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5. Softphone Voice - for use by softphone applications on typical data centric devices, such as PCs or laptops.
6. Video Conferencing - for use by dedicated Video Conferencing equipment and other similar appliances supporting
real-time interactive video/audio services.
7. Streaming Video - for use by broadcast or multicast based video content distribution and other similar applications
supporting streaming video services that require specific network policy treatment. Video applications relying on TCP
with buffering would not be an intended use of this application type.
8. Video Signaling - for use in network topologies that require a separate policy for the video signaling than for the video
media.
Policy:
Policy indicates that an Endpoint Device wants to explicitly advertise that the policy is required by the device. Can be
either Defined or Unknown
Unknown: The network policy for the specified application type is currently unknown.
Defined: The network policy is defined.
TAG:
TAG is indicative of whether the specified application type is using a tagged or an untagged VLAN. Can be Tagged or
Untagged.
Untagged: The device is using an untagged frame format and as such does not include a tag header as defined by IEEE
802.1Q-2003.
Tagged: The device is using the IEEE 802.1Q tagged frame format.
VLAN ID:
VLAN ID is the VLAN identifier (VID) for the port as defined in IEEE 802.1Q-2003. A value of 1 through 4094 is used to
define a valid VLAN ID. A value of 0 (Priority Tagged) is used if the device is using priority tagged frames as defined by
IEEE 802.1Q-2003, meaning that only the IEEE 802.1D priority level is significant and the default PVID of the ingress
port is used instead.
Priority:
Priority is the Layer 2 priority to be used for the specified application type. One of the eight priority levels (0 through 7).
DSCP:
DSCP is the DSCP value to be used to provide Diffserv node behavior for the specified application type as defined in IETF
RFC 2474. Contain one of 64 code point values (0 through 63).
3.8.5 EEE
By using EEE power savings can be achieved at the expense of traffic latency. This latency occurs due to the circuits EEE
turns off to save power, need time to boot up before sending traffic over the link. This time is called "wakeup time". To
achieve minimal latency, devices can use LLDP to exchange information about their respective tx and rx "wakeup time",
as a way to agree upon the minimum wakeup time they need.
This page provides an overview of EEE information exchanged by LLDP.
Web Interface
To show LLDP EEE neighbors:
1. Click LLDP, than click EEE to show discover EEE devices
2. Click Refresh for manual update web screen
3. Click Auto-refresh for auto-update web screen
Figure 3-8.5: The LLDP Neighbors EEE information
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LANCOM GS-2310P/GS-2326(P) User Manual
3 Configuration