Winter 2011 Joint Techs - Internet2 · Winter 2011 Joint Techs ADVA Optical Networking ... FSP NM End to End surveillance of native and alien wavelengths by monitoring FSP 3000 and

Winter 2011 Joint Techs ADVA Optical Networking – Industry Update

Brian Savory Director, Business Development January 2011

© 2011 ADVA Optical Networking. All rights reserved. Confidential. 2 2

Presentation Content

! Agile Optical Networking

! Georgia Tech 100G Center

! 100G Update

! ADVA NOC Services

! ADVA – Juniper Update

Agile Optical Networking


Au

tomated

end

-to-end

service man

agem

ent

Agile optical connectivity The next-generation transport network

Packets

Time slots

Wavelengths

New applications

  Collapsed networks

  Integrated technologies

  Dynamic and easy to operate

  Purpose-built platforms

  One technology

  Static

Traditional networks

Packet switching and optical transport

Automated packet and optical transport A scalable NGN foundation with flexibility and simplified operation

Time slots


Ag

ile , scalable core

ADVA’s Product Strategy Flexible optical connectivity

Distortion-tolerant Extended reach

AAA* optical switching

DC/PoP concentration

Simplified, scalable and automated bandwidth delivery

  High capacity and reach

  Simple design & operation

  Ultra-fast provisioning

  Limited scalability

  Specialized network design

  Slow, static provisioning

Static wavelength layer Dynamic high-capacity demand

Fixed WDM layer WDM

Support of optical and Ethernet services POT

X

Optical network

* Triple A: Any wavelength, Anytime, Anywhere


Traditional networks

PMO*

Operational

integration

Integrated

NMS and

operations

Equipment delayering

Combined NE hardware and

control of packet and optical

Flexible networking

Integrated packet optical switching

Equipment optimization

 Achievable as upgrades of existing networks

 Reduced interface count on new services

 Higher network efficiency

Operational integration  Achievable as upgrades

of existing network

 Key steps  GMPLS interop

 Collapsed management

Fully integrated  Achievable as upgrade and/or overlay of existing networks

 Maximizes interface and operational efficiencies

*Present Mode of Operation

Paths to flexible networking


GMPLS-based control plane

1. Automated self-inventory 2. Automated connection management

3. Efficient operations 4. Self-healing network

Network/Service Manager

Network/Service Manager

Planned maintenance works

Migrated traffic

Network failure

Auto-restored traffic

Operational automation decreases costs by mechanizing manual and repetitive tasks associated with service management

Georgia Tech 100G Center


Georgia Tech 100G Center G

eorg

ia T

ech

100G

Cen

ter

Geo

rgia

Tec

h 10

0G C

ente

r

100G OpticalNetworking Consortium



School of Electrical andComputer Engineering

Steven M. Searcy1,2, Andrew J. Stark1, Thomas F. Detwiler1, Yu-Ting Hsueh1, Sorin Tibuleac2, Gee-Kung Chang1, and Stephen E. Ralph1

Developing accurate simulations for high-speed fiber links

1School of Electrical and Computer Engineering, Georgia Institute of Technology, Atlanta, GA 30332, USA2ADVA Optical Networking, 5755 Peachtree Industrial Blvd, Norcross, GA 30092, USA

26 January 2011

Work supported by:


Georgia Tech 100G Center G

eorg

ia T

ech

100G

Cen

ter

Geo

rgia

Tec

h 10

0G C

ente

r

Summary

n We have developed a robust simulation model that closely matches experimental results

n We achieve absolute matching between simulation and laboratory to within ±0.25 dB for back-to-back configuration

n We achieve absolute matching within ±1 dB for nearly all multi-span configurations, including different launch powers, fiber types, dispersion maps, and number of WDM channels

n Further work remains towards improving robustness of the model in the highly nonlinear regime



! “DQPSK for Metro Networks” by Andy Stark, Yu-Ting Hsueh Steven Searcy, Cheng Liu, Alan McCurdy, Robert Lingle Jr., Mark Filer, Sorin Tibuleac, GK Chang, and Stephen E. Ralph

! “Dispersion Map Optimization of Single and Dual-Pol QPSK” in the Presence of Aggressor Channels” by Andrew Stark, Yu-Ting Hsueh, Tom Detwiler, Mark Filer, Sorin Tibuleac, Alan McCurdy, Robert Lingle, Jr., Gee-Kung Chang and Stephen E. Ralph

! “Scaling 100G QPSK links for Reliable Network Development” by Andrew Stark, Yu-Ting Hsueh, Steven Searcy, Thomas Detwiler, Sorin Tibuleac2 Mark Filer, GK Chang, and Stephen E. Ralph

! “Scaling 112 Gb/s PDM-QPSK Hybrid Optical Networks” by Andrew Stark, Yu-Ting Hsueh, Steven Searcy, Thomas Detwiler, Sorin Tibuleac, Mark Filer, GK Chang, and Stephen E. Ralph

ADVA 100G Update


112/120G Coherent PolMux-QPSK

  Highest performance 100G transport, but highest complexity (cost)

  Supports 50 GHz DWDM with 2 (bit/s)/Hz spectral efficiency, ROADM networking, and >2000 km reach

PBC PBS

Driver Filter

Driver Filter

PC

PC

Dig

ital F

ilter

90° Hybr.

QPSK Coder

QPSK Coder

90° Hybr.

0°

90°

0°

90°

CW LD

90°

90°

PC PBS LO

Clie

nt I/

F (C

FP)

Clie

nt I/

F (C

FP)

FEC

, Fra

min

g, M

onito

ring

FEC

, Fra

min

g, M

onito

ring

AD

C

AD

C

AD

C

AD

C

Re

Im PM-QPSK


Low-cost Enterprise/Regional Transport

TX TX TX TX

Rx Rx Rx Rx

Clie

nt I/

F

ITU

-T D

WD

M

ITU

-T D

WD

M

Clie

nt I/

F

FEC

FEC

  Line interface solution

  Multi-carrier modulation – 4 wavelengths @ 28Gb/s   Optical duobinary modulation: ensures low signal bandwidth and

sufficient dispersion tolerance at 28Gb/s   ‘Gear box’ chip (10x10.7G -> 4x28G) inside the line module   Enterprise /Regional distances (up to 200km/GFEC, 500km/EFEC)   Lowest cost   Low power consumption, low footprint, low latency


Low-cost Enterprise/Metro Transport

100G Enterprise Muxponder 100G Regional Transponder

4x 28G DWDM network 4x 28G DWDM network

10x (4G…10G) clients 1x 100G client

10GE, 4/8G FC 100GE, OTU4

200km (GFEC) 500km (EFEC)

Enterprise connectivity Metro Core /Carrier networks

  Two card solutions based on the 4x 28G low cost line interface


Comparison 10G serial 40G serial 100G serial (coherent)

4x25G parallel

Spectral efficiency [b/s/Hz]

0.2 (50GHz) 0.8 (50GHz) 2.0 (50GHz) 0.5 (50GHz)

Reach 3000km 1000km 2000km 200-500km

Cos

t p

er b

/s

Long Haul & Regional Networks 100G DWDM interfaces

Nx10G transport modules Only in first year

  WCC-PCTN-100G, 2TCC-PCTN-100G 10TCC-PCTN-100G

  WCE-PCN-100G 2TCE-PCN-100G 10TCE-PCN-100G


Highspeed Transport Roadmap 100G cards in FSP3000

2010 2011 2012

100G: 2x 40G LH Muxp.

100G: LH Transp.

100G: Enterprise Muxp.

100G: Regional/ Enterprise Transp.

100G: 10x 10G LH Muxp.

100G Carrier Core

100G Enterprise

 High performance LH solutions (Transponder and Muxponders) for Core market

 Low cost Enterprise Muxponder and Enterprise/Regional Transponder

Feature in planning Feature confirmed

100G Regional

ADVA Technical Services Network Operations Center


ATLANTA NETWORK OPERATIONS (NOC) Primary Facility - Norcross, GA

“Hardened” Construction Features

Protected Primary Power Feed

Backup Power with UPS and Generator

Dual HVAC System and FM200 Chemical Fire Suppressant System

Access key card controlled secure entry

NOC Services: Facilities Basics

Norcross, GA


ATLANTA NETWORK OPERATIONS CENTER Diverse fiber feeds into facility

Dedicated and geographically diverse network links providing bi-directional monitoring

“Time and Distance” back up facilities in Atlanta and Vancouver

Switchable, Dedicated Global Toll-Free Number for customer convenience

NOC Services: Facilities Features

Backup - Vancouver Facility


ATLANTA NETWORK OPERATIONS (NOC) Dedicated, ADVA customer, partitioned NOC and Network Services

Comprehensive, single source, network monitoring and services management (Equipment, Fiber Cable and Facilities)

Minimized response and repair times through single ownership of NOC, Dispatch, and Field Services

7X24X365 staffing for all service response

Customer option for “real time” access to trouble ticket and repair progress

“Fast Track” Service for circuit additions and changes

NOC Operational Differentiators

Call & Dispatch Center


ATLANTA NETWORK OPERATIONS (NOC) TL-9000 Standards

Significant ADVA experience on team

Access to ADVA lab networks for trouble simulation

Located within 1 mile of ADVA’s R&D team

Integrated Network Monitoring and Field Services under single management and control*

Many SLA programs available with and without FLM and Depot*

Continual monitoring and assessment of critical performance indicators

NOC Operational Attributes

*All custom services are quoted at the then current standard ADVA rates. For control purposes, those values would be documented in the contract or SOW.

ADVA Optical Networking – Juniper Networks Update


ADVA Optical Networking – Juniper Networks

! Key Elements ! Juniper T/M-Series Routers ! Juniper MX Series Ethernet aggregation Routers ! ADVA FSP 3000 DWDM solution

! Interoperability ! Flexible optical interface interworking:

! T/M: gray and alien wavelength (G.709) interworking over 1200km

! MX: gray and alien wavelength (10G WAN PHY) interworking

! GMPLS interworking ! Transparent router based GMPLS setup of wavelengths

for gray and alien, and multiple protection models (IP level, Optical Level)

! FSP NM End to End surveillance of native and alien wavelengths by monitoring FSP 3000 and Juniper router interfaces.


GMPLS Interworking

= GbE 1310nm to ADVA transponder

= STM64 DWDM to ADVA eROADM

= 10/100 eth (fe0, eth0)

= GRE tunnel

= OSC

WDC LAN ADVA WAN

WDC-M7i

ATL-M120

WDC-F71 WDC-F72

= RSVP-TE, OSPF-TE

! Control Plane ! Optical tunnels setup via CP; label is Lambda ! Ethernet tunnels also setup via CP; label is

VLAN tag ! VLAN tag may change along service path, per

policy

Brian Savory ADVA Optical Networking [email protected] (404) 512-9907

Thank you

IMPORTANT NOTICE The content of this presentation is strictly confidential. ADVA Optical Networking is the exclusive owner or licensee of the content, material, and information in this presentation. Any reproduction, publication or reprint, in whole or in part, is strictly prohibited.

The information in this presentation may not be accurate, complete or up to date, and is provided without warranties or representations of any kind, either express or implied. ADVA Optical Networking shall not be responsible for and disclaims any liability for any loss or damages, including without limitation, direct, indirect, incidental, consequential and special damages, alleged to have been caused by or in connection with using and/or relying on the information contained in this presentation.

Copyright © for the entire content of this presentation: ADVA Optical Networking.

Documents

Winter 2011 Joint Techs - Internet2 · Winter 2011 Joint Techs ADVA Optical Networking ... FSP NM End to End surveillance of native and alien wavelengths by monitoring FSP 3000 and