Guest

Cisco ONS 15454 Series Multiservice Transport Platforms

Cisco ONS 15454 100Gbps Coherent DWDM Trunk Card

  • Viewing Options

  • PDF (1.0 MB)
  • Feedback

Product Overview

The Cisco® ONS 15454 Multiservice Transport Platform (MSTP) supports a trunk card that delivers Dense Wavelength-Division Multiplexing (DWDM) transmission using a coherent polarization-multiplexed differential quadrature phase shift keying (CP-DQPSK) modulation scheme. The Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card (Figure 1) simplifies the integration and transport of 100 Gigabit Ethernet and Optical Transport Unit Level 4 (OTU-4) interfaces and services into enterprises and service provider optical networks.

Release 9.6 of the Cisco ONS 15454 MSTP extends the total data transport capacity by a factor of three, allowing DWDM transmission of up to 9.6 Tbps (96 wavelengths at 100 Gbps each) in the C band.

Figure 1. Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card

Challenge and Solution

The bandwidth carried on core and metropolitan DWDM networks is growing exponentially, while operators’ revenues are not keeping pace. The Cisco ONS 15454 100-Gbps solution can dramatically lower the cost to carry bandwidth, helping to maintain and improve customers’ profitability. Internet growth is still exponential, mainly due to demand for next-generation services such as quadruple play (data, voice, video, and mobility), video distribution, Internet Protocol Television (IPTV), and other high-bandwidth services.

With advanced modulation schemes, the ability to transmit 100-Gbps wavelengths on existing or new DWDM systems improves return on investment by increasing the overall capacity per fiber pair without impacting the unregenerated transmission distance supported by the system. Scaling from 10 Gbps to 40 Gbps and now 100 Gbps increases by a factor of 10 the bandwidth that can be transported over existing fiber networks.

The new CP-DQPSK modulation supports 9.6 Tbps capacity transmission over Ultra-Long-Haul (ULH) networks of up to 3000 km of unregenerated optical spans.

The Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card is designed to provide the following benefits:

Transport of 100-Gbps wavelengths over fully uncompensated networks, up to 3000 km of unregenerated optical spans

Transport at 100 Gbps over very low-quality fiber with very high Polarization Mode Dispersion (PMD)

Support for up to ninety-six 100-Gbps wavelengths (50-GHz channel spacing) with very high tolerance to filtering penalties

Improved overall system density for 100 Gbps per slot, five times greater than the density achieved with 40‑Gbps units

Support for different configurations (transponder, muxponder, or regenerator) through software provisioningonly

Product Features and Benefits

The Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card is a plug-in module to the Cisco ONS 15454 MSTP, providing a cost-effective architecture for delivering 100-Gbps services. The card also features a pluggable client interface that can be used to provide transponder capabilities, mapping the client signal to a single DWDM line interface.

The client port supports a standard Channel Express (CXP) format pluggable compliant with IEEE 100GBASE-SR10 LAN PHY or OTU-4 equivalent interface.

The trunk card features a software-configurable baud rate between 27.952 Gbaud and 31.241 Gbaud, depending on Forward Error Correction (FEC) selection as well as a G.709v3 OTU-4 digital wrapper, long-reach and long-haul, ITU-compliant, 50-GHz spaced optical interface using LC connectors. The DWDM output line interface is tunable to 96 wavelengths across the full optical C band, dramatically reducing inventories for spares. When operated within the outlined specifications, the trunk card can operate with a post-FEC bit error rate (BER) of better than 10E-15.

The trunk card provides many carrier-class features and advanced capabilities necessary to deliver 100-Gbps services, including protocol transparency, wavelength tunability, flexible protection mechanisms, flow-through timing, and management and performance monitoring capabilities (Figure 2).

Figure 2. Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card Block Diagram

Enhanced Forward Error Correction Capability

The Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card can support FEC mechanisms on trunk and client interfaces.

The trunk port supports three software-configurable FEC coding options, which cannot be disabled.

Generic FEC (GFEC): Standard G.975 Reed-Solomon algorithm with 7 percent overhead (OH).

Ultra FEC (UFEC): Standard G.975.1 (Subclause I.7) with 20 percent overhead. This FEC scheme uses two orthogonally concatenated BCH Enhanced FEC (EFEC) codes. The constructed code is decoded iteratively to rebuild the original frame.

High-Gain FEC (HG-FEC): High-Gain FEC with 7 percent overhead, providing better performance than standard G.975.1 seven percent overhead FEC. Because of the reduced overhead and lower bit rate, HG-FEC is suitable for applications where 100-Gbps wavelengths are passing through a large number of reconfigurable optical add-drop multiplexer (ROADM) nodes with limited pass-band performance.

The client port supports the standard G.975 Reed-Solomon FEC algorithm, which can be enabled or disabled through software configuration.

Advanced Modulation Scheme

The Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card features an advanced modulation scheme to provide optical performance significantly better than industry-standard 10-Gbps equivalent interfaces.

Cisco selected a CP-DQPSK modulation format to optimize 100-Gbps transmission in terms of Optical Signal-to-Noise Ratio (OSNR), Chromatic Dispersion (CD), and Polarization Mode Dispersion (PMD) robustness.

The CP-DQPSK modulation scheme consists of multiplexing two DQPSK signals using two different orthogonal light polarizations, as shown in Figures 3 and 4.

Figure 3. CP-DQPSK Logical Modulation Scheme

Figure 4. CP-DQPSK Logical Transmitter Scheme

The core of the 100-Gbps CP-DQPSK modulation scheme is the optical receiver, based on coherent optical detection, where a Digital Signal Processor (DSP) calculates the inverse of the optical system matrix, allowing the receiver to recover the original transmitted signals (Figure 5).

Figure 5. CP-DQPSK Logical Receiver Scheme

The primary benefits of CP-DQPSK are:

Strong optical signal-to-noise ratio performance

Outstanding chromatic dispersion robustness, avoiding any additional cost related to optical chromatic dispersion compensation equipment

Extended polarization mode dispersion robustness (three times better than 10-Gbps units)

Very high spectral efficiency, allowing 100-Gbps wavelengths to be transmitted across a large number of ROADMs with negligible penalty

Trunk Card Versions

Two versions of the Cisco ONS 15454 100 Gbps Coherent DWDM Trunk card are offered to support different application requirements:

An extended-performance version offering full performance targeting Ultra Long-Haul applications where the network is optimized for CP-DQPSK transmission (no 10-Gbps channels or dispersion compensation units [DCUs])

A metro edge performance version with differential mode only (CP-DQPSK), cost-optimized for metropolitan application and 10-Gbps installed networks

Protocol Transparency

The Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card can transparently deliver 100-Gbps point-to-point services cost-effectively for the Cisco ONS 15454 MSTP platform. Table 1 shows transponder client configurations and mapping.

Table 1. Transponder Client Configurations and Mapping

Client

Mapping

Trunk

Format

Rate (Gbps)

Format

Rate with 7% GFEC or HG-FEC OH (Gbps)

Rate with 20% UFEC OH (Gbps)

100GE LAN-PHY

101.125

Bit transparent through standard G.709v3 mapping

OTU-4

111.809

124.964

OTU-4

111.809

Transparent G.709 standard

Wavelength Tunability

The trunk card supports software-provisionable tunability across the full C band, covering 96 channels on the 50-GHz grid. Tunability provides flexibility and reconfigurability of services transported on ROADM-based networks, and also allows ordering and inventory of a single part for deployment and sparing.

Flexible Protection Mechanism Support

The trunk card supports multiple protection mechanisms commonly used in optical transport networks. Table 2 outlines the available protection options and the associated service-level agreements (SLAs) that can be provided.

Table 2. Protection Formats

Protection Type

Capabilities

Unprotected

No client terminal interface, transponder card, or DWDM line protection.

The client signal is transported over a single unprotected transponder card or optical path.

1+1 protection

Provides protection for the client terminal interface, transponder card, and DWDM line through client Automatic Protection Switching (APS) or Linear Multiplex Section Protection (LMSP) signaling transported transparently over the transponder card or optical path.

Protection is provided through client line or path protection through transparent signal transport through a transponder circuit.

OCH-trail protection

Provides protection for DWDM signal through external optical switch units: Protection Switch Module (PSM).

Flow-Through Timing

The Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card allows timing to flow through from client to line optical interface. The received timing from the client interface is used to time the line transmitter interface. This flow-through timing allows multiple trunk cards to be placed in the same shelf but be independently timed, independent of the network element timing.

Management

The Cisco ONS 15454 MSTP system provides comprehensive management capabilities to support Operations, Administration, Maintenance, and Provisioning (OAM&P) capabilities through the integrated Cisco Transport Controller craft interface with support from the Cisco Prime™ optical element management system. The trunk card features provisionable digital wrapper (G.709) functionality, providing per-wavelength performance management capabilities, especially for services transported transparently across the network. Without the digital wrapper functions, a carrier transporting a service transparently would be unable to identify network impairments that may degrade the transported signal and violate the SLA agreements. The digital wrapper’s Generic Communication Channel (GCC) provides a separate communications channel on a per-wavelength basis to be used by the platform when transparent signals are transported. GCC allows the Cisco ONS 15454 MSTP system to extend its advanced network autodiscovery capabilities to DWDM-based services. The integrated Cisco Transport Controller craft manager and Cisco Prime provide the user with OAM&P functionalities for the system.

Far-End-Laser-Off Behavior

The Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card can provision the far-end-laser-off behavior when SONET/SDH payloads are present. Customers can use Cisco Transport Controller to configure how the remote client interface will behave following a fault condition. It is possible to configure the remote client to Squelch or to send an Alarm Indication Signal (AIS). For 100-Gigabit Ethernet signals, the default behavior is Squelching.

Performance Monitoring

The Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card provides support for both transparent and nontransparent signal transport performance monitoring. The digital wrapper channel is monitored according to G.709 Optical Transport Network (OTN) and G.8021 standards. Performance monitoring of optical parameters on the client and DWDM line interface include Loss of Signal (LOS), laser bias current, transmit optical power, and receive optical power. Calculation and accumulation of the performance monitoring data are supported in 15-minute and 24-hour intervals as per G.7710.

Physical system parameters measured at the wavelength level, such as mean polarization mode dispersion, accumulated chromatic dispersion, or received optical signal to noise ratio, are also included in the set of performance monitoring parameters. These can greatly simplify troubleshooting operations and enhance the set of data that can be collected directly from the equipment. A detailed list of performance monitors is given in Table 8.

The trunk card incorporates faceplate-mounted LEDs to provide a quick visual check of the operational status of the card. An orange circle is printed on the faceplate, indicating the shelf slot in which you can install the card.

A specific configuration of the client will support IP over DWDM (IPoDWDM) proactive Fast Reroute (FRR) messaging over the CXP client in case of 100 Gigabit Ethernet connectivity.

Regeneration Application

The Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card supports OTU-4 regeneration capabilities. Two cards can be configured to work in back-to-back mode connecting through the backplane in the same shelf, and perform the OTN Optical-Electrical-Optical (OEO) regeneration of the frame as depicted in Figure 6.

Figure 6. OTU-4 Regeneration Application for 100 Gbps OTU-4 Client Signal

100 Gigabit Ethernet or OTU-4 clients are supported. Regeneration capability uses the OTU-4 backplane interconnection supported by the Cisco ONS 15454 MSTP M6 or M2 chassis; OTU-4 overhead is terminated, allowing ODU-4 traffic to transparently pass through. GCC0 is properly terminated, while GCC1 and GCC2 are properly passed through (Figure 7).

No CXP client is required, as communication between the two cards acting as a regeneration group is supported through the chassis backplane.

A dedicated IPoDWDM configuration can be enabled in the regeneration configuration to support proactive FRR messaging between IPoDWDM router interfaces.

Figure 7. OTU-4 Regeneration Configuration in a Cisco ONS 15454 M2 chassis

In case of failure on one side, ODUk-AIS is generated and propagated on the other side while an OTUk-BDI is sent back on the same side as defined by the ITU G.709 standard.

Cisco ONS 15454 10-Port 10 Gbps Line Card Configuration

The Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card can be coupled with the Cisco ONS 15454 10-Port 10-Gbps Line Card to support 10-port 10-Gbps muxponder capability. The Cisco ONS 100 Gbps Coherent DWDM Trunk Card can be connected through the Cisco ONS 15454 MSTP M6 or M2 backplane (no client CXP required) with the Cisco ONS 15454 10-Port 10 Gbps Line Card to provide OTN multiplexing of 10 ports of 10-Gbps data streams into a single 100-Gbps DWDM OTU-4 wavelength (Figure 8).

Supported client signals are any combination of 10 Gigabit Ethernet LAN-PHY, 10 Gigabit Ethernet WAN-PHY, OC-192, STM-64, 10-Gbps and 8-Gbps Fibre Channel (FICON), or OTU-2 data rates.

Please refer to the Cisco ONS 15454 10-Port 10 Gbps Line Card data sheet for additional information.

Figure 8. Three Cisco ONS 15454 10-Port 10 Gbps Line Card Applications in an M6 Chassis

Cisco ONS 15454 2-Port CFP 40-Gbps Muxponder Application

The Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card can be coupled with the Cisco ONS 15454 2-Port CFP Line Card to support two ports of 40-Gbps muxponder capability in a C Form-Factor Pluggable (CFP) configuration. The trunk card can be connected through the Cisco ONS 15454 MSTP M6 or M2 backplane (no client CXP required) with the 2-port CFP line card and provides OTN multiplexing of the two ports of 40-Gbps data streams into a single 100-Gbps DWDM OTU-4 wavelength.

Supported client signals are any mix and combination of 40 Gigabit Ethernet LAN-PHY, or OTU-3 data rates. Please refer to the Cisco ONS 15454 2-Port CFP Line Card data sheet for additional information.

Cisco 100-Gbps LR4 Transponder Application

The Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card can be coupled with the Cisco ONS 15454 2-Port CFP Line Card to support the 100GBASE-LR4 client interface for the 100-Gbps transponder. The 2-port CFP line card can be connected through the Cisco ONS 15454 M6 or M2 backplane with up to two trunk cards placed in slots immediately above and below the line card to provide the functionality of two 100-Gbps LR4 transponders, using CFP pluggables as the client-facing interface (Figure 9).

Figure 9. LR4 Transponder Application Plus One 10-Port 10 Gbps Muxponder in an M6 Chassis

Supported client signals are 100 Gigabit Ethernet LAN-PHY or OTU-4 data rates.

Please refer to the Cisco ONS 15454 2-Port CFP Line Card data sheet for additional information.

Application Description

The Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card provides cost-effective 100-Gbps transport services using the Cisco ONS 15454 MSTP platform.

Two main applications promote the 100-Gbps deployments.

100-Gbps router interconnection for business services and research networks: Cisco research indicates that the total volume of worldwide IP traffic is doubling every two years, requiring an increase in transfer rate from 10 Gbps to 100 Gbps. The transponder solution aims to provide DWDM interconnection between 100-Gbps router interfaces across DWDM metro, regional, or ULH networks. The advanced CP-DQPSK modulation scheme is designed to cope with long-distance applications, allowing the extension of unregenerated 100-Gbps services across fiber spans up to 3000 km.


OTU-4 links in carrier backbone networks: OTN technology is crucial to backbone carrier networks. OTN is normally the preferred method used for inter-carrier or inter-domain capacity exchange at 2.5-Gbps (OTU-1), 10-Gbps (OTU-2), 40-Gbps (OTU-3) and 100-Gbps (OTU-4) data rates. The Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card supports a fully standard OTU-4 client interface, which can be connected to any G.709-based OTN cross-connect, 100-Gbps router interface, or other 100-Gbps transponder interfaces.

Licensing Approach

The Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card includes the ability to cost-effectively transport 10-Gbps services through a pay-as-you-grow licensing model for the 10-Port 10-Gbps muxponder configuration. A licensed version of the Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card works in conjunction with a licensed version of the Cisco ONS 15454 10-Port 10 Gbps Line Card, offering a cost-effective solution for aggregation and transport of 10-Gbps services. These two cards can only work in this configuration. Additional 10-Gbps services will be provided by mounting a 10-Gbps license through software key distribution. Up to nine additional 10-Gbps licenses can be added to the Cisco ONS 15454 10-Port 10 Gbps Line Card (only one is provided in the initial configuration).

To simplify spares management, it is also possible to upgrade the licensed version of the trunk card to full functionality.

Table 3. Supported Software Licenses

License Part Number

License Description

Card Applicability

Card Description

15454-M-LIC-10G=

One-Port 10-Gb License for 100-Gb muxponder

15454-M-10X10-LIC=

10x10G Multirate client line card licensed with 1 license at 10 Gb

15454-M-LIC-100G=

100G TXP Reg License for 100-Gb trunk line card

15454-M-100GC-LIC=

100G OTU-4 ITU-T CP-DQPSK Full C-Band Tunable Line Card License

More information about the Cisco licensing policy is available at http://www.cisco.com/en/US/docs/general/warranty/English/EU1KEN_.html.

Product Specifications

Compact Design

Single-slot card design for high-density, 100-Gbps solutions

Up to six trunk cards per Cisco ONS 15454 M6 shelf assembly, supporting up to forty-two 100-Gbps ports per 42-rack-unit (RU) bay frame

Flexible Restoration Options

Transparent support for UPSR, SNCP, BLSR, MS-SPRing, and 1+1 APS and MSP

OCH-trail protection through protection switch module

Unprotected (0+1)

Regulatory Compliance

Table 4 lists regulatory compliance information for the trunk card. Note that all compliance documentation may not be completed at the time of product release. Please check with your Cisco sales representative for countries other than Canada, the United States, and the European Union.

Table 4. Regulatory Compliance

ANSI System

ETSI System

Countries and Regions Supported

Canada
United States
Korea
Japan
European Union
European Union
Africa
CSI
Australia
New Zealand
China
Korea
India
Saudi Arabia
South America

EMC (Class A)

FCC47CFR15,2007
ETSI EN 300 386 V1.4.1 (2008-04) Telecommunication network equipment EMC requirements (Note: EMC-1)
CISPR22:2008 and EN55022:2006/A1:2007 Information Technology Equipment (Emissions) (EMC-2)
CISPR24: 1997/ A1:2001/A2:2002 and EN55024:1998/A1:2001/A2:2003: Information Technology Equipment – Immunity characteristics – Limits and Methods of Measurement (test levels)

Safety

CSA C22.2 #60950-1 – Edition 7, March 2007
UL 60950-1 – Edition 2, March 2007
GR-1089-CORE Issue 4, NEBS EMC and Safety, June 2006
UL 60950-1 – Edition 2, March 2007
IEC 60950-1 Information technology equipment Safety Part 1: General requirements – Edition 2, 2005 and National Differences as per CB Bulletin 112A
IEC/EN 60950-1 (2006/10) with Amendment 11:2004 to EN 60950-1:2001, 1st Edition and National Differences as per CB Bulletin 112A.
EN 60950-1, Edition 2 (2006) Information technology equipment – Safety – Part 1: General requirements
CE Safety Directive: 2006/95/EC

Laser

UL 60950-1 – Edition 2, March 2007
IEC 60825-1: 2001 Ed.1.2 (incl. am1+am2) Safety of laser products Part 1: Equipment classification, requirements and users guide
IEC60825-2 Ed.3 (2004) Safety of laser products Part 2: Safety of optical fiber communication systems + A1:2006
IEC 60825-1: 2001 Ed.1.2 (incl. am1+am2) Safety of laser products Part 1: Equipment classification, requirements and users guide
IEC60825-2 Ed.3 (2004) Safety of laser products Part 2: Safety of optical fibre communication systems + A1:2006
21CFR1040 (2008/04) (Accession Letter and CDRH Report) Automatic Laser Shutdown and restart (ALS) according to ITU-T G.664 (03/06). Guidance for Industry and FDA Staff (Laser Notice No. 50) , June 2007
Laser Products: Conformance with IEC 60825-1 and IEC 60601-2-22; Guidance for Industry and FDA Staff (Laser Notice No. 50), June 2007

Environmental

GR-63-CORE Issue 3 ,Network Equipment Building Standards (NEBS) Physical Protection, March 2006
ETS 300-019-2-1 V2.1.2(Storage, Class 1.1)
ETS 300-019-2-2 V2.1.2(1999-09): Transportation, Class 2.3
ETS 300-019-2-3V2.2.2 (2003-04):Operational, Class 3.1E

Optical

GR-253-CORE – Issue 04
ITU-T G.691
ITU-T G.709
ITU-T G.975

Quality

TR-NWT-000332, Issue 4, Method 1 calculation for 20-year mean time between failure (MTBF)

Miscellaneous

GR-1089-CORE Issue 4, NEBS EMC and Safety (June 2006) (Note: NEBS-1)
GR-63-CORE Issue 3, NEBS Physical Protection (March 2006) (Note: NEBS-2)
ATT-TP-76200 : 2008
ANSI T1.315-2001
GR-499: 2004 Transport Systems Generic Requirements (TSGR): Common Requirements

Other Specifications

Table 5 lists system requirements for the Cisco ONS 15454 100 Gbps Coherent DWDM Trunk Card. Table 6 provides the DWDM specifications, Table 7 details receive-side optical performances, Table 8 lists performance monitoring parameters, Table 9 provides card specifications, and Table 10 gives ordering information.

Table 5. System Requirements

Component

Cisco ONS 15454 M6

Cisco ONS 15454 M2

Processor

TNC/TSC/TNC-E/TSC-E

TNC/TSC/TNC-E/TSC-E

Shelf assembly

Cisco ONS 15454-M6-SA shelf assembly with FTA2

Cisco ONS15454-M2-SA shelf assembly with FTA2

System software

Release 9.6 ANSI/ETSI or later

Release 9.6 ANSI/ETSI or later

Slot compatibility

2 through 7

2 through 3

Table 6. DWDM Specifications

Parameter

Value

Bit rate

27.952 Gbaud ±20 ppm (OTU4 with GFEC or HG-FEC 7% OH)

31.241 Gbaud ±20 ppm (OTU4 with UFEC 20% OH)

Automatic laser shutdown and restart

ITU-T G.664 (06/99)

Nominal wavelengths (lTnom)

Full-tunable between 1528.77 and 1566.72 nm (C-Band – 50 GHz)

Connector type (TX/RX)

LC, duplex (shuttered)

Optical Transmitter

Type

CP-DQPSK modulation format

Output power (PTmin)

–2 to +0.5 dBm (metro edge performance)

–1 to +1.5 dBm (extended performance)

Required optical return loss, minimum (ORLmin)

27 dB

Laser safety class

1

Optical Receiver

Chromatic dispersion tolerance (DLRmax)

+/– 70,000 ps/nm

Overload

0 dBm

Receiver reflectance (maximum)

30 dB

Input wavelength bandwidth (lc_rx)

Between 1528.77 and 1566.72 nm (C-Band – 50 GHz)

Table 7. DWDM Receive-Side Optical Performances

CD Tolerance

FEC Type

Pre-FEC BER

Post-FEC BER

Input Power Sensitivity

DGD

OSNR
(0.5 nm RWB)

Extended Performance

0 ps/nm

UFEC
(20% OH)

<1x10E (–2)

<10E (–15)

0 to –14 dBm
(–20 dBm with 0.5 dB of OSNR penalty)

7.5 dB

0 ps/nm

180 ps

8.0 dB

+/– 70,000 ps/nm

180 ps

9.0 dB

0 ps/nm

HG-FEC
(7% OH)

<4.0x10E (–3)

<10E (–15)

0 to –14 dBm
(–20 dBm with 0.5 dB of OSNR penalty)

8.0 dB

0 ps/nm

180 ps

8.5 dB

+/– 70,000 ps/nm

180 ps

9.5 dB

0 ps/nm

GFEC
(7% OH)

<1.0x10E (–3)

<10E (–15)

0 to –14 dBm
(–20 dBm with 0.5 dB of OSNR penalty)

9.5 dB

0 ps/nm

180 ps

10.0 dB

+/– 70,000 ps/nm

180 ps

11.0 dB

Metro Edge Performance

0 ps/nm

HG-FEC
7% OH

<4.0x10E (–3)

<10E (–15)

0 to –14 dBm
–20 dBm with 0.5 dB of OSNR penalty

11.0 dB

+/– 5,000 ps/nm

30 ps

11.5 dB

Table 8. Performance Monitoring Parameters

Area

Parameter Name

Description

OTN

OTUk SM

ODUk PM

BBE-SM

BBE-PM

Number of background block errors

BBER-SM

BBER-PM

Background block error ratio

ES-SM

ES-PM

Number of errored seconds

ESR-SM

ESR-PM

Errored seconds ratio

SES-SM

SES-PM

Number of severely errored seconds

SESR-SM

SESR-PM

Severely errored seconds ratio

UAS-SM

UAS-PM

Number of unavailable seconds

FC-SM

FC-PM

Number of failure counts

FEC

Bit errors

Number of corrected bit errors

Uncorrectable words

Number of uncorrectable words

Trunk optical performance monitoring

OPT

Transmitter optical power

LBC

Transmitter laser bias current

OPR

Receiver optical power

RCD

Residual chromatic dispersion

PMD

Mean polarization mode dispersion

OSNR

Optical signal-to-noise ratio, calculated with 0.5 nm RBW

SOPMD

Second Order PMD (SOPMD Estimation

SOPCR

Polarization Change Rate Estimation

PDL

Polarization Dependent Loss (PDL) Estimation

Table 9. Card Specifications

Management

Card LEDs

Failure (FAIL)

Active/standby (ACT/STBY)

Signal fail (SF)

Red

Green/yellow

Yellow

Client port LEDs (per port)

Active input signal

Green

DWDM port LEDs

Active input signal

Output wavelength

Green

Green

Power (including pluggable)

Typical

Maximum

125W (25C and –48VDC)

133W (55C and –38VDC)

Physical

Dimensions

Occupies 1 slot

Weight

4 lb (1.8 kg)

Reliability and availability

Mean time between failures (MTBF)

116,052 hrs

Latency (end to end)

G.709 – GFEC

G.709 – HG-FEC 7%

G.709 – UFEC 20%

4 microseconds

20 microseconds

39 microseconds

Storage temperature

–40ºC to 70ºC (–40ºF to 158ºF)

Operating temperature

Normal

Short-term1

0ºC to 40°C (32°F to 104°F)

–5ºC to 55ºC (23ºF to 131ºF)

Relative humidity

Normal

Short-term1

5% to 85%, noncondensing

5% to 90% but not to exceed 0.024 kg water/kg of dry air

1 Short-term refers to a period of not more than 96 consecutive hours and a total of not more than 15 days in 1 year (a total of 360 hours in any given year, but no more than 15 occurrences during that 1-year period). The values shown are valid for M6 or M2 chassis.

Table 10. Ordering Information

Part Number

Description

15454-M-100G-LC-C=

100G OTU-4 ITU-T CP-DQPSK Full C Band Tuneable LC

15454-M-100G-ME-C=

100G OTU-4 CP-DQPSK Full C Band Tuneable LC Metro Edge

15454-M-100GC-LIC=

100G OTU-4 ITU-T CP-DQPSK Full C Band Tuneable LC – Licensed

15454-M-LIC-100G=

100G TXP/Reg License for 100G Trunk Line card

ONS-CXP-100G-SR10=

CXP – 100GBASE-SR – Commercial Temp

For More Information

For more information about the Cisco ONS 15454 MSTP, visit http://www.cisco.com/en/US/products/hw/optical/ps2006/ps5320/index.html.