
88(1)
Addressing Model
88(1)
Text Representation of Addresses
89(1)
Text Representation of Address Prefixes
90(1)
Address Type Identification
91(1)
Unicast Addresses
91(1)
Interface Identifiers
92(1)
The Unspecified Address
93(1)
The Loopback Address
93(1)
Global Unicast Addresses
94(1)
IPv6 Addresses with Embedded IPv4 Addresses
94(1)
Local-Use IPv6 Unicast Addresses
95(1)
Anycast Addresses
95(1)
Required Anycast Address
96(1)
Multicast Addresses
97(1)
Predefined Multicast Addresses
98(2)
A Node's Required Addresses
100(1)
IANA Considerations
100(1)
Creating Modified EUI-64 Format Interface Identifiers
101(3)
Links or Nodes with IEEE EUI-64 Identifiers
101(1)
Links or Nodes with IEEE 802 48-Bit MACs
102(1)
Links with Other Kinds of Identifiers
103(1)
Links without Identifiers
103(1)
Bit Global Identifier (EUI-64) Registration Authority
104(1)
Application Restrictions
104(1)
Distribution Restrictions
104(1)
Application Documentation
105(1)
Manufacturer-Assigned Identifiers
105(1)
Additional Technical Details
105(2)
References
105(2)
Transition Approaches and Mechanisms
107(36)
Introduction
107(2)
IPv6/IPv4 Dual Stack
109(1)
Translation Mechanisms
110(13)
Stateless Internet Protocol/Internet Control Messaging Protocol Translation (SIIT)
110(1)
Overview
110(1)
SIIT Details
111(3)
Bump in the Stack (BIS)
114(2)
Bump in the API (BIA)
116(1)
Overview
116(1)
Details
117(2)
Network Address Translation-Protocol Translation
119(1)
Overview
119(1)
Details
119(2)
Transport Relay Translator
121(1)
Overview
121(1)
Details
122(1)
Tunneling
123(20)
Static Tunneling
124(1)
Automatic Tunneling Using IPv4-Compatible Addresses
124(1)
6over4 Transition Mechanism
125(4)
6to4 Transition Mechanism
129(1)
Overview
129(2)
6to4 Addressing and Site Routing
131(1)
6to4 Transition Mechanism Details
131(2)
Intrasite Automatic Tunnel Addressing Protocol (ISATAP)
133(1)
Overview
133(1)
ISATAP Addressing
133(1)
Example Network
134(1)
Teredo
135(1)
Overview
135(3)
Architecture
138(1)
Teredo Addressing and Address Configuration Process
139(1)
Sample Teredo Communication
139(1)
References
140(3)
IPv6 Network Software and Hardware
143(18)
Introduction
143(1)
IPv6 End Systems Applications
144(1)
IPv6 End Systems Communications Software
145(7)
Dual-IP-Layer Architecture
146(1)
Installed and Enabled by Default
146(1)
GUI-Based Configuration
147(1)
Full Support for IPsec
147(1)
Multicast Listener Discovery Version 2 (MLDv2)
147(1)
Link-Local Multicast Name Resolution (LLMNR)
147(1)
Literal IPv6 Addresses in URLs
148(1)
Support for ipv6-literal.net Names
148(1)
IPv6 over PPP
148(1)
Dynamic Host Control Protocol Version 6
149(1)
Random Interface IDs
149(1)
Updates to Teredo
149(1)
Enhanced Security for IPv6 and Teredo
150(1)
Features to Disable IPv6 Components
151(1)
IPv6 Support by Major Router Vendors
152(3)
Cisco Systems
153(1)
Juniper Networks
154(1)
Alcatel-Lucent
154(1)
Carrier/ISP IPv6 Services
155(4)
Asia Pacific
155(1)
NTT Communications IPv6-Related Services
155(2)
KDDI/KDDI Lab
157(1)
Japan Telecom
157(1)
Europe
157(1)
European Internet Exchange Association
157(1)
BT --- UK6x
158(1)
North America
158(1)
Moonv6
158(1)
AT&T
158(1)
Global Crossing
159(1)
IPv6 in Wireless Networks
159(2)
References
160(1)
Implementing IPv6 Transition Strategies
161(8)
Introduction
161(1)
Summary of NREN Transition Recommendations
162(4)
General Approach for NREN Transition
162(1)
Dual-Stack Issues
162(1)
General Tunneling Issues
163(1)
IPv6 over MPLS Issues
164(1)
Layer 2 Transport Protocol Considerations for NRENs
165(1)
Packet over SONET (PoS) Scenario
165(1)
MPLS Scenario
165(1)
ATM Scenario
165(1)
IPv6 Operations Working Group: Transition Scenarios for ISPs
166(3)
References
168(1)
IPv6 Applications
169(8)
Introduction
169(1)
Application Programming Interface Overview
169(2)
Socket API Example
171(4)
Core Socket Functions
172(1)
Address Data Structures
172(2)
Name-to-Address Translation Functions
174(1)
Address Conversion Functions
174(1)
Socket Functions for IPv6
174(1)
IPv6 Support for Networking Applications
175(2)
References
176(1)
Security in IPv6 Networks
177(46)
Introduction
177(1)
Confidentiality and Integrity of Information While in Transit
177(3)
IPsec Mechanisms
180(6)
Keyed Hashing for Message Authentication
182(1)
Security Architecture for the Internet Protocol
182(1)
IP Authentication Header
183(1)
Use of HMAC-MD5-96 within ESP and AH
183(1)
Use of HMAC-SHA-96 within ESP and AH
184(1)
ESP DES-CBC Cipher Algorithm with Explicit IV
184(1)
IP Encapsulating Security Payload
185(1)
Automatic Key Management
185(1)
The Internet Key Exchange
185(1)
Transport Layer Security Mechanisms
186(1)
Conclusion
187(2)
References
187(2)
Appendices
Basic IPv6 Terminology
189(14)
Basic IPv6 Bibliography
203(20)
Index 223


Amoss, John J.; Minoli, Daniel