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Cisco IOS ISDN Voice Configuration Guide, Release 12.4
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ISDN Features Roadmap
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Overview of ISDN Voice Interfaces
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Basic ISDN Voice-Interface Configuration
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Expanded Scope for Cause-Code-Initiated Call-Establishment Retries
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Clear Channel T3/E3 with Integrated CSU/DSU
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High-Density Analog (FXS/DID/FXO) and Digital (BRI) Extension Module for Voice/Fax (EVM-HD)
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Integrated Data and Voice Services for ISDN PRI Interfaces on Multiservice Access Routers
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Integrated Voice and Data WAN on T1/E1 Interfaces
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ISDN GTD for Setup Message
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NFAS with D-Channel Backup
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PRI Backhaul and IUA Support Using SCTP
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QSIG Support for Tcl IVR 2.0
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Implementing T1 CAS for VoIP
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Implementing FCCS (NEC Fusion)
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Digital J1 Voice Interface Card
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Table Of Contents
Integrated Voice and Data WAN on T1/E1 Interfaces
High-Complexity Voice Compression
Network Clock Source and Participation
How to Configure Integrated Voice and Data WAN on T1/E1 Interfaces Using the AIM-ATM-VOICE-30 Module
Configuring Network Clock Source and Participation
Configuring Clock Source Internal
Configuring the Clock-Source Line
Configuring the AIM-ATM-VOICE-30 Card for High-Complexity Codecs and Time Slots
Configuring Integrated Voice and Serial Data WAN
Verifying Integrated Voice and Serial Data WAN
Single-Serial-Data WAN: Example
Multiple-Serial-Data WAN: Example
High-Complexity Codecs and Network Clock: Example
Integrated Voice and Data WAN on T1/E1 Interfaces
This chapter describes how to implement the Integrated Voice and Data WAN on T1/E1 Interfaces with the AIM-ATM-VOICE-30 Module feature. This card provides a voice-processing termination solution at a density of 30 VoIP or VoFR voice or fax channels, while not consuming a network-module slot. It provides the following benefits:
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Integrated voice and serial data WAN functionality on the same T1/E1 interface or on the second port of the voice/WAN interface cards (VWIC)
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The serial interface supports the following features:
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Feature History for Integrated Voice and Data WAN on T1/E1 Interfaces with the AIM-ATM-VOICE-30 Module
Finding Support Information for Platforms and Cisco IOS Software Images
Use Cisco Feature Navigator to find information about platform support and Cisco IOS software image support. Access Cisco Feature Navigator at http://www.cisco.com/go/fn. You must have an account on Cisco.com. If you do not have an account or have forgotten your username or password, click Cancel at the login dialog box and follow the instructions that appear.
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For a list of references cited in this chapter, see the "Additional References" section.
Contents
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Prerequisites for Configuring Integrated Voice and Data WAN on T1/E1 Interfaces Using the AIM-ATM-VOICE-30 Module
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Cisco 2600 series and Cisco 2600XM
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Cisco 3660, Cisco 3725, and Cisco 3745
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Restrictions for Configuring Integrated Voice and Data WAN on T1/E1 Interfaces Using the AIM-ATM-VOICE-30 Module
Restrictions are described in the Restrictions for Configuring ISDN Voice Interfaces, page 4. In addition, the following apply.
Cisco 2600 Series Restrictions
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Other Platform Restrictions
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Hardware Restrictions
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Information About Integrated Voice and Data WAN on T1/E1 Interfaces Using the AIM-ATM-VOICE-30 Module
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To implement this feature, you should understand the following concepts:
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AIM-ATM-VOICE-30 Module
The AIM-ATM-VOICE-30 module is an advanced integration module capable of supporting up to 30 voice or fax channels when used in a supported platform with one of the T1/E1 voice/WAN interface cards (such as VWIC-1T1). The module includes DSPs that are used for a number of voice-processing tasks such as voice compression and decompression, voice-activity detection or silence suppression, and PBX or PSTN signaling protocols.
The module supports VoIP, VoFR, and VoIP over ATM (VoATM) while leaving the router network-module slot open for other functions such as asynchronous or synchronous serial concentration. For additional information, see AIM-ATM, AIM-VOICE-30, and AIM-ATM-VOICE-30 on the Cisco 2600 Series and Cisco 3660.
Integrated Voice and Data WAN
This feature adds integrated voice and serial-data WAN service on the same T1 or E1 interface or VWIC on AIM-ATM-VOICE-30 DSP cards. This enhancement enables you to use some DS0 channels for serial-data Frame Relay, high-level data link control (HDLC), and Point-to-Point Protocol (PPP), for example, while the remaining T1 or E1channels can be used for voice channel-associated signaling (CAS) or PRI.
Figure 7 shows a typical application scenario in which 16 channels of a T1 line are used for voice and 4 channels are used for Frame relay data. Integrating voice and serial data on the same T1 or E1 line minimizes the recurring cost of providing PSTN and data WAN access. In particular, integrated access provides a number of voice DS0s (for PSTN access) and a Frame Relay link on the same T1.
Figure 7 Typical Application Scenario
Figure 8 shows a typical deployment scenario in which port 0 of the VWIC-MFT module is connected to an integrated voice and data service provider with 20 channels. These 20 channels are used for voice (running CAS or PRI); the remaining four channels are used for serial data (running Frame Relay). Using this type of configuration, you can take advantage of the integrated service offered by a service provider and minimize the cost of leasing and supporting T1 or E1 lines.
Figure 8 Typical Feature Deployment
High-Complexity Voice Compression
This feature adds high-complexity G.723, G.728, and GSM-FR codec support to the AIM-ATM-VOICE-30 module so that the DSP can support both medium- and high-complexity codecs running separately. Each DSP core can process up to two voice channels, so each module can support up to 16 voice channels when running a high-complexity DSP firmware image.
The following high-complexity codecs are supported:
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The following medium-complexity codecs are supported in high-complexity mode:
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Network Clock Source and Participation
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Packet voice and video are sensitive to time delays. To prevent mismatches and data slips, you must synchronize data flows to a single clock source, known as the network clock. When a network clock is configured on a gateway, the router is externally clocked by one T1 or E1 port and passes that clock signal across the backplane to another T1 or E1 port on another WIC or network module slot. Use of a network clock on a gateway is configured by naming the network modules and interface cards that are participating in network clocking, and then selecting a port to act as the source of timing for the network clock.
The network clock provides timing from the source, through the port to the AIM, and then out to all participating router slots. The number of supported AIM slots is as follows:
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The network clock source must be derived from an external source—for example, PSTN, PBX, or ATM network. For digital voice ports, the clock source command in configures the type of timing (internal or from the line) for each port that you designate as a primary source or backup for the network clock.
This command allows maximum flexibility. For example, on a router with a multiflex trunk VWIC connected to an ATM network and a digital T1/E1 packet voice trunk network module connected to a PBX, you can set up network clocking in any of three ways:
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How to Configure Integrated Voice and Data WAN on T1/E1 Interfaces Using the AIM-ATM-VOICE-30 Module
This section contains the following procedures:
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Configuring Network Clock Source and Participation
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Configuring Clock Source Internal
To configure a clock with an internal source, perform the following steps.
Prerequisites
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SUMMARY STEPS
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DETAILED STEPS
Configuring the Clock-Source Line
To configure the clock-source line, perform the following steps.
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mode cas
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ds0-group timeslots
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pri-group timeslots
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Configuring the AIM-ATM-VOICE-30 Card for High-Complexity Codecs and Time Slots
To configure the AIM-ATM-VOICE-30 card for high-complexity codecs and time slots, perform the following steps.
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Configuring Integrated Voice and Serial Data WAN
To configure integrated voice and serial data WAN, perform the following steps.
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pri-group timeslots
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Verifying Integrated Voice and Serial Data WAN
To verify integrated voice and serial data WAN, perform the following steps (listed alphabetically).
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Step 1
Use this command to display the configuration on the serial interface
Router# show controllers serial 0/0:3Interface Serial0/0:3 is upHardware is ATM AIM SERIALhwidb=0x82C1B768, sardb=0x826404A4slot 0, unit 0, subunit 0Current (mxt5100_t)sardb:Ind_Q(0x3D53580), Ind_Q_idx(695), Ind_Q_size(30000)Cmd_Q(0x3D4E720), Cmd_Q_idx(359), Cmd_Q_size(20000)Inpool(0x3B9E1A0), Inpool_size(4096)Outpool(0x3D1B080), Outpool_size(4096)Localpool(0x3D20000), Localpool_size(256)StorBlk(0x3BA7000), host_blk(0x3BA4840), em_blk(0x3BA4900)tx_buf_desc(0x3D476A0), tx_free_desc_idx (1023)num_fallback(0)MXT5100 Port Info:Port Number (4), Port ID (0xE05)Interface Number (0), Interface ID (0xF5E0)Port Type 2, Port Open Status SUCCESSHDLC channels opened(1)Port counters:Tx Packets:50686, Rx Packets:42864Tx Bytes:0, Rx Bytes:0Discards:No Resource:0, Protocol Errors 4MXT5100 Channel Info:HDLC Channel Info (0):Chan_ID (0xF25), Open Status SUCCESStx_limited=0(8)Step 2
Use this command to display the configuration on the serial interface.
Router# show interface serial 0/0:3Serial0/0:3 is up, line protocol is upHardware is ATM AIM SERIALInternet address is 20.0.0.1/16MTU 1500 bytes, BW 64 Kbit, DLY 20000 usec,reliability 255/255, txload 1/255, rxload 1/255Encapsulation PPP, loopback not setLCP OpenOpen:IPCP, CDPCPLast input 00:00:09, output 00:00:09, output hang neverLast clearing of "show interface" counters 18:36:25Input queue:0/75/0/0 (size/max/drops/flushes); Total output drops:0Queueing strategy:weighted fairOutput queue:0/1000/64/0 (size/max total/threshold/drops)Conversations 0/1/256 (active/max active/max total)Reserved Conversations 0/0 (allocated/max allocated)Available Bandwidth 48 kilobits/sec5 minute input rate 0 bits/sec, 0 packets/sec5 minute output rate 0 bits/sec, 0 packets/sec6696 packets input, 446400 bytes, 0 no bufferReceived 0 broadcasts, 0 runts, 0 giants, 0 throttles0 input errors, 0 CRC, 0 frame, 0 overrun, 0 ignored, 0 abort6697 packets output, 460924 bytes, 0 underruns0 output errors, 0 collisions, 0 interface resets0 output buffer failures, 0 output buffers swapped out0 carrier transitionsTimeslot(s) Used:4, Transmitter delay is 0 flagsStep 3
Use this command to display the status of all ISDN interfaces, including active layers, timer information, and switch-type settings.
Step 4
Use this command to display the current chosen clock and the list of all sources of network clocks according to their priority.
Router# show network-clocksNetwork Clock Configuration---------------------------Priority Clock Source Clock State Clock Type3 E1 6/2 GOOD E15 T1 2/0 GOOD T19 Backplane Good PLLCurrent Primary Clock Source---------------------------Priority Clock Source Clock State Clock Type3 E1 6/2 GOOD E1Step 5
Use this command to display the basic router configuration.
Step 6
Use this command to display the voice DSP configuration.
Router# show voice dspDSP DSP DSPWARE CURR BOOT PAK TX/RXTYPE NUM CH CODEC VERSION STATE STATE RST AI VOICEPORT TS ABORT PACK COUNT==== === == ======== ======= ===== ======= === == ========= == ===== ============C5421000 00 {high} 3.6.14 IDLE idle 0 0 0/0:0 01 0 5313/1516
Configuration Examples for Integrated Voice and Data WAN on T1/E1 Interfaces Using the AIM-ATM-VOICE-30 Module
This section contains the following configuration examples:
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Single-Serial-Data WAN: Example
This example shows the configuration of a router whose E1 (0/0) controller is used for integrated voice and serial data. Note that E1 timeslots 1 to 11 are configured for serial data and E1 timeslots 12 to 31 are configured for PRI voice. Also note that interface Serial0/0:1 is the logical interface for E1 timeslots 1 to 11 and interface Serial0/0:15 is the logical interface for E1 timeslots 12 to 31.
Router# show running-configBuilding configuration...Current configuration : 1356 bytes!version 12.2service timestamps debug datetime msecservice timestamps log datetime msecno service password-encryption!hostname "buick-hc"!network-clock-participate wic 0network-clock-participate aim 0network-clock-select 1 E1 0/0voice-card 5dspfarm!ip subnet-zero!!isdn switch-type primary-qsigno voice hpi capture bufferno voice hpi capture destination!mta receive maximum-recipients 0!controller E1 0/0channel-group 1 timeslots 1-11 aim 0pri-group timeslots 12-31!controller E1 0/1!controller E1 0/3controller E1 0/2!interface FastEthernet0/0no ip addressshutdownduplex autospeed auto!interface Serial0/0:1ip address 175.0.0.1 255.0.0.0encapsulation ppp!interface Serial0/0:15no ip addressno logging event link-statusisdn switch-type primary-qsigisdn incoming-voice voiceno cdp enable!interface FastEthernet0/1ip address 1.10.10.1 255.0.0.0speed 100full-duplex!ip http serverip classless!call rsvp-sync!voice-port 0/0:15!mgcp profile default!dial-peer cor custom!dial-peer voice 40 potsdestination-pattern 427....direct-inward-dialport 0/0:15prefix 427!dial-peer voice 400 voipdestination-pattern 525....session target ipv4:1.10.10.2!line con 0exec-timeout 0 0line aux 0line vty 0 4login!endMultiple-Serial-Data WAN: Example
This example shows the configuration of a router whose E1 (0/0) controller is used voice and serial data traffic and whose E1 (0/1) controller is used completely for data traffic.
Router# show running-configBuilding configuration...Current configuration : 1492 bytes!version 12.2service timestamps debug datetime msecservice timestamps log datetime msecno service password-encryption!hostname "buick-hc"!network-clock-participate wic 0network-clock-participate aim 0network-clock-select 1 E1 0/0voice-card 5dspfarm!ip subnet-zero!isdn switch-type primary-qsig!no voice hpi capture bufferno voice hpi capture destination!mta receive maximum-recipients 0!controller E1 0/0channel-group 1 timeslots 1-11 aim 0pri-group timeslots 12-31!controller E1 0/1channel-group 1 timeslots 1-31 aim 0!controller E1 0/3!controller E1 0/2!interface FastEthernet0/0no ip addressshutdownduplex autospeed auto!interface Serial0/0:1ip address 172.0.0.1 255.0.0.0encapsulation ppp!interface Serial0/0:15no ip addressno logging event link-statusisdn switch-type primary-qsigisdn incoming-voice voiceno cdp enable!interface FastEthernet0/1ip address 10.10.10.1 255.0.0.0speed 100full-duplex!interface Serial0/1:1ip address 175.5.0.1 255.0.0.0encapsulation frame-relay!ip http serverip classless!call rsvp-sync!voice-port 0/0:15!mgcp profile default!dial-peer cor custom!dial-peer voice 40 potsdestination-pattern 427....direct-inward-dialport 0/0:15prefix 427!dial-peer voice 400 voipdestination-pattern 525....session target ipv4:10.10.10.2!line con 0exec-timeout 0 0line aux 0line vty 0 4login!endHigh-Complexity Codecs and Network Clock: Example
This example shows the configuration of a router in which the WIC at slot 0 and AIM at slot 0 are configured to received clock from the network (see the lines network-clock-participate). Also note that E1 0/0 controller is the source of the network clock (see the line network-clock-select). This example also shows that the voice card in slot 5 uses a high-complexity codec.
Router# show running-configBuilding configuration...Current configuration : 1276 bytes!version 12.2service timestamps debug datetime msecservice timestamps log datetime msecno service password-encryption!hostname "router-hc"!network-clock-participate wic 0network-clock-participate aim 0network-clock-select 1 E1 0/0voice-card 5codec complexity highdspfarm!ip subnet-zero!isdn switch-type primary-qsigno voice hpi capture bufferno voice hpi capture destination!mta receive maximum-recipients 0!controller E1 0/0pri-group timeslots 1-16!controller E1 0/1!controller E1 0/3!controller E1 0/2!interface FastEthernet0/0no ip addressshutdownduplex autospeed auto!interface Serial0/0:15no ip addressno logging event link-statusisdn switch-type primary-qsigisdn incoming-voice voiceno cdp enable!interface FastEthernet0/1ip address 1.10.10.1 255.0.0.0speed 100full-duplex!ip http serverip classless!call rsvp-sync!voice-port 0/0:15!mgcp profile default!dial-peer cor custom!dial-peer voice 40 potsdestination-pattern 427....direct-inward-dialport 0/0:15prefix 427!dial-peer voice 400 voipdestination-pattern 525....session target ipv4:0.10.10.2!line con 0exec-timeout 0 0line aux 0line vty 0 4login!endAdditional References
General ISDN References
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References Mentioned in This Chapter
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