Table Of Contents
Release Notes for Cisco ONS 15454
Release 4.1.5Changed to Resolved Software Caveats
DDTS # CSCdy48478 Fan Tray Assembly Fan Fail Lamp Test Failure
CWDM and DWDM GBIC Compatibility with G1000-4 Cards and G1K-4 Cards
SONET and SDH Card Compatibility
Active Cross Connect (XC/XC10G/XCVT) or TCC+/TCC2 Card Removal
DDTS # CSCds02031 E1000-2/E100
DDTS # CSCed78149, TCP/IP Host-Mode Services
Maintenance and Administration
Changed Default Alarm Severities
DDTS # CSCdx40462, CSCdx47176, CSCdw22170
ONS 15454 Conducted Emissions Kit
Upgrading to Use the G1000-4 Ethernet Card
DDTS # CSCdv10824: Netscape Plugins Directory
DDTS # CSCds13769: Fujitsu FLM-150 and Nortel OC-3 Express
DDTS # CSCeb24331 and CSCeb40119
Active Cross Connect (XC/XC10G/XCVT) or TCC+/TCC2 Card Removal
Transponder (TXP_MR_10G) and Muxponder (MXP_2.5G_10G) Documentation
Resolved Software Caveats for Release 4.1.5
DDTS # CSCdv05723 and DDTS # CSCdw37046
DDTS # CSCec88426, CSCec88508, CSCed85088
DDTS # CSCec59739, CSCed02439, CSCed22547
DDTS # CSCec88402, CSCed31918, CSCed83309, CSCec85982
DDTS # CSCea16455, CSCea37089, CSCea37185
Maintenance and Administration
Transmission Control Protocol Specification
New Features and Functionality
New Software Features and Functionality
DS3i-N-12 Card Support for SONET Platforms
ML-Series Resilient Packet Ring
Protect Threshold Crossing Alarms
Alarms, Conditions, and Errors Changed in Release 4.1.x
Obtaining Technical Assistance
Contacting TAC by Using the Cisco TAC Website
Release Notes for Cisco ONS 15454
Release 4.1.5
October, 2007
Note The terms "Unidirectional Path Switched Ring" and "UPSR" may appear in Cisco literature. These terms do not refer to using Cisco ONS 15xxx products in a unidirectional path switched ring configuration. Rather, these terms, as well as "Path Protected Mesh Network" and "PPMN," refer generally to Cisco's path protection feature, which may be used in any topological network configuration. Cisco does not recommend using its path protection feature in any particular topological network configuration.
Release notes address closed (maintenance) issues, caveats, and new features for the Cisco ONS 15454 SONET multiplexer. For detailed information regarding features, capabilities, hardware, and software introduced with this release, refer to the "Release 4.1.x and 4.5" version of the Cisco ONS 15454 Procedure Guide; Cisco ONS 15454 Reference Guide; Cisco ONS 15454 Troubleshooting Guide; and Cisco ONS 15454 and Cisco ONS 15327 TL1 Command Guide. For the most current version of the Release Notes for Cisco ONS 15454 Release 4.1.5, visit the following URL:
http://www.cisco.com/univercd/cc/td/doc/product/ong/15400/454relnt/index.htm
Cisco also provides Bug Toolkit, a web resource for tracking defects. To access Bug Toolkit, visit the following URL:
http://www.cisco.com/cgi-bin/Support/Bugtool/launch_bugtool.pl
Contents
Resolved Software Caveats for Release 4.1.5
New Features and Functionality
Obtaining Technical Assistance
Changes to the Release Notes
This section documents supplemental changes that have been added to the Release Notes for Cisco ONS 15454 Release 4.1.5 since the production of the Cisco ONS 15454 System Software CD for Release 4.1.5.
The following changes have been added to the release notes for Release 4.1.5.
Changes to Caveats
The following caveat has been added.
DDTS # CSCed78149, TCP/IP Host-Mode Services
Changed to Resolved Software Caveats
The following resolvede caveats have been added.
Caveats
Review the notes listed below before deploying the ONS 15454. Caveats with DDTS tracking numbers are known system limitations that are scheduled to be addressed in a subsequent release. Caveats without DDTS tracking numbers are provided to point out procedural or situational considerations when deploying the product.
Hardware
DDTS # CSCdy48478 Fan Tray Assembly Fan Fail Lamp Test Failure
A user-initiated lamp test does not illuminate the fan fail LED on the fan tray assembly for the ONS 15454 or the ONS 15454 SDH. The lamp test successfully lights the LEDs for major, minor, and critical alarms on the fan tray, and for all cards in the chassis, but does not light the fan fail LED. An actual fan failure, however, will light the fan fail LED.
CWDM and DWDM GBIC Compatibility with G1000-4 Cards and G1K-4 Cards
G1000-4 cards support CWDM and DWDM GBICs. G1K-4 cards with the CLEI code of WM5IRWPCAA (manufactured after August 2003) support CWDM and DWDM GBICs. G1K-4 cards manufactured prior to August 2003 do not support CWDM or DWDM GBICs.
Note Operating temperature of the DWDM GBICs is -5 degrees C to 40 degrees C.
DDTS # CSCdw57215
In a configuration with OC-48 Any Slot cards and an STS-24c circuit, provisioned between G1000-4 cards with traffic going over the OC-48 span, extracting the G1000-4 card at one end of the STS-24c circuit before deleting the circuit will result in a traffic hit on all existing SONET circuits defined over that same span. This only occurs when the STS-24c is provisioned on timeslot 25.
In the Cisco ONS 15454 Procedure Guide, Release 4.1.x, refer to the "NTP-77 Delete Circuits" procedure to delete the 24c circuit before removing the card. Once you have deleted the circuit, refer to the "DLP-191 Delete a Card from CTC" task (also in the procedure guide) to delete the G1000-4 card. This issue will be resolved in Release 6.0.
Line Cards
Note Rarely, when the active TCC2 is removed, small traffic errors of 2 to 30 ms can sometimes occur. To avoid this issue, switch to the protect TCC2 before removing the working TCC2.
DDTS # CSCef43718
Under the conditions listed below, the DS1 card does not raise Loss of Frame for a Mismatched Frame Format. This can happen when you change from the correct frame format to an incorrect frame format, where the correct format is Unframed and the incorrect format is D4, and you switch from the incorrect, to correct, and back to the incorrect format. This issue is resolved in Release 5.0.
DDTS # CSCef24504
When a circuit is deleted from a DS3XM while DS1 loopbacks exist on the ports associated with that circuit, the loopbacks become frozen on those ports and cannot be removed. If this occurs, reestablish a circuit that uses those ports, then remove the loopbacks prior to deleting the circuit. This issue is resolved in Release 5.0.
DDTS # CSCef18088
A DS1 AINS circuit might change to IS state after two-fiber BLSR switch on a mixed-node network with one ONS 15327 and two ONS 15454s. This issue will be resolved in a future release.
DDTS # CSCec39567
Deleting a DS3I 1:N protection group may leave the protect card LED in a standby state. This can occur in a DS3I 1:N protection group with a LOCKON applied to the working card (ONS 15454 ANSI chassis only). Upon deleting the protection group, the LED on the protect DS3I card and the CTC display are still in the standby state. Soft reset the protect card to update the LED on the card and in CTC. An alternative workaround is to remove the LOCKON before deleting the protection group. This issue will be resolved in a future release.
DDTS # CSCeb45064
Terminal loopback on DS3XM-6 card may not work properly. AIS-P may be transmitted towards the system (away from the line side) direction. A VT circuit newly created to the DS3XM-6 with no valid input signal to the port can cause this. A terminal loopback will not work because AIS-P is being transmitted towards the system direction. To avoid this issue, apply a valid signal to the input port for the DS3XM card for at least 10 seconds with no terminal or facility loopback applied to that particular port. After receiving a valid signal for this time period, the terminal loopback will function properly even if the input signal is disconnected from the DS3XM port. This issue is resolved in Release 4.6.
DDTS # CSCdz49928
When using KLM type fuses with specific types of fuse and alarm panels, the PWR-REDUN alarm may not be displayed once the fuse is blown. A KLM fuse does not have a blown fuse indicator build into it. As a result, the blown fuse detection circuitry on the FAP may continue to provide voltage on its output despite a blown fuse.
Ethernet Polarity Detection
The TCC2 does not support polarity detection & correction on the LAN Ethernet port. This is a change from prior common control cards, such as the TCC+. If your LAN Ethernet connection has the wrong polarity (due to incorrect wiring on the backplane wire-wrap pins), the connection will work when using a TCC+, but not with a TCC2. To avoid possible problems, ensure that your Ethernet cable has the correct mapping of the backplane wire-wrap pins. For Ethernet pin mappings, consult the "DLP-A 21 Install LAN Wires on the Backplane" procedure in the user documentation.
If you are using a TCC+, the Release 4.0 or 4.1.x software will report the polarity issue (previous releases do not), by raising the standing condition: LAN Connection Polarity Reverse Detected (COND-LAN-POL-REV). Also, notification will appear on the fan tray LCD, which will display "BP LAN POL. NEG." The issue will typically be reported during the software upgrade process, but can also be raised during a new installation when using TCC+ and Release 4.0 or 4.1.x.
If this is a new installation with a TCC2 and you have the Ethernet polarity reversed, the TCC2 will not communicate over the LAN Ethernet interface (no polarity correction will occur), and no condition will be reported, nor will the fan tray LCD indicate an issue.
SONET and SDH Card Compatibility
Tables 1, 2, and 3 list the cards that are compatible for the ONS 15454 SONET and ONS 15454 SDH platforms. All other cards are platform specific.
DDTS # CSCdw27380
Performing cross connect card switches repeatedly might cause a signal degrade condition on the lines or paths that can trigger switching on these lines or paths. If you must perform repeated cross connect card switches, lock out the corresponding span (path protection, BLSR, or 1+1) first. This issue will be resolved in Release 6.0.
LOS Behavior
When an OC-N card is seeing LOS and the problem is resolved (for example, the pulled fiber is reinserted) the LOS will normally clear quickly, and any other errors seen on the signal will be raised. However, in the special case where the restored signal is unframed, the LOS will remain raised (that is, the LOS will not be replaced by an LOF). This is standard SONET behavior per Telcordia GR-253 R6-57, Method 1, where to clear LOS the signal must also contain valid framing alignment patterns.
DDTS # CSCdw66444
When an SDH signal is sent into an ONS 15454 OC-12/STM-4 (IR, 1310 LR and 1550 LR) or an OC-48/STM-16 high-speed (IR and LR) port which has been configured to support SDH, an SD-P (Signal Degrade) alarm will appear as soon as the circuit is created. This alarm will continue to exist until the circuit is deleted.
To avoid this problem, when provisioning an OC-12/STM-4 (IR, 1310 LR and 1550 LR) or an OC-48/STM-16 high-speed (IR and LR) port to support SDH, disable the signal degrade alarm at the path level (SD-P) on the port.
Also, PM data at the path level will not be reliable. You must set associated threshold values to 0 in order to avoid threshold crossing alerts (TCA) on that port. The path threshold values to set to zero are CV-P, ES-P, SES-P, and UAS-P.
These issues are the result of a hardware limitation, and there are no current plans to resolve them.
DDTS # CSCdw09604
If you are using an XC10G with OC-48, you must use either OC-48AS or OC-48 cards with a revision number higher than 005D.
Jitter Performance with XC10G
During testing with the XC10G, jitter generation above 0.10 UI p-p related to temperature gradient testing has been observed. This effect is not expected to be seen under standard operating conditions. Changes are being investigated to improve jitter performance in a future release. DDTS numbers related to this issue include CSCdv50357, CSCdv63567, CSCdv68418, CSCdv68441, CSCdv68389, CSCdv59621, and CSCdv73402.
Active Cross Connect (XC/XC10G/XCVT) or TCC+/TCC2 Card Removal
You must perform a lockout in BLSR, path protection, and 1+1 before physically removing an active cross connect (XC/XC10G/XCVT) or TCC+/TCC2 card. The following rules apply.
Active cross connect (XC/XC10G/XCVT) cards should not generally be physically removed. If the active cross connect or TCC+/TCC2 card must be removed, you can first perform an XC/XCVT/XC10G side switch or TCC+/TCC2 reset and then remove the card once it is in standby, or you can perform a lockout on all circuits that originate from the node whose active cross connect or active TCC+/TCC2 will be removed (performing a lockout on all spans will also accomplish the same goal). No lockout is necessary for switches initiated through CTC or through TL1.
DDTS # CSCdv62565, CSCdv62573
In a 1:N protection group, traffic loss could occur if a DS-N card is preprovisioned and then added to the group while another working card in the group is removed from its slot. To avoid this, before adding slots to a protection group ensure that:
•The protect card is not actively carrying traffic (that is, the card is in standby)
•Any working slot you add to the group actually contains a working card at the time you add it
This issue will be resolved in Release 6.0.
E Series and G Series Cards
Note When using ONS 15327s as passthrough nodes with Release 3.2, you cannot create 9c or 24c gigabit Ethernet circuits through any 15327.
DDTS # CSCdy37198
On Cisco ONS 15454s equipped with XC or XCVT cross-connect cards, neither the E100T-12 nor the E1000-2 cards raise an alarm or condition in CTC when Ethernet traffic is predictably lost due to the following circumstances:
Circuits exist between Ethernet cards (E100T-12 and/or E1000-2) built over Protection Channel Access (PCA) bandwidth on BLSR spans. When BLSR issues a switch, the PCA bandwidth is preempted. Since there is no longer a connection between the ends of the Ethernet circuit, traffic is lost.
Note In nodes equipped with XC10G, these Ethernet cards will raise an AIS-P condition.
This issue will be resolved in a future release.
DDTS # CSCdr94172
Multicast traffic can cause minimal packet loss on the E1000-2, E100-12, and E100-4 cards. Packet loss due to normal multicast control traffic should be less than 1%. This issue was resolved in Release 2.2.1 for broadcast, and in Release 2.2.2 for OSPF, and some multicast frames. As of Release 3.0.3, the ONS 15454 supports HSRP, CDP, IGMP, PVST, and EIGRP, along with the previously supported broadcast and OSPF.
Note If multicast is used for such applications as video distribution, significant loss of unicast and multicast traffic will result. These cards were not designed for, and therefore should not be used for, such applications.
Note If the multicast and flood traffic is very rare and low-rate, as occurs in most networks due to certain control protocols and occasional learning of new MAC addresses, the loss of unicast frames will be rare and likely unnoticeable.
Note A workaround for this issue is to use the port-mapped mode of the E-series cards.
Multicast MAC addresses used by the following control protocols have been added to the static MAC address table to guarantee no loss of unicast traffic during normal usage of these MAC addresses:
E1000-2/E100T
Do not use the repair circuit option with provisioned stitched Ethernet circuits.This issue is under investigation.
Single-card EtherSwitch
Starting with Release 2.2.0, each E100/E1000 card can be configured as a single-card EtherSwitch configuration to allow STS-12c of bandwidth to be dropped at each card. The following scenarios for provisioning are available:
1. 12c
2. 6c, 6c
3. 6c, 3c, 3c
4. 6c, six STS-1s
5. 3c, 3c, 3c, 3c
6. 3c, 3c, six STS-1s
7. Twelve STS-1s
When configuring scenario 3, the STS-6c must be provisioned before either of the STS-3c circuits.
Multicard EtherSwitch
When deleting and recreating Ethernet circuits that have different sizes, you must delete all STS circuits provisioned to the EtherSwitch before you create the new circuit scenario. (See the preceding "Single-card EtherSwitch" section for details on the proper order of circuit creation.) Enable front ports so that the VLANs for the ports are carried by the largest circuit first. A safe approach is to enable the front port before you create any circuits and then retain the front port VLAN assignment afterwards. If you break the rules when creating a circuit, or if you have to delete circuits and recreate them again, delete all circuits and start over with the largest first.
DDTS # CSCds02031 E1000-2/E100
Whenever you drop two 3c multicard EtherSwitch circuits onto an Ethernet card and delete only the first circuit, you should not provision STS-1 circuits to the card without first deleting the remaining STS-3c circuit. If you attempt to create an STS-1 circuit after deleting the first STS-3c circuit, the STS-1 circuit will not work and no alarms will indicate this condition. To avoid a failed STS-1 circuit, delete the second STS-3c prior to creating any STS-1 circuit.
ML-Series
DDTS # CSCed78149, TCP/IP Host-Mode Services
A document that describes how the Internet Control Message Protocol (ICMP) could be used to perform a number of Denial of Service (DoS) attacks against the Transmission Control Protocol (TCP) has been made publicly available. This document has been published through the Internet Engineering Task Force (IETF) Internet Draft process, and is entitled "ICMP Attacks Against TCP" (draft-gont-tcpm-icmp-attacks-03.txt).
These attacks, which only affect sessions terminating or originating on a device itself, can be of three types:
1. Attacks that use ICMP "hard" error messages
2. Attacks that use ICMP "fragmentation needed and Don't Fragment (DF) bit set" messages, also known as Path Maximum Transmission Unit Discovery (PMTUD) attacks
3. Attacks that use ICMP "source quench" messagesSuccessful attacks may cause connection resets or reduction of throughput in existing connections, depending on the attack type.
Multiple Cisco products are affected by the attacks described in this Internet draft.
Cisco has made free software available to address these vulnerabilities. In some cases there are workarounds available to mitigate the effects of the vulnerability.
This advisory is posted at http://www.cisco.com/warp/public/707/cisco-sa-20050412-icmp.shtml.
The disclosure of these vulnerabilities is being coordinated by the National Infrastructure Security Coordination Centre (NISCC), based in the United Kingdom. NISCC is working with multiple vendors whose products are potentially affected. Its posting can be found at: http://www.niscc.gov.uk/niscc/docs/re-20050412-00303.pdf?lang=en.
DDTS # CSCeb56287
When an ML-series circuit's state is provisioned from In-Service (IS) to Out-of-Service (OOS), and then back to IS, data traffic does not recover. To avoid this issue, prior to changing the state from IS, set the POS port to shut down on the CLI. After the state is changed back to IS from OOS, set the POS port to "no shutdown." This issue will be resolved in Release 4.6.
DDTS # CSCeb24757
Disconnecting a transmit fiber on an ML1000 port causes only the neighboring port to take the link down. Ideally, both ports should identify that the link went down so upper layer protocols can reroute the traffic to a different port. To work around this situation, issue "shutdown" and "no shutdown" to the port that has the disconnected or faulty transmit fiber. This issue will be resolved in Release 4.6.
DDTS # CSCea46580
SPR input counters do not increment on a BVI with an SPR interface. This issue is under investigation.
DDTS # CSCea35971
A monitor command may disappear from the configuration after a TCC reboots. To avoid this issue, use the exec command, "terminal monitor," instead (a minor drawback is that this command applies to all VTYs), or, alternatively, reapply the monitor command after connection is lost. This is as designed.
DDTS # CSCdy31775
Packets discarded due to output queue congestion are not included in any discard count. This occurs under either of the following conditions:
•Traffic on ML-series cards between Ethernet and SONET ports, with oversubscription of available circuit bandwidth configured, leading to output queue congestion.
•Traffic from SONET to Ethernet, with oversubscription of the available Ethernet bandwidth.
This issue is resolved in Release 4.6.
DDTS # CSCdz49700
The ML-series cards always forward Dynamic Trunking Protocol (DTP) packets between connected devices. If DTP is enabled on connected devices (which might be the default), DTP might negotiate parameters, such as ISL, that are not supported by the ML-series cards. All packets on a link negotiated to use ISL are always counted as multicast packets by the ML-series card, and STP and CDP packets are bridged between connected devices using ISL without being processed. To avoid this issue, disable DTP and ISL on connected devices. This functionality is as designed.
DDTS # CSCdz68649
Under certain conditions, the flow-control status may indicate that flow control is functioning, when it is not. Flow-control on the ML-series cards only functions when a port-level policer is configured. A port-level policer is a policer on the default and only class of an input policy-map. Flow-control also only functions to limit the source rate to the configured policer discard rate, it does not prevent packet discards due to output queue congestion.
Therefore, if a port-level policer is not configured, or if output queue congestion is occurring, policing does not function. However, it might still mistakenly display as enabled under these conditions. To avoid this issue, configure a port-level policer and prevent output queue congestion. This issue will be resolved in a future release.
DDTS # CSCdz69700
Issuing a shutdown/no shutdown command sequence on an ML1000 port clears the counters. This is a normal part of the startup process and there are no plans to change this functionality.
DDTS # CSCea11742
When a circuit between two ML POS ports is provisioned OOS, one of the ports might erroneously report TPTFAIL. This issue exists for both ML100T-12 and ML1000-2 cards. If this occurs, open a console window to each ML card and configure the POS port to shutdown. This issue is resolved in Release 4.6.
DDTS # CSCea20962
No warning is displayed when applying OOS to ML drop ports on the circuit provisioning window. This issue will be resolved in Release 5.0.
DDTS # CSCin29274
When configuring the same static route over two or more interfaces, use the following command:
ip route a-prefix a-networkmask a.b.c.d
Where a.b.c.d is the address of the outgoing gateway, or, similarly, use the command:
ip route vrf vrf-name
Do not try to configure this type of static route using only the interface instead of the address of the outgoing gateway in Release 4.0. This issue will be resolved in a future release.
DDTS # CSCin32057
If no BGP session comes up when VRF is configured and all interfaces have VRF enabled ensure that at least one IP interface (without VRF) is configured and add an IP loopback interface on each node. This issue will be resolved in a future release.
DDTS # CSCin35960
POS ingress classification based on IP precedence does not match the packets when inbound policy map classifying based on IP precedence is applied to the POS interface, which is configured for HDLC or PPP encapsulation. To avoid this issue, use LEX encapsulation (default) or, at the Ethernet ingress point, mark the COS based on an IP precedence classification, then classify based on the COS during POS ingress. This issue is resolved in Release 4.6.
DDTS # CSCdy47284
ML-100 FastEthernet MTU is not enforced. However, frames larger than 9050 bytes may be discarded and cause Rx and Tx errors.
DDTS # CSCdz74432
Issuing a "clear IP route *" command can result in high CPU utilization, causing other processes to be delayed in their execution. To avoid this issue do not clear a large number of route table entries at once, or, if you must use the "clear IP route *" command, do not install more than 5000 EIGRP network routes.
Maintenance and Administration
Caution VxWorks is intended for qualified Cisco personnel only. Customer use of VxWorks is not recommended, nor is it supported by Cisco's Technical Assistance Center. Inappropriate use of VxWorks commands can have a negative and service affecting impact on your network. Please consult the troubleshooting guide for your release and platform for appropriate troubleshooting procedures. To exit without logging in, enter a Control-D (hold down the Control and D keys at the same time) at the Username prompt. To exit after logging in, type "logout" at the VxWorks shell prompt.
Note CTC does not support adding/creating more than 5 circuits in auto-ranged provisioning. This is as designed.
DDTS # CSCea84427
CTC or Cisco Transport Manager (CTM) communication to a node might be lost while the node is still able to respond to a ping. The CORBA interface on the node can be locked by sending invalid (non-Corba) data to the TCC IIOP listener port. When the CORBA interface is locked, legitimate CORBA communications are lost. To prevent this from occuring, the ONS 15454 should be placed on a secure network or behind a firewall. In the event that this issue arises, CTC/CTM managment can be regained by performing a Manual TCC reset using TL1. This issue is resolved in Release 4.6.
DDTS # CSCec58326
When switching to the protect card in EC1 during 1:1 protection, IPPM goes blank. This is the result of incorrect handling of STS Path PMs (IPPM) in EC1 1:1 protection. This issue is resolved in Release 4.6.
DDTS # CSCec48038
A PCA circuit might be displayed as INCOMPLETE after a span upgrade; for example, when a BLSR span that is carrying PCA traffic is upgraded from OC-48 to OC-192. Although the circuit is reported as INCOMPLETE in CTC, traffic should be unaffected in this instance. To correct the display, restart CTC. This issue is resolved in Release 4.6.
DDTS # CSCec29230
The NE PWR-B alarm is not reported in CTC after an upgrade to Release 3.4.2. You can view the alarm through TL1. This issue is resolved in Release 5.0.
DDTS # CSCeb45149
A 1+1 non-revertive system in which the protect card is reseated while the working card is present and active reverts back to working after you clear a Force to Protect or Manual to Protect. Affected cards are OC-3 8 port and OC-12 4 port. To work around this issue, soft-reset the working card with the protect card present and active. This issue will be resolved in Release 4.6.
Changed Default Alarm Severities
The following alarm severities have changed for Release 4.1.x.
Table 4 Changed Alarm Severities
Alarm New SeverityVT-MON::AUTOSW-LOP
NSA-Minor
VT-MON::AUTOSW-UNEQ
NSA-Minor
VT-TERM::PLM-V
SA-Major
DDTS # CSCeb20996
While using the orderwire capability of the AIC-I, you must not input a station number with less than 4 digits. If you enter, for example, 123, CTC will display 0123; however, you will not be able to ring the node by dialing either *123, or *0123. This issue will be resolved in Release 4.6.
DDTS # CSCea93638
Path level alarms are displayed on the CTC conditions pane for deleted circuits. This issue may occur on any circuit deletion case. The conditions may be cleared by a TCC side switch. This issue is resolved in Release 4.6.
DDTS # CSCea61887
Terminal loopback is provisionable even if the card is in transponder mode.
To see this, in the provisioning tab for a G1000 or G1K-4 card pick a pair of ports and set them to transpond with each other. The condition also holds true by picking one port and setting it to transpond with itself (one-port unidirectional). Once the transponder setting is provisioned, go to the Maintenance tab and attempt to provision terminal loopback on any of the ports that were previously provisioned for transponder functionality. CTC allows terminal loopback to be provisioned even though the setting has no effect due to the fact that the ports are performing transponder functions. If terminal loopback is truly intended, you should remove the transponder settings. A warning stating that terminal loopback has no effect if transponders are present will be displayed in Release 4.6.
DDTS # CSCea74000
Rarely, a PLM-P alarm on an OC-12 card might remain after deleting the affected STS-1 circuit. This condition persists even after deleting the affected card. If this occurs, you can reset the TCC2s to remove the stuck alarm. This issue is resolved in Release 4.6.
DDTS # CSCea71675
Rarely, when nodes appear gray in CTC and you view the BLSR tab at the network level, the tab may be blank. When this occurs, all tabs on the same level will also become blank. To avoid this issue, do not enter into the BLSR tab at the network view until all of the nodes are some color other than gray. This issue will be resolved in Release 4.6.
DDTS # CSCea92969
The switch indicator does not clear on the Maintenance > Protection tabs when a revertive 1:1 protection group is provisioned to be non-revertive. If this occurs, from the Maintenance > Protection tabs, select the slot with the "Switch" indicator. Click the "Clear" button. This issue is resolved in Release 4.6.
DDTS # CSCea78364
Simultaneous failure of working and protect cards in 1:N protection groups may not be alarmed as service affecting. This can occur when the working card of the protection group has been removed from the chassis, and the protect card of the protection group is subsequently issued a Manual Reset. Since the working and protect facilities are impaired, the Improper removal alarm should clear and be reissued as a Critical and service affecting condition. This issue will be resolved in Release 5.0.
DDTS # CSCea81001
When a fault condition exists against a circuit or port that is in the OOS-MT or OOS-AINS state (or when you are using the "Suppress Alarms" check box on the CTC Alarm Behavior pane), the alarm condition is not assigned a reference number. If you were to place the circuit or port in service at this time, in the absence of the reference number, the CTC alarm pane would display the condition with a time stamp indicating an alleged, but incorrect, time that the autonomous notification was issued. Clicking the CTC alarm "Synchronize" button at this stage will correct the alarm time stamp. There is no way to remedy the lack of reference number. This issue will be resolved in Release 6.0.
DDTS # CSCdx35561
CTC is unable to communicate with an ONS 15454 that is connected via an Ethernet craft port. CTC does, however, communicate over an SDCC link with an ONS 15454 that is Ethernet connected, yielding a slow connection. This situation occurs when multiple ONS 15454s are on a single Ethernet segment and the nodes have different values for any of the following features:
•Enable OSPF on the LAN
•Enable Firewall
•Craft Access Only
When any of these features are enabled, the proxy ARP service on the node is also disabled. The ONS 15454 proxy ARP service assumes that all nodes are participating in the service.
This situation can also occur immediately after the aforementioned features are enabled. Other hosts on the Ethernet segment (for example, the subnet router) may retain incorrect ARP settings for the ONS 15454s.
To avoid this issue, all nodes on the same Ethernet segment must have the same values for Enable OSPF on the LAN, Enable Firewall, and Craft Access Only. If any of these values have changed recently, it may be necessary to allow connected hosts (such as the subnet router) to expire their ARP entries.
You can avoid waiting for the ARP entries to expire on their own by removing the SDCC links from the affected ONS 15454 nodes. This will disconnect them for the purposes of the proxy ARP service and the nodes should become directly accessible over the Ethernet. Network settings on the nodes can then be provisioned as desired, after which the SDCC can be restored.
This issue will not be resolved.
DDTS # CSCdz84149
If a user is logged into CTC as a superuser (or other higher level security type), and then another superuser changes the first user's security level to "retrieve" (or another lower level security type) without first logging the user out, the lower level user is then still able to perform some actions authorized only for the original login security level. For example, a "provisioning" level user demoted to "retrieve" level in this manner can still provision and edit MS-SPRings (BLSRs) while logged into the current session, though the same user may no longer provision DCCs. To ensure that a user's level is changed completely, the superuser must log the user out prior to changing the security level. This issue will be resolved in Release 4.6.
DDTS # CSCdz90753
In the Maintenance > Cross Connect Resource Pane, the VT matrix port detail is inconsistent with the general VT matrix data. This can occur when a 1+1 protection scheme is in place. To avoid confusion, note that the VT matrix data counts the VTs for both the working and protect card, while the detail data counts the VTs only for the working card. This issue will be resolved in Release 4.6.
DDTS # CSCdz35479
Rarely, CTC Network view can freeze following the deletion or addition of a node from or to a BLSR/MS-SPRing. This can result in the CTC Network view no longer updating correctly. If this occurs, restart CTC. This issue will be resolved in Release 4.6.
DDTS # CSCdy57891
An LOP-P alarm can be inadvertently cleared by an LOS that is raised and cleared. On OC48AS, OC192, and OC12-4 cards, when an LOP condition and an LOS condition are both present on the input, an LOS will be raised as per Telcordia GR 253 alarm hierarchy. However, upon clearing the LOS with the LOP still present, the LOP alarm, which should then be raised, is not. An AIS-P condition will be visible. This issue will be resolved in Release 6.0.
DDTS # CSCdy56693
Microsoft Windows XP uses more memory than previous Microsoft operating systems, and this may result in reduced CTC performance. To avoid reduced performance, you can:
•Limit the number of nodes you log into
•Avoid or limit bulk operations
•Avoid bulk circuit deletion
•Prevent CTC's discovery of DCC connected nodes by using the login "Disable Network Discovery" feature
•Prevent CTC's discovery of circuits unless needed by using the login "Disable Circuit Management" feature
DDTS # CSCdy61275
Far end path FC-P is not counted on EC1 or OC3 cards. When a path defect is transmitted to the far end, it reports RDI-P. However, the condition is not examined and reported as a PM count. This issue will be resolved in a future release.
DDTS # CSCdy10030
CVs are not positively adjusted after exiting a UAS state. When a transition has been made from counting UAS, at least 10 seconds of non-SES must be counted to exit UAS. When this event occurs, Telcordia GR-253 specifies that CVs that occurred during this time be counted, but they are not. This issue will be resolved in Release 6.0.
DDTS # CSCdy55556
In a 1:N protection group, where a protect card is protecting a failed card and another working card, which is missing, has a lockon condition, upon removing the lockon condition from the missing working card, the protect card may switch from the card it had been protecting to carry the traffic of the missing working card that just had the lockon removed. To avoid this issue, replace the failed working card before removing the lockon. This issue will be resolved in Release 6.0.
DDTS # CSCdy11012
When the topology host is connected to multiple OSPF areas, but CTC is launched on a node that is connected to fewer areas, the topology host appears in CTC, and all nodes appear in the network view, but some nodes remain disconnected. This can occur when the CTC host does not have routing information to connect to the disconnected nodes. (This can happen, for example, if automatic host detection was used to connect the CTC workstation to the initial node.)
CTC will be able to contact the topology host to learn about all the nodes in all the OSPF areas, but will be unable to contact any nodes that are not in the OSPF areas used by the launch node. Therefore, some nodes will remain disconnected in the CTC network view.
To work around this issue, if no firewall enabled, then the network configuration of the CTC host can be changed to allow CTC to see all nodes in the network. The launch node must be on its own subnet to prevent network partitioning, and craft access must not be enabled. The CTC host must be provisioned with an address on the same subnet as the initial node (but this address must not conflict with any other node in the network), and with the default gateway of the initial node. CTC will now be able to contact all nodes in the network.
If a firewall is enabled on any node in the network, then CTC will be unable to contact nodes outside of the initial OSPF areas.
NE Defaults
The following caveats apply for NE defaults.
•OC12-4 allows provisioning of PJStsMon from 0 to 48. The workaround is to limit provisioning to between Off and 1 to 12 only.
•CTC displays "PJStsMon=off" in the standard provisioning pane when provisioning PJStsMon off; however, TL1 and the NE Defaults editor both display 0 for this same condition.
•If you only make changes to a single default in the NE defaults editor, you must click on another default or column before the Apply button becomes functional.
DDTS # CSCdy35514
The terminology used for provisioning overhead circuits has changed as of Release 3.4 as follows.
Overhead Circuit Types
•LDCC_TUNNEL has changed to DCC Tunnel D4-D12
•SDCC_TUNNEL has changed to DCC Tunnel D1-D3
Overhead Channel Types
•SDCC has changed to DCC1(D1-D3)
•LDCC_TUNNEL1 has changed to DCC2(D4-D6)
•LDCC_TUNNEL2 has changed to DCC3(D7-D9)
•LDCC_TUNNEL3 has changed to DCC4(D10-D12)
•LDCC has changed to DCC(D4-D12)
Note These circuits are now provisioned at the network level, rather than on a node-by-node basis.
DDTS # CSCds88976
When a new circuit is created around a ring (path protection or BLSR), the SD BER or SF BER alarm can be raised depending on the order in which the spans are provisioned. The alarms will eventually clear by themselves. Traffic is not affected. This issue will be resolved in Release 6.0.
DDTS # CSCdx40462, CSCdx47176, CSCdw22170
While upgrading nodes from releases prior to 3.2, CTC might lose connection to the far end nodes. When this occurs, you will not be able to ping the grayed-out nodes; however, if you continue the upgrade, this problem resolves itself. This issue is resolved in Release 3.2, but can still occur when upgrading from nodes with earlier software releases.
DDTS # CSCdw66895
XCVTs (both active and standby) reboot continuously when the K3 byte is mapped to the E2 byte on one side of a WTR span. The rebooting occurs after the WTR timer expires. This has been seen on a two fiber BLSR with OC-48AS. To avoid this issue, if possible, change the K3 mapping on both ends of the span before creating the ring; or, alternatively, you can prevent the ring from reverting during the K3 mapping by setting the Ring Reversion time to "never." Once you have completed the mapping of the K3 byte to the E2 byte on both sides, return the Ring Reversion to its normal value. This issue is resolved in Release 4.6.
ONS 15454 Conducted Emissions Kit
If you are deploying the Cisco ONS 15454 within a European Union country that requires compliance with the EN300-386-TC requirements for Conducted Emissions, you must obtain and install the Cisco ONS 15454 Conducted Emissions kit (15454-EMEA-KIT) in order to comply with this standard.
Upgrading to Use the G1000-4 Ethernet Card
Before installing or seating the G1000-4 Ethernet card on node running Release 3.1 or prior, you must upgrade the software on that node to Release 3.2 or later. This is as designed.
DDTS # CSCdv10824: Netscape Plugins Directory
If you use CTC, JRE, and the Netscape browser with a Microsoft Windows platform, you must ensure that any new installation of Netscape uses the same Netscape directory as the previous installation did, if such an installation existed. If you install Netscape using a different path for the plugins directory, you will need to reinstall JRE so that it can detect the new directory.
DDTS # CSCdu82934
When you auto-route a VT circuit on an ONS 15454 node, a path is computed based on the availability of STSs on the nodes involved. This selection process, when combined with a lack of VT matrix (or STS-VT connections) on an auto-route selected node, can result in the VT circuit creation failing with the message "unable to create connection object at node." To correct this situation, manually route VT circuits in cases when auto-routing fails. The error message will indicate which node is at issue.
"Are you sure" Prompts
Whenever a proposed change occurs, the "Are you sure" dialog box appears to warn the user that the action can change existing provisioning states or can cause traffic disruptions.
Interoperability
DDTS # CSCds13769: Fujitsu FLM-150 and Nortel OC-3 Express
You cannot provision the FLM-150 and OC-3 Express in 1+1 revertive switching mode. The problem occurs when the ONS 15454 issues a user request in revertive mode to the protect channel. When the user request is cleared, the ONS 15454 issues a No Request. However, the FLM-150 and OC-3 Express issues a Do Not Revert, which causes traffic to remain on the protection channel. Based on GR-253, section 5.3.5.5, the FLM-150 and the OC-3 Express should respond with a No Request.
BLSR Functionality
DDTS # CSCec74273
If a four-fiber BLSR execute MS-R or WTR coexists with SF-P on the same span and FS-R is issued on a different span in the ring, the FS-R preempts the MS-R or WTR, causing a traffic outage. The ring switch is removed, but one side remains in the ring switch state. To recover from this situation, issue a lockout of the protect span on the span that raised the ring switch event. This issue is resolved in Release 4.6.
DDTS # CSCeb24331 and CSCeb40119
If you create a four-fiber BLSR with a VT circuit on it, then delete the circuit and the ring, then created a two-fiber BLSR on the same ports, you may see an unexpected AIS-V on the path, even before any additional circuit is created. A soft switch of the TCC will clear the AIS-V condition. This issue is resolved in Release 4.6.
DDTS # CSCeb09217
Circuit states are not updated after a span update. If you update a four node OC-12 two-fiber BLSR to a four node OC-192 two-fiber BLSR, the previous PCA circuits should be shown as two-fiber BLSR protected, but they are shown as "UNKNOWN" protected. If you relaunch CTC this situation is corrected. This issue will be resolved in Release 5.0.
DDTS # CSCea59342
DS3 PCA traffic may take up to 20 seconds to recover after a BLSR switch is cleared. This can occur with DS3 PCA traffic on two-Fiber or four-Fiber BLSR configuration with XCVT cards in the same nodes as the DS3 cards. This issue will be resolved in a future release.
DDTS # CSCea81000
In a two-fiber or four-fiber BLSR, MS-RFI is not reported for an LOS or LOF with a ring lockout in place on a different span. This issue will be resolved in Release 5.0.
DDTS # CSCdy68207
Failing the working and protect spans on a four-fiber BLSR while an extra traffic circuit runs over the span and a lockout is on the span can cause the extra traffic to permanently fail, with no AIS.
The failure scenario is only reproducible by failing and restoring fibers in the following sequence.
Step 1 Create a four-fiber BLSR.
Step 2 Create extra traffic circuits (one or more) over one of the spans, say, from Node A east to Node B west. At Node A, issue a lockout span east. This causes the BLSR to not switch in the event of a span failure.
Step 3 At node A, remove the working transmit fiber east, then remove the protect transmit fiber east. Both protected traffic and extra traffic are down, as expected.
Step 4 Reinsert the protect transmit fiber east, then reinsert the working transmit fiber east. Protected traffic is restored, but extra traffic is not restored.
If this issue occurs, clear the lockout span. All extra traffic is immediately restored. You may then reissue the lockout span. This issue will be resolved in Release 5.0.
DDTS # CSCdy56668
Ethernet circuits may appear in the CTC circuit table with an INCOMPLETE status after a BLSR/MSSP span is upgraded. The circuits, when this occurs, are not truly incomplete. They are unaffected and continue to carry traffic. To see the circuit status correctly, restart CTC. This issue is resolved in Release 4.6.
DDTS # CSCdy45902
Traffic that should be dropped remains unaffected when a BLSR Protection Channel Access (PCA) VT tunnel is placed OOS. You must place all circuits in the tunnel OOS before the traffic will be dropped. This issue will be resolved in Release 5.0.
DDTS # CSCdw32540
The two protect OC48AS cards at the ends of a four fiber BLSR span must both be configured as either K3 or Z2 (not a mixture). If both ends are not the same, the BLSR may fail to switch correctly. In Release 3.4 the BLSR wizard ensures that both ends are configured correctly; however, you must still avoid manually changing the value on one side only (and hence, causing a mismatch) at the card level. If you do mismatch bytes at the card level, you can discover this by going to the BLSR edit map tied in with the BLSR wizard. The mismatched span will be red, and right-clicking on the span will allow you to correct the problem.
DDTS # CSCdw58950
You must lock out protection BLSR, 1+1, and path protection traffic to avoid long, or double traffic hits before removing an active XC, XCVT, or XC10G card. You should also make the active cross connect card standby before removing it.
DDTS # CSCdv70175
When configuring a node with one 4 Fiber BLSR and one 2 Fiber BLSR, or with two 2 fiber BLSRs, an issue exists related to the version of XC deployed. Revision 004H and earlier revisions of the XC do not support these configurations. All later revisions of the XC and all versions of the XCVT and XC10G cross connects support all permutations of two BLSRs per node.
DDTS # CSCdv53427
In a two ring, two fiber BLSR configuration (or a two ring BLSR configuration with one two fiber and one four fiber ring) it is possible to provision a circuit that begins on one ring, crosses to a second ring, and returns to the original ring. Such a circuit can have protection vulnerabilities if one of the common nodes is isolated, or if a ring is segmented in such a way that two non-contiguous segments of the circuit on the same ring are each broken.
DDTS # CSCct03919
VT1.5 and VC3/VC12 squelching is not supported in BLSR/MSSPR.
Database Restore on a BLSR
When restoring the database on a BLSR, follow these steps:
Step 1 To isolate the failed node, issue a force switch toward the failure node from the adjacent east and west nodes.
Step 2 If more than one node has failed, restore the database one node at a time.
Step 3 After the TCC+/TCC2 has reset and booted up, release the force switch from each node.
Path Protection Functionality
DDTS # CSCeb37707
With a VT path protection circuit, if you inject signals with a thru-mode test set into one path of the circuit in a particular order, you may not see the appropriate alarms. This can occur when you first inject LOP-P, then clear, then inject LOP-V. This issue will be resolved in Release 6.0.
DDTS # CSCdv42151
When a path protection circuit is created end-to-end, CTC might not create the cross-connection on all the nodes along the path at the same time. This might cause an SD-P condition along the path. When the circuit is fully provisioned on all nodes, the SD-P will clear automatically. Other conditions that can be expected while the circuit is being created are LOP-P and UNEQ-P. To reduce the risk of unexpected transient conditions, circuits should be created in the OOS_AINS state.
Active Cross Connect (XC/XC10G/XCVT) or TCC+/TCC2 Card Removal
As in BLSR and 1+1, you must perform a lockout on path protection before removing an active cross connect or TCC+/TCC2 card. The following rules apply to path protection.
Active cross connect (XC/XC10G/XCVT) cards should not generally be physically removed. If the active cross connect or TCC+/TCC2 card must be removed, you can first perform an XC/XCVT/XC10G side switch or TCC+/TCC2 reset and then remove the card once it is in standby, or you can perform a lockout on all circuits that originate from the node whose active cross connect or active TCC+/TCC2 will be removed (performing a lockout on all spans will also accomplish the same goal). No lockout is necessary for switches initiated through CTC or through TL1.
Performance Monitoring
DDTS # CSCeb41916
If you create a 1+1 protection group, create a circuit on the working line, and then try to retrieve the path PMs on the protect side using TL1, the request is denied. To work around this issue, use CTC to retrieve the Path PMs on the protect line. This issue will be resolved in Release 5.0.
DDTS # CSCea38791
In the CTC Performance > Statistics tab of the G1000-4 or G1000-2, there are no entries for Rx/Tx Multicast and Broadcast packets. This issue is resolved in Release 4.6.
Documentation
The following two notes on page 5-30 of the Cisco ONS 15454 Reference Manual, R4.1.x and R4.5 should be replaced.
Note G-Series cards manufactured before August 2003 do not support DWDM GBICs. G1000-4 cards compatible with DWDM GBICs have a CLEI code of SNP8KW0KAB. Compatible G1K-4 cards have a CLEI code of WM5IRWPCAA.
Note All versions of G1000-4 and G1K-4 cards support CWDM GBICs.
The replacement information is contained in CWDM and DWDM GBIC Compatibility with G1000-4 Cards and G1K-4 Cards.
Transponder (TXP_MR_10G) and Muxponder (MXP_2.5G_10G) Documentation
The documentation set for the Cisco ONS 15454 contains references to new transponder (TXP_MR_10G) and muxponder (MXP_2.5G_10G) cards. These portions of the documentation are meant to refer to cards that will become available with a future release. The nXP cards are not available with Release 4.1.x. Cisco apologizes for any confusion this may cause.
TL1
Note To be compatible with TL1 and DNS, all nodes must have valid names. Node names should contain alphanumeric characters or hyphens, but no special characters or spaces.
DDTS # CSCed08144
Rarely, TL1 autonomous messages might not be displayed in a session after several days of PM-related provisioning changes. This issue will be resolved in Release 5.0.
DDTS # CSCeb33033
An exception is raised when retrieving PM stats via TL1 for the protect card of a 1:1 protection group when the working card is active. To avoid this issue, retrieve stats from the working card instead of the protect card. This issue is resolved in Release 4.6.
DDTS # CSCdz86121
In one rare case, the ONS 15454/15327 times out a user session without communicating the timeout to TL1. If this happens, the TL1 user remains logged in, although the session is actually timed out. This can occur when you log into the node with a timeout of X minutes. If the user session sits idle for all but 5 seconds of the X minutes, then you have only 5 seconds to type in a command to notify the node that the session is active. If you try this, you will likely miss the five second window, in which case the node will respond as though the session is inactive and deny access. However, because you have typed a key, irrespective of the five second window, TL1 responds as though the session is active and does not log you out (time out). You will not have access to the node and will receive a "DENY" response to TL1 commands. The error message may vary depending on commands issued. To recover from this situation, log out and log back in to TL1. This issue is resolved in Release 4.5.
DDTS # CSCdz26071
The TL1 COPY-RFILE command, used for SW download, database backup, and database restore, currently does not allow a user-selected port parameter to make connections to the host. The command expects the default parameter of Port 21 and will only allow that number. This issue will be resolved in Release 5.0
DDTS # CSCdu53509
When a TL1 session to a remote node (ENE) is established via a gateway node (GNE) and you have changed the node name of the ENE via either TL1, CTC or SNMP, then you must wait for about 30 seconds to issue a TL1 command via the GNE. This delay is to permit the updates to propagate to all nodes in the network. During this transition, neither the old node name nor the new node name can be used in the TL1 session to access the ENE. This 30 second window may be reduced in Release 6.0.
Resolved Software Caveats for Release 4.1.5
The following items are resolved in Release 4.1.5.
Hardware
DDTS # CSCdv05723 and DDTS # CSCdw37046
DS-3 traffic hits can occur during synchronization changes (frequency offsets applied) on the node's timing.
A specific scenario under which this has been seen involves configurations with multiple nodes line-timed off each other in series. If a network configuration has a DS-3 circuit routed over a chain of nodes that are line-timed off each other in sequence (more than 1 line-timed "hop"), the DS-3 traffic might exhibit errors on timing disturbances applied on the source node.
The other scenario involves an abrupt change in reference frequency between two nodes. This can result in test set errors.
This issue is resolved in Release 4.1.
ML-Series Cards
DDTS # CSCdz87944
Error messages indicating "Stuck Ucode" and "MDA_INTERNAL_ERROR" occur when routing 64-byte VLAN tagged frames at line rate. For VLANs, use bridging instead of routing. This issue is resolved in Release 4.0.
DDTS # CSCed31946
An STS-24C circuit with oversubscription (more than 1 GigE of traffic) can incur possible loss of some high priority packets (such as VoIP) when using an STS-24C POS circuit between ML-series cards. The input error count can be seen in "show int pos." To avoid this issue, limit total ring traffic to 1 Gbit, or upgrade to Maintenance release 4.1.4. This issue is resolved in Release 4.1.4.
DDTS # CSCed13435
When overloading ML-1000 with Gig rate 64 byte traffic in both directions over RPR, traffic in one direction might get only about 20% throughput. This occurs only during heavy oversubscription of the processing rate of the card, as described above, and only for specific traffic patterns over RPR, where RPR circuits are all created from POS 0 to POS 1, and all traffic has even-numbered MAC addresses at one end and odd-numbered MAC addresses at the other end. Generally, such heavy packets-per-second on a Gig link are not normal network behavior, and so this should not be a traffic affecting issue in a deployed network. This issue is resolved in Release 4.1.4.
DDTS # CSCed21693
Unicast traffic added to the RPR ring always load balances solely based on the source and destination MAC addresses; this might cause load-balancing issues when routers are connected to RPR. This issue is resolved in Release 4.1.4.
DDTS # CSCec78266
Under certain conditions, the transmitter of an ML-100 FastEthernet interface might stop transmitting. The interface receives traffic but does not transmit traffic, and transmit counts on the ML-100 FastEthernet interface do not increment. No alarms are raised. A card reset is required to restore traffic.
To prevent this issue, enable auto-negotiation and disable flow control on both ends of each FastEthernet link. Use the following ML-100 interface commands:
speed auto
flowcontrol send off
If auto-negotiation is undesirable, the chance of the issue occurring can be reduced by disabling flow-control on the device at the other end of the ML-100 FastEthernet link.
This issue is resolved in Release 4.6 and maintenance Release 4.1.3.
DDTS # CSCin25238
If you configure Fast EtherChannel and POS-channel in the same bridge group, during system boot, the Fast EtherChannel or POS-channel configuration may be lost and following error message displayed:
Interface FastEthernet1 is attempting to join Port-channel1. But Port-channel1 belongs to bridge-group 1 which has another FE(C) member in it. FEC + FE(C) is not allowed in the same bridge group. Please change your configuration and retry
.This issue is resolved in Release 4.1.
DDTS # CSCea23629
During an upgrade, all ML-series cards are reset at the same time. This can result in a lengthy disruption to local traffic. This issue will be resolved in a future release, in which the upgrade will be altered to reset ML cards one at a time, so that L2/L3 protection can be used to minimize loss of local add/drop traffic during node upgrade. This issue is resolved in Release 4.1.
DDTS # CSCea18623
To avoid possible ML-series card resets when adding interfaces to a bridge group, always configure the Spanning-Tree Protocol for the bridge group (using the bridge number protocol command) before performing any other configuration on the bridge group.
If you want to use a bridge group that does not run the Spanning-Tree Protocol, you must first configure the bridge group with the Spanning-Tree Protocol, and then disable the Spanning-Tree Protocol for that bridge group on every interface where it is used (using the bridge-group number spanning-disabled interface configuration command). This issue is resolved in Release 4.1.
G Series Cards
DDTS # CSCec03291
A G1-K traffic loss can occur on a software upgrade from Release 4.0, 4.1, or 4.5 to a later software release in an ONS 15454 node with XC or XCVT cards installed. This issue does not occur if the equipment has XC10G cards installed. This issue is resolved in Release 4.6 and maintenance Release 4.1.3
DDTS # CSCec05896
When a G-series card is used in transponder mode the severity of reported alarms is incorrect in some cases. When using transponder mode on G-series cards, if alarm severity is an issue, use the alarm profile editor to set the severity to the desired values. This issue is resolved in Release 4.6 and maintenance Release 4.1.3.
DDTS # CSCeb80771
An Ethernet traffic hit of 500-600 ms may occur when upgrading to Release 4.1 from a prior release. This can occur if active traffic is running on a G1000-4, G1K-4 or G1000-2 card when upgrading the node to Release 4.1. The hit will occur only the first time that you upgrade to Release 4.1. On subsequent downgrades followed by upgrades there will be no traffic hit and the upgrade will be errorless. There is no workaround; however the issue will not occur when upgrading from Release 4.1 to a later release. This issue is resolved in Releases 4.1.3 and 4.6.
Line Cards
DDTS # CSCed06531
Malformed IP packets can potentially cause the XTC, TCC/TCC+/TCC2 and TCCi/TCC2 control cards to reset. Repeated transmission of these malformed packets could cause both the control cards to reset at the same time. This issue is resolved in Release 5.0, and maintenance Releases 4.1.4, 2.3.5, 4.0.3, and 4.6.2.
DDTS # CSCed86946
Malformed ICMP packets can potentially cause the XTC, TCC/TCC+/TCC2 and TCCi/TCC2 control cards to reset. Repeated transmission of these malformed packets could cause both the control cards to reset at the same time. This issue is resolved in Release 5.0, and maintenance Releases 4.1.4, 2.3.5, 4.0.3, and 4.6.2.
DDTS # CSCec88426, CSCec88508, CSCed85088
Malformed TCP packets can potentially cause the XTC, TCC/TCC+/TCC2, and TCCi/TCC2 control cards to reset. Repeated transmission of these malformed packets could cause both the control cards to reset at the same time. This issue is resolved in Release 5.0, and maintenance Releases 4.1.4, 2.3.5, 4.0.3, and 4.6.2.
DDTS # CSCec59739, CSCed02439, CSCed22547
The XTC, TCC/TCC+/TCC2 and TCCi/TCC2 control cards are susceptible to a TCP-ACK Denial of Service (DoS) attack on open TCP ports. The controller card on the optical device will reset under such an attack.
A TCP-ACK DoS attack is conducted by withholding the required final ACK (acknowledgement) for a 3-way TCP handshake to complete, and instead sending an invalid response to move the connection to an invalid TCP state. This issue is resolved in maintenance Releases 4.1.4, 2.3.5, 4.0.3, and 4.6.2.
DDTS # CSCec88402, CSCed31918, CSCed83309, CSCec85982
Malformed UDP packets can potentially cause the XTC, TCC/TCC+/TCC2, and TCCi/TCC2 control cards to reset. Repeated transmission of these malformed packets could cause both the control cards to reset at the same time. This issue is resolved in Release 5.0, and maintenance Releases 4.1.4, 2.3.5, 4.0.3, and 4.6.2.
DDTS # CSCea16455, CSCea37089, CSCea37185
Malformed SNMP packets can potentially cause the XTC, TCC/TCC+/TCC2 and TCCi/TCC2 control cards to reset. Repeated transmission of these malformed packets could cause both the control cards to reset at the same time. This issue is resolved in Release 4.6, and maintenance Releases 4.0.1, 4.0.3, and 4.1.3.
DDTS # CSCeb63327
The High Temperature Alarm is raised at 50 degrees Celsius. This is, however, not optimal on an Itemp rated system, which can tolerate up to 65 degrees Celsius. To work around this issue, the alarm can be downgraded or suppressed, but note that this will result in no temperature alarm provided at all. Alternatively, Cisco TAC provides a method of retrieving the temperature from the node, which can thus be monitored periodically for temperature-related problems. This issue is resolved in Release 4.6, and in maintenance Release 4.1.3.
DDTS # CSCed05846
In Releases 4.0, 4.0.1, and 4.1 the standby TCC+, TCC2, or XTC card might reset automatically. This can occur at any time, but only rarely. This issue is resolved in Release 4.6, and maintenance releases 4.1.1 and 4.1.3.
Maintenance and Administration
DDTS # CSCeb07274
Meaningless trailing characters might be seen in the domain name within the CTC network view. A workaround is to limit the number of CTC sessions to one. This issue is resolved in Releases 4.1.5 and 4.6.2.
DDTS # CSCed27600
When a node is configured to run OSPF on the TCC LAN port, and then the it loses the Ethernet connection, workstation connectivity might also be lost. To avoid this, disable OSPF on the LAN port, or reconnect the Ethernet. This issue will be resolved Release 4.1.5.
DDTS # CSCee24230
You might be unable to select a link that connects to a virtual node in a domain during circuit manual routing. (A virtual node represents a real node that isn't present in the viewing domain.) Before invoking the Circuit Creation Dialog, the link of interest must connect to the real nodes inside a domain. To accomplish this, move the real node into the domain. This issue will be resolved Release 4.1.5.
DDTS # CSCee35403
When more than one user is logged into an ONS 15454/15327 network, nodes cannot be removed or deleted from the domains at the network view. If a node is moved from a domain to the parent view, the node immediately returns to its original domain. Nodes will also not be deleted. After repeated effort this procedure can work, but results are sporadic and unpredictable. To work around this issue, disable the global update feature that will update every user logged into a network of nodes whenever one user makes a change. This can be done by placing an altered CTC.INI file on each user's workstation. The result is that only the user who makes a change will see the change. This issue is resolved in Releases 4.1.5 and 4.6.2.
DDTS # CSCee55443
In Releases 4.1.4 and 2.3.5, when TCC-B is the active shelf controller card, the NE will not send SNMP traps to the provisioned trap destinations. When TCC-A is the active shelf controller card, SNMP traps will be sent. This only occurs in software Releases 2.3.5 and 4.1.4. To work around this issue, make TCC-A the active shelf controller card. This issue is resolved in all releases other than Releases 4.1.4 and 2.3.5.
DDTS # CSCed76192
If a host on the same Ethernet as a given NE sends ARP requests to the NE, with a source address that is in a restricted address range (see below), the NE might reboot and other cards in the shelf reset. The NE might become unmanageable under these circumstances. The NE will install an ARP entry for the illegal IP address, with the MAC supplied in the ARP request, thereby misrouting important addresses.
Restricted addresses are those in the loopback network, 127.0.0.0/8, in the multicast networks, 224.0.0.0/4, and in the cell bus network, 192.168.100.0/24.
The workaround is to ensure that no legitimate hosts have addresses in the illegal networks, and that no compromised hosts that might generate ARP attacks are on the Ethernet. This issue is resolved in Releases 4.0.3, 4.6.2, 4.1.5, and 5.0.
Transmission Control Protocol Specification
A vulnerability in the Transmission Control Protocol (TCP) specification (RFC793) has been discovered by an external researcher. The successful exploitation enables an adversary to reset any established TCP connection in a much shorter time than was previously discussed publicly. Depending on the application, the connection might be automatically reestablished. In other cases, a user must repeat the action (for example, open a new Telnet or SSH session). Depending on the attacked protocol, a successful attack might have consequences beyond terminated connection that also must be considered. This attack vector is only applicable to those sessions that terminate on a device (such as a router, switch, or computer) and not to those sessions that only pass through the device (for example, transit traffic that is being routed by a router). Also, this attack vector does not directly compromise data integrity or confidentiality.
All Cisco products that contain TCP stack are susceptible to this vulnerability.
This advisory is available at http://www.cisco.com/warp/public/707/cisco-sa-20040420-tcp-ios.shtml, and describes the vulnerability as it applies to Cisco products that run Cisco IOS® software.
A companion advisory that describes the vulnerability for products that do not run Cisco IOS software is available at http://www.cisco.com/warp/public/707/cisco-sa-20040420-tcp-nonios.shtml.
This issue is resolved in Releases 2.3.5, 4.1.4 and 4.6.2.
DDTS # CSCec31352
After modifying the IP address of a node to an address that is included in the 192.168.190.x range, cards in the shelf reboot. This issue is present in all major and minor releases through 4.1 and 4.5. To avoid this issue, do not provision static routes with a destination address in the subnet range 192.168.190.x, and avoid overlap between IP addresses in the network and the internal subnet range 192.168.190.x. If the issue does occur, reset your TCCs. This issue is resolved in Release 4.6 and in maintenance Release 4.1.4.
DDTS # CSCeb33776
VT level alarms fail to clear after traffic has recovered from an error. This can happen when you configure a VT 1.5 circuit terminating on a DS1 card, then inject UNEQ-V to the terminating node, wait for the UNEQ-V alarm to be raised, then terminate the UNEQ-V signal and restore normal traffic. This issue does not occur on intermediate nodes of the circuit. The UNEQ-V alarm can be cleared using a TCC side switch. This issue is resolved in Release 4.1.3.
DDTS # CSCec84338
With multiple unnamed circuits (circuit name listed as "Unknown") on a node, where at least one is a path protection circuit, a cross-connect from one of these unnamed circuits will incorrectly appear on the Circuit Edit > Path Protection Selectors, and Circuit Edit > Path Protection Switch Counts tabs of the other unnamed circuits. Also, the State tab will show paths in the wrong column (for example, both source and destination in the CRS End B column).
This issue can manifest anytime you create multiple unnamed circuits (via TL1 or from CTC using the TL1-like option) on a node, where at least one is a path protection circuit. This issue is resolved in Release 4.6 and maintenance Releases 4.1.1 and 4.1.3.
DDTS # CSCeb63327
The High Temperature Alarm is raised at 50 degrees Celsius. This is not appropriate on an Itemp rated system, which can handle up to 65 degrees Celsius. The alarm can be downgraded or suppressed to work around the issue, but then no temperature alarm at all is provided. Cisco TAC is providing a method of retrieving the temperature from the node that enables you to periodically monitor temperature related problems. This issue is resolved in Release 4.6 and in maintenance Release 4.1.3.
DDTS # CSCeb34133
When provisioning a circuit as OOS, path level PM collecting is not disabled. To work around this issue, deselect the IPPM for the path. This issue is resolved in Releases 4.1.3 and 4.6.
DDTS # CSCeb34133
When provisioning a circuit as OOS, path level PM collecting is not disabled. To work around this issue, deselect the IPPM for the path. This issue is resolved in Releases 4.1.3 and 4.6.
DDTS # CSCeb84342
Occasionally, after both power sources are removed and plugged in with one power source (Battery A), the node reboots but does not raise PWR-B alarms. To correct this, remove PWR-B and plug it back. This issue is resolved in Releases 4.6 and 4.1.3.
DDTS # CSCec20521
After addition and deletion of a static route that overlaps with the internal IP addresses range, all cards in the shelf reboot. This can also happen after the node learns a similar route through OSPF or RIP updates. This issue is present in all releases through 4.1 and 4.5. To avoid this issue, do not provision static routes with a destination address in the subnet range 192.168.190.x, and avoid overlap between IP addresses in the network and the internal subnet range 192.168.190.x. If the issue does occur, reset your TCCs. This issue is resolved in Release 4.6 and in maintenance Release 4.1.3.
DDTS # CSCec16812
UNEQ-V alarms are incorrectly raised prior to connecting a TAP to a TACC, and also after disconnecting the TAP from the TACC. This issue is resolved in Releases 4.1.1, 4.1.3, and 4.6.
DDTS # CSCdy01598
Rarely, there is a delay in CTC before the correct card status is displayed after a protection switch. When a manual or forced switch is made to a protection type, the protection switch occurs immediately, but the card status might take a while approximately 2 minutes to show up under rare circumstances. If a switch is not reflected right away, wait for the status change to occur. This issue is resolved in Release 4.1.
DDTS # CSCdy38603
VT Cross-connects downstream from a DS1 can automatically transition from the OOS-AINS state to the IS state even though the DS1 signal is not clean (for example, when there is an LOS present). This can occur when you have created a VT circuit across multiple nodes with DS1s at each end, and you have not yet applied a signal to the DS1 ports, and then you place the DS1 ports in OOS-AINS, OOS-MT, or IS. When you then place the circuit in OOS-AINS, the circuit state changes to IS (within one minute). This issue is resolved in Release 4.1.
BLSR Functionality
DDTS # CSCeb40296
IPPM counts for PCA (extra) traffic will not be displayed in CTC if a BLSR ring-switches back to working after a failure recovery. To work around this issue, lockout the ring by issuing a LockoutOfProtection (LK-S) user command on both east and west on all the nodes in the ring. Reboot the OCn card that is not showing PCA path level counts. This procedure needs to be done whenever there is a switch in BLSR configuration. This issue is resolved in Releases 4.1.3 and 4.6.
DDTS # CSCdy48872
Issuing an LK-S in one direction while a ring switch (SF-R) is active on the other direction may result in a failure to restore PCA circuits on the ring.
To see this issue, on a node participating in a two fiber BLSR with PCA circuits terminating at the node over the two fiber BLSR, cause an SF-R by failing the receive fiber in one direction (say, west). Then, issue an LK-S in the other direction (in our example, east). Since the LK-S has higher priority than the SF-R, the ring switch should clear and PCA traffic should be restored on spans without a fiber fault. The ring switch does clear, but PCA traffic does not restore. To correct this issue, clear the fiber fault. All traffic restores properly. This issue is resolved in Release 4.1.
DDTS # CSCdy65890
If you have PCA circuits over two-fiber or four-fiber BLSR protect channels, an incorrect auto-inservice transition occurs after traffic preemption. You may place the circuit back into the OOS-AINS state after the BLSR has returned to the unswitched mode, using the Circuit Editing pane of the CTC. This issue is resolved in Release 4.1.
TL1
DDTS # CSCed10618
If the TL1 craft port is disconnected while a retrieve level user (or a user with no timeout) is logged in, and there is a currently active CTC session, then the active TCC will reset. To avoid this, log the craft access user out before disconnecting the TL1 craft port. This issue is resolved in Release 4.6 and in maintenance Release 4.1.4.
DDTS # CSCed22816
The TL1 "COPY-RFILE" command fails when executed on an ENE through an ONS 15454 GNE. This issue occurs when a Checkpoint firewall is between the FTP server and the GNE. The 'COPY-RFILE' will work properly when executed on the GNE but fails when executed on the ENE with an ONS 15454 GNE. The workaround is to stop FTP protocol monitoring on the
Checkpoint firewall when the FTP client is a GNE and the FTP server is the COPY-RFILE server. This issue is resolved in Release 4.1.4.
DDTS # CSCec87770
In a TL1 GNE/ENE configuration where user does not log in (that is, where the user fails to issue an ACT-USER to the GNE Node), a TCC might reset and/or some lower priority tasks might become "CPU starved," resulting in one or all of the following consequences:
•TL1 Autonomous messages (alarms, events, and report database changes) not generated or processed
•LCD display not updated
To avoid this issue, be sure to log in via TL1 to the GNE node. This issue is resolved in Releases 4.0.2, 4.1.1, 4.1.4, and 4.6. It is not resolved in Releases 4.1.2 or 4.1.3.
DDTS # CSCec10357
Release 4.1 and 4.5 TL1 cannot display/retrieve/delete a DS3Xm VT Non-STS-1 cross-connection/circuit. This applies to ONS 15454s with DS3XM VT cross-connection provisioning via TL1, on any STS or port other than STS-1 or PORT-1, and with the AID format of:
VT1-Slot#-Sts#-Group#-Vt#
The cross-connection is provisioned as expected; however, the connection STS number in the TL1 VT AID format is always shown as "1" for the RTRV-CRS::ALL command and RTRV-CRS-VT1 with the AID used in the creation command (the non-one STS).
This issue has an impact on any DS3Xm VT connection deletion via TL1 where the STS number is not actually 1. The displayed VT1 AID cannot be used to retrieve the connection, and also cannot be used to delete the created connection. Also, the VT alarms/events/conditions on such a DS3XM VT circuit/connection will have the same AID issue: the StsNumber in the AID is always 1.
To work around this issue, delete the TL1-created DS3XM VT non-STS-1 cross-connection using the provisioned DS3XM VT AID (non-STS-1) or using CTC. There is no workaround for the alarm/event reporting for the non-STS-1 DS3XM VT circuit in the impacted releases (4.1 and 4.5). This issue is resolved in Release 4.6 and in maintenance Release 4.1.3.
DDTS # CSCdz79471
The default state, when no PST or SST inputs are given for The TL1 command, RMV-<MOD2_IO>, is OOS instead of OOS-MT. Thus, if you issue a RMV statement, followed by maintenance-state-only commands, such as OPR-LPBK, the maintenance state commands will not work, since the port will be in the out-of-service state (OOS), instead of the out-of-service maintenance state (OOS-MT). To work around this issue, place ports in the OOS-MT state, by specifying the primary state as OOS and a secondary state of MT in either the RMV-<MOD2_IO> command or the ED-<MOD2_IO> command.
Scripts that depend on the RMV-<MOD2_IO> command defaulting to OOS-MT without specifying the primary and secondary states should be updated to force the primary and secondary state inputs to be populated. This issue is resolved in Release 4.1.
DDTS # CSCea03186
The TL1 command, INH-USER-SECU, does not disable the userid appropriately. The command should disable the userid until the corresponding ALW-USER-SECU command is issued; however, the userid is automatically re-enabled after the user lock-out period expires. The user lockout period is set from the CTC. This issue is resolved in Release 4.1.
New Features and Functionality
This section highlights new features and functionality for Release 4.1.x. For detailed documentation of each of these features, consult the user documentation.
New Software Features and Functionality
DS3i-N-12 Card Support for SONET Platforms
Release 4.1.3 adds SONET support for the DS3i-N-12 card, as specified herein. For DS3i-N-12 card features and specifications, refer to the Cisco ONS 15454 SDH Reference Manual, R4.1.x and R4.5.
Compatibility and Interoperability
The DS3i-N-12 card is not compatible with the DS3 or the DS3E card. There is no in-service upgrade path from DS3 or DS3E to DS3i-N-12. Plugging a DS3i-N-12 card into a slot provisioned for DS3 will result in an MEA. Plugging a DS3 card into a slot provisioned for DS3i-N-12 will result in an MEA.
The DS3i-N-12 card operates with either the XC10G or the XCVT card. Future cross connect cards will be supported as they become available.
The DS3i-N-12 card operates with either the TCC+ or the TCC2 as the shelf controller as long as the particular type of TCC card is supported with the particular software release. Future shelf controller cards will be supported as they become available.
Caution Plugging a DS3i-N-12 card into a SONET chassis running a 4.0 or later software release that does not support the DS3i-N-12 will result in an MEA. On software releases prior to 4.0, the DS3i-N-12 card will continuously reboot without raising any alarm.
Circuit Provisioning
The following guidelines apply for circuit provisioning with the DS3i-N-12 card.
•A circuit from a DS3i-N-12 port to a DS3 port cannot be provisioned.
•A circuit from a DS3i-N-12 port on an ONS 15454 (SONET) node to a DS3i-N-12 port on another ONS 15454 node can be made.
•A circuit from a DS3i-N-12 port on an ONS 15454 (SONET) node to a DS3i-N-12 port on an ONS 15454 SDH node can be made, but there will be no end-to-end provisioning. The circuit must be provisioned in a two part process: The DS3i-N-12 to optical card is provisioned on the SONET side and the DS3i-N-12 to the corresponding SDH optical card is provisioned.
•You are only allowed to create STS3C circuits from/to the DS3i-N-12 card.
•There can only be four independent STS3C circuits provisioned from/to the DS3i-N-12 card.
•The ports used in each of the STS3C circuits are 1, 2, and 3; 4, 5, and 6; 7, 8, and 9; 10, 11, and 12.
•Each port on the DS3i-N-12 card can be provisioned independently in or out of service, but if less than three ports are used, the extra bandwidth is underutilized, because the STS3C will still be provisioned across the span cards.
•You cannot add or drop individual DS3 circuits out of the STS3C on intermediate nodes. To maximize bandwidth utilization, you must fill the STS3C at the circuit endpoints on the DS3i-N-12 cards by using the three contiguous DS3i-N-12 ports allocated to the particular STS3C.
Note When provisioning circuits in SDH to interoperate with SONET DS3i-N-12, you must create a VC4 containing VC3s as a payload in the exact order in which they will attach to port groups on the SONET side.
Protection Group Support
For SONET nodes, the DS3i-N-12 card supports 1:1 and 1:N where 1 <= N <= 5. Any DS3i-N-12 card can function as a protect card in a 1:N protection group. The working and protect slots follow the convention for other 1:1 and 1:N electrical protection groups.
For 1:1 protection:
•Slot 1 protects Slot 2
•Slot 3 protects Slot 4
•Slot 5 protects Slot 6
•Slot 13 protects Slot 12
•Slot 15 protects Slot 14
•Slot 17 protects Slot 16
For 1:N protection, the protect Slot 3 can protect Slots 1, 2, 4, 5, and 6; and protect Slot 15 can protect Slots 12, 13, 14, 16, and 17.
Mixed protection groups between DS3 and DS3i-N-12 cards are not supported.
Protection switching for 1:1 and 1:N meets required 60 ms switch times.
Switch times for XCVT or XC10G side switches meet required 60 ms switch times.
The current equipment protection behavior of switch, lock on, and lock out are supported.
Performance Monitoring Support
Releases 4.1.3 and 4.1.4 support the following performance monitoring functions related to the DS3i-N-12.
•Enhanced DS3 PMs for C-bit and M13 framing mode are supported (similar to the DS3E cards).
•Automatic DS3 frame format detection is supported (similar to the DS3E card).
•Path level PMs are supported at the STS level similar to the current DS3 cards.
•Intermediate optical cards only support monitoring path level PMs on the STS3C circuit.
•Far end path PMs are supported at the STS level similar to the current DS3 cards.
Note The default DS3i-N-12 framing type (provisionable from the Maintenance > Provisioning tab) matches the default for SDH (in other words, it is C-bit).
Note The DS3i-N-12 does not have the latest C-bit detection capability released in the Release 4.1 time frame for the DS3E card.
Alarm Support
SD/SF BER calculation is performed at the DS3 line level (similar to the DS3 cards). SD/SF alarming occurs if the BER exceeds the provisioned SD, or SF thresholds, respectively. The SF alarm suppresses the reporting of the SD alarm.
The DS3i-N-12 card supports the standard DS3 alarms, LOS and LOF.
Path Trace Support
The DS3i-N-12 card supports setting and reading of a 16 or 64 byte J1 path trace string.
Intermediate monitoring of the J1 path trace by the optical cards is not supported.
On a path trace mismatch, the TIM-P alarm is raised.
Generation of AIS on TIM-P is user-provisionable as "on" or "off."
Software Upgrade Support
Software upgrades are errorless for TCC2/XC10G systems.
Note If there is a DS3i-N-12 protection group, the protect card must be in the standby state before the software activation process.
CTC Support
As of Release 4.1.3 the column "Path Width" has been added to Alarms, Conditions and History panes. The Path Width column provides the width of the STS path on which the alarm is raised or cleared, in units of STS (how many STSs wide the path is). The path width only applies to the "STS-" alarmable object type. For any non-STS object, the column remains blank.
CTC also supports the following functionality for the DS3i-N-12 card as of Release 4.1.3.
•Preprovisioning of a slot for DS3i-N-12
•Creating a 1:1 or 1:N protection group with DS3i-N-12, enforcing the limitations specified under the protection section
•Maintenance mode operations (loopbacks, protection switching, ports in and out of service, etc.)
•Shelf view and the card view display of a DS3i-N-12 card
•NE defaults for the DS3i-N-12 card on the SONET platform that match the defaults available on the SDH platform
TL1 Support
TL1 supports the DS3i-N-12 card for the following commands.
•ENT-EQPT, to provision the DS3i-N-12 card.
•RTRV-EQPT, to retrieve the DS3i-N-12 card parameters.
•ENT-CRS-STS, for circuit creation.
•ED-T3, to provision the ports of the DS3i-N-12 card.
•ED-EQPT, to ensure protection group creation rules for the DS3i-N-12 card.
•RTRV-PM-STS, for PM retrieval at the Path level.
•RTRV-PM-T3, for PM retrieval at the Line level.
•RTRV-ALM, to ensure alarms are being retrieved correctly.
•RTRV-STS, for setting and retrieving the Path trace strings.
ML-Series Resilient Packet Ring
RPR (Resilient Packet Ring) is a new protocol available on the ML-Series cards enabling you to use SONET bandwidth more efficiently, with 50 ms recovery times.
Basic Feature Description
RPR for the ML-Series line cards provides a set of enhancements to the performance of any such card running the Release 4.1.x. These improvements include:
RPR for the ML-Series line cards allows new deployment applications for all cards running Release 4.1.x. These improvements include:
•Better SONET bandwidth utilization compared to an STP controlled ring topology.
•Non-SONET fail-over mechanism with sub 50-millisecond convergence for fiber cuts, restores, node failures and inserting new nodes.
•Ability to perform ML-Series QOS (quality of service) features on all SONET traffic (pass-through, drop, and add).
•No hardware changes: Only requires ONS 15454 Release 4.1.x, which includes the new IOS configuration.
•Increased number of supportable VLANs and MAC addresses on the ring.
•A scalable, inter-ring protection mechanism for increased network resiliency.
•The addition of RPR does not remove any Release 4.0 functionality. RPR features are enabled via a new set of configuration commands.
For further details of RPR uses and features, consult the user documentation for Release 4.1.x.
Open Ended Path Protection
In previous releases, you could create an end-to-end path protection circuit on any Cisco ONS 15XXX network using A-Z provisioning of CTC/CTM. This feature requires you to specify one source node and one destination node of a path protection circuit. CTC/CTM requires these nodes to be part of the network that is discovered by CTC/CTM.
With Release 4.1.x you can create an open ended path protection circuit in addition to a regular path protection. An open ended path protection circuit is a partial path protection circuit. This feature helps you create end-to-end path protection circuits where a part of the given path protection circuit is on a Cisco 15XXX network, while the other part of the circuit is on another vendor's equipment. The circuit may consist of one source point and two end points. There are two paths from the source; one path is from the source to one end point and the other path is from the source to the other end point. The source has a bridge that sends the traffic on both paths. The end points do not have any selectors and may hand off the traffic to another vendor's equipment. For bidirectional circuits, the source also contains a selector for the reverse traffic from end points to source. Alternatively, open ended path protection can be used to create a circuit with two sources and one destination. In the unidirectional case, the destination node has a selector, and the source nodes have one-way connections.
NE Defaults
The NE defaults pane user interface is changed in Release 4.1.x as follows:
•The NE defaults pane now has a highlighted title at the top of the pane, indicating the last action taken by the user.
•If you import or export a file, the title shows the file name and the time of the action.
•If you load or apply a file to the node, the changes and the time of the action will be displayed.
User Privileges
As of Release 4.1.x, The following user privileges have changed:
•A Maintenance level user can back up the database and transfer a software package to the node.
•A Provisioning level user can delete and reset cards.
Protect Threshold Crossing Alarms
As of Release 4.1.x, BLSR/MS-SPR and path protection/SNCP protect thresholds at both the card and port level are inherited from the working card/port.
C-bit framing
To be compatible with certain legacy deployments, the DS3-12E card C bit detection algorithm has changed conjunction with Release 4.1.x through an FPGA change in the DS3-12E modules.
Gigabit Ethernet Transponder
The Gigabit Ethernet Transponder is a software enhancement to existing G-series Ethernet cards that allows these cards to support transponder functionality.
The following features support Gigabit Ethernet Transponder functionality for Release 4.1.x.
Note In this section, unless otherwise mentioned, all items apply equally to both G1000-4 cards and G1K-4 cards. Some capabilities also apply to G1000-2 cards.
CWDM GBICs
Note This applies only to the ONS 15454-based G-series cards (G1000-4 and G1K-4).
CWDM GBICs correspond to the eight wavelengths supported by the Cisco CWDM GBIC solution on the ONS 15454: CWDM-GBIC-1470, CWDM-GBIC-1490, CWDM-GBIC-1510, CWDM-GBIC-1530, CWDM-GBIC-1550, CWDM-GBIC-1550, CWDM-GBIC-1570, CWDM-GBIC-1590.
DWDM GBICs
This applies only to the latest revision of the ONS 15454-based G-series cards (G1000-4 and G1K-4).
DWDM GBICs correspond to the 32 different ITU-100GHz wavelengths supported on the ONS 15454: 1530.33, 1531.12, 1531.90, 1532.68, 1534.25, 1535.04, 1535.82, 1536.61, 1538.19, 1538.98, 1539.77, 1540.56, 1542.14, 1542.94, 1543.73, 1544.53, 1546.12, 1546.92, 1547.72, 1548.51, 1550.12, 1550.92, 1551.72, 1552.52, 1554.13, 1554.94, 1555.75, 1556.55, 1558.17, 1558.98, 1559.79, and 1560.61. The ONS 15454 version DWDM GBICs are the only officially supported DWDM GBICs for the G-Series Ethernet cards. These GBICs have wideband reception capability and can receive with adequate sensitivity across the 1260-1620 nm range (refer to GBIC specs in the user documentation for details). This capability can be exploited in some of the transponder applications.
GBIC Notes
New GBICs are supported for only those vendors/brands that are officially certified for use on the ONS 15454.
GBIC inventorying functions are not currently supported. However, the type of GBIC plugged in and the wavelength used are displayed to CTC and TL1 users (as well as CTM users when CTM support is added).
Performance monitoring of optical parameters such as DWDM power levels per wavelength are not supported in Release 4.1.x.
The GBIC security feature is not supported in Release 4.1.x.
Three Transponder Modes of Operation
Release 4.1.x supports three transponder modes of operation:
Bidirectional 2-port transponder
Bidirectional 1-port transponder
Unidirectional 2-port transponder
This applies only to the ONS 15454-based G-series cards (G1000-4 and G1K-4). This feature also includes the ability of the cards to operate (when in transponder mode) independent of the cross connect cards and even operate without any cross connect cards in the shelf.
When at least one port is provisioned in a transponder mode, the entire card will be in transponder mode. When SONET/SDH circuits are provisioned on a card, the card is said to be in normal/SONET mode.
Hybrid mode of operation is not supported in Release 4.1.x. At any given time, a card can be either in transponder mode (with one or more ports being provisioned to provide transponder capabilities) or in normal SONET mode. A mixed or hybrid mode (in which only some ports are performing transponder functions while others are switching traffic into the SONET/SDH network) is not supported and you will be prevented from provisioning such a combination. In order to move a card from SONET mode to transponder mode you must first delete all SONET/SDH circuits terminating on the card, after which ports will become provisionable as transponders. Similarly you must first turn off transponder mode on all ports before a card can become eligible for SONET/SDH circuits again.
Facility Loopback
Facility Loopback is supported for Release 4.1.x transponder functionality.
This applies to all G-series cards (G1000-4 and G1K-4 on the ONS 15454 and G1000-2 on the ONS 15327).
Provisionable Flow Control Watermarks
Provisionable flow control watermarks are supported for Release 4.1.x. This capability enables the user to tune the flow control mechanism on the G-Series cards for some network applications.
This applies to all G-series cards (G1000-4 and G1K-4 on the ONS 15454 and G1000-2 on the ONS 15327).
Changed Alarms
The following alarms have changed as of Release 4.1.x.
SONET CRITICAL Alarms
LOC is added in Release 4.1.x.
SONET MAJOR Alarms
OTUK-IAE is dropped in Release 4.1.x.
PLM-V is added in Release 4.1.x.
SQUELCHED is MJ in Release 4.0 but changed to NA in Release 4.1.x.
FEC-MISM is added in Release 4.1.x.
SONET MINOR Alarms
OTUK-TIM is MN in Release 4.0 but changed to NA in Release 4.1.x.
SONET NA/NR Conditions
ERFI-P-CONN is added in Release 4.1.x.
ERFI-P-PAYLD is added in Release 4.1.x.
ERFI-P-SRVR is added in Release 4.1.x.
EXERCISE-RING-FAIL is added in Release 4.1.x.
EXERCISE-SPAN-FAIL is added in Release 4.1.x.
INTRUSION-PSWD is added in Release 4.1.x.
LPBKFACILITY (G-Series) is added in Release 4.1.x.
New TL1 Features
The following TL1 features are new for release 4.1.x. For detailed instructions on using TL1 commands, consult the TL1 Command Guide for Release 4.1.x.
Removed Commands
The following commands were dropped from Release 4.0.
REPT^ALM^SECU
ALW-USER-SECU
INH-USER-SECU
New Commands
The following command was added in Release 4.1.x.
CLR-COND-SECU
New Support
The following new support has been added for Release 4.1.x.
•Facility loopbacks on G1000 are supported in Release 4.1.x.
•Escaped double quotes (\")" was introduced in Release 4.1.x for Inner Strings (See Telcordia GR-831-CORE, Section 2.2.10) for GR compliance.
•In the command COPY-RFILE, DB backup and DB Download can be done by a MAINT user in Release 4.1.x (in addition to SUPERUSER).
•Negative MonLevels are accepted in Release 4.1.x.
•The command RTRV-COND-SYNCN can be used with the ALL AID to suppress conditions with the same root cause. This behavior is enhanced in Release 4.1.x to display all Synchronization related conditions.
•The ED-BITS and RTRV-BITS commands now support the AIDs SYNC-BITS1 and SYNC-BITS2 for setting and retrieving the BITS-OUT port state.
•The parameter VOATTN, in ED/RTRV-OCH, has a range of -40 to +30.
The following BLSR ringid alarms are changed in Release 4.1.x to report on the OCn port.
•BLSROSYNC, MN, NSA, "BLSR Out Of Sync"—Always reported against the East working OCn facility of the BLSR.
•APSCNMIS, MN, NSA, "Node Id Mismatch"—Always reported against the working OCn facility that detects the mismatch.
•RING-MISMATCH, MN, NSA, "Far End Of Fiber Is Provisioned With Different Ring ID"—Always reported against the East working OCn facility of the BLSR.
Command Request changes
In the following command requests, the Release 4.0 request syntax appears first, followed by the new Release 4.1.x syntax.
ED-G1000 In Release 4.0:
ED-G1000:[<TID>]:<aid>:<CTAG>:::[MFS=<mfs>,][FLOW=<flow>,]:[<pst>],[<sst>];
ED-G1000 In Release 4.1.x:
ED-G1000:[<TID>]:<aid>:<CTAG>:::[MFS=<mfs>,][FLOW=<flow>,][LOWMRK=<lowmrk>,][HIWMRK=<hiwmrk>]:[<pst>],[<sst>];
ED-T1 in Release 4.0:
ED-T1:[<TID>]:<aid>:<CTAG>:::[LINECDE=<linecde>,][FMT=<fmt>,][LBO=<lbo>,][TACC=<tacc>,][SOAK=<soak>,]:[<pst>],[<sst>];
ED-T1 in Release 4.1.x:
ED-T1:[<TID>]:<aid>:<CTAG>:::[LINECDE=<linecde>,][FMT=<fmt>,][LBO=<lbo>,][TACC=<tacc>,][SOAK=<soak>,][SFBER=<sfber>,][SDBER=<sdber>]:[<pst>],[<sst>];
ED-T3 in Release 4.0:
ED-T3:[<TID>]:<aid>:<CTAG>:::[LINECDE=<linecde>,][FMT=<fmt>,][LBO=<lbo>,][TACC=<tacc>,][SOAK=<soak>,]:[<pst>],[<sst>];
ED-T3 in Release 4.1.x:
ED-T3:[<TID>]:<aid>:<CTAG>:::[LINECDE=<linecde>,][FMT=<fmt>,][LBO=<lbo>,][TACC=<tacc>,][SOAK=<soak>,][SFBER=<sfber>,][SDBER=<sdber>]:[<pst>],[<sst>];
ED-EC1 in Release 4.0:
ED-EC1:[<TID>]:<aid>:<CTAG>:::[PJMON=<pjmon>,][LBO=<lbo>,][SOAK=<soak>,]:[<pst>],[<sst>];
ED-EC1 in Release 4.1.x:
ED-EC1:[<TID>]:<aid>:<CTAG>:::[PJMON=<pjmon>,][LBO=<lbo>,][SOAK=<soak>,][SFBER=<sfber>,][SDBER=<sdber>]:[<pst>],[<sst>];
Command Response changes
In the following command responses, the Release 4.0 response syntax appears first, followed by the new Release 4.1.x syntax.
RTRV-USER-SECU response in Release 4.0:
"<uid>:,<uap>"
RTRV-USER-SECU response in Release 4.1.x:
"<uid>:,<uap>:LOGGEDIN=<loggedin>[,NUMSESSIONS=<numsess>],LOCKEDOUT=<lockedout>"
RTRV-G1000 response in Release 4.0:
"<aid>::[MFS=<mfs>,][FLOW=<flow>,][LAN=<lan>,][OPTICS=<optics>:[<pst>],[<sst>]"
RTRV-G1000 response in Release 4.1.x:
"<aid>::[MFS=<mfs>,][FLOW=<flow>,][LAN=<lan>,][OPTICS=<optics>,][TRANS=<trans>,][TPORT=<tport>,][LOWMRK=<lowmrk>,][HIWMRK=<hiwmrk>]:[<pst>],[<sst>]"
RTRV-T1 response in Release 4.0:
"<aid>::[LINECDE=<linecde>,][FMT=<fmt>,][LBO=<lbo>,][TACC=<tap>,][SOAK=<soak>,]:<pst>,[<sst>]"
RTRV-T1 response in Release 4.1.x:
"<aid>::[LINECDE=<linecde>,][FMT=<fmt>,][LBO=<lbo>,][TACC=<tap>,][SOAK=<soak>,][SOAKLEFT=<soakleft>,][SFBER=<sfber>,][SDBER=<sdber>]:<pst>,[<sst>]"
RTRV-T3 response in Release 4.0:
"<aid>::[LINECDE=<linecde>,][FMT=<fmt>,][LBO=<lbo>,][TACC=<tap>,][SOAK=<soak>,]:<pst>,[<sst>]"
RTRV-T3 response in Release 4.1.x:
"<aid>::[LINECDE=<linecde>,][FMT=<fmt>,][LBO=<lbo>,][TACC=<tap>,][SOAK=<soak>,][SOAKLEFT=<soakleft>,][SFBER=<sfber>,][SDBER=<sdber>]:<pst>,[<sst>]"
RTRV-OCH response in Release 4.0:
"<aid>:,,,[<status>]:[RDIRN=<rdirn>,][OPTYPE=<opticalPortType>,][OPWR=<power>,][EXPWLEN=<expWlen>,][ACTWLEN=<actWlen>,][ILOSS=<iloss>,][VOAMODE=<voamode>,][VOAATTN=<voaattn>,][VOAPWR=<voapwr>,][VOAREFATTN=<voarefattn>,][VOAREFPWR=<voarefpwr>,][REFOPWR=<refopwr>,][CALOPWR=<calopwr>,][NAME=<portname>,][SFBER=<sfber>,][SDBER=<sdber>,][ALSMODE=<alsmode>,][ALSRCINT=<alsrcint>,][ALSRCPW=<alsrcpw>,][COMM=<comm>,][GCCRATE=<gccrate>,][DWRAP=<dwrap>,][FEC=<fec>,][OSFBER=<osfber>,][OSDBER=<osdber>,][MACADDR=<macaddr>,][SYNCMSG=<syncmsg>,][SENDDUS=<senddus>,][LSRSTAT=<lsrstat>,][SOAK=<soak>,]:<pst>,[<sst>]"
RTRV-OCH response in Release 4.1.x:
"<aid>:,,,[<status>]:[RDIRN=<rdirn>,][OPTYPE=<opticalPortType>,][OPWR=<power>,][EXPWLEN=<expWlen>,][ACTWLEN=<actWlen>,][ILOSS=<iloss>,][VOAMODE=<voamode>,][VOAATTN=<voaattn>,][VOAPWR=<voapwr>,][VOAREFATTN=<voarefattn>,][VOAREFPWR=<voarefpwr>,][REFOPWR=<refopwr>,][CALOPWR=<calopwr>,][NAME=<portname>,][SFBER=<sfber>,][SDBER=<sdber>,][ALSMODE=<alsmode>,][ALSRCINT=<alsrcint>,][ALSRCPW=<alsrcpw>,][COMM=<comm>,][GCCRATE=<gccrate>,][DWRAP=<dwrap>,][FEC=<fec>,][OSFBER=<osfber>,][OSDBER=<osdber>,][MACADDR=<macaddr>,][SYNCMSG=<syncmsg>,][SENDDUS=<senddus>,][LSRSTAT=<lsrstat>,][SOAK=<soak>,][SOAKLEFT=<soakleft>]:<pst>,[<sst>]"
RTRV-CLNT response in Release 4.0:
"<aid>:,,[<role>],<status>:[NAME=<portname>,][COMM=<comm>,][SFBER=<sfber>,][SDBER=<sdber>,][ALSMODE=<alsmode>,][ALSRCINT=<alsrcint>,][ALSRCPW=<alsrcpw>,][SYNCMSG=<syncmsg>,][SENDDUS=<senddus>,][LSRSTAT=<lsrstat>,][CLEI=<clei>,][PN=<partnum>,][SN=<serialnum>,][VENDOR=<vendor>,][VENDORREV=<vendorrev>,][PLGTYPE=<plgtype>,][MACADDR=<macaddr>,][SOAK=<soak>,]:<pst>,[<sst>]"
RTRV-CLNT response in Release 4.1.x:
"<aid>:,,[<role>],<status>:[NAME=<portname>,][COMM=<comm>,][SFBER=<sfber>,][SDBER=<sdber>,][ALSMODE=<alsmode>,][ALSRCINT=<alsrcint>,][ALSRCPW=<alsrcpw>,][SYNCMSG=<syncmsg>,][SENDDUS=<senddus>,][LSRSTAT=<lsrstat>,][CLEI=<clei>,][PN=<partnum>,][SN=<serialnum>,][VENDOR=<vendor>,][VENDORREV=<vendorrev>,][PLGTYPE=<plgtype>,][MACADDR=<macaddr>,][SOAK=<soak>,][SOAKLEFT=<soakleft>]:<pst>,[<sst>]"
RTRV-OCN response in Release 4.0:
"<aid>:,,[<role>],[<status>]:[DCC=<dcc>,][TMGREF=<tmgref>,][SYNCMSG=<syncmsg>,][SENDDUS=<senddus>,][PJMON=<pjmon>,][SFBER=<sfber>,][SDBER=<sdber>,][MODE=<mode>,][WVLEN=<wvlen>,][RINGID=<ringid>,][BLSRTYPE=<blsrtype>,][MUX=<mux>,][UNIC=<unic>,][CCID=<ccid>,][NBRIX=<nbrix>,][SOAK=<soak>,]:<pst>,[<sst>]"
RTRV-OCN response in Release 4.1.x:
"<aid>:,,[<role>],[<status>]:[DCC=<dcc>,][TMGREF=<tmgref>,][SYNCMSG=<syncmsg>,][SENDDUS=<senddus>,][PJMON=<pjmon>,][SFBER=<sfber>,][SDBER=<sdber>,][MODE=<mode>,][WVLEN=<wvlen>,][RINGID=<ringid>,][BLSRTYPE=<blsrtype>,][MUX=<mux>,][UNIC=<unic>,][CCID=<ccid>,][NBRIX=<nbrix>,][SOAK=<soak>,][SOAKLEFT=<soakleft>]:<pst>,[<sst>]"
RTRV-EC1 response in Release 4.0:
"<aid>::[PJMON=<pjmon>,][LBO=<lbo>,][RXEQUAL=<rxequal>,][SOAK=<soak>,]:<pst>,[<sst>]"
RTRV-EC1 response in Release 4.1.x:
"<aid>::[PJMON=<pjmon>,][LBO=<lbo>,][RXEQUAL=<rxequal>,][SOAK=<soak>,][SOAKLEFT=<soakleft>,][SFBER=<sfber>,][SDBER=<sdber>]:<pst>,[<sst>]"
ENUM changes
The following enum items have changed for Release 4.1.x.
ALS_RESTART enum items added to Release 4.1.x:
ALS_RESTART_AUTO => "AUTO-RESTART"
ALS_RESTART_MAN => "MAN-RESTART"
ALS_RESTART_MAN_TEST => "MAN-TEST-RESTART"
MOD2 enum items added to Release 4.1.x:
MOD2_M2_G1000 => "G1000"
OPTICS enum items dropped from Release 4.0:
OPTICS_OP_IR => "IR"
OPTICS_OP_LR => "LR"
OPTICS_OP_SR => "SR"
OPTICS_OP_VLR => "VLR"
OPTICS enum items added to Release 4.1.x:
OPTICS_OP_1000_BASE_CX => "1000_BASE_CX"
OPTICS_OP_CWDM_1470 => "CWDM_1470"
OPTICS_OP_CWDM_1490 => "CWDM_1490"
OPTICS_OP_CWDM_1510 => "CWDM_1510"
OPTICS_OP_CWDM_1530 => "CWDM_1530"
OPTICS_OP_CWDM_1550 => "CWDM_1550"
OPTICS_OP_CWDM_1570 => "CWDM_1570"
OPTICS_OP_CWDM_1590 => "CWDM_1590"
OPTICS_OP_CWDM_1610 => "CWDM_1610"
OPTICS_OP_ITU_100G_1530_33 => "ITU_100G_1530_33"
OPTICS_OP_ITU_100G_1531_12 => "ITU_100G_1531_12"
OPTICS_OP_ITU_100G_1531_90 => "ITU_100G_1531_90"
OPTICS_OP_ITU_100G_1532_68 => "ITU_100G_1532_68"
OPTICS_OP_ITU_100G_1534_25 => "ITU_100G_1534_25"
OPTICS_OP_ITU_100G_1535_04 => "ITU_100G_1535_04"
OPTICS_OP_ITU_100G_1535_82 => "ITU_100G_1535_82"
OPTICS_OP_ITU_100G_1536_61 => "ITU_100G_1536_61"
OPTICS_OP_ITU_100G_1538_19 => "ITU_100G_1538_19"
OPTICS_OP_ITU_100G_1538_98 => "ITU_100G_1538_98"
OPTICS_OP_ITU_100G_1539_77 => "ITU_100G_1539_77"
OPTICS_OP_ITU_100G_1540_56 => "ITU_100G_1540_56"
OPTICS_OP_ITU_100G_1542_14 => "ITU_100G_1542_14"
OPTICS_OP_ITU_100G_1542_94 => "ITU_100G_1542_94"
OPTICS_OP_ITU_100G_1543_73 => "ITU_100G_1543_73"
OPTICS_OP_ITU_100G_1544_53 => "ITU_100G_1544_53"
OPTICS_OP_ITU_100G_1546_12 => "ITU_100G_1546_12"
OPTICS_OP_ITU_100G_1546_92 => "ITU_100G_1546_92"
OPTICS_OP_ITU_100G_1547_72 => "ITU_100G_1547_72"
OPTICS_OP_ITU_100G_1548_51 => "ITU_100G_1548_51"
OPTICS_OP_ITU_100G_1550_12 => "ITU_100G_1550_12"
OPTICS_OP_ITU_100G_1550_92 => "ITU_100G_1550_92"
OPTICS_OP_ITU_100G_1551_72 => "ITU_100G_1551_72"
OPTICS_OP_ITU_100G_1552_52 => "ITU_100G_1552_52"
OPTICS_OP_ITU_100G_1554_13 => "ITU_100G_1554_13"
OPTICS_OP_ITU_100G_1554_94 => "ITU_100G_1554_94"
OPTICS_OP_ITU_100G_1555_75 => "ITU_100G_1555_75"
OPTICS_OP_ITU_100G_1556_55 => "ITU_100G_1556_55"
OPTICS_OP_ITU_100G_1558_17 => "ITU_100G_1558_17"
OPTICS_OP_ITU_100G_1558_98 => "ITU_100G_1558_98"
OPTICS_OP_ITU_100G_1559_79 => "ITU_100G_1559_79"
OPTICS_OP_ITU_100G_1560_61 => "ITU_100G_1560_61"
TRANS enum items added to Release 4.1.x:
TRANS_NONE => "NONE"
TRANS_ONE_PORT_BI => "ONE-PORT-BI"
TRANS_TWO_PORT_BI => "TWO-PORT-BI"
TRANS_TWO_PORT_RX_ONLY => "TWO-PORT-RX-ONLY"
TRANS_TWO_PORT_TX_ONLY => "TWO-PORT-TX-ONLY"
Alarms, Conditions, and Errors Changed in Release 4.1.x
The following conditions have been added for Release 4.1.x.
ERFI-P-CONN—Enhanced Remote Failure Indication, Path, Connectivity
ERFI-P-PAYLD—Enhanced Remote Failure Indication, Path, Payload
ERFI-P-SRVR—Enhanced Remote Failure Indication, Path, Server
The following error has changed for Release 4.1.x.
IDMS has changed from "Loopback Type Missing" to "Missing Internal Data."
Related Documentation
Release-Specific Documents
•Release Notes for the Cisco ONS 15454, Release 4.1.4
•Release Notes for the Cisco ONS 15454 SDH, Release 4.1.5
•Release Notes for the Cisco ONS 15327, Release 4.1.5
•Cisco ONS 15454 Software Upgrade Guide, Release 4.1.x and 4.5
Platform-Specific Documents
•Cisco ONS 15454 Procedure Guide, Release 4.1.x and 4.5
•Cisco ONS 15454 Reference Guide, Release 4.1.x and 4.5
•Cisco ONS 15454 Troubleshooting Guide, Release 4.1.x and 4.5
•Cisco ONS 15454 and Cisco ONS 15327 TL1 Command Guide, Release 4.1.x and 4.5
•Cisco ONS 15454 Product Overview, Release 4.1.x and 4.5
Obtaining Documentation
The following sections provide sources for obtaining documentation from Cisco Systems.
World Wide Web
You can access the most current Cisco documentation on the World Wide Web at the following sites:
Documentation CD-ROM
Cisco documentation and additional literature are available in a CD-ROM package, which ships with your product. The Documentation CD-ROM is updated monthly and may be more current than printed documentation. The CD-ROM package is available as a single unit or as an annual subscription.
Ordering Documentation
Cisco documentation is available in the following ways:
•Registered Cisco Direct Customers can order Cisco Product documentation from the Networking Products MarketPlace:
http://www.cisco.com/cgi-bin/order/order_root.pl
•Registered Cisco.com users can order the Documentation CD-ROM through the online Subscription Store:
http://www.cisco.com/go/subscription
•Nonregistered Cisco.com users can order documentation through a local account representative by calling Cisco corporate headquarters (California, USA) at 408 526-7208 or, in North America, by calling 800 553-NETS(6387).
Documentation Feedback
If you are reading Cisco product documentation on the World Wide Web, you can submit technical comments electronically. Click Feedback in the toolbar and select Documentation. After you complete the form, click Submit to send it to Cisco.
You can e-mail your comments to bug-doc@cisco.com.
To submit your comments by mail, use the response card behind the front cover of your document, or write to the following address:
Attn Document Resource Connection
Cisco Systems, Inc.
170 West Tasman Drive
San Jose, CA 95134-9883We appreciate your comments.
Obtaining Technical Assistance
Cisco provides Cisco.com as a starting point for all technical assistance. Customers and partners can obtain documentation, troubleshooting tips, and sample configurations from online tools. For Cisco.com registered users, additional troubleshooting tools are available from the TAC website.
Cisco.com
Cisco.com is the foundation of a suite of interactive, networked services that provides immediate, open access to Cisco information and resources at anytime, from anywhere in the world. This highly integrated Internet application is a powerful, easy-to-use tool for doing business with Cisco.
Cisco.com provides a broad range of features and services to help customers and partners streamline business processes and improve productivity. Through Cisco.com, you can find information about Cisco and our networking solutions, services, and programs. In addition, you can resolve technical issues with online technical support, download and test software packages, and order Cisco learning materials and merchandise. Valuable online skill assessment, training, and certification programs are also available.
Customers and partners can self-register on Cisco.com to obtain additional personalized information and services. Registered users can order products, check on the status of an order, access technical support, and view benefits specific to their relationships with Cisco.
To access Cisco.com, go to the following website:
Technical Assistance Center
The Cisco TAC website is available to all customers who need technical assistance with a Cisco product or technology that is under warranty or covered by a maintenance contract.
Contacting TAC by Using the Cisco TAC Website
If you have a priority level 3 (P3) or priority level 4 (P4) problem, contact TAC by going to the TAC website:
P3 and P4 level problems are defined as follows:
•P3—Your network performance is degraded. Network functionality is noticeably impaired, but most business operations continue.
•P4—You need information or assistance on Cisco product capabilities, product installation, or basic product configuration.
In each of the above cases, use the Cisco TAC website to quickly find answers to your questions.
To register for Cisco.com, go to the following website:
http://www.cisco.com/register/
If you cannot resolve your technical issue by using the TAC online resources, Cisco.com registered users can open a case online by using the TAC Case Open tool at the following website:
http://www.cisco.com/tac/caseopen
Contacting TAC by Telephone
If you have a priority level 1 (P1) or priority level 2 (P2) problem, contact TAC by telephone and immediately open a case. To obtain a directory of toll-free numbers for your country, go to the following website:
http://www.cisco.com/warp/public/687/Directory/DirTAC.shtml
P1 and P2 level problems are defined as follows:
•P1—Your production network is down, causing a critical impact to business operations if service is not restored quickly. No workaround is available.
•P2—Your production network is severely degraded, affecting significant aspects of your business operations. No workaround is available.
This document is to be used in conjunction with the documents listed in the "Related Documentation" section.
Copyright © 2007 Cisco Systems, Inc. All rights reserved.