Abstract:
A DWDM network supporting first bit rate data streams, the DWDM network comprising a plurality of network hubs interfacing to subscriber line connections, and a core hub for providing cross connections between the network hubs, wherein each of the network hubs comprises a first bi-directional multiplexing unit arranged to multiplex n subscriber data streams each having a second bit rate which is substantially 1/nth of the first bit rate into a single first bit rate data stream for distribution on the DWDM network, and wherein the core hub comprises a plurality of second bi-directional multiplexing units each for de-multiplexing one of the single first bit rate data streams originating from the network hubs into the subscriber data streams and a switching unit arranged to selectively cross-connect the individual subscriber data streams back to individual ones of the second multiplexing units for distribution of the subscriber data streams to their respective destination network hubs in single first bit rate data streams each comprising n multiplexed subscriber data streams destined for the same network hub.

Description:
FIELD OF THE INVENTION  
         [0001]    The present invention relates broadly to a dense wavelength division multiplexing (DWDM) network and a method of distributing data on a DWDM network.  
         BACKGROUND OF THE INVENTION  
         [0002]    Individual subscribers of e.g. a metro dense wavelength division multiplexing (DWDM) network may each desire a connection whose bit rate is lower than the maximum bit rate supported by the individual DWDM channels of the network. In this case, greater efficiency may be achieved if multiple subscriber channels can be combined to utilise a single DWDM channel in the metro network.  
           [0003]    In designing a system that facilitates such sharing of the DWDM channel resources it must also be considered that the subscribers will need to communicate to different locations within the metro network, or may require to communicate via e.g. a long haul network to which the metro network is connected.  
           [0004]    At least preferred embodiments of the present invention seek to provide a method and apparatus for facilitating such connectivity in optical networks.  
         SUMMARY OF THE INVENTION  
         [0005]    In accordance with a first aspect of the present invention there is provided a DWDM network supporting first bit rate data streams, the DWDM network comprising a plurality of network hubs interfacing to subscriber line connections and a core hub for providing cross connections between the network hubs, wherein each of the network hubs comprises a first bi-directional multiplexing unit arranged to multiplex n subscriber data streams each having a second bit rate which is substantially 1/nth of the first bit rate into a single first bit rate data stream for distribution on the DWDM network, and wherein the core hub comprises a plurality of second bi-directional multiplexing units each for de-multiplexing one of the single first bit rate data streams originating from the network hubs into the subscriber data streams and a switching unit arranged to selectively cross-connect the individual subscriber data streams back to individual ones of the second multiplexing units for distribution of the subscriber data streams to their respective destination network hubs in single first bit rate data streams each comprising n multiplexed subscriber data streams destined for the same network hub.  
           [0006]    In a preferred embodiment, the subscriber data streams are 1 Gbit/s Gigabit Ethernet (GbE) data streams, and the first bit rate data streams are 2.488 Gbit/s SONET/SDH (OC48) data streams.  
           [0007]    Each of the first and second multiplexing unit may comprise a 2×GbE/OC48 Packet Over SONET (POS) multiplexer unit.  
           [0008]    In another embodiment, each multiplexing unit may comprise a SONET time division multiplexing (TDM) multiplexer unit. Advantageously, the SONET TDM multiplexer units are arranged, in use, to first decode 1.25 Gbit/s 8b/10b encoded GbE streams to produce two 1 Gbit/s streams, and to then multiplex the two 1 Gbit/s streams into SONET Virtual Containers. Alternatively, the SONET TDM multiplexer units may be arranged, in use, to first decode the 1.25 Gbit/s 8b/10b encoded GbE streams to produce two 1 Gbit/s streams, and to then multiplex the two  1  Gbit/s streams into a SONET frame in alternate time slots. In such an embodiment, the SONET TDM multiplexer units are preferably arranged in a manner such that, in use, additional filler bytes are being inserted to match to the capacity of the SONET frame.  
           [0009]    The SONET TDM multiplexer units may further be arranged in a manner such that, in use, the decoded GbE streams are being re-encoded utilising a 5b/6b line code to produce 1.2 Gbit/s streams, before employing the multiplexing into the 2.488 Gbit/s OC 48 data streams.  
           [0010]    Each of the first and second multiplexing units advantageously comprises a tagging unit for tagging each incoming subscriber data stream, and for allocating a wavelength to each outgoing subscriber data stream based on tags on the incoming first bit rate data stream.  
           [0011]    The first and/or second multiplexing units may each comprise a uni-directional multiplexing sub-unit and a uni-directional de-multiplexing sub-unit.  
           [0012]    Preferably, each of the first multiplexing units and/or the second multiplexing units is incorporated in a Trunk Interface Card interfacing to the DWDM network.  
           [0013]    The switching unit may further be arranged, in use, to selectively cross connect any m subscriber data streams originating from one or more of the network hubs of the DWDM network destined for any same one of a plurality of other network elements on a second network supporting third bit rate data steams, which are substantially a multiple m of the first bit rate, to one of a plurality of third multiplexing units of the core hub for multiplexing into a single third bit rate data stream for distribution to the same other network element.  
           [0014]    The third bit rate may be substantially equal to the first bit rate. Preferably, the third bit rate data streams are 2.488 Gbit/s OC48 data streams.  
           [0015]    In accordance with a second aspect of the present invention there is provided a core hub for providing cross connections between network hubs interfacing to subscriber line connections, the core hub comprising a plurality of bi-directional multiplexing units each for de-multiplexing one first bit rate data stream originating from one of the network hubs into n subscriber data streams having a bit rate which is substantially 1/nth of the first bit rate, and a switching unit arranged to selectively cross-connect the individual subscriber data streams back to individual ones of the multiplexing units for distribution of the subscriber data streams to their respective destination network hubs in single first bit rate data streams each comprising n multiplexed subscriber data streams destined for the same network hub.  
           [0016]    In a preferred embodiment, the subscriber data streams are 1 Gbit/s Gigabit Ethernet (GbE) data streams, and the first bit rate data streams are 2.488 Gbit/s SONET/SDH (OC48) data streams.  
           [0017]    Each of the multiplexing units advantageously comprises a tagging unit for tagging each incoming subscriber data stream, and for allocating a wavelength to each outgoing subscriber data stream based on tags on the incoming first bit rate data stream.  
           [0018]    The multiplexing units may each comprise a unidirectional multiplexing sub-unit and a uni-directional de-multiplexing sub-unit.  
           [0019]    Preferably, each of the multiplexing units is incorporated in a Trunk Interface Card interfacing to the DWDM network.  
           [0020]    The switching unit may further be arranged, in use, to selectively cross connect any m subscriber data streams originating from one or more of the network hubs of the DWDM network destined for any same one of a plurality of other network elements on a second network supporting third bit rate data steams, which are substantially a multiple m of the first bit rate, to one of a plurality of third multiplexing units of the core hub for multiplexing into a single third bit rate data stream for distribution to the same other network element.  
           [0021]    The third bit rate may be substantially equal to the first bit rate. Preferably, the third bit rate data streams are 2.488 Gbit/s OC48 data streams.  
           [0022]    In accordance with a third aspect of the present invention there is provided method of distributing data on a DWDM network supporting first bit rate data streams, the DWDM network comprising a plurality of network hubs interfacing to subscriber line connections and a core hub for providing cross connections between the network hubs, the method comprising the steps of at each network hub multiplexing n subscriber data streams each having a second bit rate which is substantially 1/nth of the first bit rate into a single first bit rate data stream for distribution on the DWDM network, at the core hub de-multiplexing the single first bit rate data streams originating from the network hubs into the subscriber data streams, multiplexing any n subscriber data streams into a single first bit rate data stream for distribution to a same one of the network hubs.  
           [0023]    In a preferred embodiment, the subscriber data streams are 1 Gbit/s Gigabit Ethernet (GbE) data streams, and the first bit rate data streams are 2.488 Gbit/s SONET/SDH (OC48) data streams.  
           [0024]    The method advantageously comprises the steps of at the network hubs and the core hub tagging each incoming subscriber data stream, and allocating a wavelength to each outgoing subscriber data stream based on tags on the incoming first bit rate data stream.  
           [0025]    The method may further comprise the steps of at the core hub selectively cross connecting any m subscriber data streams originating from one or more of the network hubs of the DWDM network destined for any same one of a plurality of other network elements on a second network supporting third bit rate data steams, which are substantially a multiple m of the first bit rate, to one of a plurality of third multiplexing units of the core hub for multiplexing into a single third bit rate data stream for distribution to the same other network element.  
           [0026]    The third bit rate may be substantially equal to the first bit rate. Preferably, the third bit rate data streams are 2.488 Gbit/s OC48 data streams. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0027]    Preferred forms of the present invention will now be described, by way of example only, with reference to the accompanying drawings.  
         [0028]    [0028]FIG. 1 is a schematic drawing illustrating the connectivity in a metro ring network between two metro hubs and a core hub.  
         [0029]    [0029]FIG. 2 is a schematic drawing illustrating an OC48/2×GbE Integrated Trunk and Line Interface Card embodying the present invention.  
         [0030]    [0030]FIG. 3 is a schematic drawing illustrating the main functional components of an OC48/2×GbE Multiplexing Unit.  
         [0031]    [0031]FIG. 4 is a schematic drawing illustrating a core hub structure embodying the present invention.  
         [0032]    [0032]FIG. 5 is a schematic drawing illustrating an OC48/2×GbE Trunk Interface Card embodying the present invention.  
         [0033]    [0033]FIG. 6 is a functional block diagram of a metro hub structure corresponding to the metro hubs of FIG. 1. 
     
    
     DETAILED DESCRIPTION OF THE EMBODIMENTS  
       [0034]    The preferred embodiment described provides a DWDM network in which each DWDM channel carries a single 2.488 Gbit/s OC48 data stream which comprises two 1 Gbit/s GbE subscriber data streams, thereby reducing DWDM channel resource requirements or, in other words, increasing the number of subscriber lines per number of DWDM channels.  
         [0035]    [0035]FIG. 1 shows an exemplary configuration of a metro DWDM network  900  embodying the present invention. The DWDM network  900  comprises a core hub  902 , described in more detail below with reference to FIG. 4, and a plurality of metro hubs, exemplary metro hubs  904 ,  906  being shown in FIG. 1. Each of the metro hubs  904 ,  906  has two subscriber GbE connections,  908  and  910  connected to the first metro hub  904 , and  912  and  914  connected to the second metro hub  906 . Each pair of subscriber GbE connections e.g.  908 ,  910  is interfaced to the metro DWDM network  900  via an OC48/2×GbE integrated Trunk and Line Card (TLC) e.g.  915 , to be described in more detail below with reference to FIG. 2. Each OC48/2×GbE TLC, e.g.  915 , multiplexes two GbE streams onto a single OC48 DWDM channel e.g.  916 . Accordingly, the connections between the metro hubs e.g.  904  and the core hub  902  of the metro DWDM network  620  are provided via 2.488 Gb/s DWDM channel connections e.g.  916 .  
         [0036]    In the exemplary case shown in FIG. 1, a first GbE channel  908  and a second GbE channel  910  are combined at the first metro hub  904  to form a first OC48 channel  916 . Additionally, a third GbE channel  912  and a fourth GbE channel  914  are combined at the second metro hub  906  to form a second OC48 channel  918 . The two OC48 channels  916 ,  918  are transmitted to the core hub  902  where they are received on OC48/2×GbE Trunk Interface Card (TIC) units  920 . The OC48/2×GbE TIC&#39;s  920  demultiplex the OC48 channels into their component GbE channels for switching in the cross-connect switch  922 . Any individual GbE channel may be switched either to one of the OC48/2×GbE Line Interface Cards (LIC&#39;s)  924 , or to one of the OC48/2×GbE TIC&#39;s  920 , where it may be multiplexed along with a second independent GbE channel into a single 2.488 Gb/s OC48 channel interconnected to the core network via a short-haul connection e.g.  926 , or to a metro hub via a DWDM connection e.g.  918 .  
         [0037]    Accordingly a system is provided wherein individual GbE channels e.g.  908  may be independently interconnected within the metro DWDM network  900 , or across the core network (not shown) while utilising only 2.488 Gb/s OC48 channels for transmission.  
         [0038]    [0038]FIG. 2 shows the structure  1000  of an OC48/2×GbE TLC e.g.  915  in the form of a functional block diagram. A full duplex DWDM 2.488 Gb/s OC48 stream  1002  is connected from the metro DWDM network  900  (FIG. 1) to a DWDM transceiver  1004 . The transceiver  1004  may comprise a broadband receiver such as e.g. a semiconductor PI detector, to receive the incoming OC48 channel. The transceiver  1004  may further comprise a suitable single-frequency DWDM laser for transmission of the outgoing DWDM 2.488 Gb/s OC48 signal into the network via the DWDM Ring Interface (not shown). Depending upon factors such as, e.g. the maximum transmission distance, this laser may be a relatively low-cost device, such as a directly modulated, temperature-stabilised distributed feedback (DFB) semiconductor laser. Alternatively the laser may be a more costly, higher-performance device, such as a DFB semiconductor laser incorporating an integrated external electro-absorption modulator (DFB-EA), and active wavelength stabilisation, in order to achieve longer transmission distance, or more closely spaced DWDM channels. In a further alternative embodiment, the DWDM laser source may be provided separately from the modulator.  
         [0039]    The DWDM transceiver  1004  is connected to an OC48/2×GbE multiplexing unit  1008  via an electronic switch  1006  and an electrical connection  1007 . The function of the switch  1006  is to enable the OC48 channel  1007  to be switched to the alternate path  1009  in the case of e.g. a failure of the DWDM transceiver  1004 . The alternate path  1009  may provide a connection to a cross-connect switch (not shown) via a short-haul optical transceiver  1010 . The switch, if present, may enable the OC48 channel to be connected to an optional alternate Trunk Interface Card (not shown), which may be provided for the purpose of channel protection. The OC48/2×GbE multiplexing unit  1008  is shown in more detail in FIG. 3.  
         [0040]    [0040]FIG. 3 shows a block diagram  400  of an exemplary embodiment of an OC48/2×GbE multiplexing unit e.g.  314 , based on an application note provided in the product literature for the PMC-Sierra PM3386 S/UNI®-2×GE Dual Gigabit Ethernet Controller. The multiplexing unit  400  comprises three main components, being a dual Gigabit Ethernet controller  406 , interface logic  416 , and a 2.488 Gb/s SONET/SDH user network interface device  426 . The dual Gigabit Ethernet controller  406  may comprise e.g. a PMC-Sierra PM3386 S/UNI®-2×GE Dual Gigabit Ethernet Controller integrated circuit (IC). The interface logic  416  may be implemented using e.g. a field programmable gate array (FPGA) device. The 2.488 Gb/s SONET/SDH user network interface device  426  may comprise e.g. a PMC-Sierra PM5381 S/UNI® SATURN® User Network Interface IC. It will be appreciated by a person skilled in the art that another chip-set may be used, e.g. a chip set that could provide a choice between 2×GbE/OC48 grooming and 4×OC12.OC48 grooming.  
         [0041]    The dual Gigabit Ethernet controller  406  includes a serialiser/deserialiser unit  408  for converting the two GbE streams  402 ,  404  between serial and parallel formats. The dual Gigabit Ethernet controller  406  further includes a dual GbE Medium Access Control (MAC) unit for transmitting and receiving GbE packets on the two GbE streams  402 ,  404 . The dual Gigabit Ethernet controller  406  further includes a Packet-Over-SONET Physical layer (POS-PHY) level 3 (PL3) Slave unit  412  for transmitting and receiving packets over the standard PL3 channel  414 . The dual Gigabit Ethernet controller  406  further provides an in-band addressing function that enables the source port of each packet to be identified.  
         [0042]    The interface logic  416  includes two PL3 Master units  418 ,  422  for transmitting and receiving packets on the two standard PL3 channels  414 ,  424  connected to the dual Gigabit Ethernet controller  406  and the 2.488 Gb/s SONET/SDH user network interface device  426 . The interface logic further includes a buffering and processing functional unit  420 , that provides a first-in first-out (FIFO) buffer function for data passing between the dual Gigabit Ethernet controller  406  and the SONET/SDH user network interface device  426 . The buffering and processing functional unit  420  further provides an Ethernet over SONET/SDH (EOS) processing function. The EOS processing function may use the in-band addressing function of the Dual Gigabit Ethernet controller  406  to tag packets and ensure that they exit by the correct GbE port at the destination network element.  
         [0043]    The 2.488 Gbit/s SONET/SDH user network interface device  426  includes a PL3 Slave unit  428  for transmitting and receiving packets over the standard PL 3  channel  424 . The user network interface device  426  further includes a SONET/SDH processing unit that provides SONET/SDH framing and path overhead functionality. The user network interface device  426  further includes a serialiser/deserialiser unit  432  for converting the 2.488 Gbit/s SONET/SDH stream  434  between parallel and serial formats.  
         [0044]    Returning now to FIG. 2, the two GbE channels  1012 ,  1014  of the OC48/2×GbE multiplexing unit  1008  are further connected to line interfaces comprising optical transceivers  1016 ,  1018 . The optical transceivers  1016 ,  1018  may comprise e.g. 850 nm multimode GbE optical transceivers. The line interfaces may be connected to subscriber equipment via optical fibre connections (not shown).  
         [0045]    In FIG. 4, an arrangement  700  for the core hub  902  (FIG. 1) is illustrated. The arrangement  700  comprises a plurality of OC48/2×GbE TIC e.g.  702 . Each OC48/2×GbE TIC e.g.  702  is connected to a single 2.488 Gb/s OC48 DWDM channel e.g.  704 , comprising two GbE channels multiplexed as described above with reference to FIG. 3. Accordingly, the core hub  700  is now able to service the same number of GbE channels from the metro DWDM network  706  while utilising only half the number of DWDM connections as a DWDM network supporting only unmultiplexed GbE channels. Alternatively, up to twice the original number of GbE channels may be supported in the metro DWDM network  706  by utilising the same number of DWDM connections, with each connection comprising a 2.488 Gb/s OC48 channel carrying two multiplexed GbE channels.  
         [0046]    [0046]FIG. 5 shows the structure  800  of an OC48/2×GbE TIC e.g.  702  in the form of a functional block diagram. A full duplex DWDM 2.488 Gb/s OC48 stream  802  is connected from the DWDM network  706  (FIG. 4) to a DWDM transceiver  804 . The transceiver  804  may comprise a broadband receiver such as e.g. a semiconductor PIN detector, to receive the incoming OC48 channel. The transceiver  804  may further comprise a suitable single-frequency DWDM laser for transmission of the outgoing DWDM 2.488 Gb/s OC48 signal into the network via the DWDM Ring Interface e.g  716  (FIG. 4). Depending upon factors such as, e.g. the maximum transmission distance, this laser may be a relatively low-cost device, such as a directly modulated, temperature-stabilised distributed feedback (DFB) semiconductor laser. Alternatively the laser may be a more costly, higher-performance device, such as a DFB semiconductor laser incorporating an integrated external electro-absorption modulator (DFB-EA), and active wavelength stabilisation, in order to achieve longer transmission distance, or more closely spaced DWDM channels. In a further alternative embodiment, the DWDM laser source may be provided separately from the modulator.  
         [0047]    The DWDM transceiver  804  is connected to an OC48/2×GbE multiplexing unit  808  via an electrical connection  806 . The OC48/2×GbE multiplexing unit  808  may comprise components as described previously with reference to FIG. 3. The two GbE channels of the OC48/2×GbE multiplexing unit  808  are further connected to electronic switches  810 ,  812  which switch the GbE streams to one of two pairs of paths i.e.  814 ,  816  or  818 ,  820 . Each pair of paths is connected in use to two ports on one of two redundant cross-connect switches e.g.  708 ,  710  (FIG. 4). The connections to the switches are via short-haul intra-office optical interconnects, e.g.  712 ,  713  or  714 ,  715  (FIG. 4). Thus the OC48/2×GbE TIC comprises four further intra-office optical transceivers  822 ,  824 ,  826 ,  828 . The intra-office optical transceivers may comprise e.g.  850  nm multimode GbE optical transceivers.  
         [0048]    [0048]FIG. 6 shows a functional block diagram  1100  of a metro hub structure required for deployment in the exemplary metro DWDM network  900  (FIG. 1). The DWDM Ring Interface  1102  includes a DWDM Multiplexer/Demultiplexer (MUX/DEMUX) Unit  1104 , a Coarse DWDM (CWDM) Unit  1106 , a Management Channel MUX/DEMUX  1108  and a Hub Bypass Switch  1110 . The Hub Bypass Switch  1110  provides the physical connection to the metro ring network, and enables the hub to be physically disconnected from the network. The Management MUX/DEMUX Unit  1108  is used to add and drop a single wavelength (at around 1510 nm in the exemplary embodiment) that is used as a network management channel. The data on the network management channel is processed by a Management Processing Unit  1114 , connected to a Management Channel Tx/Rx Unit  1112  that is used to transmit and receive the 1510 nm optical management channel. The CWDM Unit  1106  adds and drops a specific band of wavelengths corresponding to the 16 DWDM channels multiplexed by the DWDM Ring Interface  1102 , while expressing all other wavelengths back onto the metro DWDM network. The DWDM MUX/DEMUX Unit  1104  is used to multiplex and demultiplex the individual DWDM channels within this band. The DWDM MUX/DEMUX Unit  1104  is connected to the TLC&#39;s  1117  and/or optional TIC&#39;s  1116 , the optional Channel Switch  1118 , the optional Line Interface Cards  1120  and on to the subscribers&#39; equipment  1122 .  
         [0049]    If present, the optional LIC&#39;s  1120  may provide independent line interfaces to subscribers  1122 . If present, the optional TIC&#39;s  1116  may provide independent DWDM trunk interfaces to the metro DWDM network. In this case, the optional Channel Switch  1118  may provide reconfigurable connections between TIC&#39;s, LIC&#39;s and the protection path  1009  (FIG. 2) provided on each TLC. Accordingly, the full configuration provides a metro hub in which connections may be dynamically established between subscribers and the DWDM trunk connections of the metro DWDM network. Additionally, the full configuration may provide for protection against the failure of e.g. DWDM transceivers on the TLC&#39;s  1117  through the provision of spare TIC&#39;s  11   16 . In a minimal configuration, full connectivity without protection may be provided to subscribers  1122  via the TLC&#39;s  1117  at reduced cost, since the LIC&#39;s  1120 , Channel Switch  1118  and TIC&#39;s need not be deployed.  
         [0050]    It will be appreciated by a person skilled in the art that numerous variations and/or modifications may be made to the present invention as shown in the specific embodiments without departing from the spirit or scope of the invention as broadly described. The present embodiments are, therefore, to be considered in all respects to be illustrative and not restrictive.  
         [0051]    For example, the present invention is not limited to GbE into OC48 grooming, but may applied for other data streams, including 4×OC12 into OC48 or 16×OC3 into OC48.