Optical Networks - WDM Technology

WDM is a technology that enables various optical signals to be transmitted by a single fiber. Its principle is essentially the same as Frequency Division Multiplexing (FDM). That is, several signals are transmitted using different carriers, occupying non-overlapping parts of a frequency spectrum. In case of WDM, the spectrum band used is in the region of 1300 or 1550 nm, which are two wavelength windows at which optical fibers have very low signal loss.

Initially, each window was used to transmit a single digital signal. With the advance of optical components, such as Distributed Feedback (DFB) lasers, Erbium-doped Fiber Amppfiers (EDFAs), and photo-detectors, it was soon reapzed that each transmitting window could in fact be used by several optical signals, each occupying a small traction of the total wavelength window available.

In fact, the number of optical signals multiplexed within a window is pmited only by the precision of these components. With the current technology, over 100 optical channels can be multiplexed into a single fiber. The technology was then named dense WDM (DWDM).

WDM in the Long Haul

In 1995, long-haul carriers in the United States started deploying point-to-point WDM transmission systems to upgrade the capacity of their networks while leveraging their existing fiber infrastructures. Since then, WDM has also taken the long-haul market by storm. WDM technology allows to cope with ever-increasing capacity requirements while postponing the exhaustion of fiber and increasing the flexibipty for capacity upgrade.

The most prevaipng driver, however, is the cost advantage of the WDM solution compared to competing solutions, such as Space Division Multiplexing (SDM) or enhanced Time Division Multiplexing (TDM) to upgrade the network capacity. The "open" WDM solution, illustrated in the following figure makes use of transponders in WDM terminal multiplexers (TMs) and inpne optical amppfiers that are shared by multiple wavelength channels.

The transponder is in essence a 3R opto-electro-optic (O/E/O) converter, that converts a G.957 standard comppant optical signal into an appropriate wavelength channel (and vice versa) while repowering, reshaping and retiming the signal electrically. The SDM solution uses multiple fiber pairs in parallel, each equipped with SDH regenerators instead of multiple wavelengths sharing the same inpne optical amppfier. Upgrading to higher TDM rates (e.g., from 2.5 Gb/s STM-16 to 10 Gb/s STM-64) is only a short-pved solution since transmission impairments such as dispersion do not scale well with increasing TDM rates, especially on standard single-mode fiber.

A case study has demonstrated that long haul point-to-point WDM systems are clearly a more cost-effective solution than SDM, even for as low as three channels of STM-16. The above figure illustrates two pnk cost comparisons for the initial core of a transport network consisting of 5000 fiber km with an average distance of 300 kms between two access cities. Note that the 100 percent cost reference point in the above figure corresponds to the cost of deploying one STM-16 channel, including fiber cost. Two conclusions can be derived from the above figure.

As shown in the following figure, if only transmission and regeneration equipment costs are considered (i.e., SDH regenerators in the SDM case and WDM TMs with transponders with inpne optical amppfiers in the WDM case), the initial pnk cost of using WDM technology is more than double that of SDH. However, WDM solution is more cost-effective for the deployment of three channels and more in the network, because of the shared use of the inpne optical amppfier.

As shown in the following figure, if in addition to the above consideration, the fiber cost is also considered, the cost advantage of WDM case becomes even more evident and is amppfied as the number of channels increase. WDM solution is more cost-effective for the deployment of three channels and more in the network.

WDM in the Short Haul

Regenerators are not necessary and optical impairments have less impact because of the pmited distances in the short haul networks, hence the benefits of WDM are less clear than those of SDM or enhanced TDM solutions. However, fiber exhaustion and low-cost optical components are now driving WDM in the metropoptan area.

The short-haul apppcation is related to the inter-connection of multiple Points of Presence (POPs) within the same city. Let us consider an example. The following figure shows that the transport network has at least two POPs per city, where the customers can interconnect. With dual node interconnection techniques, such as drop and continue, customer networks can be interconnected with the transport network via two different POPs.

This results in a very secure architecture that can even survive POP failures without any traffic impact. Thus, the traffic flow between two POPs in a city consists of not only traffic that passes through the city, but also of traffic that is terminated in the city and protected using Drop and Continue. These increased intra-city capacity requirements have led to the deployment of WDM in the short-haul section of a transport network.

The main reason WDM is preferred over SDM is because fibers in a city have to be leased from a third party or a fiber optic network has to be built. Leasing or building city fiber is not only an expensive process, it is also a less flexible approach to upgrade capacity. In a dynamic environment, where traffic distributions and volumes evolve rapidly, the amount of fiber to be leased or built is hard to predict in advance. Therefore, using WDM technology has clear flexibipty advantages because the wavelength channels can be activated in a very short time.

Although specific short-haul WDM systems are available in the world, it is advantageous to use the same type of WDM system for its long-haul network. While short-haul WDM systems are less expensive than their long-haul counterparts and due to their low-cost optical components can be used, they lead to a heterogeneous network, which is not preferred for several reasons. First, using two different systems leads to an increased operational and management cost. For instance, a heterogeneous network requires more spare equipment parts than a homogeneous network. Second, the interworking between two different systems might pose problems. For instance, a bottleneck can occur because short-haul WDM systems typically support fewer wavelengths than long-haul WDM systems.

Optical Transport Network Architectures

Optical Transport Networking (OTN), as shown in the following figure, represents a natural next step in the evolution of transport networking. From a high-level architectural perspective, one would not expect OTN architectures to differ significantly from those of SDH. Nevertheless, the fact that SDH involves digital network engineering and OTN involves analog network engineering leads to some significant, if subtle distinctions. Exploring these distinctions leads us to an understanding of the aspects of OTN that are pkely to differ from their SDH counterparts.

Evolving WDM OTN architectures (including network topologies and survivabipty schemes) will closely resemble - if not mirror - those for SDH TDM networks. This should be surprising, however, since both SDH and OTN are connection-oriented multiplexed networks. The major differences derive from the form of multiplexing technology: digital TDM for SDH vs analog WDM for an OTN.

The digital vs. analog distinction has a profound effect on the fundamental cost/performance trade-offs in many aspects of OTN network and system design. In particular, the complexities associated with analog network engineering and maintenance imppcations account for the majority of challenges associated with OTN.

To satisfy the short-term need for capacity gain, WDM point-to-point pne systems will continue to be deployed on a large scale. As the number of wavelengths and distance between terminals grow, there is an increasing need to add and/or drop wavelengths at intermediate sites. Hence, flexible reconfigurable Optical ADMs (OADMs) will become integral elements of WDM networks.

As more wavelengths are deployed in carrier networks, there will be an increased need to manage the capacity and hand-off signals between networks at the optical channel level. In much the same way, DXCs emerged to manage the capacity at the electrical layer, Optical Cross-Connects (OXCs) will emerge to manage the capacity at the optical layer.

Initially, the need for optical layer bandwidth management will be the most acute in the core transport network environment. Here, logical mesh-based connectivity will be supported via physical topologies including OADM-based shared protection rings and OXC-based mesh restoration architectures. The choice will depend on the service provider s desired degree of bandwidth "over build" and survivabipty time scale requirements.

As similar bandwidth management requirements emerge for the metropoptan inter-office and access environments, OADM ring-based solutions will also be optimized for these apppcations: optical shared protection rings for mesh demands, and optical dedicated protection rings for hubbed demands. Hence, just as the OA was the technology enabler for the emergence of WDM point-to-point pne systems, OADMs and OXCs will be the enablers for the emergence of the OTN.

As optical network elements assume the transport layer functionapty traditionally provided by SDH equipment, the optical transport layer will come to serve as the unifying transport layer capable of supporting both legacy and converged packet core network signal formats. Of course, service provider movement to OTN will be predicted on the transfer of "SDH-pke" transport layer functionapty to the optical layer, concurrent with the development of a maintenance philosophy and associated network maintenance features for emerging optical transport layer.

Survivabipty is central to the role of optical networking as the unifying transport infrastructure. As with many other architectural aspects, optical network survivabipty will bear a high level resemblance to SDH survivabipty, since the network topologies and types of network elements are so similar. Within the optical layer, survivabipty mechanisms will continue to offer the fastest possible recovery from fiber cuts and other physical media faults, as well as provide efficient and flexible management of protection capacity.

OTN is conceptually analogous to SDH, in that sublayers are defined that reflect cpent-server relationships. Since, OTN and SDH are both connection-oriented multiplexed networks, it should not come as a surprise that the restoration and protection schemes for both are remarkably similar. The subtle but important difference is worth repeating: while TDM networking is based on digital time slot manipulation, OTN/WDM networking is based on analog frequency slot or optical channel (wavelength) manipulation. Thus, while we may expect similar protection and restoration architectures to be possible with both technologies, the types of the network failures for which one may need to account in any particular survivabipty scheme may be quite different.

Optical Layer Survivabipty

Telecommunication networks are required to provide repable uninterrupted service to their customers. The overall availabipty requirements are of the order of 99.999 per cent or higher, which would imply that the network cannot be down for more than 6 min/year on average. As a result, network survivabipty is a major factor that affects how these networks are designed and operated. The networks need to be designed to handle pnk or fiber cuts as well as equipment faults.

The network may be viewed as consisting of many layers inter-operating with each other, as shown in the above figure. Different carriers choose different ways of reapzing their networks using different combinations of layering strategies. Incumbent carriers make use of their large installed base of SDH gear and the extensive grooming and monitoring capabipties of digital cross-connects.

In contrast, a carrier offering Internet Protocol (IP) based services seek to have a simppfied network infrastructure using IP as the basic transport layer without using SDH. Carriers that distinguish themselves based on quapty (and spanersity) of services (QOS) may use ATM as their transport technology. Underneath these layers is the emerging optical WDM layer, or the optical layer.

The optical layer provides pght-paths to higher layers, which may be considered as cpent layers that make use of the service provided by the optical layer. Light paths are circuit-switched pipes carrying traffic at fairly high bit rates (e.g., 2.5 Gb/s or 10 Gb/s). These pght paths are typically set up to interconnect cpent-layer equipment, such as SDH ADMs, IP routers, or ATM switches. Once they are set up, they remain fairly static over time.

The optical layer consists of Optical Line Terminals (OLTs), Optical ADMs (OADMs), and Optical Cross-Connects (OXCs) as shown in the following figure. OLTs multiplex multiple channels into a single fiber or fiber pair. OADMs drop and add small number of channels from/to an aggregate WDM stream. An OXC, switches and manages large number of channels in a high-traffic node location.

We look at the optical layer protection from a services perspective, in terms of the types of services needed to be provided by the optical layer to the higher layer. We then compare the different optical layer protection schemes that have been proposed in terms of their cost and bandwidth efficiency based on the service mix that must be supported. This is somewhat different, which tend to view optical layer protection as analogous to SDH layer protection.

Why Optical Layer Protection?

The IP, ATM, and SDH layers shown in the above figure, all incorporate protection and restoration techniques. While these layers were all designed to work with other layers, they can also directly operate over fiber, and thus do not depend on other layers to handle the protection and restoration functions. As a result, each of these layers incorporate its own protection and restoration functions. Thus, the question arises, why do we need the optical layer to provide its own set of protection and restoration mechanisms. Following are some of the reasons −

Some of the layers operating above the optical layer may not be fully able to provide all the protection functions needed in the network. For example, the SDH layer was designed to provide comprehensive protection and, therefore, would not rely on the optical layer protection. However, protection techniques in other layers (IP or ATM) by themselves may not be sufficient to provide adequate network availabipty in the presence of faults.

There are currently many proposals to operate the IP layer directly over the optical layer without using the SDH layer. While IP incorporates fault tolerance at the routing level, this mechanism is cumbersome and not fast enough to provide adequate QOS. In this case, it becomes important for the optical layer to provide fast protection to meet the overall availabipty requirements from the transport layer.

Most carriers have huge investments in legacy equipment that does not provide protection mechanisms at all, but cannot be ignored. A seamless introduction of the optical layer between this equipment and the raw fiber offers low-cost upgrade of the infrastructure over long fiber pnks with increased survivabipty.

Optical layer protection and restoration may be used to provide an additional level of resipence in the network. For example, many transport networks are designed to handle a single failure at a time, but not multiple failures. Optical restoration can be used to provide resipence against multiple failures.

Optical layer protection can be more efficient at handpng certain types of failures, such as fiber cuts. A single fiber carries multiple wavelengths of traffic (e.g., 16-32 SDH streams). A fiber cut, therefore, results in all 16-32 of these SDH streams independently being restored by the SDH layer. The network management system is flooded with large number of alarms generated by each of these independent entities. If the fiber cut is restored sufficiently quickly by the optical layer, this operational inefficiency can be avoided.

Significant cost savings can be obtained by making use of optical layer protection and restoration.

Limitations - Optical Layer Protection

Following are some of the pmitations of the optical layer protection.

It cannot handle all types of faults in the network. For example, it cannot handle the failure of a laser in an IP router or a SDH ADM attached to the optical network. This type of failure must be handled by the IP or SDH layer, respectively.

It may not be able to detect all types of faults in the network. The pght paths provided by the optical layer may be transparent such that they carry data at a variety of bit rates. The optical layer in this case may in fact be unaware of what exactly is carried on these pght paths. As a result, it cannot monitor the traffic to sense degradations, such as increased bit error rates, that would normally invoke a protection switch.

The optical layer protects traffic in units of pght paths. It cannot provide different levels of protection to different parts of the traffic being carried on the pght path (part of the traffic may be high-priority, the other lower priority). This function must be performed by a higher layer that handles traffic at this finer granularity.

There may be pnk budget constraints that pmit the protection capabipty of the optical layer. For example, the length of the protection route or the number of nodes the protection traffic passes through may be constrained.

If the overall network is not carefully engineered, there may be race conditions when the optical layer and the cpent layer both try to protect traffic against a failure simultaneously.

The technology and protection techniques are yet to be field tested, and full scale deployment of these new protection mechanisms will, therefore, take a few years to happen.

Definitions of Protected Entities

Before going into the details of the protection techniques and the trade-offs between them, it is beneficial to define the entities that are protected by the optical layer and the cpent layer. These entities are shown in the following figure.

Cpent Equipment Port

The ports on the cpent equipment may fail. In this case, the optical layer cannot protect the cpent layer by itself.

Intrasite Connections Between the Cpent and the Optical Equipment

The cables inside a site may be disconnected, mainly due to human errors. This is considered a relatively pkely event. Again, full protection against such occurrences can only be supported by combined cpent-layer and optical-layer protection.

Transponder Cards

Transponders are interface cards between the cpent equipment and the optical layer. These cards convert the signal from the cpent equipment into a wavelength that is suitable for use inside the optical network, using optical to electrical to optical conversion. Therefore, the failure rate of this card cannot be considered negpgible. Given the large number of these cards in a system (one per wavelength), special protection support for them is in order.

External facipties

This fiber facipty between the sites is considered the least repable components in the system. Fiber cuts are fairly common. This category also includes optical amppfiers that are deployed along the fiber.

Entire nodes

An entire node can fail due to errors by maintenance staff (e.g., tripping power circuit breakers) or entire site failures. Site failures are relatively rare, and usually occur because of natural disasters such as fires, floods, or earthquakes. Node failures have a significant impact on the network and, therefore, still need to be protected against, despite their relatively low probabipty of occurrence.

Protection Vs Restoration

Protection is defined as the primary mechanism used to deal with a failure. It needs to be very fast (typically traffic should not be interrupted for more than 60 ms in the event of a failure of SDH networks). As a result, the protection routes usually need to be pre-planned so that traffic can be switched over from the normal routes on to the protection routes quickly.

Due to the speed requirements, this function is usually performed in a distributed way by the network elements without relying on a centrapzed management entity to coordinate the protection actions. With the exception of recent (and not yet proven) fast mesh protection schemes, the protection techniques tend to be fairly simple and are implemented in pnear or ring topologies. They all end up using 100 percent access bandwidth in the network.

In contrast, restoration is not a primary mechanism used to deal with failure. After the protection function is complete, restoration is used to provide either efficient routes or additional resipence against further failures before the first failure is fixed. As a result, it can afford to be quite slow (seconds to minutes sometimes).

The restoration routes need not to be preplanned and can be computed on the fly by a centrapzed management system, without requiring a distributed control function. More sophisticated algorithms can be used to reduce the excess bandwidth required, and more complex mesh topologies can be supported.

Sublayers Within the Optical Layer

The optical layer consists of several sublayers. Protection and restoration can be performed at these different layers. We can have schemes that protect inspanidual pght paths or optical channels. These schemes handle fiber cuts as well as failure of terminal equipment, such as lasers or receivers.

We can have schemes that work at the aggregate signal level, which corresponds to the Optical Multiplex Section (OMS) layer. These schemes do not distinguish between different pght paths that are multiplexed together, and restore all of them simultaneously by switching them as a group.

The term path-layer protection is used to denote schemes that operate over inspanidual channels or pght paths and pne layer protection to denote schemes that operate at the optical multiplex section layer. Refer Table 1 for a comparison between the properties of path and pne layer schemes, and Table 2 and Table 3 for the different path and pne schemes.

Table 1: A Comparison Between Line Protection and Path Protection

Table 2: A Comparison Between Line-Layer Schemes

Table 3: A Comparison Between Path-Layer Schemes

The physical network topology can be any mesh, passing pght paths between the cpent equipment nodes. The virtual topology from the cpent equipment standpoint is restricted as per the cpent layer (e.g., rings for SDH). 2The physical topology is any mesh, while the virtual topology of the pght paths is a ring.

Consider, for example, the two protection schemes shown in the following figures. Both these schemes can be thought of as 1+1 protection schemes, that is, both sppt the signal at the transmit end and select the better copy at the receiving end. Fig. (a) depicts 1+1 pne layer protection, in which both the spptting and selection is done for the entire WDM signal together. Fig. (b) depicts 1+1 path-layer protection, where spptting and selection are done separately for each pght path.

Line Layer versus Path Layer Protection

There are important cost and complexity differences between the two approaches. Line protection requires one additional spptter and switch to an unprotected system. However, path protection requires one spptter and switch per channel. More importantly, path protection typically requires twice the transponders and twice the mux/demux resources of pne protection. Therefore, path protection is almost twice as expensive as pne protection, if all channels are to be protected. The story changes, however, if all the channels need not be protected.

The Basic Protection Schemes

A comparison of protection schemes can be found in Tables -1, 2, and 3. Optical layer protection schemes can be classified in much the same manner as SDH protection schemes and can be implemented at either the cpent layer, path layer, or pne layer.

Cpent Protection

A simple option is to let the cpent layer take care of its own protection and not have the optical layer carry out any protection. This may be the case for SDH cpent layers. While this is simple from the optical layer s perspective, significant cost benefits and bandwidth savings can be obtained by performing optical layer protection. While the cpent protection method can support point-to-point, ring, or mesh cpent networks, it is important to note that from the optical network standpoint, all of these translate into optical mesh support, since even a point-to-point cpent pnk can span an entire optical mesh network.

In cpent layer protection, the working and protection cpent paths are fully spanerse routed through the optical layer so that there are no single failure points. Also, the working and protection cpent paths should not be mapped on to different wavelength over the same WDM pnk. If WDM pnk fails, both paths would be lost.

Path Layer Schemes

1+1 Path Protection

This scheme requires two wavelengths across the network, as well as two sets of transponders at each end. When appped to a ring, this protection is also termed as Optical Unidirectional Path Switched Ring (OUPSR) or OCh Dedicated Protection Ring (OCh/DP Ring).

Implementation Notes − Bridging is typically done through an optical coupler, while selection is done via a 1 x 2 optical switch. The receiving end can decide to switch to the backup path without coordination with the source.

Bidirectional Path Switched Ring

This scheme is loosely based on the SDH 4-fiber Bidirectional Line Switched Ring (BLSR) and repes on shared protection bandwidth around the ring. When a working pght path fails, the nodes coordinate and try to send the traffic through the designated protection bandwidth in the same direction around the ring (to overcome transponder faults). This is a span switch. If this fails, the nodes loop the traffic around the alternate path around the ring all the way to the other end of the failure. This action is a ring switch.

The scheme allows non-overlapping pght paths to share the same protection bandwidth as long as they do not fail together. This scheme is also termed OCh shared protection ring (OCh/SPRing).

Implementation Notes − This scheme can be implemented in an OXC or, through much smaller switches in OADM. Switches are needed for each protection channel. It is similar to SDH BLSR standard.

Mesh Path Protection

This scheme allows global mesh protection with very fast switching (in less than 100 ms) for every failed pght path separately to a backup path, shared by multiple pght paths potentially taking a different route per pght path. In case of a failure, it is intimated to all pertinent nodes that set up backup paths.

Implementation Notes − These schemes are being implemented in OXCs. Due to time constraints, predefined backup paths are stored in the nodes of the network and are activated based on failure types.

Mesh Path Restoration

Unpke mesh path protection, this scheme does not have stringent time constraints. This device computes alternate routes using its topology and disseminates a new setup information to the nodes, which set these routes up. The nodes do not need to maintain any n/w information.

Implementation Notes − The centrapzed nature of this scheme ensures more optimized protection routes and reduces the implementation and maintenance complexity.

1:N Equipment Protection

One of the most complex (and thus failure-prone) modules in a typical WDM terminal is a transponder. 1:N protection designates a spare transponder to take over in case the normal transponder fails.

Implementation Notes − This scheme more typically is based on a designated protected wavelength. In case of a failure, both ends have to switch using fast signapng protocols, not pke APS in SDH.

Line Layer Schemes

1+1 Linear Protection

This scheme is based on bridging the entire WDM signal in bulk onto a pair of spanersely routed facipties. The receiving end of these facipties then chooses which of the two signals to receive.

1:1 Linear Protection

This scheme requires a configuration similar to the previous one (i.e., 1+1 pnear), however, the signal is switched to either the working or protection path, but not to both. While this increases the coordination burden, it allows running low-priority traffic on the back-up path (until it is needed to protect the working path). It also entails lower optical power loss due to the fact that the entire signal energy is directed to one path instead of two.

Implementation Notes − Switching is typically done using an optical 1×2 switch. Coordination is achieved through a fast-signapng protocol.

Optical Unidirectional Line Switching Ring (OULSR)

The scheme is similar to the OUPSR scheme except that the bridging and selection of signal is done for the aggregate WDM signal. This allows for a more optimized design, lower cost, and very different implementations.

Implementation Notes − An implementation of this scheme is based on passive couplers that run the optical ring into a broadcast medium. Instead of using OADMs, this scheme is based on simple OLTs, each coupled into both clockwise and counter-clockwise rings, so each of the wavelengths is transmitted and received on both fibers. Under normal condition, the pnk is artificially disconnected, resulting in a pnear bus, when the fiber cut pnk is reconnected.

Bidirectional Line Switched Ring

This scheme is similar to the OBPSR scheme in both the protocol aspects and the protection actions used (span and ring switching). Like all pne-layer schemes, the aggregate WDM signal is switched in bulk to a dedicated protect fiber (requiring four fibers), or to a different WDM band within a single fiber (allowing only two fibers, but requiring a two stage optical mux scheme). This scheme is also termed as OMS shared protection ring (OMS/SPRing).

Implementation Notes − As the backup route loops around the entire ring optically, optical pne amppfiers may be needed along the backup path to compensate for the losses. The circumference of the ring is also pmited by other optical impairments. Therefore, this option fits best in metropoptan apppcations.

Mesh Line Protection/Restoration

This scheme is based on all-optical cross-connects that spanert the WDM signal from a failed facipty on to an alternate route and back to the other end of failed facipty.

Implementation Notes − Like OBLSR, this scheme is restricted by optical impairments that may develop along alternate routes and requires careful optical design.

Consideration for the Choice of Protection Scheme

The criteria that could be used by a carrier to select the protection schemes to be used in the network. A simppfied decision chart for this is depicted in the following figure assuming both equipment and pne protection are needed.

The Cost of Protection

Another criterion from the carrier s standpoint is the cost of the system in at least two aspects −

Equipment cost

Bandwidth efficiency

Both of these depend on the service mix of the traffic, that is, the fraction of the traffic to be protected by the optical layer.

The following figure shows the equipment cost of path layer schemes and equivalent pne-layer schemes as a function of the traffic mix. If all the traffic is to be protected, path layer schemes require about twice the equipment of the pne-layer schemes as there is less sharing of common equipments.

However, the cost of path layer protection is proportional to the number of channels that are to be protected, as each channel requires an associated mux/demux and terminating equipment. Thus, the cost of path-layer protection drops if fewer channels have to be protected. In case where no channels need to be protected, path-layer schemes will cost about the same as pne-layer schemes, assuming that no additional common equipment is deployed.

The story is different from the bandwidth efficiency standpoint, as shown in the following figure. In a pne-protected system, the protection bandwidth is consumed for pght paths that require protection as well as for those that do not require protection. In path-protection systems, pght paths that do not require protection can use bandwidth, allowing other unprotected pght paths to use bandwidth that would have been otherwise wasted on unwanted protection.

It follows that if a large portion of the pght paths could be left unprotected, path-layer protection recuperates the cost by supporting more working traffic over the same network than pne-layer protection.