Alcatel-Lucent 100 GbE Manuel d'utilisation

Alcatel-Lucent Innovation Days – December 2008

Context

Modern telecommunication networks need to be built
with enormous traffic growth in mind. For example,
today some internet exchange nodes have annual
growth rates of more than 200% due to dramatic
increases in users coupled with the needs of enriched
data and broadband video services.

Accommodation of the global explosion in traffic
(Figure 1) can only be assured by implementation of
the most advanced high capacity optical metro/core
transport network technologies. Soon networks based
on next generation 40/100 Gigabit Ethernet (GbE)
transport technologies will predominate. They will be
based on standards currently under preparation by
several standards organisations (e.g. IEEE, ITU-T).

Figure 1: Technology roadmap of optical transport networks.
40/100GbE will be dominant technology within the next decade.

Alcatel-Lucent’s concepts and real-time trials
demonstrate 100Gbe’s graceful introduction and
evolution to meet operators’ future needs.

Challenges

To get from here to there, several challenges
associated with development and operation of ultra-
high speed components and systems for serial 100
Gbit/s optical transmission must be overcome:

•

Stronger transmission signal impairments
associated with the upgrade of data rates,
due to chromatic dispersion (CD) and

polarization mode dispersion (PMD), must be
compensated or mitigated efficiently.

•

Spectral efficiency must increase, enabling
100Gb/s transmissions over exsiting 10/40G
DWDM systems (50/100GHz channel spacing).

•

Complex integrated circuits for digital signal
processing (DSP) and new very high-speed
components have to be developed using
state-of-the-art electronics and photonics.

Innovation

Alcatel-Lucent has developed 100 Gbe concepts,
shown prototypes and done field trials demonstrating
its expertise in addressing future requirements.

Dispersion

tolerant

serial

Nx100Gb/s

DWDM

transmission with high spectral efficiency

Figure 2 is a schematic of how high capacity
Nx100Gb/s optical transmission is feasible over long-
haul fiber links without dispersion compensation units
(DCU) using conventional 10Gb/s DWDM platforms
with narrow channel spacing (50GHz) corresponding
to a spectral efficiency of 2bit/s/Hz.

Figure 2: Nx100Gb/s Coherent PDM-QPSK DWDM transmission over
1200km laboratory fibre link.

Verizon 100G field trial with live traffic

Alcatel-Lucent, in a real-time field trial with Verizon
(Figure 3),

proved a 100Gb/s channel carrying a HDTV

video signal can transmit parallel to existing live
traffic 10Gb/s DWDM channels.

10Mb/s

10Gb/s

1Gb/s

100Mb/s

100Gb/s

THE

ETHERNET

EVOLUTION

ROADMAP

(LAN/WAN)

100GbE

10GbE

1GbE

100MbE

10MbE

40GbE

DAT

A

RAT

2000

2010

1990

YEAR

40/100GbE will be

dominant transport

technology in next
generation optical

metro/core networks

A.O.

SSMF

Tunable

filter

x3

A.O.

100km

SSMF

SSMF

SSMF

100G

Coherent

RX

WSS

Optium

1

3

2x28Gbit/s

M

w

a

v

e

le

n

g

th

s

QPSK

QPSK

2x28Gbit/s

Nx112Gbit/s

Switch

Fiber (dispersion, PMD)

A.O.

SSMF

Tunable

filter

x3

A.O.

100km

SSMF

SSMF

SSMF

100G

Coherent

RX

WSS

Optium

1

3

2x28Gbit/s

M

w

a

v

e

le

n

g

th

s

QPSK

QPSK

2x28Gbit/s

Nx112Gbit/s

Switch

Fiber (dispersion, PMD)

Polarization Division Multiplexed
Quadrature Phase Shift Keying
Transmitter

100 Gigabit Ethernet (100 GbE)

Advanced Serial 100Gb/s Transmission Technology for Next Generation
Optical Transport Networks