User Manual
Table Of Contents
- Chapter 1 INTRODUTION
- Chapter 2 INSTALLATION
- Chapter 3 Switch Management
- Chapter 4 Basic Switch Configuration
- Chapter 5 File System Operations
- Chapter 6 Cluster Configuration
- Chapter 7 Port Configuration
- Chapter 8 Port Isolation Function Configuration
- Chapter 9 Port Loopback Detection Function Configuration
- Chapter 10 ULDP Function Configuration
- Chapter 11 LLDP Function Operation Configuration
- Chapter 12 Port Channel Configuration
- Chapter 13 Jumbo Configuration
- Chapter 14 EFM OAM Configuration
- Chapter 15 VLAN Configuration
- Chapter 16 MAC Table Configuration
- Chapter 17 MSTP Configuration
- Chapter 18 QoS Configuration
- Chapter 19 Flow-based Redirection
- Chapter 20 Egress QoS Configuration
- Chapter 21 Flexible QinQ Configuration
- Chapter 22 Layer 3 Forward Configuration
- Chapter 23 ARP Scanning Prevention Function Configuration
- Chapter 24 Prevent ARP, ND Spoofing Configuration
- Chapter 25 ARP GUARD Configuration
- Chapter 26 ARP Local Proxy Configuration
- Chapter 27 Gratuitous ARP Configuration
- Chapter 28 Keepalive Gateway Configuration
- Chapter 29 DHCP Configuration
- Chapter 30 DHCPv6 Configuration
- Chapter 31 DHCP option 82 Configuration
- Chapter 32 DHCPv6 option37, 38
- Chapter 33 DHCP Snooping Configuration
- Chapter 34 Routing Protocol Overview
- Chapter 35 Static Route
- Chapter 36 RIP
- Chapter 37 RIPng
- Chapter 38 OSPF
- Chapter 39 OSPFv3
- Chapter 40 BGP
- 40.1 Introduction to BGP
- 40.2 BGP Configuration Task List
- 40.3 Configuration Examples of BGP
- 40.3.1 Examples 1: configure BGP neighbor
- 40.3.2 Examples 2: configure BGP aggregation
- 40.3.3 Examples 3: configure BGP community attributes
- 40.3.4 Examples 4: configure BGP confederation
- 40.3.5 Examples 5: configure BGP route reflector
- 40.3.6 Examples 6: configure MED of BGP
- 40.3.7 Examples 7: example of BGP VPN
- 40.4 BGP Troubleshooting
- Chapter 41 MBGP4+
- Chapter 42 Black Hole Routing Manual
- Chapter 43 GRE Tunnel Configuration
- Chapter 44 ECMP Configuration
- Chapter 45 BFD
- Chapter 46 BGP GR
- Chapter 47 OSPF GR
- Chapter 48 IPv4 Multicast Protocol
- 48.1 IPv4 Multicast Protocol Overview
- 48.2 PIM-DM
- 48.3 PIM-SM
- 48.4 MSDP Configuration
- 48.4.1 Introduction to MSDP
- 48.4.2 Brief Introduction to MSDP Configuration Tasks
- 48.4.3 Configuration of MSDP Basic Function
- 48.4.4 Configuration of MSDP Entities
- 48.4.5 Configuration of Delivery of MSDP Packet
- 48.4.6 Configuration of Parameters of SA-cache
- 48.4.7 MSDP Configuration Examples
- 48.4.8 MSDP Troubleshooting
- 48.5 ANYCAST RP Configuration
- 48.6 PIM-SSM
- 48.7 DVMRP
- 48.8 DCSCM
- 48.9 IGMP
- 48.10 IGMP Snooping
- 48.11 IGMP Proxy Configuration
- Chapter 49 IPv6 Multicast Protocol
- Chapter 50 Multicast VLAN
- Chapter 51 ACL Configuration
- Chapter 52 802.1x Configuration
- 52.1 Introduction to 802.1x
- 52.2 802.1x Configuration Task List
- 52.3 802.1x Application Example
- 52.4 802.1x Troubleshooting
- Chapter 53 The Number Limitation Function of Port, MAC in VLAN and IP Configuration
- 53.1 Introduction to the Number Limitation Function of Port, MAC in VLAN and IP
- 53.2 The Number Limitation Function of Port, MAC in VLAN and IP Configuration Task Sequence
- 53.3 The Number Limitation Function of Port, MAC in VLAN and IP Typical Examples
- 53.4 The Number Limitation Function of Port, MAC in VLAN and IP Troubleshooting Help
- Chapter 54 Operational Configuration of AM Function
- Chapter 55 TACACS+ Configuration
- Chapter 56 RADIUS Configuration
- Chapter 57 SSL Configuration
- Chapter 58 IPv6 Security RA Configuration
- Chapter 59 VLAN-ACL Configuration
- Chapter 60 MAB Configuration
- Chapter 61 PPPoE Intermediate Agent Configuration
- Chapter 62 SAVI Configuration
- Chapter 63 Web Portal Configuration
- Chapter 64 VRRP Configuration
- Chapter 65 IPv6 VRRPv3 Configuration
- Chapter 66 MRPP Configuration
- Chapter 67 ULPP Configuration
- Chapter 68 ULSM Configuration
- Chapter 69 Mirror Configuration
- Chapter 70 RSPAN Configuration
- Chapter 71 sFlow Configuration
- Chapter 72 SNTP Configuration
- Chapter 73 NTP Function Configuration
- Chapter 74 DNSv4/v6 Configuration
- Chapter 75 Summer Time Configuration
- Chapter 76 Monitor and Debug
- Chapter 77 Reload Switch after Specified Time
- Chapter 78 Debugging and Diagnosis for Packets Received and Sent by CPU
- Chapter 79 MPLS Overview
- Chapter 80 LDP
- Chapter 81 MPLS VPN
- Chapter 82 Public Network Access of MPLS VPN
- Chapter 83 SWITCH OPERATION
- Chapter 84 TROUBLE SHOOTING
- Chapter 85 APPENDEX A
- Chapter 86 GLOSSARY
- EC Declaration of Conformity
22-32
every connection status which increases network delay greatly and decreases network performance.
Moreover, the translation of network data packet addresses baffles the end-to-end network security check,
IPSec authentication header is such an example.
Therefore, in order to solve all kinds of problems existing in IPv4 comprehensively, the next generation
Internet Protocol IPv6 designed by IETF has become the only feasible solution at present.
First of all, the 128 bits addressing scheme of IPv6 Protocol can guarantee to provide enough globally unique
IP addresses for global IP network nodes in the range of time and space. Moreover, besides increasing
address space, IPv6 also enhanced many other essential designs of IPv4.
Hierarchical addressing scheme facilitates Route Aggregation, effectively reduces route table entries and
enhances the efficiency and expansibility of routing and data packet processing.
The header design of IPv6 is more efficient compared with IPv4. It has less data fields and takes out header
checksum, thus expedites the processing speed of basic IPv6 header. In IPv6 header, fragment field can be
shown as an optional extended field, so that data packets fragmentation process won’t be done in router
forwarding process, and Path MTU Discovery Mechanism collaborates with data packet source which
enhances the processing efficiency of router.
Address automatic configuration and plug-and-play is supported. Large amounts of hosts can find network
routers easily by address automatic configuration function of IPv6 while obtaining a globally unique IPv6
address automatically as well which makes the devices using IPv6 Internet plug-and-play. Automatic address
configuration function also makes the readdressing of existing network easier and more convenient, and it is
more convenient for network operators to manage the transformation from one provider to another.
Support IPSec. IPSec is optional in IPv4, but required in IPv6 Protocol. IPv6 provides security extended
header, which provides end-to-end security services such as access control, confidentiality and data integrity,
consequently making the implement of encryption, validation and Virtual Private Network easier.
Enhance the support for Mobile IP and mobile calculating devices. The Mobile IP Protocol defined in IETF
standard makes mobile devices movable without cutting the existing connection, which is a network function
getting more and more important. Unlike IPv4, the mobility of IPv6 is from embedded automatic configuration
to get transmission address (Care-Of-Address); therefore it doesn’t need Foreign Agent. Furthermore, this
kind of binding process enables Correspondent Node communicate with Mobile Node directly, thereby avoids
the extra system cost caused by triangle routing choice required in IPv4.
Avoid the use of Network Address Translation. The purpose of the introduction of NAT mechanism is to share
and reuse same address space among different network segments. This mechanism mitigates the problem of
the shortage of IPv4 address temporally; meanwhile it adds the burden of address translation process for
network device and application. Since the address space of IPv6 has increased greatly, address translation
becomes unnecessary, thus the problems and system cost caused by NAT deployment are solved naturally.
Support extensively deployed Routing Protocol. IPv6 has kept and extended the supports for existing Internal
Gateway Protocols (IGP for short), and Exterior Gateway Protocols (EGP for short). For example, IPv6
Routing Protocol such as RIPng, OSPFv3, IS-ISv6 and MBGP4+, etc.
Multicast addresses increased and the support for multicast has enhanced. By dealing with IPv4 broadcast
functions such as Router Discovery and Router Query, IPv6 multicast has completely replaced IPv4
broadcast in the sense of function. Multicast not only saves network bandwidth, but enhances network
efficiency as well.