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Title:
METHOD AND DEVICE FOR DATA PROTECTION IN AN OPTICAL COMMUNICATION NETWORK
Document Type and Number:
WIPO Patent Application WO/2011/076256
Kind Code:
A1
Abstract:
A method and a device for processing data in an optical communication network are provided, wherein a main service is provided via a shared medium; and wherein at least one separate resource of the shared medium is reserved for a backup service. In addition, a communication system comprising at least one such device is suggested.

Inventors:
CHARZINSKI JOACHIM (DE)
STADEMANN RAINER (DE)
Application Number:
PCT/EP2009/067722
Publication Date:
June 30, 2011
Filing Date:
December 22, 2009
Export Citation:
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Assignee:
NOKIA SIEMENS NETWORKS OY (FI)
CHARZINSKI JOACHIM (DE)
STADEMANN RAINER (DE)
International Classes:
H04J14/02; H04B10/00; H04J3/16
Foreign References:
EP1450509A22004-08-25
EP0877502A21998-11-11
EP2117138A12009-11-11
US20020071149A12002-06-13
EP1746857A12007-01-24
US20060083513A12006-04-20
US7212738B12007-05-01
EP1450509A22004-08-25
EP0877502A21998-11-11
EP2117138A12009-11-11
US20020071149A12002-06-13
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Claims:
A method for processing data in an optical communication network,

- wherein a main service is provided via a shared me¬ dium;

- wherein at least one separate resource of the shared medium is reserved for a backup service.

The method according to claim 1, wherein the backup service is activated in case the main service is impaired.

The method according to claim 2, wherein subscribers af¬ fected by the impairment are supplied by the backup ser¬ vice, wherein the backup service in particular comprises service limitations.

The method according to any of claims 2 or 3, wherein in case the backup service is activated, an optical network unit affected by the impairment tunes onto the resource of the shared medium that is reserved for backup ser¬ vices.

The method according to any of the claims 2 to 4, wherein the main service is re-activated after the im¬ pairment and the backup service enters a standby mode.

The method according to any of the preceding claims, wherein the at least one separate resource of the shared medium is reserved and/or used as a backup service for several main services that are in particular provided by several optical line terminals.

The method according to any of the preceding claims, wherein the main service is provided by a first physical component and the backup service is provided by a second physical component, wherein the first physical component and the second physical component are deployed at dif¬ ferent locations or sites. The method according to any of the preceding claims, wherein the optical communication network comprises at least one passive optical network.

The method according to any of the preceding claims, wherein the shared medium utilizes wavelength division multiplexing .

The method according to any of the preceding claims, wherein the at least one separate resource reserved for the backup service utilizes a multiplexing scheme on at least one wavelength or at least one wavelength band.

The method according to claim 10, wherein the at least one wavelength or the at least one wavelength band is within a spectrum of the wavelengths used for the main service or at a separate spectrum.

The method according to any of the preceding claims, wherein several separate resources are provided for sev¬ eral backup services.

A device comprising a processing unit that is arranged such that the method according to any of the preceding claims is executable thereon.

The device according to claim 13, wherein said device is an optical network component, in particular a or being associated with an optical network unit or an optical line terminal. 15. A communication system comprising the device according to any of claims 13 or 14.

Description:
Description

METHOD AND DEVICE FOR DATA PROTECTION IN AN OPTICAL COMMUNICATION NETWORK

The invention relates to a method and to a device for proces ¬ sing data in an optical communication network. In addition, a communication system comprising at least one such device is suggested .

This invention in particular relates to the field of wave ¬ length division multiplexing (WDM) networks, in particular next-generation optical access (NGOA) ultra-dense WDM (UDWDM) access networks.

Telecommunication access networks have to be protected against link and node failures. Especially if there is a lar ¬ ge number (e.g., more than 100.000) of subscribers served by a single office, precautions need to be taken against a complete failure of such office.

This issue becomes even more apparent considering the conver ¬ gence of services, i.e. voice, broadband data and television (TV) services being served via the same network connection. Hence, an outage of the access service may simultaneously af ¬ fect a huge number of user services without any chance for the subscribers to further communicate or to obtain any in ¬ formation via alternative services. Therefore, measures for geographical redundancy are required directly at the access system if the access system such as an ultra-dense WDM NGOA PON is used for office consolidation, serving hundreds of thousands of subscribers from one physi ¬ cal site. A known approach is to deploy a second fiber back- haul to a backup site for each PON, which introduces a dupli ¬ cation of required OLT equipment at correspondingly high costs . Existing protection mechanisms against optical link failure require duplication of interfaces and/or optically switching signals to alternative paths. Protection mechanisms against node or site failure require the full service of a node or site to be taken over by an al ¬ ternative node or site, requiring corresponding physical connectivity to all those nodes or sites. In POTS (plain old telephony system) networks, the number of subscribers per local office (short distance office, SDO) is sufficiently small (usually less than 50.000) to allow the network to be operated without a geographical redundancy con ¬ cept for failures of local offices. As the number of subscri- bers aggregated per long distance offices (LDOs) is signifi ¬ cantly larger, protection against failures of complete LDOs is usually provided by geographically redundant uplinks from SDOs to at least two different LDOs. Fig.l shows a schematic diagram depicting a protection scheme in a POTS network. Subscribers 101 to 103 are connected to a street cabinet SC11 via subscriber lines 107 to 109 and subscribers 104 to 106 are connected to a street cabinet SC12 via subscriber lines 110 to 112. The street cabinets SC11 and SC12 are connected via lines 113, 114 to a short distance of ¬ fice SDOll, which is further connected via lines 115, 116 to a long distance office LDOll and to a long distance office LD012. As indicated in Fig.l, neither subscriber lines 107 to 112 nor cable bundles 113, 114 are protected. However, each local exchange (e.g., SDOll) is connected to at least two long di ¬ stance offices LDOll, LD012 by redundant uplink lines

(trunks) 115, 116. Hence, the scale of an outage in case of a complete site failure is limited to the number of subscribers connected to one SDO. Fig.2 shows a schematic diagram visualizing a site consolida ¬ tion approach via a long reach WDM PON. Subscribers 201 to 203 are connected to a passive optical splitter 207 and subscribers 204 to 206 are connected to a passive optical splitter 208. The splitters 207 and 208 are connected to a passive splitter 211 that is deployed in an SDO 209. The splitter 209 is further connected to an OLT 212, which is deployed in an LDO 210. If NGOA PON systems are used for site consolidation purposes, the function of short distance offices is reduced to housing a passive fiber splitter and all optoelectronic processing is done in the previous long-distance offices, as indicated in Fig.2, concepts are required to protect subscribers against the outage of an LDO site.

Fig.3 shows a schematic diagram comprising a geographically redundant 1:1 protection scheme of an OLT (site) by employing a passive optical splitter/combiner element SPC 301 that con- nects the access fiber 302 via separate fibers 303 and 304 both to an active OLT 305 and to a standby OLT 306, each OLT being deployed at different LDO locations 307, 308. This con ¬ cept requires each OLT to be duplicated, hence substantially doubling the costs for an NGOA PON system on the OLT side.

Fig.4 shows a schematic diagram comprising an alternative ap ¬ proach using optical switches and a standby OLT in a 1:1 ge ¬ ographically redundancy architecture for WDM PONs based on the scenario shown in Fig.3. Fig.4 comprises an additional link 403 between the active OLT 305 and the standby OLT 306 and two fiber switches 401 and 402, allowing the active OLT 305 to stay in service even if the link 305 is broken.

The advantage of the scenario shown in Fig.4 over that of Fig.3 is that the active OLT 305 may continue serving its previous subscribers and there is no re-training or re ¬ configuration of ONUs required after a link failure. On the other hand, if the complete node of the active OLT 305 or its site fails, service can be taken over by the standby OLT 306. Using the same concept as in Fig. 4, the amount of standby OLT resources required can be reduced from 100% to 100%/N by sharing each standby OLT between N active OLTs. In order to provide geographical redundancy, different active OLTs to be protected have to be located on different places throughout the network. Fig.5 shows a diagram visualizing such a 1:N geographical redundancy concept for NGOA WDM PON using switched optical fiber networks and a shared OLT.

A metro access 501 is connected to a switched active OLT 503 and to a switched optical network 506. Another metro access 502 is connected to a switched active OLT 504 and to a swit ¬ ched optical network 507. Each of the switched optical net ¬ works 506, 507 is connected to a switched standby OLT 505 for protection purposes.

While the solution shown in Fig.5 can save standby OLT re ¬ sources, it introduces significant complexity and cost for providing the switched optical network: The switches and fi ¬ bers all have to carry the full optical WDM spectrum that is used in the PON system and consequently dedicated fibers are required for each of the links. In addition, it has to be no ¬ ted that usually there will be multiple PONs served by each LDO site, so a number of fibers has to be switched in paral ¬ lel by each of the fiber switches, which further increases the complexity and thus cost of such an architecture.

The problem to be solved is to overcome the disadvantages stated above and in particular to provide an efficient redun ¬ dancy mechanism that is in particular applicable in WDM PONs.

This problem is solved according to the features of the inde ¬ pendent claims. Further embodiments result from the depending claims . In order to overcome this problem, a method for processing data in an optical communication network is provided,

- wherein a main service is provided via a shared me- dium;

- wherein at least one separate resource of the shared medium is reserved for a backup service.

The backup service provides an efficient solution in case of a failure of the main service. The main service may be provi ¬ ded by a PON, in particular by at least one OLT of this PON.

Hence, a geographical redundancy approach is suggested in particular for protection against node failures, significant- ly reducing the cost for additional network components and being capable of coping without fiber switches.

In an embodiment, the backup service is activated in case the main service is impaired.

Such impairment of the main service may be any situation that requires switching to the backup service, e.g., a distortion, an outage or failure of the service or the site, a signal de ¬ gradation, a disconnection or the like.

In another embodiment, subscribers affected by the impairment are supplied by the backup service, wherein the backup servi ¬ ce in particular comprises service limitations. Such service limitations may comprise restrictions or reduced capacities regarding, e.g., the bandwidth for data access that is supplied to each subscriber affected by the impair ¬ ment of the main service. Furthermore, less important servi ¬ ces may not be provided (to some or to all subscribers) in case of an impairment. It is also an option that basic te ¬ lephony services and/or basic data access services (with a minimum bandwidth) are provided to all subscribers or a group thereof. It is further noted that the limitations could be dynamically adjusted based on the actual resources that are available for backup services and/or based on a quality of service level the particular subscriber has requested or signed up for.

It is thus a particular option to provide backup services for a selection of subscribers only. This can be achieved, e.g., by allowing only selected ONUs to tune in to the wave ¬ length (s) provided by the backup service.

According to a further embodiment, in case the backup service is activated, an optical network unit affected by the impair ¬ ment tunes onto the resource of the shared medium that is re ¬ served for backup services.

The optical network unit may recognize the impairment (e.g., by detecting a loss of signal) and hence may tune its recei ¬ ver to the wavelength ( s ) of the shared medium and enter, e.g., a TDM operation mode.

In a next embodiment, the main service is re-activated after the impairment and the backup service enters a standby mode.

The subscribers, in particular the ONUs associated with the subscribers, can be instructed via a management channel to switch back to the main service.

It is also an option that the ONUs probe the management chan ¬ nel of the main service to determine whether the main service is active again. In this case, the ONUs may switch to the main service (again) .

It is also an embodiment that the at least one separate re ¬ source of the shared medium is reserved and/or used as a backup service for several main services that are in particu ¬ lar provided by several optical line terminals. As the component providing the backup service is deployed on a different site as are the components providing the main services, it can provide backup services for several main services of various optical networks or OLTs. In this case, the OLT providing the backup services is connected to the subscribers of all such main services. Such connection can be achieved by deploying a splitter and/or combiner to connect the subscribers, e.g., ONUs to the OLTs providing the main service and to the OLT providing the backup services.

The backup services may utilize different resources (e.g., at least one different wavelength) for the different main servi ¬ ces .

Pursuant to another embodiment, the main service is provided by a first physical component and the backup service is pro ¬ vided by a second physical component, wherein the first phy ¬ sical component and the second physical component are deploy ¬ ed at different locations or sites.

Hence, in case of an outage of the site the first physical component is located at, the site of the second physical com ¬ ponent may provide backup services towards the subscribers affected .

According to an embodiment, the optical communication network comprises at least one passive optical network.

There may be several passive optical networks, each being served by an OLT.

According to another embodiment, the shared medium utilizes wavelength division multiplexing. The shared medium could be a WDM, in particular a UDWDM service provided via a PON. In yet another embodiment, the at least one separate resource reserved for the backup service utilizes a multiplexing sche ¬ me on at least one wavelength or at least one wavelength band .

It is noted that various multiplexing schemes could be utili ¬ zed, e.g., TDMA, CDMA, OFDMA or SC-FDMA.

The at least one wavelength or at least one wavelength band could be used per direction (uplink and downlink) . It is noted that uplink refers to the direction from the subscriber towards the network and downlink refers to the opposite di ¬ rection . According to a next embodiment, the at least one wavelength or the at least one wavelength band is within a spectrum of the wavelengths used for the main service or at a separate spectrum. Said spectrum may be a (UD)WDM PON spectrum or a predefined wavelength band.

It is noted that in case the main service and the backup ser ¬ vice use the same spectrum, wavelength filters can be provi- ded to reduce interference and/or crosstalk.

Pursuant to yet an embodiment, several separate resources are provided for several backup services. It may be of advantage to provide a particular backup service per resource, e.g., at least one wavelength for telephony services, another at least one wavelength for TV and/or a further at least one wavelength for data access services. The problem stated above is also solved by a device compri ¬ sing or being associated with a processing unit that is arranged such that steps of the method stated herein may be executable thereon. It is further noted that said processing unit can comprise at least one, in particular several means that are arranged to execute the steps of the method described herein. The means may be logically or physically separated; in particular seve ¬ ral logically separate means could be combined in at least one physical unit.

Said processing unit may comprise at least one of the follo- wing: a processor, a microcontroller, a hard-wired circuit, an ASIC, an FPGA, a logic device.

The solution provided herein further comprises a computer program product directly loadable into a memory of a digital computer, comprising software code portions for performing the steps of the method as described herein.

In addition, the problem stated above is solved by a compu ¬ ter-readable medium, e.g., storage of any kind, having compu- ter-executable instructions adapted to cause a computer sys ¬ tem to perform the method as described herein.

Furthermore, the problem stated above is solved by a communi ¬ cation system comprising at least one device as described herein.

Embodiments of the invention are shown and illustrated in the following figures: Fig.6 shows a diagram visualizing a shared OLT that pro ¬ vides geographical redundancy with a limited backup service on a dedicated wavelength for subscribers that are served by primary OLTs; Fig.7 shows a diagram visualizing the shared OLT according to Fig.6, wherein an additional SPC is used to com ¬ bine the fibers between the shared OLT and the split ¬ ters connecting the ONUs; Fig.8 shows two spectrum diagrams each comprising a UDWDM PON spectrum, wherein one diagram visualizes a spectrum layout with a backup channel that is part of the UDWDM spectrum and the other diagram depicts a spectrum layout with a backup channel that is in a sepa ¬ rate wavelength range (e.g., another band) .

The approach suggested in particular provides a restricted service backup instead of a full service backup. A standby OLT may use a single reserved wavelength per direction that is not used in the active WDM PON system. Instead of dedica ¬ ting that wavelength fully to one ONU service, it can be sha ¬ red, e.g., in a TDM mode (similar to a GPON, EPON, GEPON sys- tern) or in optical OFDMA mode between multiple ONUs . Hence, the solution may provide a restricted service of, e.g., a da ¬ ta rate amounting to 256Kbit/s per subscriber instead of the full data rate of, e.g., lGbit/s per subscriber. Hence, in the backup scenario, e.g., in case of a severe network failu- re, the subscriber is still supplied with telephony and basic data access services.

It is noted that in case the conventional (primary) scenario cannot be maintained, the restricted backup scenario is acti- vated. Scenario in this case may refer to at least one access service. These scenarios may be associated each with at least one optical network, in particular at least one PON, or with at least one OLT. The OLT hence is a centralized optical com ¬ ponent in an optical network conveying services towards subscribers, which can be attached to the optical network via ONUs. After the outage is corrected, the conventional scena ¬ rio can be re-activated and the backup scenario can be swit ¬ ched to standby. The backup service does not have to be as optimized as the primary access service. However, as the ONUs are capable of coherent detection, the backup service can be optimized in two ways : (a) A much higher split ratio can be allowed than in standard GPON (i.e. in the conventional scenario) thereby improving the optical budget due to coherent detection.

(b) A less efficient and thus less sophisticated upstream transmission (larger inter-frame gaps, less precise ranging requirements) can be provided compared to the standard GPON (i.e. the conventional scenario).

The ONUs that do not require backup service, because their primary active OLT is reachable, do not tune onto the backup service wavelength ( s ) so that multiple PONs can be protected by a single standby OLT without any need to interrupt the pa- rallel fiber connections.

Fig.6 shows a diagram visualizing a shared OLT 613 that pro ¬ vides geographical redundancy with a limited backup service on a dedicated wavelength for subscribers that are served by OLTs 614 to 616.

The OLT 614 is deployed at a site 617 and connected via a fi ¬ ber 610 to an SPC 604 to which several lines 601 are connec ¬ ted towards subscribers (not shown) .

The OLTs 615 and 616 are deployed at a site 618, wherein the OLT 615 is connected via a fiber 611 to an SPC 605 to which several lines 602 are connected towards subscribers (not shown) . Further, the OLT 616 is connected via a fiber 612 to an SPC 606 to which several lines 603 are connected towards subscribers (not shown) .

The OLTs 614 to 616 are active OLTs, wherein said OLT 613 is a standby OLT deployed at a different location or site 619. The OLT 613 is connected via a fiber 607 to the SPC 604, via a fiber 608 to the SPC 605 and via a fiber 609 to the SPC 606. The fibers 607 to 612 can be part of a metro access fiber network .

In case of a failure at any of the OLTs 614 to 616 or at any of the sites 617 or 618, the OLT 613 is able to provide at least a portion of the services to the subscribers affected by this failure. This can in particular be achieved via at least one (dedicated) wavelength or range of wavelengths that is/are reserved for backup services.

Fig.7 shows a diagram visualizing the shared OLT 613 according to Fig.6, wherein an additional SPC 701 is used to com ¬ bine the fibers 607 to 609 and to convey traffic via a single fiber 702 to the OLT 613. Another fiber 703 indicates that the standby OLT 613 may be connected in a similar manner to further SPCs (not shown) .

It is an advantage of the solution suggested that a signifi ¬ cant amount of resources (fiber switches and/or OLTs) can be saved, whereas the geographical redundancy required for long- reach PON systems with site consolidation can still be provided. This alleviates the issue that the subscribers do not face a complete loss of all services in case of failure of their associated OLT as the backup OLT provides a reduced set of services that allow for, e.g., telephone communication as well as basic data services (with reduced bandwidth compared to the normal scenario with the conventional OLTs being up and running) . Fig.8 shows two spectrum diagrams 801, 802 each comprising a UDWDM PON spectrum, wherein the diagram 801 visualizes a spectrum layout with a backup channel 803 that is part of the UDWDM spectrum. In contrast, the diagram 802 visualizes a spectrum layout with a backup channel 804 that is in a sepa- rate wavelength range (e.g., another band) .

The following shows an exemplary sequence of actions proces ¬ sed at an ONU in case a connection to the conventional or primary PON or OLT is lost (such loss may in particular be detected by the ONU) :

- A long-time loss or a ( semi- ) permanent loss of signal on a normal (management) wavelength is detected by the ONU.

- The ONU releases subscriber state information, e.g., subscriber IP addresses.

- The ONU ' s receiver is tuned to a (e.g., pre- configured) wavelength for a backup system.

- A TDM PON code is activated on a processor or a TDM chip .

- A synchronization is conducted (e.g., signal, MAC, etc . ) .

- A communication with the backup TDM PON (backup OLT) is established.

In case the primary PON is again available, the ONU may re ¬ turn to normal operation.

As an option, the backup OLT may operate on a same wavelength band as does the conventional OLT. In this case, at least one unused wavelength can be utilized for backup purposes.

It is also possible that the backup OLT and the conventional OLT both operate on different wavelength bands.

In case the backup OLT and the conventional OLT operate on separate wavelength windows (bands), the fibers 607 to 609 (see Fig.6 and Fig.7) can be equipped with wavelength filters to reduce crosstalk between the at least one backup wave ¬ length and the wavelengths of the conventional OLTs.

It is a further option that multiple backup systems (e.g., one backup system per service such as TV, telephony or data) can be provided via several wavelengths. In addition, different multiplexing and modulation schemes can be used for the backup PON, e.g. TDMA, CDMA, OFDMA, SC- FDMA. Instead of offering the backup service to all subscribers, only selected subscribers can be served by the backup servi ¬ ce. This can be realized by only allowing selected ONUs to tune in to the backup service wavelength ( s ) . Optical switches can be employed between the splitter and/or combiners and the backup OLT to allow the OLT to select a set of PONs to connect to. An advantage compared to the solutions shown in Fig.4 or Fig.5 is that only a single wavelength needs to be switched.

Multiple PONs may be protected in parallel by using separate wavelengths in the backup OLT.

A backup TDM PON system can have less stringent requirements regarding an upstream timing (e.g., longer inter-burst gaps, longer synchronization preambles and less strict ranging accuracy) compared to the conventional (active) (G)PON.

The approach could be combined with optical backup paths bet- ween SPCs and active OLTs, which would avoid using the backup PON in case of a mere link failure.

The backup OLT can inform the ONUs via its management channel to switch back to the conventional OLT (primary PON) .

The ONUs can regularly probe the primary system' s management channel to check if the primary system is up again. This can be done by shortly tuning a receiver to another wavelength (the primary system' s management channel wavelength) or by using a separate receiver in the ONU, which might exist any ¬ way for parallel reception of video broadcast transmissions. The wavelength ( s ) used by the backup PON system can be pre- configured or configured towards the ONUs via management in the primary PON system. The ONUs can be equipped with an (optical) indicator that signals the emergency operation to the subscriber.

List of Abbreviations:

CDMA Code Division Multiple Access

DWDM Dense Wavelength Division Multiplexing

EPON Ethernet PON

FDMA Frequency Division Multiple Access

GEPON Ethernet PON

GPON Gigabit PON

LDO Long Distance Office

OFDMA Orthogonal Frequency Division Multiple Access

OFS Optical Fiber Switch

OLT Optical Line Terminal

ONU Optical Network Unit (also referred to as "ONT",

Optical Network Termination)

OXC Optical CrossConnect

PON Passive Optical Network

POTS Plain Old Telephony System

ROADM Reconfigurable Optical Add-Drop Multiplexer

SC-FDMA Subcarrier Frequency Division Multiple Access

SDO Short Distance Office

SPC Splitter and/or Combiner

TDM Time Division Multiplexing

TDMA Time Division Multiple Access

TV Television

UDWDM Ultra-Dense Wavelength Division Multiplexing

WDM Wavelength Division Multiplexing