User Manual
Table Of Contents
- 1. INTRODUCTION
- 2. INSTALLATION
- 3. SWITCH MANAGEMENT
- 4. WEB CONFIGURATION
- 4.1 Main Web Page
- 4.2 System
- 4.2.1 System Information
- 4.2.2 IP Configuration
- 4.2.3 IP Status
- 4.2.4 Users Configuration
- 4.2.5 Privilege Levels
- 4.2.6 NTP Configuration
- 4.2.7 Time Configuration
- 4.2.8 UPnP
- 4.2.9 DHCP Relay
- 4.2.10 DHCP Relay Statistics
- 4.2.11 CPU Load
- 4.2.12 System Log
- 4.2.13 Detailed Log
- 4.2.14 Remote Syslog
- 4.2.15 SMTP Configuration
- 4.2.16 Web Firmware Upgrade
- 4.2.17 TFTP Firmware Upgrade
- 4.2.18 Save Startup Config
- 4.2.19 Configuration Download
- 4.2.20 Configuration Upload
- 4.2.21 Configuration Activate
- 4.2.22 Configuration Delete
- 4.2.23 Image Select
- 4.2.24 Factory Default
- 4.2.25 System Reboot
- 4.3 Simple Network Management Protocol
- 4.4 Port Management
- 4.5 Link Aggregation
- 4.6 VLAN
- 4.6.1 VLAN Overview
- 4.6.2 IEEE 802.1Q VLAN
- 4.6.3 VLAN Port Configuration
- 4.6.4 VLAN Membership Status
- 4.6.5 VLAN Port Status
- 4.6.6 Port Isolation
- 4.6.7 VLAN setting example:
- 4.6.8 MAC-based VLAN
- 4.6.9 MAC-based VLAN Status
- 4.6.10 IP Subnet-based VLAN
- 4.6.11 Protocol-based VLAN
- 4.6.12 Protocol-based VLAN Membership
- 4.7 Spanning Tree Protocol
- 4.8 Multicast
- 4.8.1 IGMP Snooping
- 4.8.2 Profile Table
- 4.8.3 Address Entry
- 4.8.4 IGMP Snooping Configuration
- 4.8.5 IGMP Snooping VLAN Configuration
- 4.8.6 IGMP Snooping Port Group Filtering
- 4.8.7 IGMP Snooping Status
- 4.8.8 IGMP Group Information
- 4.8.9 IGMPv3 Information
- 4.8.10 MLD Snooping Configuration
- 4.8.11 MLD Snooping VLAN Configuration
- 4.8.12 MLD Snooping Port Group Filtering
- 4.8.13 MLD Snooping Status
- 4.8.14 MLD Group Information
- 4.8.15 MLDv2 Information
- 4.8.16 MVR (Multicaset VLAN Registration)
- 4.8.17 MVR Status
- 4.8.18 MVR Groups Information
- 4.8.19 MVR SFM Information
- 4.9 Quality of Service
- 4.9.1 Understanding QoS
- 4.9.2 Port Policing
- 4.9.3 Port Classification
- 4.9.4 Port Scheduler
- 4.9.5 Port Shaping
- 4.9.6 Port Tag Remarking
- 4.9.7 Port DSCP
- 4.9.8 DSCP-based QoS
- 4.9.9 DSCP Translation
- 4.9.10 DSCP Classification
- 4.9.11 QoS Control List
- 4.9.12 QCL Status
- 4.9.13 Storm Control Configuration
- 4.9.14 QoS Statistics
- 4.9.15 Voice VLAN Configuration
- 4.9.16 Voice VLAN OUI Table
- 4.10 Access Control Lists
- 4.11 Authentication
- 4.11.1 Understanding IEEE 802.1X Port-based Authentication
- 4.11.2 Authentication Configuration
- 4.11.3 Network Access Server Configuration
- 4.11.4 Network Access Overview
- 4.11.5 Network Access Statistics
- 4.11.6 RADIUS
- 4.11.7 TACACS+
- 4.11.8 RADIUS Overview
- 4.11.9 RADIUS Details
- 4.11.10 Windows Platform RADIUS Server Configuration
- 4.11.11 802.1X Client Configuration
- 4.12 Security
- 4.12.1 Port Limit Control
- 4.12.2 Access Management
- 4.12.3 Access Management Statistics
- 4.12.4 HTTPs
- 4.12.5 SSH
- 4.12.6 Port Security Status
- 4.12.7 Port Security Detail
- 4.12.8 DHCP Snooping
- 4.12.9 Snooping Table
- 4.12.10 IP Source Guard Configuration
- 4.12.11 IP Source Guard Static Table
- 4.12.12 ARP Inspection
- 4.12.13 ARP Inspection Static Table
- 4.13 Address Table
- 4.14 LLDP
- 4.15 Network Diagnostics
- 4.16 Power over Ethernet (PoE series only)
- 4.17 Loop Protection
- 4.18 RMON
- 5. SWITCH OPERATION
- 6. Power over Ethernet Overview
- 7. TROUBLESHOOTING
- APPENDIX A: Networking Connection
- APPENDIX B : GLOSSARY
- EC Declaration of Conformity
User’s Manual of WGSD / WGSW Layer 2+ Series
4.16.2 System Configuration
In a power over Ethernet system, operating power is applied from a power source (PSU-power supply unit) over the LAN
infrastructure to powered devices (PDs), which are connected to ports. Under some conditions, the total output power required
by PDs can exceed the maximum available power provided by the PSU. The system may a prior be planed with a PSU capable
of supplying less power than the total potential power consumption of all the PoE ports in the system. In order to maintain the
majority of ports active, power management is implemented.
The PSU input power consumption is monitored by measuring voltage and current .The input power consumption is equal to the
system’s aggregated power consumption .The power management concept allows all ports to be active and activates additional
ports, as long as the aggregated power of the system is lower than the power level at which additional PDs cannot be
connected .When this value is exceeded, ports will be deactivated, according to user-defined priorities. The power budget is
managed according to the following user-definable parameters: maximum available power, ports priority, maximum allowable
power per port.
Reserved Power determined by
There are five modes for configuring how the ports/PDs may reserve power and when to shut down ports.
Classification mode
In this mode each port automatic determines how much power to reserve according to the class the connected PD belongs
to, and reserves the power accordingly. Four different port classes exist and one for 4, 7, 15.4 and 30.8 Watts.
Class Usage Range of maximum power used by the PD Class Dsecription
0 Default 0.44 to 12.95 watts Classification unimplement
1 Optional 0.44 to 3.84 watts Very low power
2 Optional 3.84 to 6.49 watts Low power
3 Optional 6.49 to 12.95 Watts (or to 15.4 watts) Mid power
4 Optional 12.95 to 25.50 Watts (or to 30.8 watts) High power
1. In this mode the Maximum Power fields have no effect.
2. The PoE chip of PD69012 has designed to that Class level 0, which will be assigned to
15.4 watts by AF mode and 30.8 watts by AT mode under classification power limit
mode. It is hardware limited.
Allocation mode
In this mode the user allocates the amount of power that each port may reserve. The allocated/reserved power for each
port/PD is specified in the Maximum Power fields. The ports are shut down when total reserved powered exceeds the
amount of power that the power supply can deliver.
In this mode the port power is not turned on if the PD requests more available power.
LLDP mode
In this mode the ports of PoE power is managed and determined by LLDP Media protocol.
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