- About Cisco IOS Documentation
- Chapter 1, Overview
- Chapter 2, CTC Operations
- Chapter 3, Initial Configuration
- Chapter 4, Configuring Interfaces
- Chapter 5, Configuring POS
- Chapter 6, Configuring Bridges
- Chapter 7, Configuring STP and RSTP
- Chapter 8, Configuring VLANs
- Chapter 9, Configuring IEEE 802.1Q and Layer 2 Protocol Tunneling
- Chapter 10, Configuring Link Aggregation
- Chapter 11, Configuring Networking Protocols
- Chapter 12, Configuring IRB
- Chapter 13, Configuring VRF Lite
- Chapter 14, Configuring Quality of Service
- Chapter 15, Configuring the Switching Database Manager
- Chapter 16, Configuring Access Control Lists
- Chapter 17, Configuring Resilient Packet Ring
- Chapter 18, Configuring Ethernet over MLPS
- Chapter 19, POS on ONS Ethernet Cards
- Chapter 20, E-Series and G-Series Ethernet Operation
- Chapter 21, CE-100T-8 Ethernet Operation
- Chapter 22, Configuring RMON
- Chapter 23, Configuring SNMP
- Appendix A, Command Reference
- Appendix B, Unsupported CLI Commands
- Appendix C, Using Technical Support
Configuring POS
This chapter describes advanced packet-over-SONET/SDH (POS) interface configuration for the ML-Series card. Basic POS interface configuration is included in "Configuring Interfaces." For more information about the Cisco IOS commands used in this chapter, refer to the Cisco IOS Command Reference publication. POS operation on ONS Ethernet cards, including the ML-Series card, is described in "POS on ONS Ethernet Cards."
This chapter contains the following major sections:
POS on the ML-Series Card
Ethernet and IP data packets need to be framed and encapsulated into SONET/SDH frames for transport across the SONET/SDH network. This framing and encapsulation process is known as POS and is done in the ML-Series card. "POS on ONS Ethernet Cards," explains POS in greater detail.
The ML-Series card takes the standard Ethernet ports on the front of the card and the virtual POS ports and includes them all as switch ports. Under Cisco IOS, the POS port is an interface similar to the other Ethernet interfaces on the ML-Series card. It is usually used as a trunk port. Many standard Cisco IOS features, such as IEEE 802.1 Q VLAN configuration, are configured on the POS interface in the same manner as on a standard Ethernet interface. Other features and configurations are done strictly on the POS interface. The configuration of features limited to POS ports is shown in this chapter.
ML-Series SONET and SDH Circuit Sizes
SONET is an American National Standards Institute (ANSI) standard (T1.1051988) for optical digital transmission at hierarchical rates from 51.840 Mbps (STS-1) to 2.488 Gbps (STS-48) and greater. SDH is the international standard for optical digital transmission at hierarchical rates from 155.520 Mbps (STM-1) to 2.488 Gbps (STM-16) and greater.
Both SONET and SDH are based on a structure that has a basic frame and speed. The frame format used by SONET is the synchronous transport signal (STS), with STS-1 being the base level signal at 51.84 Mbps. A STS-1 frame can be carried in an OC-1 signal. The frame format used by SDH is the synchronous transport module (STM), with STM-1 being the base level signal at 155.52 Mbps. A STM-1 frame can be carried in an OC-3 signal.
Both SONET and SDH have a hierarchy of signaling speeds. Multiple lower level signals can be multiplexed together to form higher level signals. For example, three STS-1 signals can be multiplexed together to form a STS-3 signal, and four STM-1 signals can be multiplexed together to form a STM-4 signal.
SONET circuit sizes are defined as STS-n, where n is a multiple of 51.84 Mbps and n is equal to or greater than 1. SDH circuit sizes are defined as STM-n, where n is a multiple of 155.52 Mbps and n is equal to or greater than 0. Table 5-1 shows STS and STM line rate equivalents.
|
SDH Circuit Size |
Line Rate in Mbps |
---|---|---|
STS-1 (OC-1) |
VC-31 |
52 Mbps |
STS-3c (OC-3) |
STM-1 (VC4) |
156 Mbps |
STS-6c (OC-6) |
STM-2 (VC4-2c) |
311 Mbps |
STS-9c (OC-9) |
STM-3 (VC4-3c) |
466 Mbps |
STS-12c (OC-12) |
STM-4 (VC4-4c) |
622 Mbps |
STS-24c (OC-24) |
STM-8 (VC4-8c) |
1244 Mbps (1.24 Gbps) |
1 VC-3 circuit support requires an XCVL card to be installed. |
For step-by-step instructions on configuring an ML-Series card SONET STS circuit, refer to the "Create Circuits and VT Tunnels" chapter of the Cisco ONS 15454 Procedure Guide. For step-by-step instructions on configuring an ML-Series card SDH STM circuit, refer to the "Create Circuits and Tunnels" chapter of the Cisco ONS 15454 SDH Procedure Guide.
VCAT
VCAT significantly improves the efficiency of data transport over SONET/SDH by grouping the synchronous payload envelopes (SPEs) of SONET/SDH frames in a nonconsecutive manner into VCAT groups. VCAT group circuit bandwidth is divided into smaller circuits called VCAT members. The individual members act as independent circuits.
Intermediate nodes treat the VCAT members as normal circuits that are independently routed and protected by the SONET/SDH network. At the terminating nodes, these member circuits are multiplexed into a contiguous stream of data. VCAT avoids the SONET/SDH bandwidth fragmentation problem and allows finer granularity for provisioning of bandwidth services.
The ONS 15454 SONET and ONS 15454 SDH ML-Series card VCAT circuits must also be routed over common fiber and be both bidirectional and symmetric. Only high order (HO) VCAT circuits are supported. The ML-Series card supports a maximum of two VCAT groups, with each group corresponding to one of the POS ports. Each VCAT group can contain two circuit members. Table 5-2 shows supported VCAT circuit sizes for the ML-Series.
|
|
---|---|
STS-1-2v |
VC-3-2v |
STS-3c-2v |
VC-4-2v |
STS-12c-2v |
VC-4-4c-2v |
A VCAT circuit originating from an ML-Series card must terminate on another ML-Series card or a CE-Series card. Table 5-3 shows ML-Series card supported VCAT circuit sizes.
For step-by-step instructions on configuring an ML-Series card SONET VCAT circuit, refer to the "Create Circuits and VT Tunnels" chapter of the Cisco ONS 15454 Procedure Guide. For step-by-step instructions on configuring an ML-Series card SDH VCAT circuit, refer to the "Create Circuits and Tunnels" chapter of the Cisco ONS 15454 SDH Procedure Guide. For more general information on VCAT circuits, refer to the "Circuits and Tunnels" chapter of the Cisco ONS 15454 Reference Manual or the Cisco ONS 15454 SDH Reference Manual.
Note ML-Series card POS interfaces normally send PDI-P to the far-end when the POS link goes down or RPR wraps. ML-Series card POS interfaces do not send PDI-P to the far-end when PDI-P is detected, when RDI-P is being sent to the far-end or when the only defects detected are GFP LFD, GFP CSF, VCAT LOM or VCAT SQM.
SW-LCAS
A link capacity adjustment scheme (LCAS) increases VCAT flexibility by allowing the dynamic reconfiguration of VCAT groups without interrupting the operation of noninvolved members. Software link capacity adjustment scheme (SW-LCAS) is the software implementation of a LCAS-type feature. SW-LCAS differs from LCAS because it is not errorless and uses a different handshaking mechanism.
SW-LCAS on the ML-Series cards allows the automatic addition or removal of a VCAT group member in the event of a failure or recovery on a two-fiber bidirectional line switched ring (BLSR). The protection mechanism software operates based on ML-Series card link events. SW-LCAS allows service providers to configure VCAT member circuits on the ML-Series as protection channel access (PCA) circuits. This PCA traffic is dropped in the event of a protection switch, but is suitable for excess or noncommited traffic and can double the total available bandwidth on the circuit.
For step-by-step instructions on configuring SW-LCAS, refer to the "Create Circuits and VT Tunnels" chapter of the Cisco ONS 15454 Procedure Guide or the "Create Circuits and Tunnels" chapter of the Cisco ONS 15454 SDH Procedure Guide. For more general information on SW-LCAS, refer to the "Circuits and Tunnels" chapter of the Cisco ONS 15454 Reference Manual or the Cisco ONS 15454 SDH Reference Manual.
Framing Mode, Encapsulation, and CRC Support
The ML-Series cards on the ONS 15454 and ONS 15454 SDH support two modes of the POS framing mechanism, GFP-F framing and HDLC framing (default). The framing mode, encapsulation, and CRC size on source and destination POS ports must match for a POS circuit to function properly. "POS on ONS Ethernet Cards," explains the framing mechanisms, encapsulations, and cyclic redundancy check (CRC) bit sizes in detail.
Supported encapsulation and CRC sizes for the framing types are detailed in Table 5-4.
Note ML-Series card POS interfaces normally send PDI-P to the far-end when the POS link goes down or RPR wraps. ML-Series card POS interfaces do not send PDI-P to the far-end when PDI-P is detected, when RDI-P is being sent to the far-end or when the only defects detected are GFP LFD, GFP CSF, VCAT LOM or VCAT SQM.
Configuring Framing Mode
You configure framing mode on an ML-Series card only through CTC. For more information on configuring framing mode in CTC, see "CTC Operations."
Configuring Encapsulation Type
To configure the encapsulation type for a ML-Series card, perform the following steps beginning in global configuration mode:
Configuring CRC Size in HDLC Framing
To configure additional properties to match those of the interface at the far end, perform the following steps, beginning in global configuration mode:
Setting the MTU Size
To set the maximum transmission unit (MTU) size, perform the following steps, beginning in global configuration mode:
|
|
|
---|---|---|
Step 1 |
Router(config)# interface pos number |
Activates interface configuration mode to configure the POS interface. |
Step 2 |
Router(config-if)# mtu bytes
|
Configures the MTU size up to a maximum of 9000 bytes. See Table 5-5 for default MTU sizes. |
Step 3 |
Router(config-if)# end |
Returns to the privileged EXEC mode. |
Step 4 |
Router# copy running-config startup-config |
(Optional) Saves configuration changes to NVRAM. |
Table 5-5 shows the default MTU sizes.
|
|
---|---|
LEX (default) |
1500 |
HDLC |
4470 |
PPP |
4470 |
Configuring Keep Alive Messages
To configure keep alive messages for the ML-Series card, perform the following steps beginning in global configuration mode:
SONET/SDH Alarms
The ML-Series cards report SONET/SDH alarms under both Cisco IOS and CTC/TL1. A number of path alarms are reported in the Cisco IOS console. Configuring Cisco IOS console alarm reporting has no effect on CTC alarm reporting. The "Configuring SONET/SDH Alarms" procedure specifies the alarms reported to the Cisco IOS console.
CTC/TL1 has sophisticated SONET/SDH alarm reporting capabilities. As a card in the ONS node, the ML-Series card reports alarms to CTC/TL-1 like any other ONS card. On the ONS 15454 SONET, the ML-Series card reports Telcordia GR-253 SONET alarms in the Alarms panel of CTC. For more information on alarms and alarm definitions, refer to the "Alarm Troubleshooting" chapter of the Cisco ONS 15454 Troubleshooting Guide, or the Cisco ONS 15454 SDH Troubleshooting Guide.
Configuring SONET/SDH Alarms
All SONET/SDH alarms appear by default But to provision the reporting of SONET/SDH alarms on the Cisco IOS CLI, perform the following steps beginning in global configuration mode:
To determine which alarms are reported on the POS interface and to display the bit error rate (BER) thresholds, use the show controllers pos command, as described in the "Monitoring and Verifying POS" section.
Note Cisco IOS alarm reporting commands apply only to the Cisco IOS CLI. SONET/SDH alarms reported to the TCC2/TCC2P are not affected.
Configuring SONET/SDH Delay Triggers
You can set path alarms listed as triggers to bring down the line protocol of the POS interface. When you configure the path alarms as triggers, you can also specify a delay for the triggers using the pos trigger delay command. You can set the delay from 200 to 2000 ms. If you do not specify a time interval, the default delay is set to 200 ms.
To configure path alarms as triggers and specify a delay, perform the following steps beginning in global configuration mode:
C2 Byte and Scrambling
One of the overhead bytes in the SONET/SDH frame is the C2 byte. The SONET/SDH standard defines the C2 byte as the path signal label. The purpose of this byte is to communicate the payload type being encapsulated by the SONET framing overhead (FOH). The C2 byte functions similarly to EtherType and Logical Link Control (LLC)/Subnetwork Access Protocol (SNAP) header fields on an Ethernet network; it allows a single interface to transport multiple payload types simultaneously. The C2 byte is not configurable. Table 5-6 provides C2 byte hex values.
Third-Party POS Interfaces C2 Byte and Scrambling Values
If a Cisco POS interface fails to come up when connected to a third-party device, confirm the scrambling and cyclic redundancy check (CRC) settings as well as the advertised value in the C2 byte. On routers from Juniper Networks, configuring RFC 2615 mode sets the following three parameters:
•Scrambling enabled
•C2 value of 0x16
•CRC-32
Previously, when scrambling was enabled, these third-party devices continued to use a C2 value of 0xCF, which did not properly reflect the scrambled payload.
Configuring SPE Scrambling
SPE scrambling is on by default. To configure POS SONET/SDH Payload (SPE) scrambling, perform the following steps, beginning in global configuration mode:
Monitoring and Verifying POS
The show controller pos [0 | 1] command (Example 5-1) outputs the receive and transmit values and the C2 value. Thus, changing the value on the local end does not change the value in the show controller command output.
Example 5-1 show controller pos [0 | 1] Command
ML_Series# sh controllers pos 0
Interface POS0
Hardware is Packet/Ethernet over Sonet
Framing Mode: HDLC
Concatenation: CCAT
Alarms reportable to CLI: PAIS PLOP PUNEQ PTIM PPLM ENCAP PRDI PPDI BER_SF_B3 BER_SD_B3 VCAT_OOU_TPT LOM SQM
Link state change defects: PAIS PLOP PUNEQ PTIM PPLM ENCAP PRDI PPDI BER_SF_B3
Link state change time : 200 (msec)
*************** Path ***************
Circuit state: IS
PAIS = 0 PLOP = 0 PRDI = 0 PTIM = 0
PPLM = 0 PUNEQ = 0 PPDI = 0 PTIU = 0
BER_SF_B3 = 0 BER_SD_B3 = 0 BIP(B3) = 0 REI = 0
NEWPTR = 0 PSE = 0 NSE = 0 ENCAP = 0
Active Alarms : PAIS
Demoted Alarms: None
Active Defects: PAIS
DOS FPGA channel number : 0
Starting STS (0 based) : 0
VT ID (if any) (0 based) : 255
Circuit size : STS-3c
RDI Mode : 1 bit
C2 (tx / rx) : 0x01 / 0x01
Framing : SONET
Path Trace
Mode : off
Transmit String :
Expected String :
Received String :
Buffer : Stable
Remote hostname :
Remote interface:
Remote IP addr :
B3 BER thresholds:
SFBER = 1e-4, SDBER = 1e-7
0 total input packets, 0 post-HDLC bytes
0 input short packets, 0 pre-HDLC bytes
0 input long packets , 0 input runt packets
0 input CRCerror packets , 0 input drop packets
0 input abort packets
0 input packets dropped by ucode
0 total output packets, 0 output pre-HDLC bytes
0 output post-HDLC bytes
Carrier delay is 200 msec
The show interface pos {0 | 1} command (Example 5-2) shows scrambling.
Example 5-2 show interface pos [0 | 1] Command
ML_Series# show interface pos 0
POS0 is administratively down, line protocol is down
Hardware is Packet/Ethernet over Sonet, address is 0011.2130.b340 (bia 0011.2130.b340)
MTU 1500 bytes, BW 145152 Kbit, DLY 100 usec,
reliability 255/255, txload 1/255, rxload 1/255
Encapsulation: Cisco-EoS-LEX, crc 32, loopback not set
Keepalive set (10 sec)
Scramble enabled
ARP type: ARPA, ARP Timeout 04:00:00
Last input 01:21:02, output never, output hang never
Last clearing of "show interface" counters 00:12:01
Input queue: 0/75/0/0 (size/max/drops/flushes); Total output drops: 0
Queueing strategy: fifo
Output queue: 0/40 (size/max)
5 minute input rate 0 bits/sec, 0 packets/sec
5 minute output rate 0 bits/sec, 0 packets/sec
0 packets input, 0 bytes
Received 0 broadcasts (0 IP multicast)
0 runts, 0 giants, 0 throttles
0 parity
0 input errors, 0 CRC, 0 frame, 0 overrun, 0 ignored
0 input packets with dribble condition detected
0 packets output, 0 bytes, 0 underruns
0 output errors, 0 applique, 0 interface resets
0 babbles, 0 late collision, 0 deferred
0 lost carrier, 0 no carrier
0 output buffer failures, 0 output buffers swapped out
0 carrier transitions
POS Configuration Examples
The following sections show ML-Series card POS configuration examples for connecting to other ONS Ethernet cards and POS-capable routers. These examples are only some of the ML-Series card configurations available to connect to other ONS Ethernet cards and POS-capable routers. For more specifics about the POS characteristics of ONS Ethernet cards, see "POS on ONS Ethernet Cards."
ML-Series Card to ML-Series Card
Figure 5-1 illustrates a POS configuration between two ONS 15454 or ONS 15454 SDH ML-Series cards.
Figure 5-1 ML-Series Card to ML-Series Card POS Configuration
Example 5-3 shows the code associated with the configuration of ML-Series card A.
Example 5-3 ML-Series Card A Configuration
hostname ML_Series_A
!
interface FastEthernet0
ip address 192.168.1.1 255.255.255.0
!
interface POS0
ip address 192.168.2.1 255.255.255.0
crc 32
pos flag c2 1
!
router ospf 1
log-adjacency-changes
network 192.168.1.0 0.0.0.255 area 0
network 192.168.2.0 0.0.0.255 area 0
Example 5-4 shows the code associated with the configuration of ML Series B.
Example 5-4 ML-Series Card B Configuration
hostname ML_Series_B
!
interface FastEthernet0
ip address 192.168.3.1 255.255.255.0
!
interface POS0
ip address 192.168.2.2 255.255.255.0
crc 32
pos flag c2 1
!
router ospf 1
log-adjacency-changes
network 192.168.2.0 0.0.0.255 area 0
network 192.168.3.0 0.0.0.255 area 0
!
ML-Series Card to Cisco 12000 GSR-Series Router
Figure 5-2 illustrates a POS configuration between an ML-Series card and a Cisco 12000 GSR-Series router. PPP/BCP encapsulation or Cisco HDLC encapsulation may be used for interoperation.
Figure 5-2 ML-Series Card to Cisco 12000 Series Gigabit Switch Router (GSR) POS Configuration
Example 5-5 shows the code associated with configuration of ML-Series card A.
Example 5-5 ML-Series Card A Configuration
hostname ML_Series_A
!
interface FastEthernet0
ip address 192.168.1.1 255.255.255.0
!
!
interface POS0
ip address 192.168.2.1 255.255.255.0
encapsulation ppp
crc 32
!
router ospf 1
log-adjacency-changes
network 192.168.1.0 0.0.0.255 area 0
network 192.168.2.0 0.0.0.255 area 0
Example 5-6 shows the code associated with the configuration of the GSR-12000.
Example 5-6 GSR-12000 Configuration
hostname GSR
!
interface FastEthernet1/0
ip address 192.168.3.1 255.255.255.0
!
interface POS2/0
ip address 192.168.2.2 255.255.255.0
crc 32
encapsulation PPP
pos scramble-atm
!
router ospf 1
log-adjacency-changes
network 192.168.2.0 0.0.0.255 area 0
network 192.168.3.0 0.0.0.255 area 0
!
The default encapsulation for the ML-Series card is LEX and the corresponding default MTU is 1500 bytes. When connecting to an external POS device, it is important to ensure that both the ML-Series switch and the external device uses the same configuration for the parameters listed in Table 5-7.
ML-Series Card to G-Series Card
Figure 5-3 illustrates a POS configuration between an ML-Series card and a G-Series card.
Figure 5-3 ML-Series Card to G-Series Card POS Configuration
Example 5-7 shows the code associated with the configuration of ML-Series card A.
Example 5-7 ML-Series Card A Configuration
hostname ML_Series_A
!
interface FastEthernet0
ip address 192.168.1.1 255.255.255.0
!
interface POS0
ip address 192.168.2.1 255.255.255.0
crc 32
!
router ospf 1
log-adjacency-changes
network 192.168.1.0 0.0.0.255 area 0
network 192.168.2.0 0.0.0.255 area 0
ML-Series Card to ONS 15310 ML-100T-8 Card
Figure 5-3 illustrates a POS configuration between an ML-Series card and an ONS 15310 ML-100T-8 card. For step-by-step circuit configuration procedures for the connected ML-100T-8 card, refer to the Cisco ONS 15310-CL and Cisco ONS 15310-MA Ethernet Card Software Feature and Configuration Guide.
Figure 5-4 ML-Series Card to ONS 15310 CE-100T-8 Card Configuration
Example 5-7 shows the code associated with the configuration of ML-Series card A.
Example 5-8 ML-Series Card A Configuration
hostname ML_Series_A
!
interface FastEthernet0
ip address 192.168.1.1 255.255.255.0
!
interface POS0
ip address 192.168.2.1 255.255.255.0
crc 32
!
router ospf 1
log-adjacency-changes
network 192.168.1.0 0.0.0.255 area 0
network 192.168.2.0 0.0.0.255 area 0
CTC/TL1 has sophisticated SONET/SDH alarm reporting capabilities. As a card in the ONS node, the ML-Series card reports alarms to CTC/TL-1 like any other ONS card. On the ONS 15454 SONET, the ML-Series card reports Telcordia GR-253 SONET alarms in the Alarms panel of CTC. For more information on alarms and alarm definitions, refer to the "Alarm Troubleshooting" chapter of the Cisco ONS 15454 Troubleshooting Guide, or the Cisco ONS 15454 SDH Troubleshooting Guide.
Configuring SONET/SDH Alarms
All SONET/SDH alarms are logged on the Cisco IOS CLI by default. But to provision or disable the reporting of specific SONET/SDH alarms on the Cisco IOS CLI, perform the following steps beginning in global configuration mode:
To determine which alarms are reported on the POS interface and to display the bit error rate (BER) thresholds, use the show controllers pos command, as described in the "Monitoring and Verifying POS" section.
Note Cisco IOS alarm reporting commands apply only to the Cisco IOS CLI. SONET/SDH alarms reported to the TCC2/TCC2P are not affected.