1 TTM 1: Access and core networks, advanced Based on paper: “Optical networks: From point-to-point transmission to full networking capabilities” Presented.

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TTM 1: Access and core networks, advanced

Based on paper:“Optical networks: From point-to-point transmission to full networking capabilities”

Presented by: Zekarias Teshome

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Contents Introduction Transmission aspects Opaque versus transparent Re-configurable optical networks

OADM Optical cross connects

MPLS/GMPLS Network architectures

The overlay model The peer model

Reference network Future IP solutions Summery

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Introduction

It was early realized that optical fiber has a tremendous bandwidth and

Also the low electromagnetic interference of the medium makes it ideal for secure communication

The main issue would be to find technically feasible and economical ways to capitalize on this potential.

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Transmission aspectsTransmission systems use WDM( method used to increase the capacity of a single strand of fiber)

From the transmitter side: many different colored lights combined

by the WDM multiplexing device and put in to the single strand of fiber. On the receiver side: each color is separated into its own color by

WDM Demultiplexing device

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Cont. Due to the characteristic attenuation curve of fiber, there

are two regions typically used for communications.

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Cont.

Dense Wavelength Division Multiplexing(DWDM) and

Coarse Wavelength Division Multiplexing (CWDM) The difference is the channel spacing. And the range of the optical spectrum they typically cover.

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DWDM Vs. CWDMDWDM all frequencies spaced at multiples of 50 GHz with wavelengths in the 1530 – 1565 nm range, The tight spacing between these channels requires temperature

control of the lasers and increases cost.

CWDM Here the channel spacing is increased to 200 GHz,

– both the fabrication and the temperature control requirements of these lasers are lower, and

– the overall cost dramatically reduced.

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Opaque versus transparent

A core optical network architecture can be opaque or transparent. An opaque architecture implies that the optical signal carrying traffic

undergoes an optical to electronic to optical (OEO) conversion at different places in the network.

A transparent architecture implies that the optical signal carrying traffic stays in the optical domain.

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Re-configurable optical networks The key NEs in order to realize re-configurable

optical networks are Reconfigurable optical add-drop multiplexer (R-OADM) and optical cross connects (OXC).

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OADM

Typically close to 70 % of the traffic that arrives at a node is through-passing traffic, i.e. traffic with destination another node.

Instead of processing and switching/routing all traffic an optical add-drop multiplexer (OADM) can allow some of the through-passing traffic to be forwarded optically,

directly through the node. The wavelengths that have been dropped may be added back

in the link.

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Cont.

• There are two main types of OADM that can be used in WDM optical networks;

Fixed OADMs: that are used to drop or add data signals on dedicated WDM channels, and

Reconfigurable OADMs: re-configurability refers to the ability to select the desired wavelengths to be dropped and added on the fly, as opposed to having to plan ahead and deploy appropriate equipment.

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Cont.

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Optical cross connects Optical networks consist of a multiple of sub-networks. These will need to be interconnected by optical links in

an arbitrary topology, i.e. in a mesh topology In order to be able to realize mesh networks, optical

cross connects are required.

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Cont.

An OXC performs in essence the same function as an R-OADM but for a larger number of line ports and directions.

Schematic of an optical cross-connect; optoelectronic , all-optical

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Cont.

An OXC provides several key functions in a large network: Service provisioning– An OXC can be used to provide end-to-end light paths in a large

network in an automated manner. Protection and restoration– The OXC combined with monitoring equipment can provide swift

restoration of huge amounts of traffic by redirecting wavelengths from the failed paths to alternative paths.

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Cont.

Wavelength conversion‒ Light paths need not use one single wavelength through the whole

network since this complicates wavelength management in the network.

Multiplexing and grooming - in its purest form the OXC is all-optical. However, the OXC

comprises also an add-drop part where multiplexing and

grooming of ingress and egress signals can take place.

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Cont.

OXCs can be an opaque and employ an electrical core.

A large number of alternative all-optical solutions have been explored,

One of the most prominent OXC solutions is based on: a two-dimensional or three-dimensional array of miniature mirrors (MEMS based)

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Cont.

a) A picture of a miniature MEMS mirror, b) schematic of an OXC using miniature MEMS mirrors

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Cont. A new OXC architecture that uses tunable lasers and Array Waveguide Gratings (AWG) as shown in Figure below.

A schematic of an OXC based on an Arrayed Waveguide Grating and tunable wavelength converters

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Cont.

The port a signal will exit the OXC from, is explicitly determined by its wavelength and the AWG input it arrives at. Hence the OXC is re-configured by tuning the wavelength of the signal in

a wavelength converter using tunable lasers

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MPLS/GMPLS MPLS involves setting up a specific path for a given

sequence of packets by labeling every packet in order to figure out which outward path a packet

should be switched toward its destination. multiprotocol because it works with the Internet Protocol (IP),

Asynchronous Transport Mode (ATM), and frame relay network protocols. GMPLS (Generalized Multiprotocol Label Switching),

is a technology that provides enhancements to Multiprotocol Label Switching (MPLS) to support network switching for time, wavelength, and space switching as well as for packet switching.

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Network architectures Traditional transport networks can be modeled

as the interaction of two operating planes: a transport plane and a management plane.

In this model, the transport plane carries the user data and comprises network equipment, such as line interface cards, switch fabrics, backplanes and fiber plant.

Network OAM&P (operations, administration, maintenance and provisioning) is fully handled by the management plane.

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Cont. Now, we are beginning to see the deployment

of optical control planes sit between the management and transport planes. The

control plane moves some of the network intelligence down to the NEs.

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Cont. In the optical transport field, the control plane has

been called by the IETF as, Generalized Multi-Protocol Label Switching, or GMPLS.

The IP and optical control planes can be loosely or tightly coupled in terms of, firstly, the details of the optical network topology, resources, and

routing information that is revealed to the IP layer, and secondly, the degree of control IP routers have on optical network

elements and thus the degree to which they can determine the exact paths through this optical network.

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Cont.

Based on this: The overlay modelThe peer model

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The overlay model In this architecture option the optical network has full

control over its network resourceso by means of a fully independent optical control plane.

A schematic of the Automatically Switched Optical Network, according to the overlay model

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The peer model

In this architecture the control planes of the optical network and IP are fully integrated. the optical part unintelligent and rely on IP intelligence to run the network.

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Reference network The network can be seen as comprising three parts:

The core and long-haul part, The metropolitan area network, and The access part.

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Cont.The core part

is a national network connecting major cities.

The metro network extends over a large city or a province, comprises less

aggregated traffic than the core as it is closer to customers and end users, and involves lower capacities than the core.

Access part is the part that provides a connection between an end user

(e.g. a home) or a business to the metro and core networks.

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Future IP solutions IP routers do not appear to be able to scale gracefully

to meet the needs of multi-Terabit networks. Alternatively, better scalable large switching matrices

may be created using both electrical and optical switches.

A schematic of a hybrid optical-electrical router, using both optical switching matrices and electrical switches

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Cont.

A next step is optical packet or burst switching (OPS/ OBS) – or so-called optical routers.

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Summery Optical networks may well be the key to high capacity

intelligent networks that utilize their resources in an efficient way and can provide a range of

differentiated services.

Optical switching provides an economical way to handle large amounts of traffic and to build reliable networks.

Optical functionality can be introduced at a separate layer and complement higher network layers, and/or it can be directly integrated and controlled by IP routers.

Optical technology can also be employed to realize larger/higher throughput and more robust IP routers.

1 TTM 1: Access and core networks, advanced Based on paper: “Optical networks: From point-to-point transmission to full networking capabilities” Presented.

Documents

optical fiber

optical signal

optical domain

optical spectrum

optical oeo conversion

overlay model

core networks

transparent architecture