Overview
Channelized interfaces allow service providers to customize bandwidth to satisfy the needs of their customers. Whether the subscriber needs DS0, T1, fractional T1, E1, fractional E1, T3, STM1, OC3, or OC12 service, a channelized PIC can provide the necessary bandwidth today and can be reconfigured to support the customer's expanding network tomorrow. Standard channelized interfaces have been available on Juniper Networks routing platforms since JUNOS Release 3.4. These original channelized PICs for Juniper Networks M-series routers are available in the following models:
- 1-port Channelized OC12 PIC
- 10-port Channelized E1 PIC
- 1-port Channelized STM1 PIC
- 4-port Channelized DS3 PIC
- 1-port and 2-port multichannel Channelized DS3 PIC
These original channelized interfaces provide a single level of channelization and require configuration at both the [edit chassis] and the [edit interfaces] hierarchy levels. Most configuration options must be set on channel 0 and they apply to all channels on these channelized PICs.
The new channelized PICs with intelligent queuing offer several advantages over the original channelized PICs:
- Complete configuration tasks for channelized IQ interfaces are now centralized at the
[edit interfaces]hierarchy level. - Multiple levels of channelization are now possible with channelized IQ interfaces. For example, a channelized OC12 IQ interface can be divided into channelized OC1 interfaces, then subdivided into channelized T1 interfaces, and further split into NxDS0 channels.
- You can now configure interface statements, such as
clocking, on individual channels rather than configuring them on channel 0 for all channels at the same hierarchy level. - Class-of-service processing now occurs on the PIC for channelized IQ interfaces rather than in the FPC.
Channelized PICs with intelligent queuing come in the following model types:
- 1-port Channelized OC12 IQ PIC
- 1-port Channelized OC3 PIC
- 4-port Channelized DS3 IQ PIC
- 10-port Channelized T1 IQ PIC
- 10-port Channelized E1 IQ PIC
- 1-port Channelized STM1 IQ PIC
To determine which PIC is installed, issue the show chassis hardware command:
user@RouterA> show chassis hardware
Hardware inventory:
Item Version Part number Serial number Description
Chassis 20070 M160
Midplane REV 03 710-001245 AB4123
FPM CMB REV 02 710-001642 AB3266
FPM Display REV 02 710-001647 AB3038
CIP REV 04 710-001593 AB3276
PEM 0 Rev 03 740-001243 KM28410 DC
PEM 1 Rev 03 740-001243 LF21558 Power Entry Module
PCG 0 REV 03 710-001568 AB3006
PCG 1 REV 02 710-001568 AB2992
Routing Engine 0 20000005dfae3a01 RE-2.0
MCS 0 REV 04 710-001226 AB3208
MCS 1 REV 04 710-001226 AB3212
SFM 0 SPP REV 06 710-001228 AB3103
SFM 0 SPR REV 01 710-002189 AB2936 Internet Processor II
SFM 1 SPP REV 07 710-001228 AG2634
SFM 1 SPR REV 03 710-002189 AE3503 Internet Processor II
SFM 2 SPP REV 06 710-001228 AB2976
SFM 2 SPR REV 01 710-002189 AB2938 Internet Processor II
SFM 3 SPP REV 06 710-001228 AB5826
SFM 3 SPR REV 01 710-002189 AB2917 Internet Processor II
FPC 0 REV 03 710-003947 HE0614 E-FPC Type 1
CPU REV 01 710-004600 AT3217
PIC 0 REV 03 750-005636 BE1826 4x CHDS3 IQ
# This is the Channelized DS3 IQ PIC.
PIC 1 REV 07 750-003846 HG5572 1x 800M Crypto
PIC 2 REV 01 750-004507 BA5341 10x CE1-NxDS0
PIC 3 REV 06 750-003009 AM6929 4x CT3
#This is the original Channelized T3 PIC.
FPC 1 REV 03 710-003309 AD9434 E-FPC Type 2
CPU REV 05 710-001217 AH2707
PIC 2 REV 05 750-001900 AD5738 1x OC-48 SONET, SMSR
PIC 3 REV 04 750-003737 BC1106 4x G/E, 1000 BASE-SX
When you configure channelized IQ interfaces, keep in mind these rules of thumb:
- You normally configure media-related statements and options at the physical interface level (also known as the controller level). This level is indicated by the
[edit interfaces cxx-fpc/pic/port]hierarchy level. - You should always configure HDLC-related statements (for example,
bytes,fcs,idle-cycle-flag,mtu,receive-bucket,start-end-flag, andtransmit-bucket) and logical interfaces (for example,[edit interfacesinterface-nameunitunit-number]) on end channels such as DS0 and T1. Never configure these statements at the controller level. - Pay attention to the channel numbering rules:
- OC3 data channels configured on channelized OC12 IQ interfaces are numbered from 1 to 4.
- T3 channels configured on a channelized OC12 IQ or channelized OC3 IQ interface are numbered from 1 to 12.
- T1 channels on a channelized OC12 IQ, channelized OC3 IQ, channelized DS3 IQ, or channelized T1 IQ interface are numbered from 1 to 28.
- E1 channels configured on a channelized STM1 IQ interface are numbered from 1 to 63.
- NxDS0 time slots configured on a channelized OC12 IQ, channelized OC3 IQ, channelized DS3 IQ, or channelized T1 IQ interface are numbered from 1 to 24.
- NxDS0 time slots configured on either a channelized STM1 IQ interface or channelized E1 IQ interface are numbered from 2 to 32 (
1is reserved).
- You can configure Automatic Protection Switching (APS) on channelized OC12 IQ interfaces and Multiplex Section Protection (MSP) on channelized STM1 IQ interfaces. The JUNOS implementation of APS and MSP allows you to protect against circuit failures between a SONET/SDH add/drop multiplexer (ADM) and one or more routers, and between multiple interfaces in the same router. When a device fails, a backup device immediately takes over.
You configure APS and MSP at the controller level only. To configure, include the working-circuit and protect-circuit statements at the [edit interfaces coc12-fpc/pic/port sonet-options aps] or [edit interfaces coc3-fpc/pic/port sonet-options aps] hierarchy level for APS and the [edit interfaces cstm1-fpc/pic/port sonet-options aps] hierarchy level for MSP.
When you enable the controller-level interface as the working circuit, all partitions under the working circuit are also enabled. This is the default behavior even when APS or MSP is not configured. When the backup circuit interface is disabled, all partitions under this protected circuit are also disabled. If the working circuit fails, the interfaces are switched: The working circuit and all its partitions are disabled, and the protect circuit and all its partitions are enabled. You can verify this behavior by entering the show interfaces controller command. The disabled interfaces are shown as "Admin down" and the enabled interfaces are shown as "Admin up".
- You can delete several channelized interfaces simultaneously by using a single command and regular expressions. To delete sequential channelized interfaces, issue the
wildcardcommand with thedeleteoption at the[edit]hierarchy level. Specify the hierarchy level and the channelized interfaces to be summarized with a regular expression. For example, to delete channelized interfaces in the range ofds-0/0/0:0:0throughds-0/0/0:0:23, issue the command:
user@router# wildcard delete interfaces ds-0/0/0:0:.*
- If you use Frame Relay encapsulation on a channelized interface, see Table 5 for the maximum number of data-link connection identifiers (DLCIs) per channel that you can configure at each channel level for various channelized PICs.
NOTE: The actual number of DLCIs you can configure for each channel is determined by the capabilities of your system, such as the number and type of PICs installed. If the number of DLCIs in the configuration exceeds the capabilities of your system, the router might not be able to support the maximum DLCI values shown in Table 5. To determine the capabilities of your system, contact Juniper Networks customer support.
- In JUNOS Release 6.2 and later, additional Frame Relay encapsulation types on physical interfaces and channels of channelized IQ interfaces are available:
- Extended Frame Relay CCC—Allows you to assign any DLCI number from 1 to 1022 on Frame Relay CCC logical interfaces. To configure, include the
extended-frame-relay-cccstatement at the[edit interfacesinterface-nameencapsulation]hierarchy level. - Extended Frame Relay TCC—Allows you to assign any DLCI number from 1 to 1022 on Frame Relay TCC logical interfaces. To configure, include the
extended-frame-relay-tccstatement at the[edit interfacesinterface-nameencapsulation]hierarchy level. - Flexible Frame Relay—Allows you to configure any DLCI number from 1 to 1022 and any combination of Frame Relay encapsulation types on logical interfaces. To configure, include the
flexible-frame-relaystatement at the[edit interfacesinterface-nameencapsulation]hierarchy level.
- When you configure clocking, bit error rate testing (BERT), C-bit parity, and loopback statements on T3, T1, or DS0 channels on channelized IQ interfaces, you must follow these guidelines:
- If you include the statements at both the
[edit interfaces ct3-fpc/pic/port:channelt3-options]and[edit interfaces t3-fpc/pic/port:channelt3-options]hierarchy levels, channelized T3-level statements are operational and T3-level statements are ignored. - If you include the statements at both the
[edit interfaces ct3-fpc/pic/port:channelt3-options]and[edit interfaces t1-fpc/pic/port:channelt1-options]hierarchy levels, the channelized T3-level statements are operational for the T3 connections and the T1-level statements are operational for the T1 connections. - Because DS0 channels do not have a valid clocking option, you must configure clocking for all NxDS0s at the
[edit interfaces ct1-fpc/pic/port:channelt1-options]hierarchy level. - You configure BERT at the
[edit interfaces ct3-fpc/pic/port:channelt3-options]hierarchy level or on any partitioned subchannel of the channelized T3 interface. There are 12 BERT patterns available for DS0 channels and 28 BERT patterns for T1, channelized T1, T3, and channelized T3 channels within channelized IQ interfaces. - For Channelized OC3 IQ PICs, if you need a remote loopback on a far-end NxDS0 interface, and you are running a BERT test from the local NxDS0 interface, you must configure a remote loopback on the associated channelized T1 interface (
ct1) for the far-end routing platform. To do this, include theloopback remotestatement at the[edit interfaces ct1-fpc/pic/port t1-options]hierarchy level. - You can configure loopbacks at the
[edit interfaces ct3-fpc/pic/port:channelt3-options]hierarchy level. Local loopbacks recirculate framing information within the local router. Remote loopbacks resend entire frames back to the remote sender. A new loopback called a payload loopback is similar to a remote loopback, but it resends only the data portion of a frame back to the remote sender. - You can configure C-bit parity at the
[edit interfaces ct3-fpc/pic/port:channelt3-options]hierarchy level or on any partitioned subchannel of the channelized T3 interface.
- In JUNOS Release 7.5 and later, you can increase the delay buffer for E1, T1, and NxDS0 channels on all Channelized IQ PICs (except the Channelized OC12 IQ PIC) by including the
q-pic-large-bufferstatement at the[edit chassis fpcfpc-slotpicpic-slot]hierarchy level. By doing so, you enable the slower interfaces to handle bursts of traffic from faster upstream neighbors. As a result, any class-of-service (CoS) scheduler that you apply to an interface will inherit the larger delay buffer and the buffer is shared across all four CoS queues. For more information about increasing the delay buffer, see the JUNOS Class of Service Configuration Guide.NOTE: If you configure the
q-pic-large-bufferstatement and APS in a multirouter topology, the Channelized IQ PIC resets and causes an APS switchover.
For more details on channelized interface options, see the JUNOS Network Interfaces Configuration Guide.