FR3136911A1 - Method for routing data in an optical access network, selector, optical line termination equipment, corresponding computer program product - Google Patents

Abstract

Method for routing data in an optical access network, selector, optical line termination equipment, corresponding computer program product The invention relates to a method for routing data (Data) intended to be implemented by an optical access network comprising at least one multi-port optical line termination device, a point-to-point connection between a first port of the optical line termination device and a point-to-point optical network unit (ONU PtP) enabling point-to-point connectivity of a first client and a point-to-multipoint connection between a second port of the optical line terminator and at least one optical point-to-multipoint network (ONU PON) unit enabling point-to-multipoint connectivity of a plurality of second clients comprising at least one second client. The method comprises: routing (11) data from the first client according to point-to-point connectivity, routing (12) data from the second client according to point-to-multipoint connectivity, and, the first client and the second client forming only one client: a first switchover (13, Y) from the routing of client data according to so-called primary point-to-point connectivity to routing according to so-called secondary point-to-multipoint connectivity, based (13) on at least one first operating indicator ( indicPtP) of the point-to-point connection to obtain a double supply of the customer. Figure for abstract: Figure 3

Description

Method for routing data in an optical access network, selector, optical line termination equipment, corresponding computer program product Field of the invention

The field of the invention is that of optical telecommunications (by optical fiber) and optical access networks comprising a part of the “passive optical network” (PON, “Passive Optical Network”) type. Within this field, the invention relates more particularly to a data routing method intended for such an optical access network. It applies in particular to optical line termination equipment.

A passive optical network (PON) refers to an optical fiber transport principle used in optical access networks (FTTx, “Fiber To The x”). It is characterized by a passive point-multipoint fiber architecture (several users share the same optical fiber and there is no active equipment between the central office and the subscribers) allowing point-to-multipoint connectivity. There are different PON network standards, including GPON (ITU-T G.984 standard), XGS-PON (ITU-T G.9807 standard), NG-PON2 (ITU-T G.989 standard), HS-PON (ITU-T G.9804 standard), etc. These different access networks are called PON networks or PON type networks.

Prior art

An optical access network with a PON type part, illustrated schematically by the and the , comprises optical line termination equipment (OLT, “Optical Line Termination”) which is connected on the one hand to optical network units (ONU, “Optical Network Units”) called ONU PON via one or more distribution networks optical distribution network (ODN) of point-multipoint type allowing point-to-multipoint connectivity and on the other hand to at least one ONU PtP optical network unit via a fiber dedicated to a single client allowing point-to-point connectivity.

The OLT equipment is the termination equipment, on the network side, ensuring the interface with the dedicated optical fibers and with the optical fibers of one or more ODN networks. In France, it is generally located in the optical connection node (NRO) and often located in a so-called central building. It traditionally has a chassis with cards, PON Card, PtP Card, each comprising optical ports. An optical port can address several dozen clients, commonly 64, via an ODN network which includes a 1:N (one to N) S/C splitter/combiner. OLT equipment can for example include more than a hundred optical ports respectively connected to as many ODN networks to address several thousand ONU units with the restriction that one or more optical ports can be reserved for one or more PtP ONU units. for point-to-point connectivity. Currently, at least one card carrying several optical ports is dedicated to PtP ONU units.

Each ONU provides the user-side interface. It converts the optical signal received via an optical fiber into an electrical signal sent to a client. It is also sometimes called “Optical Network Termination” (ONT).

Each ODN network provides the optical transmission medium for the physical connection of a plurality of ONU units called ONU PON to the OLT equipment, with a range for example limited to 20 km. The ODN network provides the optical channel for the transmission of optical signals between the OLT and the ONU PONs in both the downstream and upstream directions.

A given ODN network therefore establishes a transmission channel between the given port of the OLT equipment and each of the addressed ONU PON units, taken both in the downstream direction (referenced “D” on the for “downstream”, that is to say “OLT towards ONU PON”) only in the upstream direction (referenced “U” on the for “upstream”, i.e. “ONU PON to OLT”).

Although an optical fiber is generally dedicated to a single direction, down or up in the core network, a single optical fiber is used for the down direction and for the up direction in the case of a PON type access network. between the OLT and a bursting point also known as a pooling point. This concentration point corresponds in the downward direction to the splitting of the optical fiber into several optical fibers implemented by an S/C splitter and in the upward direction to the grouping of the optical fibers coming from the different ONU PON units in a single fiber implemented by the same device called S/C combiner. This S/C splitter/combiner device is passive, so it divides the power of the downlink signal into as many output optical fibers. Depending on deployment constraints, several S/C splitters/combiners may follow one another.

The notion of customer covers both the residential customer, the professional customer, the business and the (mobile) radio site connected via an optical fiber.

Dedicated optical fiber is generally reserved to serve a radio site or to serve a company given its installation cost.

As for the , the optical access network illustrated schematically by the includes a PON part and a part with an optical fiber dedicated to a single customer.

The PON part connects a port, PON port, of the OLT equipment to several clients using point-to-multipoint connectivity. This part includes a main optical fiber, an S/C splitter/combiner, a plurality of secondary optical fibers and a plurality of PON ONUs. The main fiber connects a port, PON port, to the S/C splitter/combiner. The plurality of secondary fibers connects the S/C splitter/combiner to the plurality of PON ONUs. Each ONU PON serves a customer.

The fiber dedicated to the customer connects a port, PtP port, to a SW gateway (cell site gateway/Ethernet switch) via a PtP ONU to serve this customer.

Dedicated fiber serves a single customer with point-to-point connectivity. This client, whether a company or a radio site, requires very high service availability, i.e. connectivity close to permanent availability.

For various reasons, an interruption may occur in the connection part between the OLT equipment and the customer. Such an outage may result in particular from a sectioning of the dedicated fiber, a failure in the PtP ONU, etc.

To increase the reliability of the availability of service to the customer, there is a solution which consists of a double supply of the customer by means of a second dedicated fiber with, if possible, infrastructure equipment (cable containing the fiber, cable tray, boxes, optoelectronic cards, electronic cards, etc.) different. But this solution is very expensive.

The invention proposes a double adduction solution that is less expensive than the prior art.

The subject of the invention is a data routing method intended to be implemented by an optical access network comprising at least one optical line termination device with several ports, a point-to-point connection between a first port of the optical line termination device and a point-to-point optical network unit enabling point-to-point connectivity of a first client and point-to-multipoint connection between a second port of the optical line termination device and at least one optical network unit multipoint enabling multipoint connectivity of a plurality of second clients including at least one second client. This process includes:

• routing of data from the first client using point-to-point connectivity,
• routing of data from the second client according to point-to-multipoint connectivity and

and, the first client and the second client forming only one client, the method further comprises:

• a first switch from the routing of customer data according to so-called primary point-to-point connectivity to routing according to so-called secondary point-multipoint connectivity, based on at least a first indicator of operation of the point-to-point connection to obtain a double adduction of the customer.

The invention further relates to an optical access network comprising at least one optical line termination device, a point-to-point connection between a first port of the optical line termination device and a point-to-point optical network unit for carrying data from a first client in point-to-point connectivity, and a point-to-multipoint connection between a second port of the optical line terminator and at least one point-to-multipoint optical network unit for carrying data of a plurality second clients comprising at least one second client according to point-to-multipoint connectivity. The first client and the at least second client forming only one client, this access network further comprises:

• a routing selector connected to the client, to the point-to-point optical network unit and to the point-multipoint optical network unit to switch the routing of client data according to so-called primary point-to-point connectivity to routing according to so-called secondary point-multipoint connectivity, on the basis of at least a first indicator of operation of the point-to-point connection to obtain a double adduction of the customer.

The invention further relates to a routing selector intended to be connected to a client, intended to be connected to a point-to-point optical network unit for a point-to-point connection between a first port of a terminating device optical line of an optical access network and the client for carrying client data in point-to-point connectivity and intended to be connected to a point-to-multipoint optical network unit for point-to-multipoint connection between a second port of the device optical line termination and at least the client to carry the client data according to point-to-multipoint connectivity. This selector is able to switch routing of customer data according to so-called primary point-to-point connectivity to routing according to so-called secondary point-to-multipoint connectivity on the basis of at least one indicator of operation of the point-to-point connection to obtain a double adduction of the client.

The invention further relates to a multi-port optical line termination device for an optical access network, intended to be connected to a point-to-point optical network unit via a first port for conveying data from a first client in point-to-point connectivity, intended to be connected to a plurality of point-to-point optical network units via a second port for transmitting data from a plurality of second clients including the first client in point-to-multipoint connectivity. This device is adapted to switch the routing of data from the first client according to point-to-point connectivity to routing according to point-multipoint connectivity based on at least a first indicator of operation of the point-to-point connectivity.

Thus, according to the invention, in the event of failure of the primary point-to-point connection, the customer can advantageously be served via the secondary point-multipoint connection. The client is connected primarily using point-to-point connectivity and, as a backup, using point-to-multipoint connectivity. The connection via the secondary point-to-point connection thus provides a backup mode for the primary point-to-point connection. Switching between the two modes can occur via a switch between the two types of connectivity depending on the performance of the primary point-to-point connection. A port of the OLT connected to a primary point-to-point connection is thus backed up by another port of the OLT connected to a secondary point-to-point connection.

According to one embodiment of the invention, the at least first operating indicator is a performance indicator relating to an Ethernet type data routing protocol.

According to one embodiment of the invention, the at least first operating indicator relates to a so-called physical data transmission protocol layer.

According to one embodiment, the invention further comprises a second switching of the routing of client data according to secondary point-multipoint connectivity to routing according to primary point-to-point connectivity, based on at least a second indicator of operation of the point-to-point connection.

According to this mode, in the event of a return to satisfactory operation of the primary point-to-point connection, the data flow is switched from routing via the secondary point-to-point connection to routing via the primary point-to-point connection. The operating indicator taken into account to decide on the switchover is typically associated with the performance of the primary point-to-point connection. The operational indicator helps ensure that connectivity can be reestablished via the primary point-to-point connection.

According to one embodiment, the same operating indicator is used for the first switchover and the second switchover.

According to one embodiment, the invention further comprises:

• routing the data of the plurality of second clients based on a data classification, a point-to-point connection setting and a point-to-point connection setting.

According to this mode, the data intended for the second client is routed by means of point-multipoint backup connectivity taking into account a classification of the traffic of the second clients established in particular according to a priority indicator between the second clients. Thus, by respecting the respective priorities between these second clients, the impact of the routing of the data of the second client on the remaining throughput for the routing of the data of the second clients other than this second client is limited and controlled.

According to one embodiment of the invention, the point-to-multipoint connection connects the second port of the optical line termination device to a plurality of point-to-multipoint optical network units to route data from the plurality of second clients, routing data from the plurality of second clients other than the client being independent of the routing selector connected to the client.

According to this mode, the second port of the OLT can be solely dedicated to protecting a plurality of point-to-point connections to the plurality of second customers or can be used to serve a residential market with residential customers while having at at least one point-multipoint optical network unit dedicated to supporting at least one point-to-point connectivity.

According to one embodiment, an optical line termination device according to the invention further comprises a data routing selector and a microprocessor for controlling the routing selector to switch the routing of the data of the first client depending on the connectivity point-to-point to routing according to point-to-multipoint connectivity based on the first operational indicator.

List of Figures

Other characteristics and advantages of the invention will appear more clearly on reading the following description of embodiments, given by way of simple illustrative and non-limiting examples, and the appended drawings, among which:

there already described in relation to the prior art, is a ^first diagram of an optical access network,

there already described in relation to the prior art, is a ^2nd diagram of an optical access network,

there is a flowchart of one embodiment of a routing method according to the invention,

there is a diagram of a first embodiment of the invention,

there is a diagram of a second embodiment of the invention,

there is a diagram of OLT optical termination equipment according to the invention,

there is a diagram of ONU equipment according to the invention.

Description of particular embodiments

A flowchart of one embodiment of a routing method according to the invention is illustrated by the .

An implementation of the invention requires distinguishing a first connectable client as well as a plurality of second potential connectable clients. Among this plurality, at least one second client is identified.

The data routing method 10 according to the invention is intended to be implemented by multi-port OLT optical termination equipment or by ONU equipment comprising a PON ONU unit and a PtP ONU unit of a network of optical access. This optical access network includes at least the OLT optical line termination device, a point-to-point connection and a point-to-multipoint connection.

The point-to-point connection is made between a first port of the optical line termination device OLT and a point-to-point optical network unit ONU PtP. This connection allows point-to-point connectivity of the first client.

The point-to-multipoint connection is made between a second port of the OLT and at least one ONU PON point-to-multipoint optical network unit. This connection allows point-to-multipoint connectivity of the plurality of second clients.

An ONU PON or ONU PtP optical network unit designates “client” equipment, that is to say installed at the client or very close to this client.

The routing method 10 comprises:

• the routing 11 of Data data intended for the first client according to point-to-point connectivity,
• routing 12 of data intended for the second client according to point-multipoint connectivity.

The quality of the point-to-point connection is controlled by monitoring a first operating indicator IndicPtP. This first operating indicator IndicPtP may be an indicator associated with the physical layer or with another layer. The link with the physical layer can be direct and relative to the optical reception/transmission element (optical transceiver). For example, the indicator can reflect the optical power of the data received, RSSI (Received Signal Strength Indication) either by the OLT or by an ONU unit and possibly reported to the OLT. This first IndicPtP operating indicator can be a performance indicator.

The IndicPtP operating indicator is retrieved for example by a control body. This control body compares the indicator to a threshold. As long as threshold S is not crossed, output branch N of test 13, there is no switchover and routing 11 continues with the primary point-to-point link. When the threshold S is crossed, output branch Y of the test, the routing switches over. Thus, the routing 11 of data intended for the first client according to the so-called primary point-to-point connectivity is switched to a routing 12 according to the so-called secondary point-to-multipoint connectivity when this first client, then identified as a second client, is also served via a point-to-multipoint connection.

According to the implementation of the invention, the first customer and the second customer form only one customer i.e. the first customer benefits from a double supply thanks to a multipoint point connection which ensures a very strong improvement in reliability of its connectivity via the optical access network.

In the case of a performance indicator, it may relate to an Ethernet type data routing protocol. This indicator can be based on so-called OAM (Operations, Administration and Management) data at the Ethernet level. Thus, such an indicator can allow the detection of a LOC (Lack Of Continuity) loss of link continuity, or the detection of a LOS (Lack Of Signal) loss of the received signal, or the detection of a LOF loss ( Lack Of Frame) of frames received. Test 13 may consist in these cases of examining a change in state of the performance indicator or of comparing a loss counter observed over a given period of time to a threshold. When the change of state occurs or when the threshold S is crossed, test output branch Y, the switchover takes place.

The threshold value is part of the configuration of the PtP link to be backed up.

According to one embodiment, the switching of the routing follows or is concomitant with the triggering of an alarm linked to the test. The alarm can be used for the OLT to wake up the ONU PON unit in case it is in a sleep state.

According to one embodiment, the OLT activates the bidirectional OLT – ONU PON link which constitutes the secondary point-to-multipoint link using network parameters (addressing, quality of service, etc.) linked to the configuration of the primary point-to-point PtP link. These parameters must also take into account the other clients (plurality of second clients) of this point multipoint link. These parameters are dependent on the configuration of each multipoint link of this point multipoint link. Thus, depending on the respective parameters of the multipoint links of this multipoint link, a prioritization is defined between the different flows of the different second clients to flow the traffic between the OLT and the ONU PON unit. For example, the prioritization between flows takes into account the priorities between the recipient IP or MAC addresses (of the plurality of second clients) as well as a marking (tag) of the flows which reflects a QoS level assigned to these flows.

After the switchover, the method 10 includes monitoring 14 of a second operating indicator of the primary point-to-point link to detect the restoration of the proper functioning of this link. According to one embodiment, this second indicator is identical to the first operating indicator IndicPtP. Thus, the criterion for switching from the primary link to the secondary link and from the secondary link to the primary link is identical, which simplifies the implementation of the invention. When the threshold S is crossed, output branch N of test 14, there is a new switchover of the routing. Thus, routing 12 of data intended for the first client according to so-called secondary point-multipoint connectivity according to a backup mode is switched to routing 11 according to so-called primary point-to-point connectivity. As long as threshold S is not crossed, output branch Y of test 14, there is no new switchover and routing 12 continues with the secondary multipoint point link.

After the new switchover, that is to say when the operation of the primary link again satisfies the criterion (threshold), the client flow is again sent via the point-to-point link. The ONU PON unit can then release the monopolized resources for activation of the secondary link. More particularly the bidirectional OLT-ONU PON link ensuring the secondary link can be released and this ONU PON unit can be put on standby if it does not serve any client other than the first client.

A first mode of implementation of the invention is illustrated by the . According to this mode, the optical access network 20 comprises at least one optical line termination device OLT, a point-to-point connection and a point-to-multipoint connection.

The point-to-point connection is made between a first port of the OLT and a point-to-point optical network unit ONU PtP to convey data intended for a first client according to point-to-point connectivity.

The point-to-multipoint connection is provided between a second port of the OLT and a plurality of ONU PON point-to-multipoint optical network units to carry data for a plurality of second clients according to point-to-multipoint connectivity. This plurality of ONU PON point-multipoint optical network units includes at least one ONU PON point-multipoint optical network unit for a second client, the at least second client of the plurality of second clients.

The invention is placed in the context where the first client and the second client form only one client.

The access network is particular in that it also includes a routing selector which can be embedded in a SW gateway (cell site gateway/Switch). The routing selector is connected to the client, the ONU PtP point-to-point optical network unit and the ONU PON point-to-multipoint optical network unit. This selector allows you to switch the routing of data intended for the client according to so-called primary point-to-point connectivity to routing according to so-called secondary point-multipoint connectivity to obtain a double adduction of the client. This switchover is carried out in accordance with the method previously described.

According to one embodiment, the access network includes a second routing selector embedded in the OLT. This second selector makes it possible to switch at the OLT level the routing of data intended for the client according to so-called primary point-to-point connectivity to routing according to so-called secondary point-multipoint connectivity to obtain a double adduction of the client. This switchover is carried out in accordance with the method previously described.

Depending on a particular deployment, the customer can correspond to a site hosting a base station. Such a base station requires very high connectivity reliability. Protection of the point-to-point link by a multi-point point link makes it possible to achieve a satisfactory level of reliability with much lower costs than with protection obtained via a second point-to-point link.

According to the mode illustrated by , the point-multipoint link is dedicated solely to supporting point-to-point links. Such a mode provides a single backup solution for several point-to-point links and limits the need for ports in active equipment such as OLT and PON ONU units. Such a mode is particularly suitable for professional customers whose connectivity requirements are very high.

A second mode of implementation of the invention is illustrated by the . Unlike the mode illustrated by , the point-multipoint link is not only dedicated to supporting point-to-point links. Thus, according to this second mode, the point-to-point link is also used as a primary link for a plurality of second clients who are not served by a point-to-point link but only by this point-to-multipoint link. These second customers typically belong to the residential market which is less demanding in terms of reliability than the professional market. According to this mode, one or more ONU PON units can be dedicated to the protection of point-to-point links. Thus, the point-multipoint link can simultaneously provide connectivity for residential customers and backup connectivity for generally professional customers since they also benefit from a point-to-point link.

There is a diagram of OLT equipment according to the invention.

The OLT equipment includes one or more optical PON Card cards, PtP Cards, each with one or more optical ports as well as a SEL_OLT selector for Data intended for a customer or coming from a customer. For a given optical port of a card, this card comprises at least one Mux/Demux multiplexer-demultiplexer of upstream and downstream streams, an Rx receiver of uplink data coming from a client and a Tx transmitter of downlink data to be transmitted to a customer.

The OLT is intended to be connected to an ONU PtP point-to-point optical network unit via a first port and a first optical fiber to convey data intended for or originating from a first client according to point-to-point connectivity c_PtP . The OLT is further intended to be connected to a plurality of ONU PON point-multipoint optical network units via a second port to transmit data intended for a plurality of second clients including the first client or from these second clients according to a c_PtMP point-to-multipoint connectivity.

The OLT equipment further comprises a microprocessor µP or equivalent such as a microprogrammed electronic component whose operation is controlled by the execution of a program Pg whose instructions allow the implementation of a routing method according to the invention . The program Pg is for example stored in a memory MEM.

The microprocessor µP controls the routing selector SEL_OLT as well as at least the different components associated with a given optical port via control signals: the Rx receiver, the Tx transmitter, the Mux/Demux multiplexer/demultiplexer. The microprocessor µP remotely controls the ONU units via an exchange protocol which is generally transmitted in the transmitted frames (so-called In band protocol). The microprocessor µP receives from the Rx receiver or the Tx transmitter a local indicator IndicPtP of operation of the point-to-point connectivity c_PtP. This operating indicator is, according to one embodiment, an RSSI optical power indicator received at the OLT. According to one embodiment, a remote operation indicator of the PtP link comes back from the PtP ONU unit.

By executing instructions from the Pg program, the microprocessor µP toggles the routing selector SEL_OLT according to the value of the local and/or remote IndicPtP operating indicator. Thus, when this indicator, depending on its nature, changes state or passes a threshold, the (descending) data intended for the client and routed according to the so-called primary point-to-point connectivity are routed (routed) after switching according to the point connectivity. so-called secondary multipoints. The (upstream) data coming from the client is routed using the same connectivity as the downstream data. When the operation indicator of the rescued point-to-point link indicates that this link has returned to acceptable operation, data routing is again carried out via this link.

According to one embodiment of the OLT, the SEL_OLT selector is essentially implemented functionally by exploiting the destination or origin address of the data i.e. if this address corresponds to that of the client whose point-to-point link must be rescued this data is routed via the multipoint point link.

There is a diagram of one embodiment of ONU equipment according to the invention. Each ONU PtP unit, respectively ONU PON can be implemented in the form of an interface between a domestic or professional gateway (gateway) and the optical fiber which is involved in point-to-point or point-multipoint connectivity. Each of the interfaces can be part of this gateway or be incorporated into a specific box.

According to one embodiment, the ONU equipment brings together the two units ONU PtP and ONU PON. Such grouping can be advantageous for reducing the cost and energy consumption of the emergency solution according to the invention. The functional blocks of this ONU equipment intervening for the two point-to-point PtP and point-multipoint PtMP links are represented on the . Among these blocks, the PMD PtP and PMD PtMP PON blocks include the optoelectronic components including the optical transmitters and receivers for interconnection with each of the two optical fibers.

The ONU equipment also includes a storage space or MEM memory and a SEL_CLI routing selector.

The ONU equipment further comprises a calculation unit such as a microprocessor µP or equivalent such as a microprogrammed electronic component whose operation is controlled by the execution of a program Pg whose instructions allow the implementation of a method of routing according to the invention. The program Pg is for example stored in the memory MEM.

The first optical fiber i.e. of the PtP point-to-point link connects the ONU equipment to a PtP port of the OLT. The second optical fiber i.e. of the PtMP multipoint point link connects the ONU equipment to a PtMP port of the OLT via an S/C splitter/combiner.

Each implemented interface corresponding to one of the ONU PtP and ONU PON units must include several protocol layers:

• a physical layer (PHY layer) with, for a PtP point-to-point link or for a multi-point point link conforming to an IEEE standard, the three sub-layers:

• PMD Physical Medium Dependent
• PMA Physical Medium Attachment
• PCS Physical Coding Sublayer

and with, for a point-to-multipoint link conforming to an ITU standard, the two sublayers:

• PMD Physical Medium Dependent
• TC Transmission Convergence

• a link layer (data link) for physical addressing with the MAC (Medium Access Control) and LLC (Logical Link Control) sublayers
• a network layer that determines routing and logical addressing.

The functions corresponding to these protocol layers can be stored in the MEM memory in the form of specific program instructions and data and/or parameters. Thus, the execution by the microprocessor µP of these specific instructions makes it possible to activate the protocol layers necessary for the implementation of the PtP point-to-point link and/or the PtMP point-multipoint link.

By executing specific instructions of the Pg program, the microprocessor µP toggles the SEL_CLI routing selector according to the value of the local or remote IndicPtP operating indicator transmitted by the OLT. Thus, when this indicator, depending on its nature, changes state or passes a threshold, the (descending) data intended for the client and routed according to the so-called primary point-to-point connectivity are routed (routed) after switching according to the point connectivity. so-called secondary multipoints. The (upstream) data coming from the client is routed using the same connectivity as the downstream data. When the operation indicator of the rescued point-to-point link indicates that this link has returned to acceptable operation, data routing is again carried out via this link.

According to one embodiment, the microprocessor µP also takes into account an operating indicator IndicPtMP of the multipoint link to decide on the switching of the routing. According to this mode, switching cannot take place until the IndicPtMP operating indicator indicates satisfactory operation of the point-multipoint link.

The switchover is accompanied by the activation of the protocol layers necessary for the selected routing link.

According to one embodiment of the ONU equipment, the SEL_CLI selector is essentially implemented functionally, by exploiting the destination or origin address of the data i.e. if this address corresponds to that of the client whose point-to-point link must be rescued this data is routed via the multipoint link.

According to one embodiment, the implementation process on the ONU equipment side is as follows.

In an initial state, the ONU equipment is connected to the OLT via the two fibers, only the primary point-to-point link is active to flow traffic and the ONU equipment is configured with the associated protocol layers. The PMD PtP and PMD PtMP PON blocks are powered even if data is only flowed with the point-to-point link. This in fact allows the microprocessor µP of the ONU equipment to be able to recover information not only on the state of the point-to-point link but also on the state of the PtMP point-multipoint link thanks to the reception of the downlink optical signal even if the latter does not transport data (Data). Indeed, when the operating indicator IndicPtP, respectively IndicPtMP, corresponds to the RSSI then its value indicates whether the physical link PtP, respectively PtMP, is well connected to the corresponding port of the OLT.

When the state of the PtP link deteriorates and the IndicPtP operating indicator passes a threshold or changes state then the microprocessor µP controls the switching of the routing selector SEL_CLI to backup the PtP link with the PtMP link and executes the specific instructions associated with the functions corresponding to the protocol layers of this PtMP backup link.

According to one embodiment, an exchange of control takes place with the OLT for the registration of the client in association with the backup link before the data flow intended for the client is actually routed via the backup link.

When the state of the PtP link improves and the IndicPtP operating indicator returns to the threshold or changes state then the microprocessor µP commands the switching of the routing selector SEL_CLI to resume routing of the data flow via the PtP link and executes the specific instructions associated with the functions corresponding to the protocol layers of this PtP link.

Thus, the invention further relates to a computer program on an information medium, this program comprising program instructions adapted to the implementation of a method according to the invention when said program is loaded and executed in an OLT optical line termination device.

And, the invention further relates to an information medium comprising program instructions adapted to the implementation of a method according to the invention, when this program is loaded and executed in an optical line termination device OLT.

Claims (13)

Method (10) for routing data (Data) intended to be implemented by an optical access network comprising at least one optical line termination device (OLT) with several ports, a point-to-point connection between a first port of the optical line terminator (OLT) and a point-to-point optical network unit (ONU PtP) enabling point-to-point connectivity of a first client and point-to-multipoint connection between a second port of the line terminator optical network (OLT) and at least one optical point multipoint network unit (ONU PON) allowing point multipoint connectivity of a plurality of second clients comprising at least one second client, comprising:

• routing (11) of data from the first client according to point-to-point connectivity,
• routing (12) of data from the second client according to point-to-multipoint connectivity and

characterized in that it further comprises, the first client and the second client forming only one client:

• a first switchover (13, Y) from the routing of client data according to so-called primary point-to-point connectivity to routing according to so-called secondary point-to-multipoint connectivity, based (13) on at least one first operating indicator (indicPtP) point-to-point connection to obtain a double supply of the customer.

Method (10) according to claim 1, according to which the at least first indicator (IndicPtP, LOC, LOS, LOF) of operation is a performance indicator relating to an Ethernet type data routing protocol. Method (10) according to claim 1, according to which the at least first operating indicator (IndicPtP, RSSI) relates to a so-called physical data transmission protocol layer. Method (10) according to one of claims 1 to 3, further comprising:

• a second switching (14, N) of the routing of client data according to secondary point-to-point connectivity to routing according to primary point-to-point connectivity, based (14) on at least a second operating indicator (IndicPtP) of the connection point to point.

Method (10) according to claim 4, according to which the same operating indicator is used for the first switchover and the second switchover. Method (10) according to one of claims 1 to 5, further comprising:

• routing data from the plurality of second clients based on data classification, point-to-point connection setting and point-to-point connection setting.

Optical access network (20) comprising at least one optical line terminator (OLT), a point-to-point connection between a first port of the optical line terminator (OLT) and a point-to-point optical network unit (ONU PtP) for carrying data from a first client according to point-to-point connectivity, and a point-to-multipoint connection between a second port of the optical line termination (OLT) device and at least one point-to-multipoint optical network unit ( ONU PON) for routing data from a plurality of second clients comprising at least one second client according to point-to-multipoint connectivity, the access network being characterized in that it further comprises the first client and the at least second client forming only one client:

• a routing selector (SEL_CLI) connected to the client, the point-to-point optical network unit (ONU PtP) and the point-to-multipoint optical network unit (ONU PON) to switch the client's data routing according to so-called primary point-to-point connectivity to routing according to so-called secondary point-multipoint connectivity, on the basis of at least a first operating indicator (IndicPtP) of the point-to-point connection to obtain a double supply of the customer.

An optical access network (20) as claimed in claim 7, wherein the point-to-multipoint connection connects the second port of the optical line terminator (OLT) to a plurality of optical point-to-multipoint network (ONU PON) units to route the data of the plurality of second clients, the routing of the data of the plurality of second clients other than the client being independent of the routing selector connected to the client. Routing selector (SEL_CLI) for connection to a client, for connection to a point-to-point optical network unit (ONU PtP) for point-to-point connection between a first port of a line terminating device (OLT) of an optical access network and the client for carrying client data in point-to-point connectivity and intended to be connected to an optical point-multipoint network unit (ONU PON) for point-multipoint connection between a second port of the optical line termination device (OLT) and at least the client for routing the client's data according to point-multipoint connectivity, capable of switching a routing of the client's data according to the so-called primary point-to-point connectivity to a routing according to so-called secondary point-multipoint connectivity on the basis of at least one operating indicator (IndicPtP) of the point-to-point connection to obtain a double supply of the customer. A multi-port optical line termination (OLT) device for an optical access network for connection to a point-to-point optical network unit (ONU PtP) via a first port to carry data from a first client in point-to-point connectivity, for connection to a plurality of point-to-point optical network (ONU PON) units via a second port to transmit data from a plurality of second clients including the first client in point-to-point connectivity multipoint, adapted to switch the routing of data from the first client according to point-to-point connectivity to routing according to point-multipoint connectivity according to at least a first operating indicator (indicPtP) of the point-to-point connectivity. Optical line termination device (OLT) according to the preceding claim comprising a data routing selector (SEL_OLT) and a microprocessor (µP) for controlling the routing selector (SEL_OLT) to switch the routing of data from the first client according to point-to-point connectivity to routing according to point-to-point connectivity according to the first operational indicator (indicPtP). Computer program on an information carrier, said program comprising program instructions suitable for implementing a method according to any one of claims 1 to 6 when said program is loaded and executed in a terminating device optical line (OLT). Information carrier comprising program instructions adapted to the implementation of a method according to any one of claims 1 to 6, when said program is loaded and executed in an optical line termination device (OLT).