Руководство По Проектированию для Cisco Cisco Aironet 350 Mini-PCI Wireless LAN Client Adapter
5-30
Enterprise Mobility 4.1 Design Guide
OL-14435-01
Chapter 5 Cisco Unified Wireless QoS
LWAPP over WAN Connections
LWAPP 802.11 Traffic
LWAPP 802.11 traffic can be divided generally into the following two additional types:
•
802.11 management frames—802.11 management frames such as probe requests, and association
requests and responses are classified automatically with a DSCP of CS6.
requests and responses are classified automatically with a DSCP of CS6.
•
801.11 data frames—Client data and 802.1X data from the client is classified according to the
WLAN QoS settings, but packets containing 802.1X frames from the WLC are marked CS4. 802.11
data traffic classification depends on the QoS policies applied in the WLAN configuration, and is
not automatic. The default classification for WLAN data traffic is best-effort.
WLAN QoS settings, but packets containing 802.1X frames from the WLC are marked CS4. 802.11
data traffic classification depends on the QoS policies applied in the WLAN configuration, and is
not automatic. The default classification for WLAN data traffic is best-effort.
Classification Considerations
The DSCP classification of used LWAPP control traffic is CS6, which is an IP routing class, and is
intended for IP routing protocols such as Border Gateway Protocol (BGP), Open Shortest Path First
(OSPF), Enhanced Interior Gateway Routing Protocol (EIGRP), and so on.
intended for IP routing protocols such as Border Gateway Protocol (BGP), Open Shortest Path First
(OSPF), Enhanced Interior Gateway Routing Protocol (EIGRP), and so on.
The current LWAPP DSCP classification represents a classification that, although optimal for the WLAN
system, may not align with the QoS policies and needs of each customer.
system, may not align with the QoS policies and needs of each customer.
In particular, a customer may wish to minimize the amount of CS6-classified traffic generated by the
WLAN network. They may wish to stop CS6 traffic generated by client activity such as probe requests.
The simplest mechanism to do this would be to reclassify the LWAPP 802.11 CS6 traffic to a different
DSCP. The fact that the LWAPP UDP port used is different from that used by LWAPP data, and the
default DSCP marking allow for remarking this traffic without resorting to deep packet inspection.
WLAN network. They may wish to stop CS6 traffic generated by client activity such as probe requests.
The simplest mechanism to do this would be to reclassify the LWAPP 802.11 CS6 traffic to a different
DSCP. The fact that the LWAPP UDP port used is different from that used by LWAPP data, and the
default DSCP marking allow for remarking this traffic without resorting to deep packet inspection.
In addition, a customer may wish to ensure that LWAPP initialization traffic does not impact routing
traffic. The simplest mechanism for ensuring this is to mark LWAPP control traffic that is in excess of
the background rate with a lower priority.
traffic. The simplest mechanism for ensuring this is to mark LWAPP control traffic that is in excess of
the background rate with a lower priority.
LWAPP Traffic Volumes
Cisco testing has found that the average background traffic per AP is approximately 305 bits/sec.
Calculating the average initial traffic per AP is more difficult, because the average time taken for an AP
to go from rebooted to operational is a function of the WAN speed, as well as that of the WLC and AP.
In reality, the difference is minimal. While on a lab test network, the best of initial traffic might average
2614 bit/sec over 18 seconds. With a WAN link with a 100 ms RTT, the average is 2318 bits/sec over
20.3 seconds.
to go from rebooted to operational is a function of the WAN speed, as well as that of the WLC and AP.
In reality, the difference is minimal. While on a lab test network, the best of initial traffic might average
2614 bit/sec over 18 seconds. With a WAN link with a 100 ms RTT, the average is 2318 bits/sec over
20.3 seconds.
Example Router Configurations
This section contains router configuration examples to be used as guides when addressing CS6
remarking or LWAPP control traffic load.
remarking or LWAPP control traffic load.
This example uses LWAPP APs on the 192.168.101.0/24 subnet, and two WLCs with ap-managers at
192.168.60.11, and 192.168.62.11.
192.168.60.11, and 192.168.62.11.
Remarking Client Generated CS6 Packets
The following shows a sample configuration for remarking LWAPP data packets marked as CS6 to a
more appropriate value of CS3. This moves the traffic to a more suitable classification, at the level of
call control, rather than at the level of network control.
more appropriate value of CS3. This moves the traffic to a more suitable classification, at the level of
call control, rather than at the level of network control.