Optical mesh network

Optical mesh network
Transport network based on SONET/SDH ring architecture

Optical mesh networks are a type of telecommunications network.

Transport networks, the underlying optical fiber-based layer of telecommunications networks, have evolved from DCS (Digital Cross-connect Systems)-based mesh architectures in the 1980s, to SONET/SDH (Synchronous Optical Networking/Synchronous Digital Hierarchy) ring architectures in the 1990s. Technological advancements in optical transport equipment in the first decade of the 21st century, along with continuous deployment of DWDM systems, have led telecommunications service providers to replace their SONET ring architectures by mesh-based architectures. The new optical mesh networks support the same fast recovery previously available in ring networks while achieving better capacity efficiency and resulting in lower capital cost.

Optical mesh networks today not only provide trunking capacity to higher-layer networks, such as inter-router or inter-switch connectivity in an IP, MPLS, or Ethernet-centric infrastructure, but also support efficient routing and fast failure recovery of high-bandwidth services. This was made possible by the emergence of optical network elements that have the intelligence required to automatically control certain network functions, such as fault recovery.

Optical mesh networks enable a variety of dynamic services such as bandwidth-on-demand, Just-In-Time bandwidth, bandwidth scheduling, bandwidth brokering, and optical virtual private networks that open up new opportunities for service providers and their customers alike.

Example of mesh network: NSFNET 14nodes

Contents

History of transport networks

Transport networks, the underlying optical fiber-based layer of telecommunications networks, have evolved from Digital cross connect system (DCS)-based mesh architectures in the 1980s, to SONET/SDH (Synchronous Optical Networking/Synchronous Digital Hierarchy) ring architectures in the 1990s. In DCS-based mesh architectures, telecommunications carriers deployed restoration systems for DS3 circuits such as at&t FASTAR (FAST Automatic Restoration)[1] and MCI Real Time Restoration (RTR)[2], restoring circuits in minutes after a network failure. In SONET/SDH rings, carriers implemented ring protection such as SONET Universal Path Switched Ring (UPSR)[3] (also called Sub-Network Connection Protection (SCNP) in SDH networks) or SONET Bidirectional Line Switched Ring (BLSR)[4] (also called Multiplex Section - Shared Protection Ring (MS-SPRing) in SDH networks), protecting against and recovering from a network failure in 50 msecs or less[5], a significant improvement over the recovery time supported in DCS-based mesh restoration, and a key driver for the deployment of SONET/SDH ring-based protection.

There have been attempts at improving and/or evolving traditional ring architectures to overcome some of its limitations, with trans-oceanic ring architecture (ITU-T Rec. G.841), “P-cycles” protection[6], next-generation SONET/SDH equipment that can handle multiple rings, or have the ability to not close the working or protection ring side, or to share protection capacity among rings (e.g., with Virtual Line Switched Ring (VLSR)[7].

Technological advancements in optical transport switches [8] in the first decade of the 21st century, along with continuous deployment of dense wavelength-division multiplexing (DWDM) systems, have led telecommunications service providers to replace their SONET ring architectures by mesh-based architectures for new traffic. The new optical mesh networks support the same fast recovery previously available in ring networks while achieving better capacity efficiency and resulting in lower capital cost. Such fast recovery (in the tens to hundreds of msecs) in case of failures (e.g., network link or node failure) is achieved through the intelligence embedded in these new optical transport equipment, which allows recovery to be automatic and handled within the network itself as part of the network control plane, without relying on an external network management system.

Optical mesh networks

Switching, multiplexing, and grooming of traffic in an OEO device

Optical mesh networks refer to transport networks that are built directly off the mesh-like fiber infrastructure deployed in metropolitan, regional, national, or international (e.g., trans-oceanic) areas by deploying optical transport equipment that are capable of switching traffic (at the wavelength or sub-wavelength level) from an incoming fiber to an outgoing fiber. In addition to switching wavelengths, the equipment is typically also able to multiplex lower speed traffic into wavelengths for transport, and to groom traffic (as long as the equipment is so-called opaque - see subsection on transparency). Finally, these equipment also provide for the recovery of traffic in case of a network failure. As most of the transport networks evolve toward mesh topologies utilizing intelligent network elements (optical cross-connects or optical switches [8]) for provisioning and recovery of services, new approaches have been developed for the design, deployment, operations and management of mesh optical networks.

Optical mesh networks today not only provide trunking capacity to higher-layer networks, such as inter-router or inter-switch connectivity in an IP, MPLS, or Ethernet-centric packet infrastructure, but also support efficient routing and fast failure recovery of high-bandwidth point-to-point Ethernet and SONET/SDH services.

Recovery in optical mesh networks

Shared backup path protection - before failure
Shared backup path protection - after failure and recovery

Optical mesh networks support the establishment of circuit-mode connection-oriented services. Multiple recovery mechanisms that provide different levels of protection [9] or restoration [10] against different failure modes are available in mesh networks. Channel, link, segment and path protection are the most common protection schemes. P-cycles[6] is another type of protection that leverages and extends ring-based protection. Restoration is another recovery method that can work on its own or complement faster protection schemes in case of multiple failures.

In path-protected mesh networks, some connections can be unprotected; others can be protected against single or multiple failures in various ways. A connection can be protected against a single failure by defining a backup path, diverse from the primary path taken by the connection over the mesh network. The backup path and associated resources can be dedicated to the connection (aka Dedicated Backup Path Protection), or shared among multiple connections (aka Shared Backup Path Protection), typically ones whose primary paths are not likely to fail at the same time, thereby avoiding contention for the shared resources in case of a single link or node failure. A number of other protection schemes such as the use of pre-emptible paths, or only partially diverse backup paths, can be implemented. Finally, multiple diverse routes can be designed so that a connection has multiple recovery routes and can recover even after multiple failures (examples of mesh networks across the Atlantic and Pacific oceans).

Transparency

Opaque switching of traffic between fiber links
Transparent switching of traffic between fiber links

Traditional transport networks are made of optical fiber-based links between telecommunications offices, where multiple wavelengths are multiplexed to increase the capacity of the fiber. The wavelengths are terminated on electronic devices called transponders, undergoing an optical-to-electrical conversion for signal Reamplification, Reshaping, and Retiming (3R). Inside a telecommunications office, the signals are then handled to and switched by a transport switch (aka optical cross-connect or optical switch) and either are dropped at that office, or directed to an outgoing fiber link where they are again carried as wavelengths multiplexed into that fiber link towards the next telecommunications office. The act of going through Optical-Electrical-Optical (O-E-O) conversion through a telecommunications office causes the network to be considered opaque. When the incoming wavelengths do not undergo an optical-to-electrical conversion and are switched through a telecommunications office in the optical domain using all-optical switches (also called photonic cross-connect, optical add-drop multiplexer, or Reconfigurable Optical Add-Drop Multiplexer (ROADM) systems), the network is considered to be transparent. Hybrid schemes can provide limited O-E-O conversions at key locations across the network.

Transparent optical mesh networks have been deployed in metropolitan and regional networks. In 2010, operational long distance networks still tend to remain opaque.

Routing in optical mesh networks

Routing is a key control and operational aspect of optical mesh networks. In transparent or all-optical networks, routing of connections is tightly linked to the wavelength selection and assignment process (so-called routing and wavelength assignment, or "RWA"). This is due to the fact that the connection remains on the same wavelength from end-to-end throughout the network (sometimes referred to as wavelength continuity constraint, in the absence of devices that can translate between wavelengths in the optical domain). In an opaque network, the routing problem is one of finding a primary path for a connection and if protection is needed, a backup path diverse from the primary path. Wavelengths are used on each link independently of each other's. Several algorithms can be used to determine a primary path and a diverse backup path (with or without sharing of resource along the backup path) for a connection or service, such as shortest path, including Dijkstra's algorithm, k-shortest path[11], edge and node-diverse or disjoint routing, including Suurballe's algorithm[12], and numerous heuristics.

Applications

The deployment of optical mesh networks is enabling new services and applications for service providers to offer their customers, such as

  • Dynamic services such as Bandwidth-on-Demand (BoD)[13], Just-In-Time (JIT) bandwidth, bandwidth scheduling, and bandwidth brokering
  • Optical virtual private networks[14]

It also supports new network paradigms such as

  • IP-over-optical network architectures[15]

Related network architectures

Mesh networking in general and wireless mesh networking in particular.

See also

Telecommunications and networking

Telecommunications equipment

  • Cross-connect
  • Wavelength division multiplexing

Packet networking

Connection-oriented networking

Availability

References

  1. ^ FAST Automatic Restoration - FASTAR.
  2. ^ Real Time Restoration (RTR).
  3. ^ Universal Path Switched Ring (UPSR).
  4. ^ Bidirectional Line Switched Ring (BLSR).
  5. ^ Is 50 ms necessary?
  6. ^ a b W. D. Grover, (Invited Paper) "p-Cycles, Ring-Mesh Hybrids and "Ring-Mining:” Options for New and Evolving Optical Networks," Proc. Optical Fiber Communications Conference (OFC 2003), Atlanta, March 24–27, 2003, pp.201-203. (related presentation).
  7. ^ Virtual Line Switched Ring (VLSR).
  8. ^ a b Also referred to as optical cross-connects or optical switches. The term optical does not imply that the equipment handles signals completely in the optical domain, and most of the times, it does not and instead it grooms, multiplexes, and switches signals in the electrical domain, although some equipment (referred to as photonic cross-connect) do switching (only) fully in the optical domain without any O-E-O conversion.
  9. ^ Protection refers to a pre-planned system where a recovery path is pre-computed for each potential failure (before the failure occurs) and the path uses pre-assigned resources for failure recovery (dedicated for specific failure scenarios or shared among different failure scenarios)
  10. ^ With restoration, the recovery path is computed in real time (after the failure occurs) and spare capacity available in the network is used to reroute traffic around the failure.
  11. ^ K-th Shortest Path Problem.
  12. ^ J. W. Suurballe, R. E. Tarjan, "A quick method for finding shortest pairs of disjoint paths".
  13. ^ Verizon's Bandwidth on Demand (BoD)
  14. ^ PHOTONIC NETWORK COMMUNICATIONS, special issue on "Optical Virtual Private Networks (oVPNs)"
  15. ^ RFC 3717 - IP over Optical Networks: A Framework

Further reading

  • "Site on Network Protection - network protection techniques, network failure recovery, network failure events" [1]
  • “Mesh-based Survivable Transport Networks: Options and Strategies for Optical, MPLS, SONET and ATM Networking”, by Wayne Grover [2]
  • "Optical Network Control: Architecture, Protocols, and Standard", by Greg Bernstein, Bala Rajagopalan, and Debanjan Saha [3]
  • “Path Routing in Mesh Optical Networks”, by Eric Bouillet, Georgios Ellinas, Jean-Francois Labourdette, and Ramu Ramamurthy [4], [5]
  • "P-cycles: an overview", R. Asthana, Y.N. Singh, W.D. Grover, IEEE Communications Surveys and Tutorials, February 2010 [6]
  • "Survivable networks: algorithms for diverse routing", by Ramesh Bhandari [7]

External links

  • Self-Healing Mesh Optical Nets Emerge [8]
  • AT&T Optical Bandwidth on Demand Gains Velocity with More Speeds for Customer Provisioning [9]
  • AT&T offering fully meshed optical service [10]
  • Verizon Business Enhances Trans-Atlantic Network [11]
  • Verizon Business Enhances Performance and Reliability of Pacific Undersea Cable Systems on Global Network [12]
  • The Internet2 Dynamic Circuit Network (DCN) [13]
  • Intelligent optical mesh empowers digital media network [14]
  • VSNL and Tata Teleservices Build First Nationwide Intelligent Optical Mesh Network in India Using Ciena's CoreDirector [15], [16]
  • 360networks Deploys The World's Most Extensive Optical Mesh Network [17]
  • Verizon Business Circles Globe With Optical Mesh Network; Begins Extension to Middle East [18]
  • Verizon Business Global Mesh Network Investment Pays Big Dividends for Enterprise Customers During Multiple Submarine Cable System Disruptions in Asia-Pacific Region [19]
  • Verizon builds 18-city optical mesh [20]

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