Dwdm 2i395p

 sub-ring virtual-link // Using a virtual link  sub-ring non-virtual-link // Not using a virtual link

 vpls

 sap <sap-id> g8032-shg-enable eth-ring create note : shg = Split-Horizon Group, SHG is as a group of ports which cannot communicate amongst themselves, but can traffic to others ports not member of the same SHG

158 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-4/16/32 FID 9970 : TR/RTR thresholding method for TCA (ETSI mode), 11QPE24 Two different TCA modes or thresholding methods: 1) Transient condition method « TR only mode » 1 -> Threshold for generating a threshold report (TR)

2) Standing condition method « TR/RTR mode » 1= Threshold for generating a threshold report (TR) 2= Threshold for generating a reset threshold report (RTR)

FID9970 : the raising and clearing of TCA events as defects in ETSI mode


PSS-4/16/32 FID 9970 : L2 Alarm severity settings, 11QPE24 • It is now possible to change Layer2 (ERP, MEP, Port, LAG, SVC, SAP) alarm severity


PSS-4/16/32 FID 3259: L2 packs cascading configuration • The 1830 PSS will cascaded OTs • For this configuration, a signal is added at an OT client port and multiplexed onto the higher bandwidth line port. The signal is then added at a second higher-rate OT, and multiplexed to its line port. The reverse path is taken when the signal is dropped • Note that there are no committed cascaded OT configurations for the PSS-16 shelf. However, software will not prevent such a configuration on this shelf type

OT B

OT A

OT A

NE 1

NE 2


OT B

PSS-4/16/32 FID 3259: L2 packs cascading configuration – Cont. • OT CASCADING: 10G LINE

OT B

OT A

OT A

NE 1

OT B

NE 2

1350 OMS OT B

OT A

Interworking

11OPE8

11QPEN4

R7.0

11QCE12X

11QPEN4

R7.0

PhM


PSS-4/16/32 FID 3259: L2 packs cascading configuration – Cont. • OT CASCADING: 40G LINE OT B

OT A

OT A

NE 1

OT B

NE 2 1350 OMS

OT B

OT A

Interworking

11DPE12E

43SCX4

R7.0(FID 3259)

PhM

• OT CASCADING: 100G LINE OT B

OT A

OT A

NE 1

OT B

NE 2

OT B

OT A

11DPM12

130SNX10

Interworking

1350 OMS PhM

EPT

R7.0 163 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-4/16/32 FID 7063, 7063-1, 7063-2: FEC disabling on L2 cards (Latency optimization) • This FID covers the implementation of FEC disabling for lower latency on Data cards. Ultra-low latency is key for Business Services and over short metro distances, FEC (which is the greatest contributor to latency) can be disabled • This FID covers the implementation of disabling FEC for the 11DPE12A, 11QPE24, 11OPE8, and 11QCE12X packs • FEC is the main contributor for latency. In order to reduce latency, the L2 cards should be able to OTUk transmission with FEC disabled. This applies to both the OTU2e (11.096 Gbit/s) and OTU2e (11.049 Gbit/s) rates of line ports • To guarantee error-free transmission, no-FEC mode requires the use of special XFPs, e.g, 1AB375650047 from Finisar. This is a better performing XFP. FEC disabling should be available for any XFP but may not be error-free • Error-free transmission may not be guaranteed. The system will give the a warning message about this when disabling FEC • The transmission latency in noFEC mode is reduced about 5us compared to RSFEC and 50us compared to EFEC 164 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-4/16/32 FID 2937: G.8021 compliant fault management for Ethernet OAM • In R5.1, 11QPE24 packs implemented Ethernet OAM (CFM) as per FID 2208. However a subset of this FID, i.e. the fault management processing (defect detection, consequent action, defect correlation) according ITU-T G.8021 was not implemented on 11QPE24 in R5.1, deferred to a future release. It was implemented only on 11DPE12A. • Only the IEEE 802.1ag defects are provided to the which are not very friendly and do not have sufficient granularity to distinguish root cause • The following G.8021 conditions will be added: cLOC, cRDI, cUNL, cMMG, cUNM, and cUNP • The following G.8021 conditions will continue not to be ed: cSSF, cFOP, and cDEG • These new alarms are important for proper service configuration, fault identification, troubleshooting for customers using ITU-T compliant monitoring


PSS-4/16/32 FID 2937: G.8021 compliant fault management for Ethernet OAM – Cont. • This feature covers the implementation of G.8021 FM processes for 11QPE24, 11OPE8, and 11QCE12X cards • The will have a provisionable option to select default IEEE 802.1ag fault names, or ITU-T G.8021 fault names on a per card bases • The will have the ability to provision the fault mode on a card basis • The MIB parameter to manage the fault mode is tnCardEthOamCcmFaultMgntMode • The CLI commands to provision the fault mode are: config card 11ope8 shelf/slot faultmode [ ieee | itu ] config card 11qce12x shelf/slot faultmode [ ieee | itu ] config card 11qpe24 shelf/slot faultmode [ ieee | itu ]


PSS-4/16/32 FID 2937: G.8021 compliant fault management for Ethernet OAM – Cont. • The CLI commands to view the fault mode are: show card 11ope8 shelf/slot

show card 11qce12x shelf/slot show card 11qpe24 shelf/slot • To manage the alarms reported through a fault mode provisioning change, the system will follow an extension of the existing 1830 requirement (given below) managing alarms through a severity change - When the fault mode of an existing condition on a given card is changed, the system shall clear the original condition and re-report the condition with the new condition name


PSS-4/16/32 FID 2937: G.8021 compliant fault management for Ethernet OAM – Cont. • The condition names listed below, based on IEEE 802.1ag introduced in R5.1, will be reported when the card is provisioned with fault mode = ieee MEP Error CCM

MEP-ERR-CCM

MN

MEP RDI CCM

MEP-RDI-CCM

MN

MEP Remote CCM

MEP-REM-CCM

MJ

MEP Cross Connect CCM

MEP-XCON-CCM

MJ


PSS-4/16/32 FID 2937: G.8021 compliant fault management for Ethernet OAM – Cont. • The condition names listed below are the new conditions based on G.8021 that will be reported when the card is provisioned with fault mode = itu

Condition Description

Condition

Defect

Unexpected MEL

UNL

dUNL

Mismerge

MMG

dMMG

Unexpected MEP

UNM

dUNM

Unexpected Periodicity

UNP

dUNP

Loss Of Continuity

LOC

dLOC

Remote Defect Indicator

RDI

dRDI


PSS-4/16/32 FID 6969: ITU-T Y.1731 Proactive PM functions (LM, SLM, 2-way DM) on 11DPE12A with associated counters • Completion of ITU-T Y.1731 from R6.0 • In R6.0, the 11DPE12A added ITU-T Y.1731 PM functions (LMM, SLM, DM) but only on-demand, i.e. one-shot measurement per MEP. • In R7.0 these functions are extended to run in a pro-active manner ans associated counters as per MEF 35/36 (minimum, average, maximum FLR or FD in measurement interval) with binning and thresholding as on 11QPE24 R6.0 and SES, UAS


PSS-4/16/32 FID 6970: Accurate ITU-T Y.1731 1-way DM (with PTP) • The system will one-way proactive ETH-DM as additional contribution to two-way proactive ETH-DM. Performance monitoring on one-way frame delay (maximum, minimum and average) will be provided via proactive ETH-DM • The system will TCA alarms on some one-way DM counters in ETH-DM PM bins. In general, TCA should apply to max and average FD/FDV counters • The system clock synchronization mechanism, IEEE1588V2, will be run to achieve accurate one-way frame delay via ETH-DM. The engineering of system clock synchronization network will impact the accuracy of one-way delay measurement • Timestamps in DMM/DMR PDU shall be inserted/extracted by Hardware


PSS-4/16/32 FID 6969/6970: ITU-T Y.1731 Proactive PM functions (LM, SLM, 2-way DM) on 11DPE12A with associated counters / Accurate ITU-T Y.1731 1way DM (with PTP)


PSS-4/16/32 FID 6980: QoS L3/L4 Classification Enhancement Brief Description: L3/L4 QoS match criteria classification shall be ed on SAP ingress policies, these new classifications are also used with ingress meters for policing and mapping into forwarding class to provide a complete QoS solution.


PSS-4/16/32 FID 6980: QoS L3/L4 Classification Enhancement – Cont. L3/L4 Classification is part of Service ingress QoS policy. Service Ingress Policy currently available in software release 6 include: • Number of classifiers and meters for this policy • Create Meters • Configure FCs and assign meters to FCs

• Classification- DS or MAC based match criteria to map packets to a forwarding class • DS criteria for IPv4 and IPv6 • Mac criteria NOTE: Both DS criteria and MAC criteria cannot be configured in the same SAP ingress QoS policy

Enhancements to L3/L4 Classification in R7 include: • IPv4 Match criteria • IPv6 Match criteria • Frame based ing policy Each is detailed on the next slide 174 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-4/16/32 FID 6980: QoS L3/L4 Classification Enhancement – Cont. IPv4 Match criteria • IP source and mask & IP destination and mask • IP protocol • T/UDP source port or port range & T/UDP destination or port range IPv6 Match criteria - IPv6 128-bit source and mask - IPv6 128-bit destination and mask - IP protocol/next-header - T/UDP source port or port range / T/UDP destination or port range Frame Based ing Policy This feature when enabled let QoS policies to s for the Ethernet frame overhead (for example, it s for the IFG (inter-frame gap) and the preamble). Typically, the IFG and preamble constitutes about 12 + 8 = 20 bytes. The overhead for Ethernet ports uses this value. A configurable CLI command enables ing of the frame overhead at ingress or egress. When disabled, the queue rates and egress-rate do not for the Ethernet frame overhead. By default frame-based ing is disabled for both ingress and egress. 175 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-4/16/32 FID 6980: QoS L3/L4 Classification Enhancement – Cont. IPv4 Configuration Commands- CLI config-card-11qpe24-2/2-qos-sap-ingress)# <policy-id> Enter the sap-ingress policy id <2 - 65535> • ip-criteria [any | ds-only] • entry entry-id [create]

- action [fc fc-name] - description description-string - match [protocol protocol-id] - ds ds-name - dst-ip {ip-address/mask | ip-address netmask} - dst-port fc {eq} dst-port-number - fragment {true | false} - src-ip {ip-address/mask | ip-address netmask} - src-port {eq} src-port-number


PSS-4/16/32 FID 6980: QoS L3/L4 Classification Enhancement – Cont. IPv6 Configuration Commands- CLI config-card-11qpe24-2/2-qos-sap-ingress)# <policy-id> Enter the sap-ingress policy id <2 - 65535> ipv6-criteria [any | ds-only] - entry entry-id [create] - action [fc fc-name]

- description description-string - match [next-header next-header] - ds ds-name - dst-ip {ipv6-address/prefix-length} - dst-port {eq} dst-port-number} - src-ip {ipv6-address/prefix-length} - src-port {eq} src-port-number


PSS-4/16/32 FID 6980: QoS L3/L4 Classification Enhancement – Cont. Frame Based ing Policy- CLI • config-card-11qpe24-2/2-qos)# no • access-egress • network • network-queue

Remove the access-egress policy details Remove the network policy id Remove the Network Queue parameters

• port-scheduler-policy Remove port scheduler policy name • sap-ingress

Remove the sap-ingress policy details

• slope-policy

Remove the qos slope policy details

• NOTE: When frame-based-ing is enabled, ing is shown as frame-based otherwise packetbased, this is reflected in all the show QoS Commands


PSS-4/16/32 FID 9998: Zero-chirped* 10G DWDM Tunable XFP on packet cards, Optical Performance improvement • Same XFP added in R6.0 on 10XANY10G, 4XANY10G, 10XOTH10G • Part Number : 1AB394040003 • Module type : XL-64TCW

• ed on the following cards and line interfaces: - 11DPE12A : L1 and L2 ports - 11OPE8 : X1, X2, X3 and X4 ports - 11QCE12X : X1, X2, X3 and X4 ports - 11QPE24 : X1, X2, X3 and X4 ports • Behavior (auto-detection, etc) equivalent to other ALU-qualified 10G XFP • Performance much closer to MSA specification

*Chirp is a signal in which the frequency increases or decreases over time. In optics, laser pulses can exhibit chirp, which in transmission systems can increase or decrease total pulse dispersion as the signal propagates. 179 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-4/16/32 FID 9998: Zero-chirped 10G DWDM Tunable XFP on packet cards – Cont. • 11DPE12A: Pluggable module type in R6.0

• 11DPE12A: Pluggable module type in R7.0.0: XL-64TCW


PSS-4/16/32 FID 9998: Zero-chirped 10G DWDM Tunable XFP on packet cards – Cont. • 11DPE12A Line Port with XL-64TCW module

• 11DPE12A Line Port with XL-64TCW module


PSS-4/16/32 FID 9998 : Zero-chirped 10G DWDM Tunable XFP on packet cards – Cont. • 11DPE12A Line Port with XL-64TCW module, 1354 PhM R12.0


PSS-4/16/32 FID 3068: for TSOP Smart SFP • TSoP (Transparent SONET/SDH over Packet) Smart SFPs are ed on 11QPE24 and 11QCE12X as local SFPs, with a reduced set of functionality in R7.0 • Two rates are ed in different SFPs: STS-3 (STM-1) and STS-12 (STM-4) • Although it is called an RMD (remote managed device), the TSoP Smart SFP is inserted in a local port, and only managed locally through an RMD access interface configured on a port • The Interface CLI commands apply the same as other 1GbE SFPs managed locally through an RMD access interface configured on a port • The can create a TSoP Smart SFP instance, specifying its rate, on an RMD Access Interface port, if: - The Interface type is 1Gbe - The Interface moduletype is either one of the TSoP types ing that rate, or auto - Otherwise it is denied

• The Interface type cannot be changed while an RMD TSoP instance exists 183 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-4/16/32 FID 3068: for TSOP Smart SFP – Cont. • If Interface moduletype was configured and a subsequently inserted SFP is not a TSoP type ing the configured rate, a module mismatch alarm and Device Not Reachable (DNR) alarm will be generated • If moduletype was auto and a subsequently inserted SFP is not a TSoP type ing the configured rate, a DNR alarm will be generated • The moduletype cannot be changed from a TSoP Smart SFP ing the rate if the port has a TSoP RMD instance configured

• Some general RMD commands do not apply: - traffic, forwarding, eth-cfm, efm-oam, port

and those under "port:" - autonegotiate, autonegotiate-fallback, duplex, speed


PSS-4/16/32 FID 3068: for TSOP Smart SFP – Cont. • The can configure the unicast Destination MAC Address (DA) for the generated TSoP Ethernet traffic. It must match the MAC address of its peer TSoP Smart SFP • The TSoP Ethernet traffic is always untagged • The received DA is always checked against the device MAC address and traffic not matching is dropped • The can configure the Emulated Circuit Identifier (ECID) for transmitted TSoP Ethernet traffic, with default 0 • The can configure an expected ECID for received TSoP Ethernet traffic, with default 0 • When received ECID doesn't match, the packet is dropped and the Missing Packet counter incremented • The RTP (Real Time transport Protocol) payload type is fixed to 0 and is ignored in received packets


PSS-4/16/32 FID 3068: for TSOP Smart SFP – Cont. • The RTP SSRC (Synchronization SouRCe, a connection identifier) is fixed to 0 and is ignored in received packets • The can enable/disable transmitted TSoP encapsulated Ethernet traffic on the instance • G-AIS (Generalized TDM AIS) is generated automatically based on defect detection. It has no configuration • The ingress TDM defects that trigger G-AIS (L-bit indication in TSoP Control Word) are: - LOS and LOF

• The packet defects that cause G-AIS insertion into the TDM egress signal are: - L-bit in Control Word (i.e. far end TDM LOS or LOF defect)

- Missing Packet - Malformed Packet


PSS-4/16/32 FID 3068: for TSOP Smart SFP – Cont. • The synchronization mode is fixed to “SyncE,” not configurable, and only that value is displayed • For proper operation, both peer TSoP Smart SFPs must have SyncE enabled and synchronized to the same frequency • The jitter buffer configuration is fixed at:

Jitter Buffer parameters

Recommended value

JB maximum size

64 [packets]

JB ReCenter Position (JB R)

32 [packets]

JB shift

0 [packets]

JB high threshold

56 [packets]

JB low threshold

8 [packet]

JB recenter threshold

100

JB recenter increment

10


PSS-4/16/32 FID 3068: for TSOP Smart SFP – Cont. • The can enable/disable facility and/or terminal loopbacks, transparent or not, for the TDM interface of the TSoP RMD • The can enable/disable facility and/or terminal loopbacks using the Interface CLI command as for other 1GbE ports. These operate in the Ethernet switch and are independent of the TSoP SFP TDM loopbacks • The can reset the TSoP SFP • The can retrieve the same detail from the Interface commands as for other SFPs • The can retrieve the same detail from RMD commands as for other RMDs • TDM defects and alarms ed: - LOS and LOF


PSS-4/16/32 FID 3068: for TSOP Smart SFP – Cont. • TSoP CES IWF defects and alarms ed: - No_TDM_Payload

- LPL (Local Packet Lost) - RPL (Remote Packet Lost, i.e. far end LPL).

• The thresholds for raise/clear are fixed at defaults (8) • In addition, the following event notifications are ed: - DA_Mismatch - Type_Mismatch - Unknown_ECID - JB_Recentered


PSS-4/16/32 FID 3068: for TSOP Smart SFP – Cont. • The following TSoP CES IWF statistics can be displayed: - Sent Packets

- Received Packets - Malformed Packets - Missing Packets - Reordered Packets - Misordered-Dropped Packets - Played Out Packets (to TDM) - Jitter Buffer Overrun - Jitter Buffer Underrun


PSS-4/16/32 FID 3068: for TSOP Smart SFP – Cont. • The following Ethernet statistics can be displayed: - portRxCorrectBytes

- portRxCorrectFrames - portRxOtherErrors - portRxFcsErrors - portTxCorrectBytes - portTxCorrectFrames

• The can clear the TSoP statistics counters


PSS-4/16/32 FID 3068: for TSOP Smart SFP – Cont.

Architecture

Flash

Network Side

Optical Transceiver

SerDes

EEPROM

Power Mgt

Test Access

U

I2C

Electrical MSA Side to Hosting device (e.g. Eth switch)

Standard SFP

Smart SFP

 O/E Conversion  DDM (SFF-8472)

 O/E Conversion  DDM (SFF-8472)  Intelligent System Functions, typically built into an FPGA or ASIC/ASSP  (optional) U and others components (oscillator, memory, etc)

 MSA

 MSA  Programmable Software I/F

Functions

Interfaces

System Functions

TBI

SFP MSA Connector

Single or Dual Fiber


PSS-4/16/32 FID 3068: for TSOP Smart SFP – Cont.

Top view with Alcatel-Lucent customized label Standard MSA dimensions: 57mm x 13.6mm x 11.45mm

Internal Assembly showing the daughter board with FPGA plugged onto main board, and TOSA & ROSA (TOSA & ROSA : Transmit & Receive Optical Sub Assembly)


PSS-4/16/32 FID 3068: for TSOP Smart SFP – Cont. At card level, enable Synchronous Ethernet At Client, set operational mode: Synchronous


PSS-4/16/32 FID 3068: for TSOP Smart SFP – Cont. In the equipment tree, scroll down and select RMDs, then select the RMD Access Interfaces tab. Click the Create button to get the screen shown to the right. Choose an Access Interface ID and the client port for which operational mode was set to synchronous. If there was a smart SFP seated in the client port, the RMD may be discovered automatically. Otherwise, select the RMD tab and click the Create button (see next slide).


PSS-4/16/32 FID 3068: for TSOP Smart SFP – Cont. Enter the device info and click the Apply button.

The device will be reported in the RMDs list.


PSS-4/16/32 FID 3068: for TSOP Smart SFP – Cont. Highlight the RMD and click the Details button to view the TSoP details. Notice which fields can be modified.


PSS-4/16/32 FID 3068: for TSOP Smart SFP – Cont. Any alarms on the RMDs can be viewed by selecting the Fault button.


PSS-4/16/32 FID 9965 : PSS 4/16/32 ECC channel • A new method is being introduced to create an ECC Channel: GCC0, GCC1, GCC2 • WebUI menu: istration – Network Interfaces (In earlier releases, select the Line port of the OT, then the GCC tab – not shown here)

See next page 199 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-4/16/32 FID 9965 : PSS 4/16/32 ECC channel – Cont. • Create Network Interfaces, GCC1 or GCC2 at ODU2

Select Facility type

Interface Enabled

Assign an Interface ID

ECC channel = GCC1 or GCC2


PSS-4/16/32 FID 9965 : PSS 4/16/32 ECC channel – Cont. • Create Network Interfaces, GCC0 at OTU

ECC channel = GCC0 201 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-4/16/32 FID 9965: PSS 4/16/32 ECC channel – Cont. • Network Interfaces


PSS-4/16/32 FID 9965: PSS 4/16/32 ECC channel – Cont. • Modify Network Interfaces

GCC1 or GCC2


PSS-4/16/32 FID 9965: PSS 4/16/32 ECC – Cont. • Network Interfaces by CLI command: config-cn-netif


PSS-4/16/32 FID 9965: PSS 4/16/32 ECC – Cont. • Network Interfaces by cli command: config-cn-netif


PSS-4/16/32 FID 10045: PSS-32 Shelf Evolution • A new variant of the PSS-32 shelf is being manufactured to offer mechanical improvements • A new APN for the PSS-32 shelf (new APN = 8DG59319ABxx*) will be created • The improvements will include all the customer requested fixes, some cost/manufacturing improvements, and an increased depth horizontal tray • The shelf will ship as a 12” deep footprint product but with removable horizontal fiber trays (to be able to grow from 12” to 13” to 14”, etc.) for handling the amount of fibers required for high port density cards • The shelf will be software compatible with previous releases • Enhancements for Rev0 are: - New extrusion ejector rail

- Square off back side to match PSS-36 (remove angle) - Shift rail back by almost 1mm

*New APN not yet confirmed; APN may remain unchanged. 206 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-4/16/32 FID 10045: PSS-32 Shelf Evolution – Cont. • Enhancements for Rev01: - Stiffened Card Guides (without spring) to match PSS-36 - Updated backplane to move out ground layer away from power connector pins - Removal of Timing card connectors on backplane to save costs

- Removal of Timing card blanks and guides as cost reduction - Replace flaps with metal butterfly wings - Add switched latch alignment holes - Redesign front of EC/PF half slot structure to allow continuous hem on side walls - Changed material of bottom s to stainless steel to prevent bowing

- Improve lead in feature for insertion - Adjust opening for to prevent gasket damage - Increase area of the hole pattern above fan to improve airflow - Add exhaust hole patterns on upper/rear area of side s to improve air flow


PSS-4/16/32 FID 10045: PSS-32 Shelf Evolution – Cont. Possible enhancements for Rev02: - Modify EC/PF half slot structure for cost reductions (re-design as a casting) - Design new upper cover bracket mounts for easier access after installation - Create removable horizontal fiber trays (to be able to grow from 12” to 13” to 14”, etc.)

• This new shelf only uses the Z25 shelf cover, not the older existing flat cover


PSS-4/16/32 FID 10045: PSS-32 Shelf Evolution – Cont.

See slide 208 See slide 209

See slide 210

See slide 211


PSS-4/16/32

Original design:

FID 10045: PSS-32 Shelf Evolution – Cont. •Improve lead in feature for insertion •Replace flaps with metal butterfly wings •Adjust opening for to prevent gasket damage (not clearly visible from these photos) •Increase area of the hole pattern above fan to improve airflow •Add exhaust hole patterns on upper/rear area of side s to improve air flow



Redesigned fiber guides can be removed and replaced easily for different depths. Improved latching mechanism.


PSS-4/16/32 FID 10045: PSS-32 Shelf Evolution – Cont. Original rail has beveled edge and problems with ECs not fully seating have been reported.

New design is squared off and shifted back about 1mm so EC fully seats.



Stiffened Card Guides (without spring) to match PSS-36

Changed material of bottom s to stainless steel to prevent bowing

Deeper fiber guides


PSS-16/32 FID 3235: Excessive power alarm flexibility • The feature allows the to enter the voltage at which the maximum current load shall be calculated. It is ed for PSS-16 and PSS-32 shelves • The fixed value until R7.0 for this calculation has been 39.0V. This will be the default value in R7.0 • The supplied value is used in a calculation to set the ExcessLoad alarm if Load exceeds Capacity • CLI commands for this feature are: config shelf <sh> shelfVoltageFloor {value} show shelf <sh>

• TL1 - Use the ED-EQPT command with a shelf AID to set the voltage floor setting

• EPT will not be available until R7.0.1 or R7.0.2


PSS-16/32 FID 3235: Excessive power alarm flexibility – Cont. • CLI configuration screen:


PSS-16/32 FID 3235: Excessive power alarm flexibility – Cont. • CLI show screen:

• WebUI screen on next slide


PSS-16/32 FID 3235: Excessive power alarm flexibility – Cont.


PSS-16/32 FID 3235: Excessive power alarm flexibility – Cont. Example: default values shown at right

Voltage Floor modified to 55; PF has CR alarm because actual input (51.8) is below Floor. PF alarms, but does not shut off. Time

Source Card Category Severity Description

Condition SA Data

4/30/14 02:19:40 PM

1/36

PWR

PF

EQPT

Critical

Battery off or power filter off


Yes

PSS-4/16/32 FID 7160: Clock Out of Spec Alarm •

R7 software will monitor Power Filter Clock sources for deviations

•

In pre-R7 releases the Wavetracker Clock Accuracy degrade scenario could not be detected

•

A clock difference of more than 7.5ppm is enough to cause Wavekey detection failures

•

The enhancement will: -

Monitor the power filter Stratum 3 oven controlled oscillator clocks which are supposed to maintain a 4.6ppm accuracy over their 20 year lifetime. Power Filter A will measure its own clock CK32A against that of Power Filter B CK32B and vice versa for Power Filter B. This check will be known as WLTRKR

-

Both Clocks shall be measured against the System Clock. This check will be known as WLTRKT


PSS-4/16/32 FID 7160: Clock Out of Spec Alarm – Cont. • Diagram of the Power Filter OXCO and the Low Q System Clock: OCXO

OCXO_A CK_0 OCXO_B CK_1

low quality System

KYRA frequency monitor

50ppm_A

CLK_38A OCXO_B CLK_38B

PFDC left slot 19

KYRA reference inputs

PFDC right slot 36 OCXO

OCXO_B CK_0 OCXO_A CK_1

low quality system

KYRA frequency monitor

50ppm_B CLK_38A OCXO_A CLK_38B


KYRA reference inputs

PSS-4/16/32 FID 7160: Clock Out of Spec Alarm – Cont. datum1 OCXO_A vs OCXO_B

After PFDC power up, wait 10 minutes for clock to stabilize. Take a baseline reading of datum 1-5. Store Sample Set T0.

Once every 60 seconds, measure OCXO_A vs OCXO_B (datum1)

(A – B) > 25 ppm ?

yes

datum2 OCXO_A vs 50_A

datum3 OCXO_B vs 50_A

datum4 OCXO_A vs 50_B

datum5 OCXO_B vs 50_B

- Collect and store datum 1-5 as Sample Set T2. - Examine datum sets T0/T1/T2 to isolate which OCXO is drifting. - Alarm bad OCXO. - Force all line cards to use remaining good clock.

no

yes

- Collect datum 2-5. - Store datum 1-5 as Sample Set T1 (first occurrence only) - Raise a shelf TCA alarm requesting fault isolation.

yes

Once per week: - Perform 50 ppm oscillator test (see next page) - If 50ppm = good, store datum 1-5 as refreshed Sample Set T0

(A – B) > 10 ppm ? no

(A – B) < 5 ppm ? no


PSS-4/16/32 FID 7160: Clock Out of Spec Alarm – Cont. After PFDC power up, wait 60 minutes. Test flow requires two PFDCs in the shelf.

Once every week, collect datum 1-5

datum1 > 5 ppm ?

yes

Ovenized oscillators have degraded too much to perform this check.

datum1 OCXO_A vs OCXO_B

no yes d2 and d3 >55 ppm ?

50ppm_A is out of spec. Raise minor alarm against slot 19.

datum2 OCXO_A vs 50_A

datum3 OCXO_B vs 50_A

datum4 OCXO_A vs 50_B

datum5 OCXO_B vs 50_B

no

d4 and d5 >55 ppm ?

yes

50ppm_B is out of spec. Raise minor alarm against slot 36.

no


PSS-4/16/32 FID 7160: Clock Out of Spec Alarm – Cont. • New CLI Commands: - show card [type] [slot] - This command now contains a reference to which clock source is being used plus the mode (manual/automatic) of clock source selection - i.e. show card 11stmm10 1/16 - config card [type] [slot] clkswitch [auto | power filter slot] - The clock can be manually forced to either power filter 1/19 or 1/36 or left on automatic for the system to use the algorithm to determine the best clock source


PSS-4/16/32 FID 7160: Clock Out of Spec Alarm – Cont. PSS32-FO# show card 11stmm10 1/16 Shelf: 1 Slot: 16 - 11STMM10 (Equipped: 11STMM10) ------------------------------------------------------------------------------ State : Up State Qualifier : Oper State : Up S/W Load : durian-14.5-70 Status LED

: Solid Green

Card Name Card Descr Card Height

: Card-1-16 : : Full

Card Width

High Temp Threshold : 90 'C Low Temp Threshold : -5 'C Provisioned Clock Source Actual Clock Source

: Single

Temp Tolerance Temperature

: 3 'C : 39 'C

: Auto : PF-19

PSS32-FO#

PSS32-FO# config card 11stmm10 1/16 clkswitch auto Configure default clock switch for card Enter the PF slot number PSS32-FO# 224 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-4/16/32 FID 7160: Clock Out of Spec Alarm – Cont. • New GUI fields, at shelf level:


PSS-4/16/32 FID 7160: Clock Out of Spec Alarm – Cont. • New GUI fields, at card level:


PSS-4/16/32 FID 7160: Clock Out of Spec Alarm – Cont. • New GUI fields, at card level:


PSS-32 FID 3289: PSS-32H Fan Alarm • The PSS-32 NE will alarm an absent FAN32H (high speed fan) with the following optional cards:

• 112PDM11 • 112SCA1 • 112SCX10 • 112SDX11 • 112SNA1 • 112SNX10 • 11QPEN4 • 130SCA1 • 130SCX10 • 130SNX10

• 260SCX2 • 43SCA1 • 43SCGE1 • 43SCX4 • 43SCX4E • A2P2125 • RA2P • 11OPE8 • 11QCE12X

• EPT requires the FAN32H in any shelf that contains one or more of the above-mentioned cards


PSS-32 FID 3289: PSS32H Fan Alarm – Cont. • The circuit pack can either be provisioned to the slot or seated:

Alarm is raised on Slot 37 FAN 229 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-32 FID 3289: PSS32H Fan Alarm - Cont. • A Critical NSA FAN32HRQD alarm is raised if any of the cards listed is installed in a PSS-32 shelf that is not equipped with FAN32H Time Source Card 4/23/14 07:53:15 AM 1/37 FAN

Category

Severity

EQPT

Critical

Description Require high speed fan (FANH in PSS32) inserted on shelf

Condition

SA

FAN32HRQD

No

Alarm description text: “Require high speed fan (FANH in PSS32) inserted on shelf” • To clear alarm: - Equip shelf with FAN32H, or - Remove offending card

• Upon identifying a card which requires FAN32H, a PSS32 equipped with FAN32 will increase fan speed to protect the components of the thermally sensitive card as much as possible with the available airflow.


Data

PSS-4/16/32 FID 3205: MRN Improvements • An OCS layer (L1) control plane feature is implemented on top of the currently ed OCH layer (L0) control plane feature so that 1830 NE can interconnected L0 and L1 multi-layer control plane service set up and fast restoration (MRN).


PSS-4/16/32 FID 3205: MRN Improvements – Cont. •

MRN Key Features: -

L1 provides fast restoration and protection, based on ODU electrical switching

-

Interconnected L0 and L1 is prerequisite for end to end service setup in multi-region / multi-layer networks

-

MRN/MLN is prerequisite for L2 UNI/IP interworking (R8 UNI* interfaces interworking between IPD and 1830)

-

MRN/MLN provides coordination between the layers

-

for restoration

-

for maintenance

-

Simplified operation in NMS (1350 OMS and 5620 SAM)

-

no more path stitching between the layers


PSS-4/16/32 FID 3205: MRN Improvements – Cont. •

MRN Works on the concept of tunnels


PSS-4/16/32 FID 3205: MRN Improvements – Cont. • Soft-FA/virtual link improvements: - Scenario 1: restoration using different tunnel points (e.g. due to tunnel end point node failure) - Scenario 2: restoration using different tunnel end point (e.g. due to uplink card failure, link failure between uplink card and WDM node, WDM AD failure, etc) – local reroute between OCS and WDM. - Scenario 3: activation and usage of pre-planned backup tunnels for LO ODU restoration. - Scenario 4: preemption of tunnels for high priority traffic - Scenario 5: Multi-layer network restoration and preemption based on client traffic priority (tunnel priority derived from client service priorities)


PSS-4/16/32 FID 3205: MRN Improvements – Cont. • Scenario 1: Restoration using different tunnel points (node failure) OCS node Original failure route EP

uplink

uplink

OCS

OCS

WDM network

OCSEP uplink

Reroute traffic by setting up new tunnel to different node from/to the same uplink card

OCS

• Scenario 2: Restoration using different tunnel points (uplink failure) Original route

uplink

AD

EP

uplink OCS

uplink WDM network

WDM

Reroute traffic by setting up new tunnel from different uplink card 235 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

EP

OCS

PSS-4/16/32 FID 3205: MRN Improvements – Cont. • Scenario 3: Pre-planned backup tunnel topology Nominal topology used for services

EP

uplink

uplink EP

uplink

EP

uplink

EP

uplink

OCS

Pre-planned backup topology – multiple definitions per port activated when needed

OCS

OCS uplink

WDM network

EP

uplink

uplink uplink

uplink EP

OCS

• Scenario 4: Restoration with tunnel preemption Original route High priority

EP

uplink

OCS EP OCS

OCS

uplink

EP

uplink

EP

WDM network uplink Original route Low priority

Reroute traffic by setting up new tunnel with preemption of other tunnels 236

COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-4/16/32 FID 3205: MRN Improvements – Cont.

• Scenario 5: Priority Aligned restoration and preemption

Tunnel restoration for low priority traffic only

High priority traffic Performs preemption on ODU Low priority traffic

EP

OCS

uplink

EP

uplink

EP

uplink

EP

WDM network uplink

EP

OCS

Original route Low priority


PSS-4/16/32 FID 2795: TCM (Tandem Connection Monitoring) Brief Description: TCM on ODUk interfaces within OTs and Client/Line structures. The intention of OTN Tandem Connection Monitoring (TCM) is to provide monitoring capabilities per such domains or per any other istrative segments of the end-to-end ODUk trail. For this purpose, so called "TCM (sublayer) trails" are established on top of the ODUk (path) trail. As the segments that shall be monitored may not only be arranged one back to back to the other, but may also be nested (e.g. one operator uses transport across another operator´s domain), six levels of TCM are ed. The diagram on the next slide details how several TCM levels are used to monitor the segments A1 - A2, B1 - B2, B3 - B4, and C1 - C2. Segment C1 - C2 is nested in segments B1 - B2 and A1 - A2 while B1 - B2 is used back-to-back with B3 - B4. While in back-to-back configurations the same TCM level may be re-used; for nested applications different TCM levels need to be used. Eventually, TCM can not only be used in unprotected applications, but can also provide the switching criteria for protected applications 238 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-4/16/32 FID 2795: TCM (Tandem Connection Monitoring) – Cont.


PSS-4/16/32 FID 2795: TCM (Tandem Connection Monitoring) – Cont. Definitions: AM: After Matrix- defines the relative position and orientation of a TCM function. BM: Before Matrix- defines the relative position and orientation of a TCM function.

Non-terminated ODUk: the ODUk is not terminated on the local IO card. However, the ODUk may be terminated on the IO card on the other side of the matrix card. For example: in the case of an OTU2 with ODU2 with 10GbE client signal, the ODU2 path termination is on the other side of the matrix and the ODU2 is non-terminated for the local IO card. POSSEQ: defines the hardware location assigned when creating a TCM facility

Terminated ODUk: The ODUk is terminated on the local IO card. TCM: Tandem Connection Monitoring SNC/Ne: Subnetwork Connection Protection based on Non-Intrusive Monitoring of the Path Layer SNC/Ns: Subnetwork Connection Protection based on Non-Intrusive Sublayer Monitoring (TCM) SNC/S: Subnetwork Connection Protection based on Sublayer Trail Monitoring (TCM) 240 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-4/16/32 FID 2795: TCM (Tandem Connection Monitoring) – Cont. The system s provisioning 3 levels of TCM freely to one of the 6 levels defined by G.709. I • 3 BM and 1 AM are available for non-terminated ODUk in OTUk, • 2 BM and 1 AM are available for terminated ODUk in OTUk, • 2 BM and 1 AM are available for non-terminated LO ODU in HO ODUk, and • 1 AM is available for terminated ODUk with embedded client signal Two cases exist: • The ODUk is terminated and carries a set of LO ODUs • The ODUk is terminated and carries a non-OTN client signal


PSS-4/16/32 FID 2795: TCM (Tandem Connection Monitoring) – Cont. ed cards for Photonic Layer: 11QPA4 This configuration applies to the following IO cards: • 11QPA4

Level Location- 6 TCM locations- all before Matrix Mode- Non Intrusive or Termination Tx TCM Overhead Insertion- for non terminated traffic Rx TCM Overhead Removal- for non terminated traffic

Enable LTC Defect Response-The facility shall provisioning of LTC consequent action enable option. LTC consequent action enable/disable (LTCRESP) shall be provisionable.

Send AIS on Defect- The facility shall provisioning of AIS ODUk consequent action enable option. AIS consequent action enable/disable (AISONDEF) shall be provisionable. ODUk AIS means the AIS pattern over the whole ODU OH (including all TCM OH bytes) 242 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-36/64 FID 2795: TCM (Tandem Connection Monitoring) – Cont. ed cards for Non-Terminated ODUk in OTUk

This configuration applies to the following IO/Uplink cards: • 130SCUP / 130SCUPB • 11QCUPC • 10AN10G (with variant 4AN10G)

ed cards for Terminated ODUk in OTUk with Non-Terminated LO ODUk This configuration applies to the following IO cards: • 10AN10G (and variants 10ET10G, 4AN10G) • 24ANM • 24ANMB (and variants 24ET1GB, 8ET1GB)

ed cards for Transparent Mappings of Non-OTN Client Signals This configuration applies to the following IO cards: - 10AN10G (and variants 10ET10G, 4AN10G) - 24ANM

- 24ANMB (and variants 24ET1GB, 8ET1GB) 243 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-36/64 FID 2795: TCM (Tandem Connection Monitoring) – Cont. From OCS Zic, highlight required facility

Provision ODUk TCM window will be displayed

Level- TCM level 1-6 Role- to be defined Overhead Add- Y/N Position- After Matrix / Before Matrix Relative Position- 1,2,3- Hardware Location of TCM facility

Overhead Remove-Y/N NOTE: R7 delta add additional parameter to relative Position 244 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-16/32 FID 6979-3 / 3022-2 / 3186-2: Full flexible (100G) OT interworking • These features cover the new control plane implementation of the following circuit packs 6979-3 - 260SCX2 3186-2 - 130SNX10 3022-2 - 130SCUPB*

• During a restoration event within the GMRE network, the GMRE must calculate the optical reach of the transponders delivering wavelength services which require restoration.

• The optical reach depends on the combination of source and destination OT in a unidirectional manner - There could be a good transmitter (source) and bad receiver (destination) or vice versa

• The applied optical reach coefficients for channel margin, PMD/DGD and NLP/CD depend on the source (transmit) and destination (receive) type pair. *Note that although the 130SCUPB is not a PSS16/32 card, it is included here because the interworking is similar to the 260SCX2 and 130SNX10. 245 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-16/32 FID 6979-3 / 3022-2 / 3186-2: Full flexible (100G) OT interworking – Cont. • used for optical transponders are HPERF1, SPERF2, and HPERF2 - HPERF – High Performance - SPERF – Slow Performance

• GMRE will use the same term for cards using the same optical module - e.g. HPERF2 is used for 130SNX10, 130SCUP, and 260SCX2 as they have the same optical characteristics .

• The are used in EPT and GMRE. • Each card type has a specific characteristic - e.g. bad receiver, good transmitter. • For route calculation of the optical feasibility, values are used from the receiver or the transmitter in one or the other direction, and this depends on the contribution - Chromatic Dispersion (CD) or Polarization Mode Dispersion (PMD)


PSS-16/32 FID 6979-3 / 3022-2 / 3186-2: Full flexible (100G) OT interworking – Cont. The table on the next slide defines the Interworking between different 100G modules deployed within a GMRE network. NOTE: Modes tagged with 1 might be used when 3Rs or OTs are involved not ing SDFEC. Modes tagged with 2 indicate optical and electrical compatibility modes but may have issues with electrical multiplexing or adaptation. The combination 112SCA1 and 112SCX10 works only when an OTU4 client interface is used on 112SCA1. If an Ethernet port would be used it cannot work. Such dependencies are not checked by GMRE and are the responsibility of OMS/ when setting up a service. Modes tagged with 3 are given as electrical multiplexing because e2e interworking is not ed - e.g. one side is multiplexing ten 10GbE signals into an odu2 and the peer side s 100GE only - not LO-ODU multipexing. However this type can provide 3R interworking - on HO only. iCOH = Interleaved Coherent 247 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-16/32 FID 6979-3 / 3022-2 / 3186-2: Full flexible (100G) OT interworking – Cont. 112 SCA1

112 SCX10

None 112SCA1

cohAFEC

cohAFEC2

112 SNX10

112 SNA1

130 SCUP

130 SCX10

HPERF1 cohAFEC2

130 SCA1

130 SCUPB 130 SNX10

SPERF2

coh- AFEC coh- AFEC

cohAFEC2

260SCX2 130Gmode

HPERF2 coh- AFEC

coh- AFEC2

coh- AFEC2

coh-AFEC

112SCX10

coh- AFEC coh- AFEC

cohAFEC2

coh- AFEC coh- AFEC coh- AFEC3

coh- AFEC

coh- AFEC

coh-AFEC2

112SNX10

coh- AFEC

cohAFEC2

coh- AFEC coh- AFEC coh- AFEC3

coh- AFEC

coh- AFEC

Coh-AFEC2

coh- AFEC2

cohAFEC

coh-AFEC

coh- AFEC icoh- SDFEC

coh-AFEC icoh-SDFEC

coh- AFEC1 icoh- SDFEC


coh-AFEC2,1 icoh-SDFEC2

coh- AFEC1 coh- AFEC1 icoh- SDFEC icoh- SDFEC



130SCUPB

coh- AFEC1 coh- AFEC3 icoh- SDFEC icoh- SDFEC3

coh-AFEC1 icoh-SDFEC

130SNX10



112SNA1

coh- AFEC coh- AFEC

130SCUP

coh- AFEC coh-AFEC coh- AFEC coh- AFEC1 coh- AFEC icoh- SDFEC icoh- SDFEC icohicohSDFEC SDFEC

130SCX10

cohAFEC2

cohAFEC1 icohSDFEC

130SCA1

coh- AFEC

coh- AFEC3 icohSDFEC3

260SCX2

coh-AFEC1 icoh-SDFEC


PSS-16/32 FID 6979-3 / 3022-2 / 3186-2: Full flexible (100G) OT interworking – Cont. 6979-3 - 260SCX2 • Control plane will the 260SCX2 OT card in PSS32 and PSS16. The OT can be used in 2 different modes with the following capabilities:

130G mode: - Optical bitrate: 100 Gbit - Electrical bitrate: 111,810 Gbit - ed FEC: AFEC, SDFEC - ed encoding: PDM-QPSK, icoh-PDM-QPSK - Module type: HPERF2 - Interworking (HO ODU) - Card can be used as unidirectional 3R or drop OT


PSS-16/32 FID 6979-3 / 3022-2 / 3186-2: Full flexible (100G) OT interworking – Cont. 6979-3 - 260SCX2 cont. 260G mode: - Optical bitrate: 260 Gbit - Electrical bitrate: 260 Gbit

- ed FEC: SDFEC - ed encoding: PD-16QAM - Module type: None - Card can be used as unidirectional 3R or drop OT

• No dynamic change from 130G to 260G mode is required by the control plane. Configuration changes from 130G to 260G mode and vice versa will be ed when the OT is in the down state (without active traffic).


PSS-16/32 FID 6979-3 / 3022-2 / 3186-2: Full flexible (100G) OT interworking – Cont. 3186-2- 130SNX10 • Control plane will the Transmux OT card 130SNX10 in PSS32 and PSS16 shelves • The OT will be ed with the following capabilities: - Optical bitrate: 100 Gbit - Electrical bitrate: 111,810 Gbit - ed FEC: AFEC, SDFEC - ed encoding: PDM-QPSK, icoh-PDM-QPSK - Module type: HPERF2 - Interworking (HO ODU) required as given in ReqId 21869 - The card can be used as unidirectional 3R OT and drop OT


PSS-16/32 (PSS-36/64) FID 6979-3 / 3022-2 / 3186-2: Full flexible (100G) OT interworking – Cont. 3022-2 - 130SCUPB*

• Control plane will the 130SCUPB uplink card in an OCS compound. • The OT will be ed with the following capabilities: - Optical bitrate: 100 Gbit - Electrical bitrate: 111,810 Gbit - ed FEC: AFEC, SDFEC

- ed encoding: icoh-PDM-QPSK - Module type: HPERF2 - Interworking (HO ODU) - ing LO ODU 0,1,2,2e,3, as LO ODUs for MRN (OCS only)

*Note that although the 130SCUPB is not a PSS16/32 card, it is included here because the interworking is similar to the 260SCX2 and 130SNX10. 252 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-36/64 FEATURES


PSS 36/64 FEATURES 1. FID 2976-1: PSS-36/64 R7.0 In-Service Upgrade 2. FID 3022-1: 130SCUPB 1 x 100G Uplink card 3. FID 10070: PSS-36 Noise Reduction Damper 4. FID 3262: ROHS6 FLC 5. FID 2950: 1+1 Multiplex Section Protection (MSP) 6. FID 3010: SDH Line Timing 7. FID 1292: STM-256/OC-768 client mapping 8. FID 10076: for more than 11 Uplink Cards in OCS 9. FID 3095-1: OCS UAL COLLECTION OF TIME SPECIFIC LOGS


PSS-36/64 FID 2976-1: R7.0 In-Service Upgrade • Description: This feature s in-service upgrade from previous 1830 releases (as specified) and factory load to 1830 R7.0. PSS OCS:

1830 PSS Source Release

1830 PSS Destination Release

Factory Load

1830PSS 7.0-0

1830PSS 6.0-6

1830PSS 7.0-0


PSS-36/64 FID 3022-1: 130SCUPB 1 x 100G Uplink card Brief Description: The 130SCUPB is a new uplink card for R7.0. The 130SCUPB is a single-slot variant of the 130SCUP card with lower power dissipation. The 130SCUPB uses a Flex-Framer ASIC (and is not Obelix-based). The Flex-Framer can ODUflex and ODU3 mappings (not introduced in software release R7.0)

The 130SCUPB s WDM line performance similar to the 130SCUP and s wavelength tunability and wavetracker , in addition, the 130SCUPB is hardware ready to both flex grid and transmit pulse-shaping applications (not introduced in software release R7.0) - Single slot 100G uplink card - ODU-Flex ready - 30% increase in spectral density using 37.5 Flex-grid with virtually no Transmission penalty. - Hardware ready to 40G via remote configuration for ULH applications - Fully tunable, single carrier coherent PM-QPSK. - Advanced SDFEC implementation - 30% additional reach versus hard decision FEC. - Industry Unique integration of SDFEC and Differential Encoding provides improved performance while eliminating Cycle Slips. - Reduced Power Dissipation

Programmable Line

Long haul distance >3000km OTU-4 130 Gbit/s PDM-QPSK

ULH distance >5000km OTU-3 43 Gbit/s PDM-BPSK


PSS-36/64 FID 3022-1: 130SCUPB 1 x 100G Uplink card – Cont.


PSS-36/64 FID 3022-1: 130SCUPB 1 x 100G Uplink card – Cont. A. Adaptive DWDM Line Interface

B. Tributary/Switching

1. 100G single carrier using DP-QPSK -

3000 km reach* using SDFEC (longer reach applicable when Raman Amplification is used)

-

2000 km reach* when interworking with Gen1 100G via HDFEC.

-

CD Tolerance ± 80,000 ps

-

The 130SCUPB shall an adaptive line interface, ing the following - provisionable options: Option 1: A single carrier using PM-QPSK modulation format, with NRZ coding (SD-FEC). The line rate with SD-FEC is OTU4 (129.280281 Gb/s +/- 20ppm) (approximately 130 Gb/s). Option 2: A single carrier using PM-QPSK modulation format, with NRZ coding (AFEC). When provisioned for AFEC, the line bit rate shall be OTU4 (111.8099736 Gb/s +/- 20ppm).

1. ODU0, ODU1, ODU2, ODU2e, ODU3, ODU3e, ODU4 2. HW-ready for ODU-flex The 130SCUPB shall the following HO-ODU4 multiplexing options: - 80 x ODU0 multiplexed into a HO-ODU4 (1 TS per ODU0) - 40 x ODU1 multiplexed into a HO-ODU4 (2 TS per ODU1) - 10 x ODU2 multiplexed into a HO-ODU4 (8 TS per ODU2) - 10 x ODU2e multiplexed into a HO-ODU4 (8 TS per ODU2e)

C. Card Level Characteristics 1. 1 slot wide, full slot high (16 cards per PSS36). 2. typical power ~ 200 Watts using DP-QPSK 3. Card TX + RX Transmission Latency < 50 usec

2. Hardware-ready 40G single carrier using DP-BPSK -

5000 km reach using SDFEC (longer reach applicable when Raman amplification is used)

-

CD Tolerance ± 120,000 ps

D. Operations 1. 2. 3. 4.

3. DGD tolerance (no penalty): 120 ps 4. Full C-Band tuning with pulse shaping for Flex-grid 50 GHz or 37.5 GHz spacing.

E. Protection:

5. 11.2 dB FEC Coding Gain*

1. 1+1 OCH (Switching times < 50 ms) 2. L0 /MRN 3. LO/HO ODUk

6. Integrated WaveTracker encoding 7. Line Interface is standards compliant OTU4. 8. Performance Monitoring -

PRBS generation and detection Facility and Terminal Loopbacks GCC0, GCC1 Processing Delay Measurement

OPR, OPT. Laser Bias Current OTUk/ODUk Monitoring, GCC0 access (HW ready) PM based on ADC/DSP (RCD, DGD, etc) HO and LO TCM 258 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-36/64 FID 3022-1: 130SCUPB 1 x 100G Uplink card – Cont.


PSS-36 FID 10070: PSS-36 Noise Reduction Damper • • • •

Compliance with ETSI & ANSI acoustic noise specifications This applies to one PSS-36 in a rack 1830 PSS36 ANSI ACOUSTIC KIT, 3KC19506AA 1830 PSS36 ETSI ACOUSTIC KIT, 3KC19507AA Note : this solution is applied only in case of customer complaints

Anti-Recirculation Baffle with Damper Interface surface beneath damper

Damper

improved flap design necessary


Fill up with damper material (front and rear side)

PSS-36 FID 10070: PSS-36 Noise Reduction Damper – Cont. • Installation of 1830 PSS-36 with Damper

Mount damper on top of new anti-recirculation baffle

Anti-recirculation baffle


PSS-36 FID 10070: PSS-36 Noise Reduction Damper – Cont. • Two 1830 PSS-36’s in a 300mm deep ETSI rack, same principle for ANSI Rack


PSS-36 FID 10070: PSS-36 Noise Reduction Damper – Cont. • 1830 PSS-36 in a ETSI rack


PSS-36/64 FID 3262: ROHS6 FLC • New FLCs for PSS-36 and PSS-64 to meet Restriction of Hazardous Substances (RoHS) requirements - Includes P1013 U - Lead-free soldering - No functionality difference from existing FLCs

• Beyond July 22, 2016, per EU directives, pre-ROHS FLCs may not be delivered within EU • ROHS6 FLCs can be installed inhomogeneously with pre-ROHS6 FLCs • R7 will pre-ROHS6 FLCs

APN

NEW Original

PDM@ Mnemonic / Acronym

Description

Rel.

Product

Width

3AG34251AA

FLC64

PSS-64 FIRST LEVEL CONTROLLER B Version

R7.0.0

PSS-64

27mm

3KC19489AA

FLC36

PSS-36 FIRST LEVEL CONTROLLER B-Version

R7.0.0

PSS-36

20mm

8DG89216AB

EC_HC

EC_HC PSS-64 First Level Controller

ALL

PSS-64

27mm

3AG33727AA

FLC36EA

FLC36EA PSS-36 First Level Controller

ALL

PSS-36

20mm


PSS-36/64 FID 2950: 1+1 Multiplex Section Protection (MSP) • Unidirectional switching

• Non-Revertible switching • No restriction for the ports paired in a 1+1 protection group • A port may be one of the following: -

STM-1/4/16 ports on a 24XSTHMR STM64 port on a 10XSTH10G

• Switching criteria: - Signal Failure (SF) - Signal Degrade (SD)


PSS-36/64 FID 2950: 1+1 Multiplex Section Protection (MSP) – Cont. • Select STM-n port in the Protection tree, and right click to open the menu below:

• Select STM-n ports (working an Protecting) :


PSS-36/64 FID 2950: 1+1 Multiplex Section Protection (MSP) – Cont. • Select STM-n Working port to display 1+1 protection group:

• Select “View Current Conditions” from the above menu:

Note : FFP = Fast Facility Protection 267 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-36/64 FID 2950: 1+1 Multiplex Section Protection (MSP) – Cont. • From the 1+1 protection group, select the menu “Operate protection Switch”:

• Switch Command Mode: - Forced Switch to - Lockout of Protection - Prevents the protection scheme from switching to the protection, the working line is requested to stay active

- Manual Switch to


PSS-36/64 FID 2950: 1+1 Multiplex Section Protection (MSP) – Cont.

• Create 1+1 protection group with Tl1 commands : -

ENT-FFP-STM1 ENT-FFP-STM4 ENT-FFP-STM16 ENT-FFP-STM64

Note : FFP = Fast Facility Protection


PSS-36/64 FID 2950: 1+1 Multiplex Section Protection (MSP) – Cont. • Operate protection switch with Tl1 commands: -

OPR-PROTNSW-STM1 OPR-PROTNSW-STM4 OPR-PROTNSW-STM16 OPR-PROTNSW-STM64

• Release protection switch with Tl1 commands: -

RLS-PROTNSW-STM1 RLS-PROTNSW-STM4 RLS-PROTNSW-STM16 RLS-PROTNSW-STM64

• Delete 1+1 protection group with Tl1 commands: -

DLT-FFP-STM1 DLT-FFP-STM4 DLT-FFP-STM16 DLT-FFP-STM64 270 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-36/64 FID 3010: SDH Line Timing • Line timing to one of six STM-64 ports of 10XSTH10G ports card • In addition to the 2 EXTREF there are 6 LINEREF: - EXTREF-1-1-0 - EXTREF-1-1-1 -

LINEREFSYS-1-1-0 LINEREFSYS-1-1-1 LINEREFSYS-1-1-2 LINEREFSYS-1-1-3 LINEREFSYS-1-1-4 LINEREFSYS-1-1-5


PSS-36/64 FID 3010: SDH Line Timing – Cont. • Menu : System -> Internal Sync -> Line Timing • Select a LINEREF, right click and select “Properties – General”


PSS-36/64 FID 3010: SDH Line Timing – Cont. • Provision : Primary State, Assigned Port, Priority (from 1 to 8), Provisioned Quality Value

• Menu : System -> Internal Sync -> Line Timing


PSS-36/64 FID 3010: SDH Line Timing – Cont. • Menu : System -> Internal Sync -> System Timing

• Clock Mode Status: -

Locked - system timing is locked to a timing reference signal

-

Autonomous-Holdover - all system timing selection have failed, and the clock is using data previously acquired

- Autonomous-Freerunning - e.g. after initial power-up

- Forced-Freerunning - system timing switch command 274 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-36/64 FID 3010: SDH Line Timing – Cont. • Provision a LINEREF with Tl1 command: ED-SYNCN


PSS-36/64 FID 3010: SDH Line Timing – Cont. • Retrieve Sync provisioning: RTRV-SYNCN

• Perform a timing Ref switch: OPR-SYNCNSW


PSS-36/64 FID 1292: STM-256/OC-768 client mapping • I/O card : 2XANY40G • STM-256/OC-768 transparently mapped into ODU3


PSS-36/64 FID 1292: STM-256/OC-768 client mapping – Cont.

• Facilities Menu:


PSS-36/64 FID 10076: for more than 11 Uplink Cards in OCS • When the PSS-36/64 is used in grooming and traffic consolidation applications, it often requires a high number of uplink cards ed in one shelf

Legend : ETS300019-1-3 : Environmental conditions and environmental tests for telecommunications Class 3.1E: Extended temperature range 279 COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

PSS-36/64 FID 3095-1: OCS UAL Collection of time-specific logs Brief Description: FID 3095-1 defines the ability for the to generate collection of time-specific UAL ( Access Logs), the NE s the ability to accept a time window for log collection. Presently when the NMS requests the UAL log from the NE, the NE sends the entire UAL log content, which could be upwards of 2MB. This feature shall allow the NMS to send a query, specifying the time window for log collection, and the NE shall respond back with log entries that fall within that time window

Partial Log collection- ZIC


PSS-36/64 FID 3095-1: OCS UAL Collection of time-specific logs – Cont. Partial Log collection- ZIC Define the following parameters: From- UAL To- RFSUAL Protocol- SFTP Location : as required for SFTP access - as required Location- IP address of SFT server Location port- as required Location Path- as required From/To date and time- as required Filter- All/EVTALM/COMMAND/SECU Unique id- as required Click send

Partial Log collection- ZIC If the transfer is successful, the following message will be returned within the Security file transfer window


LIST OF ACRONYMS 3R – reamplify, reshape, retime – add/drop multiplexer AFEC – ALU proprietary FEC encoding, for signals 40G and higher (OTU3 and OTU4) AID – access identifier AIS – Alarm Indication Signal AM – after matrix ANSI – American National Standards Institute APN - ALU Part Number APR – automatic power reduction B&W – black and white BER – bit error rate BM – before matrix CBR – constant bit rate CD – chromatic dispersion CES – carrier Ethernet switch CFM – connectivity fault management CFP – 100G (C=100 in Roman numerals) form-factor pluggable CLI – Command Line Interface CLS – colorless CMEP – connection monitoring end point COH – coherent – circuit pack or control plane U – central processing unit CR – critical (alarm) CWDM – coarse WDM CWR – colorless wavelength router DA – destination (MAC) address dB – decibels DCM – dispersion compensation module DDM – digital diagnostics monitoring

DDR – double data rate DGD (as in PMD/DGD) – Differential group delay DM – delay measurement DMM/DMR PDU – delay measurement message/delay measurement reply protocol data unit DNR – device not reachable DS – differentiated services code point DWDM – dense WDM EC – Equipment Controller EC – equipment controller ECC – embedded control channel ECID – emulated circuit identifier EDFA – Erbium doped fiber amplifier EFEC – AMCC proprietary FEC, not as good as EFEC2 EFEC2 – ALU proprietary FEC encoding for 10G (OTU2) signals. Equivalent to AFEC, different rate. EPT – Engineering and Planning Tool ERP – Ethernet ring protection ESN – electrical sub-block network connection Protection ETH-DM – Ethernet delay measurement Ethernet OAM – Ethernet operation, istration, maintenance ETSI – European Telecommunications Standards Institute EU – European Union FA – forwarding adjacency FC – forwarding class FD/FDV – frame delay/frame delay variation FEC – Forward Error Correction FID – Feature ID FIPS – federal information processing standard FLC – First level controller FM – fault management FO – fixed optical add/drop multiplexer 282

COPYRIGHT © 2014 ALCATEL-LUCENT. ALL RIGHTS RESERVED. ALCATEL-LUCENT — INTERNAL PROPRIETARY — USE PURSUANT TO COMPANY INSTRUCTION

LIST OF ACRONYMS FPGA – field programmable gate array FTP – file transfer protocol fVOA – fast VOA G-AIS – generalized TDM AIS GCC – general communications channel GDPS – Geographically Dispersed Parallel Sysplex GMPLS – generalized multi-protocol label switching GMRE – GMPLS Routing Engine GUI – graphical interface HO-ODU – high order ODU HW – hardware iCOH – interleaved coherent IFG – inter-frame gap ILA – in-line amplifier iNRZ – inverted non-return to zero IO or I/O – Input/Output ISU – In-Service Upgrade ITLB – Interleaver, bidirectional IWF – interworking function JB – jitter buffer KM – key manager KMT – key management tool LAN – local area network LD – line driver LOF – loss of frame LO-ODU – low order ODU LOS – loss of signal LPL – local packet lost LR4/LR10 – CFP with 4 or 10 lanes respectively (10x10Gb/s or 4x25Gb/s) with 10Km SMF reach [LR=10Km SMF reach, ER=40Km SMF reach, SR=100m MMF reach]

LSP – label switched paths LTC – Loss of tandem connection MEP – monitoring end point MLN – management level network MRN – multi-region network MSA – multi-source agreement NE – Network Element NLP (as in NLP/CD) – non-linear phase shift NM – network manager NOFEC – no FEC running NRZ – non-return to zero OA – optical amplifier O – optical add/drop multiplexer OCH – optical channel OCHP – optical channel, protected OCS – optical cross connect system ODU – optical channel data unit OEO – optical to electrical to optical OH – overhead OLP – optical line protection OMS – 1350 Optical Management system OMSP – optical multiplexer section protection OPR – optical power received OPS – optical protection switch OPT – optical power transmitted OSC – optical supervisory channel OSN – optical sub-block network connection protection OSNR – optical signal to noise ratio OT – optical transponder OTN – optical transport network


LIST OF ACRONYMS PCS – physical coding sublayer PDM – Polarization Division Multiplexing PDM-16QAM/PD-16QAM – PD(M)-16 Quadrature Amplitude Modulation PDM-QPSK/PD-QPSK – PD(M)-Quaternary Phase Shift Keying PF – power filter PhM – 1354 Photonic Manager PM – performance monitoring PMD – Polarization Mode dispersion PPM – parts per million PRBS – pseudo-random binary sequence PT – payload type QoS – quality of service R-APS – ring-automatic protection switch RMD – remote managed devices RO – reconfigurable optical add/drop multiplexer ROHS – restriction of hazardous substances RPL – remote packet lost RPL – ring protection link RTP – real time transport protocol SAM – 5620 management system SAP – service access point SD – signal degrade SDFEC – Soft decision FEC – provides more net coding gain than previous generation FEC SF – signal failure SFD – static filter SFP – small form-factor pluggable SFTP – secure file transfer protocol SHG – split horizon group SNC – sub-network connection

SSH – secure shell SSL – secure socket layer SSM – synchronous status message SSRC – synchronization source sVOA – slow VOA SW – software TCA – threshold crossing alert TCM – tandem connection monitoring T/UDP – transmission control protocol/ datagram protocol TDM – time division multiplexing TL1 – transaction language one TLS – timing link switch TO – tunable optical add/drop multiplexer TSoP – transparent SONET/SDH over Packet TX – transmit T-XFP – tunable XFP UAL – access logs VID – VLAN identifier VOA – variable optical attenuator VPLS – virtual private LAN service WAN – wide area network WDM – wavelength division multiplexing WKAT – well known answer test WR – wavelength router WSS – wavelength selectable switch WT – wavetracker XFP – 10G (X=10 in Roman numerals) form-factor pluggable ZIC – zero installation craft terminal


GPR-GNPI EMAIL

for the delta training please email to: [email protected]


Dwdm 2i395p

Overview 3e4r5l

More details w3441

Related Documents 3m3m1z

Dwdm 2i395p

Dwdm Training 11542y

Dwdm Presentation 3q3720

Dwdm Hardware 6l253h

Dwdm Topologies 6e2y4j

Dwdm Basics 4m74f

More Documents from "Jorge Vargas" 3185q

6l6m1j

Unidad 2. Enfoque Del Desarrollo Organizacional. dh55

6l6m1j

Final Proceso Estrategico I 60w2r

6l6m1j

63078122 Fisica Ejercicios Resueltos Soluciones De Fisica Nuclear 2q1w1q