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Catalyst 6500 Series Software Configuration Guide, 5.5
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Index
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About This Guide
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Product Overview
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Command-Line Interfaces
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Configuring the Switch IP Address and Default Gateway
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Configuring Ethernet, Fast Ethernet, and Gigabit Ethernet Switching
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Configuring EtherChannel
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Configuring Spanning Tree
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Configuring Spanning-Tree PortFast, UplinkFast, and BackboneFast
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Configuring VTP
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Configuring VLANs
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Configuring Ethernet VLAN Trunks
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Configuring GVRP
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Configuring Dynamic Port VLAN Membership with VMPS
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Checking Port Status and Connectivity
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Administering the Switch
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Controlling Access to the Switch Using Authentication, Authorization, and Accounting
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Configuring Redundant Supervisor Engines
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Modifying the Switch Boot Configuration
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Working With the Flash File System
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Working with System Software Images
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Working with Configuration Files
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Configuring System Message Logging
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Configuring DNS
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Configuring CDP
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Configuring UDLD
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Configuring NTP
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Configuring Broadcast Suppression
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Configuring Layer 3 Protocol Filtering
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Configuring IP Permit List
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Configuring Port Security
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Configuring SNMP
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Configuring RMON
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Configuring SPAN and RSPAN
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Using Switch TopN Reports
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Configuring Multicast Services
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Configuring Quality of Service
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Configuring a Voice-Over-IP Network
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Table Of Contents
Configuring a Voice-over-IP Network
Software and Hardware Requirements
Understanding a Voice-Over-IP Network
Example 1—Single Cisco IP Phone 7960
Example 3—One Cisco IP Phone 7960 and One PC
Example 4—Two Cisco IP Phone 7960s and One PC
Catalyst Switch Configuration Procedures
Configuring Per-Port Power Management
Using show Commands to Display Module Type and Version Information
set inlinepower defaultallocation
Configuring Auxiliary VLANs on Catalyst LAN Switches
Auxiliary VLAN Configuration Guidelines
Verifying Auxiliary VLAN Configuration
Configuring the Access Gateways
Displaying Active Call Information
Configuring QoS in the Cisco IP Phone 7960
Understanding How QoS Works in the Cisco IP Phone 7960
Configuring QoS in the Cisco IP Phone 7960
Configuring a Voice-over-IP Network
This chapter describes how to configure a Voice-over-IP (VoIP) network. While this chapter introduces a number of Cisco networking products related to VoIP, the primary focus of the chapter is to provide configuration information for integrating Catalyst 6000 family products into your VoIP network.
This chapter consists of these sections:
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Software and Hardware Requirements
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Software and Hardware Requirements
The software and hardware requirements for the Catalyst switches and Cisco CallManager are as follows:
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Understanding a Voice-Over-IP Network
A telephony system built on an IP network instead of the traditional circuit-switched Private Branch Exchange (PBX) is called an IP PBX system. Figure 36-1 shows an IP PBX system; the individual components of this system are described in these sections:
Figure 36-1
IP PBX System
Cisco IP Phone 7960
The Cisco IP Phone 7960 provides connectivity to the IP PBX system. The IP phone has two RJ-45 jacks for connecting to external devices, a LAN-to-phone jack and a PC-to-phone jack. The jacks use either Category 3 or Category 5 unshielded twisted-pair (UTP) cable. The LAN-to-phone jack is used to connect the phone to the LAN using a crossover cable; a workstation or a PC can be connected to the PC-to-phone jack using a straight-through cable.
The IP phone is Dynamic Host Configuration Protocol (DHCP) capable, providing mobility with a plug-and-play capability, and optionally, the IP phone can be programmed with a static IP address.
The IP phone can be powered by the following sources:
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Examples 1 through 4 in Figure 36-2 show the various ways to connect the Cisco IP Phone 7960 and PCs to the Catalyst switch.
Figure 36-2 Connecting the Cisco IP Phone 7960 to the Catalyst Switch
Example 1—Single Cisco IP Phone 7960
Example 1 shows one IP phone connected to the 10/100 port on the Catalyst switch. The PC-to-phone jack on the phone is not used. The phone can be powered through either the 10/100 port or wall-powered.
Example 2—Single PC
Example 2 shows one PC connected to the 10/100 port on the Catalyst switch. The PC is wall-powered.
Example 3—One Cisco IP Phone 7960 and One PC
Example 3 shows one IP phone connected to the 10/100 port on the Catalyst switch and one PC connected to the PC-to-phone jack on the phone. The PC behaves as if it is connected directly to the 10/100 port on the Catalyst switch. The phone can be powered through the 10/100 port or wall-powered. The PC must be wall-powered.
Example 4—Two Cisco IP Phone 7960s and One PC
Example 4 shows two IP phones connected to the 10/100 port on the Catalyst switch and one PC connected to the PC-to-phone jack on the phone. The PC behaves as if it is connected directly to the 10/100 port on the Catalyst switch. The first phone can be powered through the 10/100 port or wall-powered. The second phone and the PC must be wall-powered.
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Cisco CallManager
Cisco CallManager is an open and industry-standard call processing system—the nerve center of the IP PBX system. Cisco CallManager software runs on a Windows NT server and sets up and tears down calls between phones, integrating traditional PBX functionality with the corporate IP network. Cisco CallManager manages the components of the IP PBX system, the phones, access gateways, and the resources necessary for such features as call conferencing and media mixing. Each
Cisco CallManager manages the devices within its zone and exchanges information with the
Cisco CallManager in charge of another zone to make calls possible across multiple zones. Additionally, Cisco CallManager can work with existing PBX systems to route a call over the Public Switched Telephone Network (PSTN).
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Access Gateways
Access gateways allow the IP PBX system to talk to existing PSTN or PBX systems. Access gateways consist of analog station gateways, analog trunk gateways, digital trunk gateways, and a converged voice gateway.
Analog Station Gateway
The Catalyst 6000 family 24-port Foreign Exchange Station (FXS) analog interface module allows plain old telephone service (POTS) phones and fax machines to connect to the IP PBX network. The analog station gateway behaves like the PSTN side for the POTS equipment. It requires an IP address, is registered with Cisco CallManager in its domain, and is managed by Cisco CallManager.
The 24-port FXS analog interface module features are listed in Table 36-1.
To configure the analog station interfaces, see the "Catalyst Switch Configuration Procedures" section. To configure the interfaces to work with Cisco CallManager, refer to the
Cisco CallManager Administration Guide, Release 3.0 publication.
Table 36-1 24-Port FXS Analog Interface Module Features
Digital Signal Processing Per Port
G.711 and G.729 voice encoding
Silence suppression, voice activity detection
Comfort noise generation
Ringer, software programmable frequency and cadence, based on country
DTMF1 detection
Signaling, loop start
Line echo cancellation (32 ms)
Impedance (600 ohms)
Programmable analog gain, signaling timers
Fax passthrough
SPAN2 or port mirroring support
Address signaling formats: In-band DTMF
Signaling formats: Loop start
Ringing tone: Programmable
Ringing voltage: Programmable, based on country
Ringing frequency: Programmable, based on country
Distance: 500-ohms maximum loop
1 DTMF = dual tone multifrequency.
2 SPAN = Switched Port Analyzer.
Analog Trunk Gateway
Cisco access analog trunk gateways allow the IP PBX to connect to the PSTN or PBX. The gateway supports up to eight trunks to the PSTN and appears like a phone to the trunk lines coming from the PSTN. Using this gateway, the IP PBX places an IP call through the PSTN. Similar to the analog station gateway, the analog trunk gateway provides line echo cancellation, dual tone multifrequency (DTMF) tone generation and detection. The analog trunk gateway does not provide ring voltage as it is not connected to POTS end devices such as POTS-phones or fax machines. The analog trunk gateway requires an IP address, is registered with Cisco CallManager in its domain, and is managed by Cisco CallManager.
To configure the analog trunk gateways, refer to the documentation that shipped with the gateway. To configure the interfaces to work with Cisco CallManager, refer to the Cisco CallManager Administration Guide, Release 3.0 publication.
Digital Trunk Gateway
The Catalyst 6000 family 8-port T1/E1 PSTN interface module is a high-density, eight port, T1/E1 VoIP module that can support both digital T1/E1 connectivity to the PSTN or transcoding and conferencing. It requires an IP address, is registered with Cisco CallManager in its domain, and is managed by Cisco CallManager.
The module software is downloaded from a TFTP server. Depending upon which software you download, the ports can serve as T1/E1 interfaces or the ports will support transcoding and conferencing. Transcoding and conferencing functions are mutually exclusive. For every transcoding port in use, there will be one less conferencing port available and vice versa.
To configure the 8-port T1/E1 PSTN interfaces, see the "Catalyst Switch Configuration Procedures" section. To configure the interfaces to work with Cisco CallManager, refer to the Cisco CallManager Administration Guide, Release 3.0 publication.
The 8-port T1/E1 PSTN interface module features are listed in Table 36-2.
Converged Voice Gateway
The Cisco Voice Gateway 200 (VG200) allows you to connect standard POTS phones (connected directly to the gateway or anywhere on the PSTN) with Cisco IP or any H.323-compliant telephony devices. When used with Cisco CallManager, the VG200 functions as a Media Gateway Control Protocol (MGCP) gateway. The Cisco VG200 Gateway provides a 10/100BaseT Ethernet port for connection to the data network. The following telephony connections are also available:
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These ports can be used to integrate a VoIP network with POTS devices, PBXs, or the PSTN.
To configure the Cisco VG200 Gateway, refer to the documentation that shipped with the gateway. To configure the interfaces to work with Cisco CallManager, refer to the Cisco CallManager Administration Guide, Release 3.0 publication.
How a Call Is Made
An IP phone is connected to a LAN either through a hub port or a switch port. The IP phone boots up and uses DHCP to get its IP address and the IP address of its TFTP file server. The IP phone uses its IP address to talk to the TFTP server and gets its configuration file. The configuration file has information including the IP address of the phone's Cisco CallManager(s). The phone then talks with Cisco CallManager and registers itself. Each time a phone boots up, it might get a different IP address. Cisco CallManager knows how to associate a consistent user phone number to a particular phone by using the MAC address of the phone. Cisco CallManager always maintains a table mapping the "phone MAC address" and "phone number." Each time a phone registers, the table is updated with the new IP address. During registration, Cisco CallManager downloads the key pad template and the feature capability for the phone. It also tells the phone which run-time image it should use. The phone then goes to the TFTP server to get its run-time image. Each phone has a dedicated TCP connection to Cisco CallManager called the "control channel." All control information, such as key pressing, goes from the phone to Cisco CallManager through this channel. Instructions to generate ring tone, busy tone, and so on comes from Cisco CallManager to the phone through this channel.
Cisco CallManager stores the IP-address-to-phone-number mapping (and vice versa) in its tables. When a user wants to call another user, the user keys in the called party's phone number.
Cisco CallManager translates the phone number to an IP address and generates an IP packet version of ring tone to the called IP phone through the TCP connection. When the called IP phone receives the packet, it generates a ring tone. When the user picks up the phone, Cisco CallManager instructs the called IP phone to start talking with the calling party and removes itself from the loop. From this point on, the call goes between the two IP phones through the Real-Time Transport Protocol (RTP) which runs over User Datagram Protocol (UDP). Because voice packets are sensitive to delays, TCP is not suitable for voice transmission as timeouts and retries increase the delay between packets. When any change occurs during the call due to a feature being pressed on one of the phones, or one of the users hanging up or pressing the flash button, the information goes to Cisco CallManager through the control channel.If a call is made to a number outside of the IP PBX network, Cisco CallManager routes the call to an analog or digital trunk gateway which in turn routes it to the PSTN.
VLAN Overview
This section describes native VLANs and auxiliary VLANs. This section uses the following terminology:
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Figure 36-3 shows how a Cisco IP Phone 7960 can be connected to a Catalyst switch.
Figure 36-3 Switch-to-Phone Connections
When the IP phone is connected to a 10/100 port on the Catalyst switch, the access port (PC-to-phone jack) of the IP phone can be used to connect a PC.
Packets to and from the PC and to and from the phone share the same physical link to the switch and the same port of the switch. Various configurations of connecting the phone and the PC are possible (see the "Cisco IP Phone 7960" section).
Introducing IP-based phones into existing switch-based networks raises the following issues:
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These issues can be solved by isolating the voice traffic onto a separate VLAN on each of the ports connected to a phone. The switch port configured for connecting a phone would have separate VLANs configured for carrying:
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Isolating the phones on a separate, auxiliary VLAN increases the quality of the voice traffic and allows a large number of phones to be added to an existing network where there are not enough IP addresses. A new VLAN means a new subnet and a new set of IP addresses.
Catalyst Switch Configuration Procedures
This section describes the command-line interface (CLI) commands used to configure the Catalyst switch for VoIP operation. This section provides the following descriptions and configuration procedures:
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Voice-Related CLI Commands
Table 36-3 lists the CLI commands described in the configuration procedures.
Table 36-3 Voice-Related CLI Command Module and Platform Support
set port inlinepower
X4
set inlinepower defaultallocation
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show port inlinepower
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show environment power
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set port auxiliaryvlan
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show port auxiliaryvlan
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set port voice interface
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show port voice interface
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show port voice
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show port voice fdl
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show port voice active
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set port qos mod/port cos-ext
set port qos mod/port trust-ext
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show port qos
X/X
1 WS-X6348-RJ45V = 48-port 10/100BaseTX switching module with voice daughter card.
2 WS-X6608-T1 and WS-X6608-E1 = 8-port T1/E1 ISDN PRI modules.
3 WS-X6624-FXS = 24-port FXS analog station interface module.
4 X = Command supported on Catalyst 6000 family switch only; XX = Command supported on Catalyst 4000, 5000, and 6000 family switches (note that all modules listed in Table 36-3 are supported only on Catalyst 6000 family switches).
Configuring Per-Port Power Management
This section describes per-port power management and the CLI commands used to configure power management for IP phones.
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For each IP phone connected to the WS-X6348-RJ45V module, the supervisor engine software allocates part of the available system power to power up and run the phone. The power can be applied on an individual port basis.
Only one IP phone can be powered per port; the phone must be connected directly to the switch port. If a second phone is daisy chained off the phone connected to the switch port, the second phone cannot be powered by the switch.
This section describes the following:
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Using show Commands to Display Module Type and Version Information
There are three versions of the Catalyst 6000 family 48-port 10/100BaseTX Ethernet switching module; each version has a unique product number:
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When you enter the show module command, the WS-X6348 modules both display as WS-X6348-RJ-45 in the "Model" field. To determine if the module has a voice daughter card installed, look at the "Sub" field. For example, in the following display the 10/100BaseTX module in slot 8 does not have a voice daughter card, while the module in slot 9 does have a voice daughter card.
Note that further down in the show module display there is a submodule field that provides information about submodules. The EARL daughter card is treated as a submodule while the MSFC internal router is not treated as a submodule. The model number for the voice daughter card, as shown in the display, is WS-F6K-VPWR.
Console> (enable) show moduleMod Slot Ports Module-Type Model Sub Status--- ---- ----- ------------------------- ------------------- -----------1 1 2 1000BaseX Supervisor WS-X6K-SUP1A-2GE yes ok15 1 1 Multilayer Switch Feature WS-F6K-MSFC no ok8 8 48 10/100BaseTX Ethernet WS-X6348-RJ-45 no ok9 9 48 10/100BaseTX Ethernet WS-X6348-RJ-45 yes okMod Module-Name Serial-Num--- ------------------- -----------1 SAD0343605515 SAD034325979 SAD03414268Mod MAC-Address(es) Hw Fw Sw--- -------------------------------------- ------ ------------------------1 00-30-80-f7-a5-06 to 00-30-80-f7-a5-07 1.0 5.2(1) 6.2(0.32-Eng)FTL00-30-80-f7-a5-04 to 00-30-80-f7-a5-0500-30-a3-4a-a0-00 to 00-30-a3-4a-a3-ff15 00-d0-bc-ee-d0-dc to 00-d0-bc-ee-d1-1b 1.2 12.0(3)XE1 12.0(3)XE18 00-d0-c0-c8-83-ac to 00-d0-c0-c8-83-db 1.1 4.2(0.24)V6.1(0.37)FTL9 00-50-3e-7c-43-00 to 00-50-3e-7c-43-2f 0.201 5.3(1)Mod Sub-Type Sub-Model Sub-Serial Sub-Hw--- ----------------------- ------------------- ----------- ------1 L3 Switching Engine WS-F6K-PFC SAD03451187 1.09 Inline Power Module WS-F6K-VPWR 1.0Console> (enable)Use the show version command to show the version of modules and submodules:
Console> (enable) show version 9Mod Port Model Serial # Versions--- ---- ------------------- -------------------------------------------------9 48 WS-X6348 SAD03414268 Hw :0.201Fw :5.3(1)Sw :6.1(0.32)FTLWS-F6K-VPWR Hw :1.0Console> (enable)Power Management Modes
Each port is configured through the CLI, SNMP, or a configuration file to be in one of the following modes (configured through set port inlinepower CLI command):
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Each port also has a status, defined as:
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Unpowered Phone
When an unpowered phone is discovered on a switching module port, the switching module reports to the supervisor engine that an unpowered phone is present and on which module/port. If the port is configured in Auto mode, the supervisor engine determines if there is enough available system power to allow the switching module to power up and run the phone. If there is sufficient power, the supervisor engine removes the default allocated power required by a phone from the total available system power and then sends a message to the switching module instructing it to provide power to the port. If there is not enough available power for the phone, the supervisor engine sends a message to the switching module indicating that power is denied to the port.
After power is applied to the port, the supervisor engine monitors the port to ensure that the link comes up. If the link does not come up within 4 seconds, the supervisor engine instructs the switching module to turn power off. The entire cycle is then repeated, and the switching module performs discovery and reports to the supervisor engine if a device is present on the port.
Power Requirements
IP Phones may have different power requirements. The supervisor engine initially allocates the configured default of 7W (167 mA at 42V) to the Cisco IP Phone. When the correct amount of power is determined from the CDP messaging with the Cisco IP Phone, the supervisor engine reduces or increases the allocated power.
For example, the default allocated power is 7W. A Cisco IP Phone requiring 6.3W is plugged into a port. The supervisor engine allocates 7W for the Cisco IP Phone and powers it up. Once the Cisco IP Phone is operational, it sends a CDP message with the actual power requirement to the supervisor engine. The supervisor engine then decreases the allocated power to the required amount.
Wall-Powered Phones
When a wall-powered phone is present on a switching module port, the switching module cannot detect its presence. The supervisor engine discovers the phone through CDP messaging with the port. If the phone supports inline power (the supervisor engine determines this through CDP), and the mode is set to Auto or Off, the supervisor engine does not attempt to power on the port. If there is a power outage and the mode is set to Auto, the phone will lose power, but the switching module will discover the phone and inform the supervisor engine, which then applies inline power to the phone.
Powering Off the Phone
The supervisor engine can turn off power to a specific port by sending a message to the switching module. That power is then added back to the available system power. This only occurs when you power off the phone through the CLI or SNMP.
Phone Removal
The switching module informs the supervisor engine if a powered phone is removed using a link-down message. The supervisor engine then adds the allocated power for that port back to the available system power.
The switching module also informs the supervisor engine if an unpowered phone is removed.
Caution
High Availability Support
To support high availability during a failover from the active supervisor engine to the standby supervisor engine, the per-port power management and phone status information is synchronized between the active and standby supervisor engines.
The information to be synchronized (on a per-port basis) is the presence of a phone, the phone power status (on, off, denied, or faulty), and the amount of power consumed by the phone. The active supervisor engine sends this information to the standby supervisor engine and the standby supervisor engine updates its internal data structures. When a switchover occurs, the standby supervisor engine allocates power to the modules and ports from the available power, one module at a time. Once the power for each module has been allocated, the supervisor engine allocates power to the phones, beginning with the lowest slot number, until all inline powered ports have been either powered on, off, or denied.
Phone Detection Summary
Figure 36-4 shows how the system detects a phone connected to a Catalyst switch port.
Figure 36-4
Power Detection Summary
Error Detection and Handling
This section describes how the Catalyst 6000 family switch handles fault detection and errors related to per-port power management.
Device is Powered but Link is Not Up
The supervisor engine detects that the device is powered but the link is not up by setting a timeout when the switching module is directed to power up the device. If the timeout occurs and the supervisor engine has not received a "link up" for the port, the following syslog message is displayed:
1999 Jul 14 10:05:58 %SYS-5-PORT_DEVICENOLINK: Device on Port 4/7 powered, no link up.The supervisor engine also directs the switching module to power off the port. The switching module then performs discovery again on the port.
Port is Unable to Provide Inline Power to the Device
The switching module detects when there is a problem providing inline power to the device and reports this to the supervisor engine. The following syslog message is displayed:
1999 Jul 14 10:05:58 %SYS-5-PORT_INLINEPWRFLTY: Port 4/7 reporting inline power as faulty.Not Enough Available Power to Power the Device
The supervisor engine keeps track of the available power left in the system and will not power up any ports if there is no available power remaining. The following syslog message is displayed:
1999 Jul 14 10:05:58 %SYS-5-PORT_NOPOWERAVAIL: Device on Port 4/7 will remain unpowered.The supervisor engine informs the switching module that power to the port is denied.
Power Supply Configured from Nonredundant to Redundant
Depending upon the number and type of modules in the chassis, some modules might need to be powered off to prevent overdrawing power from the power supply. The supervisor engine first powers off and reallocates the power supplied by the ports and then starts the process of powering off and reallocating the power used by the module.
Power Supply Configured from Redundant to Nonredundant
Once a module that was powered down due to lack of power is powered up and comes online, the module begins discovery on the ports to determine the presence of unpowered connected devices (phones). The module reports discovered devices to the supervisor engine, which then directs the switching module to power up the device (if the port is configured to do so).
For modules that are already powered on, but have devices connected that are power denied, the supervisor engine attempts to power on the devices starting with the lowest numbered slot to the highest numbered slot, and from the lowest port number to the highest port number, one module at a time.
set port inlinepower
This example shows how to set the power mode of a port or group of ports:
Console> (enable) set port inlinepower helpUsage: set port inlinepower <mod/port> <auto|off>Console> (enable) set port inlinepower 2/5 offInline power for port 2/5 set to off.Console> (enable) set port inlinepower 2/3-9 autoInline power for ports 2/3-9 set to auto.Console> (enable)set inlinepower defaultallocation
This example shows how to set the default power allocation for a port:
Console> (enable) set inlinepower defaultallocation helpUsage: set inlinepower defaultallocation <value>(value = 2000..12500 (mWatt))Console> (enable) set inlinepower defaultallocation 9500Default inline power allocation set to 9500 mWatt per applicable port.Console> (enable)show port inlinepower
This example shows how to display the power status for modules and individual ports:
Console> (enable) show port inlinepower helpUsage: show port inlinepower [mod/port]Console> show port inlinepower 3/2-6Default Inline Power allocation per port: 9.500 Watts (0.22 Amps @42V)Total inline power drawn by module 3: 0 WattPort InlinePowered PowerAllocatedAdmin Oper Detected mWatt mA @42V----- ----- ------ -------- ----- --------3/2 auto on yes 10.00 0.2503/3 auto on yes 9.8 0.1983/4 auto denied yes 0 03/5 off off no 0 03/6 off off yes 0 0Console> (enable)Operational (Oper) status field descriptions:
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show environment power
This example shows how to display the power status for modules and individual ports:
Console> (enable) show environment power helpUsage: show environment power [mod]Console> (enable) show environment power 5Feature not supported on module 5.Console> (enable) show environment power 9Module 9:Default Inline Power allocation per port: 9.500 Watts (0.22 Amps @42V)Total inline power drawn by module 9: 0 WattSlot power Requirement/Usage :Slot Card Type PowerRequested PowerAllocated CardStatusWatts A @42V Watts A @42V---- ------------------- ------- ------ ------- ------ ----------9 WS-X6348 123.06 2.93 123.06 2.93 okDefault Inline Power allocation per port: 9.500 Watts (0.22 Amps @42V)Port InlinePowered PowerAllocatedAdmin Oper Detected mWatt mA @42V----- ----- ------ -------- ----- --------9/1 auto off no 0 09/2 auto off no 0 09/3 auto off no 0 09/4 auto off no 0 09/5 auto off no 0 09/6 auto off no 0 09/7 auto off no 0 09/8 auto off no 0 0.(display text omitted).9/48 auto off no 0 0Console> (enable)Console> (enable) show environment powerPS1 Capacity: 1153.32 Watts (27.46 Amps @ 42V)PS2 Capacity: nonePS Configuration : PS1 and PS2 in Redundant Configuration.Total Power Available: 1153.32 Watts (27.46 Amps @ 42V)Total Power Available for Line Card Usage: 1153.32 Watts (27.46 Amps @ 42V)Total Power Drawn From the System: 289.80 Watts (6.90 Amps @ 42V)Remaining Power in the System: 863.52 Watts (20.56 Amps @42V)Default inline power allocation: 10.5 Watts/port (0.25 Amps @ 42V)Slot power Requirement/Usage :Slot Card-Type Power-Requested Power-Allocated Card-StatusWatts A @ 42V Watts A @ 42V---- ------------------- ------- ------- ------- ------- ------------1 0.00 0.00 126.42 3.01 none2 WS-X6K-SUP1-2GE 138.60 3.30 138.60 3.30 ok3 WS-X6348-RJ-45 114.24 2.72 151.20 3.60 ok5 WS-X6348-RJ-45 109.20 2.60 100.88 2.40 partial-deny6 Unknown 112.98 2.69 0 0 unknown7 WS-X6248-RJ-45 84.84 2.02 0 0 power-bad9 WS-X6416-GE-MT 105.00 2.50 0 0 power-denyConsole> (enable)A partial-deny status indicates that some module ports are inline powered but not all the ports on the module are inline powered.
Configuring Auxiliary VLANs on Catalyst LAN Switches
These sections describe how to configure auxiliary VLANs:
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Understanding Auxiliary VLANs
You can configure switch ports to send CDP packets that instruct an attached Cisco IP Phone 7960 to transmit voice traffic to the switch in these frame types:
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Auxiliary VLAN Configuration Guidelines
Observe the following guidelines when configuring auxiliary VLANs:
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Configuring Auxiliary VLANs
This example shows how to add voice ports to auxiliary VLANs, specify an encapsulation type, or specify that the VLAN will not send or receive CDP messages with voice-related information:
Console> (enable) set port auxiliaryvlan 2/1-3 222Auxiliaryvlan 222 configuration successful.AuxiliaryVlan AuxVlanStatus Mod/Ports------------- ------------- -------------------------222 active 1/2,2/1-3Console> (enable) set port auxiliaryvlan 5/7 untaggedPort 5/7 allows the connected device send and receive untagged packets and without 802.1p priority.Console> (enable) set port auxiliaryvlan 5/9 dot1pPort 5/9 allows the connected device send and receive packets with 802.1p priority.Console> (enable) set port auxiliaryvlan 5/12 nonePort 5/12 will not allow sending CDP packets with Voice VLAN information.Console> (enable)The default setting is none. Table 36-4 lists the set port auxiliaryvlan command keywords and their descriptions.
Verifying Auxiliary VLAN Configuration
This example shows how to display auxiliary VLAN status:
Console> show port auxiliaryvlan 123AuxiliaryVlan AuxVlanStatus Mod/Ports------------- ------------- -------------------------222 active 1/2,2/1-3Console>Configuring the Access Gateways
This section describes the commands used to configure the following Catalyst 6000 family access gateway modules:
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set port voice interface
If DHCP is enabled for a port, the port obtains all other configuration information from the TFTP server. When disabling DHCP on a port, some mandatory parameters must be specified as follows:
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These examples show how to configure the port voice interface for DHCP, TFTP, and DNS servers:
Console> (enable) set port voice interface helpUsage: set port voice interface <mod/port> dhcp enable [vlan <vlan>]set port voice interface <mod/port> dhcp disable <ipaddrspec>tftp <ipaddr> [vlan <vlan>][gateway <ipaddr>] [dns [ipaddr] [domain_name]](ipaddr_spec: <ipaddr> <mask>, or <ipaddr>/<mask><mask>: dotted format (255.255.255.0) or number of bits (0..31)vlan: 0..1000System DNS may be used if disabling DHCP without DNS parameters)Console> (enable) set port voice interface 7/1 dhcp enablePort 7/1 DHCP enabled.Console> (enable) set port voice interface 7/3 dhcp disable 171.68.111.41/24 tftp 173.32.43.11 dns 172.20.34.204 cisco.comPort 7/3 dhcp disabled.System DNS configurations applied.Console> (enable) set port voice interface 7/4-6 dhcp enable vlan 3Vlan 3 configuration successfulPorts 7/4-6 DHCP enabled.Console> (enable)show port voice interface
This example shows how to display the port voice interface configuration (this display is from the 24-port FXS analog interface module):
Console> (enable) show port voice interface helpUsage: show port voice interface <mod/port>Console> show port voice interface 5Port DHCP MAC-Address IP-Address Subnet-Mask-------- ------- ----------------- --------------- ---------------5/1-24 disable 00-10-7b-00-13-ea 10.6.15.158 255.255.255.0Port Call-Manager(s) DHCP-Server TFTP-Server Gateway-------- ----------------- --------------- --------------- ---------------5/1-24 10.6.15.155 - 10.6.15.155 -Port DNS-Server(s) Domain-------- ----------------- -------------------------------------------------5/1-24 12.2.2.1* cisco.cisco.com7.7.7.7(*): PrimaryConsole> (enable)show port voice fdl
This example shows how to display Facilities Data Link (FDL) statistics for the specified ports:
Note
Console> (enable) show port voice fdl 7/1-3Port ErrorEvents ErroredSecond SeverlyErroredSecondLast 15' Last 24h Last 15' Last 24h Last 15' Last 24h----- -------- -------- -------- -------- -------- -----------7/1 17 18 19 20 21 227/2 17 18 19 20 21 227/3 17 18 19 20 21 22Port FailedSignalState FailedSignalSecondLast 15' Last 24h Last 15' Last 24h----- -------- -------- -------- ---------7/1 37 38 39 407/2 37 38 39 407/3 37 38 39 40Port LES BES LCVLast 15' Last 24h Last 15' Last 24h Last 15' Last 24h----- -------- -------- -------- -------- -------- --------7/1 41 48 49 50 53 547/2 41 48 49 50 53 547/3 41 48 49 50 53 54Console> (enable)Table 36-5 describes the possible fields (depending on the port type queried) in the show port voice fdl command output.
show port
This example shows how to display the port configuration for individual ports. This section describes the show port command displays for the following gateway modules:
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8-Port T1/E1 PSTN Interface Module
The Status field shows Layer 2 status of the ports. Possible values are: notconnect, connected, disabled, and faulty. The following display is for the T1 module. The display would be the same for the E1 module except the port speed for the E1 module would be 2.048.
Console> show port 7Port Name Status Vlan Duplex Speed Type----- ------------------ ---------- ---------- ------ ----- ------------7/1 connected 123 full 1.544 T17/2 connected 2 full 1.544 T17/3 disable 1 full 1.544 T17/4 connected 11 full 1.544 T17/5 connected 123 full 1.544 T17/6 connected 1 full 1.544 T17/7 faulty 2 full 1.544 T17/8 faulty 2 full 1.544 T1Port DHCP MAC-Address IP-Address Subnet-Mask-------- ------- ----------------- --------------- ---------------7/1 enable 00-10-7b-00-0a-58 172.20.34.68 255.255.255.07/2 enable 00-10-7b-00-0a-59 172.20.34.70 255.255.255.07/3 enable 00-10-7b-00-0a-5a 172.20.34.64 255.255.255.07/4 enable 00-10-7b-00-0a-5b 172.20.34.66 255.255.255.07/5 enable 00-10-7b-00-0a-5c 172.20.34.59 255.255.255.07/6 enable 00-10-7b-00-0a-5d 172.20.34.67 255.255.255.07/7 enable 00-10-7b-00-0a-5e (Port host processor not online)7/8 enable 00-10-7b-00-0a-5f (Port host processor not online)Port Call-Manager(s) DHCP-Server TFTP-Sever Gateway-------- ----------------- --------------- --------------- ---------------7/1 172.20.34.207* 172.20.34.207 172.20.34.207 -callm.cisco.com7/2 172.20.34.207 172.20.34.207 172.20.34.207 172.20.34.207/3 172.20.34.207 172.20.34.207 172.20.34.207 -7/4 172.20.34.207 172.20.34.207 172.20.34.207 -7/5 172.20.34.207 172.20.34.207 172.20.34.207 -7/6 172.20.34.207 172.20.34.207 172.20.34.207 -7/7 (Port host processor not online)7/8 (Port host processor not online)Port DNS-Server(s) Domain-------- --------------- -------------------------------------------------7/1 172.20.34.207 cisco.com7/2 172.20.34.207* int.cisco.com171.69.45.34172.78.111.1327/3 172.20.34.207 -7/4 172.20.34.207 -7/5 172.20.34.207 -7/6 172.20.34.207 -7/7 (Port host processor not online)7/8 (Port host processor not online)Port CallManagerState DSP-Type-------- ---------------- --------7/1 registered C5497/2 registered C5497/3 registered C5497/4 registered C5497/5 registered C5497/6 notregistered C5497/7 (Port host processor not online)7/8 (Port host processor not online)Port NoiseRegen NonLinearProcessing----- ---------- -------------------7/1 disabled disabled7/2 disabled disabled7/3 disabled disabled7/4 disabled disabled7/5 enabled disabled7/6 disabled enabled7/7 (Port host processor not online)7/8 (Port host processor not online)(*): PrimaryConsole>8-Port T1/E1 PSTN Interface Module Configured for Trancoding/Conferencing
MTP (media termination point) and Conf Bridge (conference bridge) are types of ports. Transcoding applies to a call on an MTP port.
In this example, a transcoding port shows as "MTP" and a conference port shows as
"Conf Bridge."Console> (enable) show port 7Port Name Status Vlan Duplex Speed Type----- ------------------ ---------- ---------- ------ ----- ------------7/1 notconnect 1 full 1.544 T17/2 notconnect 1 full 1.544 T17/3 connected 1 full 1.544 T17/4 connected 1 full 1.544 T17/5 connected 1 full 1.544 T17/6 connected 1 full 1.544 T17/7 enabled 1 full - Conf Bridge7/8 enabled 1 full - MTPPort DHCP MAC-Address IP-Address Subnet-Mask-------- ------- ----------------- --------------- ---------------7/1 enable 00-10-7b-00-12-08 10.6.15.165 255.255.255.07/2 enable 00-10-7b-00-12-09 10.6.15.166 255.255.255.07/3 enable 00-10-7b-00-12-0a 10.6.15.167 255.255.255.07/4 enable 00-10-7b-00-12-0b 10.6.15.168 255.255.255.07/5 enable 00-10-7b-00-12-0c 10.6.15.169 255.255.255.07/6 enable 00-10-7b-00-12-0d 10.6.15.170 255.255.255.07/7 enable 00-10-7b-00-12-0e 10.6.15.171 255.255.255.07/8 enable 00-10-7b-00-12-0f 10.6.15.172 255.255.255.0Port Call-Manager(s) DHCP-Server TFTP-Server Gateway-------- ----------------- --------------- --------------- ---------------7/1 10.6.15.155 10.6.15.155 10.6.15.155 -7/2 10.6.15.155 10.6.15.155 10.6.15.155 -7/3 10.6.15.155 10.6.15.155 10.6.15.155 -7/4 10.6.15.155 10.6.15.155 10.6.15.155 -7/5 10.6.15.155 10.6.15.155 10.6.15.155 -7/6 10.6.15.155 10.6.15.155 10.6.15.155 -7/7 10.6.15.155 10.6.15.155 10.6.15.155 -7/8 10.6.15.155 10.6.15.155 10.6.15.155 -Port DNS-Server(s) Domain-------- ----------------- -------------------------------------------------7/1 - -7/2 - -7/3 - -7/4 - -7/5 - -7/6 - -7/7 - -7/8 - -Port CallManagerState DSP-Type-------- ---------------- --------7/1 registered C5497/2 registered C5497/3 registered C5497/4 registered C5497/5 registered C5497/6 registered C5497/7 registered C5497/8 registered C549Port NoiseRegen NonLinearProcessing----- ---------- -------------------7/1 enabled enabled7/2 enabled enabled7/3 enabled enabled7/4 enabled enabled7/5 enabled enabled7/6 enabled enabled7/7 disabled disabled7/8 disabled disabledConsole> (enable)24-Port FXS Analog Interface Module
In this example, all ports should have a "Type" of FXS, and all ports in the same module should belong to one VLAN.
Console> (enable) show port 3Port Name Status Vlan Duplex Speed Type----- ------------------ ---------- ---------- ------ ----- ------------3/1 onhook 1 full 64k FXS3/2 onhook 1 full 64k FXS3/3 onhook 1 full 64k FXS3/4 onhook 1 full 64k FXS3/5 onhook 1 full 64k FXS3/6 onhook 1 full 64k FXS3/7 onhook 1 full 64k FXS3/8 offhook 1 full 64k FXS3/9 offhook 1 full 64k FXS3/10 onhook 1 full 64k FXS3/11 onhook 1 full 64k FXS3/12 onhook 1 full 64k FXS3/13 onhook 1 full 64k FXS3/14 onhook 1 full 64k FXS3/15 onhook 1 full 64k FXS3/16 onhook 1 full 64k FXS3/17 onhook 1 full 64k FXS3/18 onhook 1 full 64k FXS3/19 onhook 1 full 64k FXS3/20 onhook 1 full 64k FXS3/21 onhook 1 full 64k FXS3/22 onhook 1 full 64k FXS3/23 onhook 1 full 64k FXS3/24 onhook 1 full 64k FXSPort DHCP MAC-Address IP-Address Subnet-Mask-------- ------- ----------------- --------------- ---------------3/1-24 enable 00-10-7b-00-13-e4 172.20.34.50 255.255.255.0Port Call-Manager(s) DHCP-Server TFTP-Sever Gateway-------- ----------------- --------------- --------------- ---------------3/1-24 172.20.34.207 172.20.34.207 172.20.34.207 -Port DNS-Server(s) Domain-------- ----------------- -------------------------------------------------3/1-24 172.20.34.207* cisco.com172.34.23.111Port CallManagerState DSP-Type-------- ---------------- --------3/1-24 registered C549Port ToneLocal Impedance InputGain(dB) OutputAtten(dB)-------- ------------- --------- ------------- ---------------3/1-24 northamerica 0 0 0Port RingFreq Timing Timing Timing Timing(Hz) Digit(ms) InterDigit(ms) Pulse(ms) PulseDigit(ms)-------- -------- --------- -------------- --------- --------------3/1-24 20 100 100 0 0(*): PrimaryConsole> (enable)Displaying Active Call Information
Use the show port voice active command to display active call information on a port. There are up to 8 calls per port for the 8-port T1/E1 PSTN interface module but only one call per port for the 24-port FXS analog station interface module.
This example shows that the ip-addr option displays one specific call for the specified IP address. You can also use an IP alias.
Console> (enable) show port voice active helpUsage: show port voice active [mod/port] [all|call|conference|transcode] [ipaddr]Console> (enable)Entering the show port voice active command without any parameters shows all the calls in the system (regular calls, conference calls, and transcoding calls). Display field descriptions are as follows:
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When 8-port T1/E1 PSTN interfaces are configured for transcoding and/or conferencing, the Type field displays "conferencing" for conferencing calls and "transcoding" for transcoding calls.
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This example shows all active calls in the system:
Console> show port voice activePort Type Total Conference-ID/ Party-ID IP-AddressTranscoding-ID----- ------------ ----- -------------- -------- ---------------3/1 call 1 - - 199.22.25.2543/2 call 1 - - 172.225.25.544/5 call 3 - - 165.34.234.111172.32.34.12198.96.23.1113/8 conferencing 2 1 1 255.255.255.2412 173.23.13.423 198.97.123.985 182.34.54.262 1 199.22.25.253 182.34.54.26 121.43.23.433/2 call 1 - - 172.225.25.543/8 transcoding 1 1 1 255.255.255.2412 183.32.43.3This example shows how to display detailed call information for a port (specifying the module only, shows detailed call information for all ports on the module):
Console> show port voice active 3/2Port 3/2:Channel #1:Remote IP address : 165.34.234.111Remote UDP port : 124Call state : RingingCodec Type : G.711Coder Type Rate : 35243Tx duration : 438543 secVoice Tx duration : 34534 secACOM Level Current : 123213ERL Level : 123 dBFax Transmit Duration : 332433Hi Water Playout Delay : 23004 msLogical If index : 4Low water playout delay : 234 msReceive delay : 23423 msReceive bytes : 2342342332423Receive packets : 23423423402384Transmit bytes : 23472377Transmit packets : 94540Channel #2:Remote IP address : 165.34.234.112Remote UDP port : 125Call state : RingingCodec Type : G.711Coder Type Rate : 35243Tx duration : 438543 secVoice Tx duration : 34534 secACOM Level Current : 123213ERL Level : 123 dBFax Transmit Duration : 332433Hi Water Playout Delay : 23004 msLogical If index : 4Low water playout delay : 234 msReceive delay : 23423 msReceive bytes : 2342342332423Receive packets : 23423423402384Transmit bytes : 23472377Transmit packets : 94540Channel #3:.(display text omitted).Console>This example shows how to display a specific call at a specified IP address:
Console> show port voice active 3/2 171.69.67.91Remote IP address : 171.69.67.91Remote UDP port : 125Call state : RingingCodec Type : G.711Coder Type Rate : 35243Tx duration : 438543 secVoice Tx duration : 34534 secACOM Level Current : 123213ERL Level : 123 dBFax Transmit Duration : 332433Hi Water Playout Delay : 23004 msLogical If index : 4Low water playout delay : 234 msReceive delay : 23423 msReceive bytes : 2342342332423Receive packets : 23423423402384Transmit bytes : 23472377Transmit packets : 94540Console>Configuring QoS in the Cisco IP Phone 7960
These sections describe QoS in the Cisco IP Phone 7960:
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Understanding How QoS Works in the Cisco IP Phone 7960
Note
You can configure the Cisco IP Phone 7960 access port (see Figure 36-5) to either trusted or untrusted mode.
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Figure 36-5 Configuring QoS on the IP Phone Ports
Configuring QoS in the Cisco IP Phone 7960
These sections describe how to configure QoS in the Cisco IP Phone 7960:
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Setting the Phone Access Port Trust Mode
This example shows how to set the phone access port to the trusted mode:
Console> (enable) set port qos 3/7 trust-ext trustedPort in the phone device connected to port 3/7 is configured to be trusted.Console> (enable)This example shows how to set the phone access port to the untrusted mode:
Console> (enable) set port qos 3/7 trust-ext untrustedPort in the phone device connected to port 3/7 is configured to be untrusted.Console> (enable)Setting the Phone Access Port CoS Value
This example shows how to configure the Layer 2 CoS value used by a phone access port in untrusted mode:
Console> (enable) set port qos 2/1 cos-ext 3Port 2/1 qos cos-ext set to 3.Console> (enable)Verifying the Phone Access Port QoS Configuration
This example shows how to display QoS configuration information:
Console> (enable) show port qos 3/4<...Output Truncated...>Port Ext-Trust Ext-Cos----- --------- -------3/4 untrusted 0<...Output Truncated...>
