The invention relates generally to network nodes.
Among the various issues that need to be taken into account in the deployment of the Next Generation Network, the clock processing of the Time Division Multiplexed (TDM) signals switched in the packet network nodes is one of the most crucial and critical ones.
Due to the nature of known packet network nodes (e.g. Ethernet) and in particular the non-constant traffic delay through their data switch fabrics there are a number of different synchronization problems that need to be addressed to match the node egress traffic quality requirements. In this regard, reference is made to International Telecommunications Union (ITU) G.707 “Network Node Interface for the Synchronous Digital Hierachy (SDH) and to ITU G.783 “Characteristics of Synchronous Digital Hierachy (SDH) Equipments Functional Blocks”.
Synchronization is required in telecommunication networks in order to meet network performance and availability requirements. Poor network synchronization will lead to large amounts of so-called jitter and wander. Jitter and wander can lead to transmission errors and buffer under/overflow. Both of those faults result in service problems causing high error rates and can lead to service unavailability. Synchronization in TDM networks is well understood and implemented. Typically, a TDM circuit service provider will maintain a timing distribution network, providing synchronization traceable to a Primary Reference Clock (i.e., clock compliance with ITU-T Recommendation G.811). By synchronisation we mean each unit of time of each system clock corresponds to the same, or substantially the same, unit of time as indicated by the reference clock. Network Synchronization requirements must therefore be carefully considered when networks are deployed.
Packet switching was originally introduced to handle asynchronous data. However, for more recent and future applications relating to TDM services the strict synchronization requirements of those applications must be considered. On the other hand, when the TDM services are carried over a packet network or only switched through packet network nodes data fabric switches some critical aspects arise. The so-called Packet Delay Variation (PDV) introduced by a packet network and/or by packet network nodes data fabric switches is one of the main problems that needs to be addressed. PDV comes about as a result of congestion, internal spreads and different flows passing through the fabric.
In the PSN bound direction the data interfaces can be required to be classified, policed, switched/routed, scheduled and so on, and the TDM interfaces can be required to be “Circuit Emulated”, i.e. segmented and encapsulated into data packets to the PSN network, or can be required to be TDM terminated in order to extract the embedded data payload (e.g. Ethernet) to be processed in the same way of the native data interfaces (e.g. classified, policed and so on).
In the PSTN bound direction the ingress data interfaces can be mapped into a TDM frame (e.g. Ethernet over SONET) and the TDM ingress interfaces can be monitored and cross-connected (switched). In this latter case of TDM ingress interfaces, TDM cross-connections and TDM egress interfaces to the PSTN network, the TDM requirements must be taken into account in the configuration of the edge node.
Whilst some hybrid systems comprise both a data switch fabric and a TDM switch fabric, state of the art data switching fabric equipment comprises a single high performance data switch fabric system able to switch all the different traffic types. This space and cost optimization allows maximization of the number of the traffic slots available in the physically constrained rack size and to obtain a cost-effective and more flexible equipment.
The expression ‘switch fabric’ is generally understood to include data processing equipment that is configured to move data coming into a network node (the ingress traffic) out by the correct port (i.e. egress traffic) to the next node in the network.
From the synchronization effects point of view one of the greatest differences between a typical TDM traffic switch fabric system and a data traffic switch data system is the fact that a TDM switch fabric is capable of performing all of the required cross-connection functions with a constant latency while the typical behaviour of a data traffic switch data system is characterized by a low, but non-zero, delay variation (i.e non-constant latency). From this point of view the requirement to have TDM egress interfaces in compliance with the international recommendations synchronization requirements (e.g. the ITU-T requirements) are in this case much more challenging and requires complex and expensive filtering and cleaning functions in the egress cards of the edge node to compensate or mitigate synchronisation impairments (i.e. variations in the data frequency) introduced by the data fabric.
Considering again the arrangement shown in
After a segmentation process is performed on the ingress traffic, the packetised traffic is cross-connected across the node by the switching fabric to an appropriate output card where it is then reassembled into TDM form for transmission to the PSTN network. This is the so-called SaR, or Segmentation and Reassembling, process, performed by the edge node, the different containers are each characterized by a respective ingress frequency modified by FDV of the switch fabric.
The task to clean or substantially eliminate this effect is significant and expensive but is nevertheless mandatory in order to meet the egress TDM (e.g. SDH STM-1) synchronization requirements; (in the example SDH case, for instance, the FDV contribution can cause undesired and unacceptable burst Vc pointer re-justification movements).
Considering the general position, an edge node has N TDM input interfaces each one characterized by a nominal frequency fnom, typical of the particular TDM interface and speed and an actual instantaneous frequency fin1, . . . , finN within the recommended frequency accuracy Δfin.
Therefore, there are N non-synchronous TDM interfaces with frequencies:
fin1(t)=fnom+Δfin1(t)Δfin1(t)<Δfin
fin2(t)=fnom+Δfin2(t)Δfin2(t)<Δfin
finN(t)=fnom+ΔfinN(t)ΔfinN(t)<Δfin
In this general scenario each TDM frame is composed of M asynchronous multiplexed flows (the case of M synchronous flows can be considered a particular case of this general scenario).
The egress filtering process (i.e. the process to ensure that the frequency of the TDM traffic output is substantially that of the node's (regulated) local clock) can be described as a function that receives f1+Δ1; f2+Δ2; . . . ; fn+Δn as inputs (with f1, . . . , fn and Δ1, . . . , Δn all unknown quantities) and provides f1+Δ1f; f2+Δ2f; . . . ; fn+Δnf as outputs with the aim to minimize the Δ1f; . . . ; Δnf terms.
The processing task for the egress cards of the edge node to take account of effects of both FDV and the various different frequencies which were received by the ingress cards so that the egress cards output TDM flows which have the required (system) data frequency is an onerous one.
We have realised that it would be desirable to adopt a new approach to address the issue of switching TDM traffic through a data switch fabric and provide a method to minimize synchronization impairments in the egress TDM traffic signals.
According to the invention there is provided a network node comprising input equipment, switching equipment and output equipment. The input equipment is arranged to be capable of packetising time division multiplexed (TDM) traffic flows. The switching equipment is arranged to be capable of routing the packetised data from the input equipment to the output equipment. The output equipment is arranged to be capable of reassembling the flows into time division multiplexed format. The input equipment is also arranged to be capable of causing the data frequency of the packetised data sent to the switching equipment to be substantially of a predetermined data frequency.
According to another aspect of the invention there is provided data processing equipment which is configured to be capable of packetising time division multiplexed (TDM) traffic flows, the equipment being suitable for connection to packet data switching equipment. The data processing equipment is arranged such that, in use, the flows are processed such that the data frequency of packetised data output by the data processing equipment is substantially of a predetermined data frequency.
According to yet a further aspect of the invention there is provided a method of processing time division multiplexed (TDM) traffic flows comprising processing the flows to generate packetised data having a data frequency substantially equal to a predetermined data frequency. Routing the packetised data across switching equipment (17, 18) and then converting the packetised data into time division multiplexed format.
Another aspect of the invention comprises machine readable instructions for controlling data processing equipment, which when run by the data processing equipment cause the equipment to process received flows of time division multiplexed data such that packetised data is output by the data processing equipment which has a data frequency which is substantially of a predetermined data frequency.
One embodiment of the invention may be viewed as a method of applying a TDM traffic re-justification process before passing through data fabric switching system such that all of the TDM traffic flows which are input into the data fabric switching system are characterized by a single, pre-determined, system frequency.
In one embodiment of the invention an egress filtering process performed by the output equipment can be described as a function receiving f1+Δ1; f2+Δ2; . . . ; fn+Δn as inputs (with f1=f2= . . . =fn and all equal to a known frequency value) and providing f1; f2; . . . ; fn as outputs with the ability to reduce the Δ1f; . . . ; Δnf terms to (substantially) null values and therefore to completely compensate the switch data fabric FDV. This egress filtering process is technically simpler and cheaper as compared to known methods.
Various embodiments of the invention will now be described, by way of example only, with reference to the accompanying drawings in which:
With reference to
Every Multiplexing/Demultiplexing function which is performed when transferring the received data across the edge node 10 is coupled with a frequency adaptation process performed by the output traffic cards on the transmitting side of the node to accommodate the M slightly asynchronous flows. The frequency adaptation process is based upon a justification/dejustification process able to interpret and alter the justification control indications Cj of the flows.
Each TDM flow is received, in packetised fomat, by an output card and each flow is characterized by an instantaneous frequency that is a function of (i) its justification indications bits and (ii) of its ingress interface frequency.
fpq(t)=F(finq(t); ΣSigmacjp(t))
So, the instantaneous frequency of the information stream, or flow, p received by an input card from an ingress interface q is a function of the ingress interface instantaneous frequency finq(t) and of the cumulative effect of the justification control indications. X of these extracted information streams are cross-connected to an egress interface characterized by its own frequency fout (still within the required frequency accuracy of the system).
The egress multiplexing function performed by the output cards on the transmitting side will therefore have the task to multiplex the X egress frequencies
fepq(t)=fpq(t)+Δfpq(t) 1)
fenm(t)=fnm(t)+Δfnm(t) 2)
fevw(t)=fvw(t)+Δfvw(t) x)
Where Δfpq(t) is the effect of the data switch fabric FDV on the information stream p from the ingress interface q.
The egress frequency adaptation and multiplexing function will have to accommodate these X flows to the egress interface fout generating the proper justification control indications. This adaptation process will have to face the undesired, often bursty, effects of the FDV Δfpq(t) that could result in unwanted and unacceptable justification movements (that will cause clock recovered smoothing problems in the consequent nodes with a general synchronization worsening).
In order to significantly simplify the processing by the output cards for the frequency adaptation process, each ingress card is configured to perform re-justification of all the information streams from the ingress interfaces to a common reference clock, namely the node's local, but system synchronised clock, before they are passed through a data fabric switch card. ITU G.783 Sn/Sm_A_So, ITU G.705 Pqe/Pyx_A_So or any other suitable process can be used by the input cards to adapt all the fpq(t) frequencies to a single common system reference one fsys(t) before they are routed to the output cards. The relations above therefore become:
fepq(t)=fsys(t)+Δfpq(t) 1)
fenm(t)=fsys(t)+Δfnm(t) 2)
fevw(t)=fsys(t)+Δfvw(t) x)
Since fsys is a known value, compensation of Δfnm(t) by the output traffic cards on the transmitting side will be a much more straightforward and much cheaper task since it will only need to take account of the FDV for each flow, and not also a (potentially) different respective nominal frequency of each flow received by the output cards. Importantly, it will allow the complete compensation of the fabric switch FDV effects in comparison with the simple reduction possible with complex and expensive filtering and cleaning circuits. Moreover this method will allow the reduction of the important overall TDM traffic elaboration latency avoiding the requirement of deep dejittering buffers tied to the egress filtering digital circuits.
Details of how the input cards perform this adaptation process are now described. Reference is made initially to
After having been routed to a particular output card by the switching fabric, the output card then only needs to take account of the FDV to ensure that the data frequency of TDM output is as required.
The flow diagram in
The node 10 offers an advantageous solution to face the FDV effects that a data switch fabric has when it is used to emulate a TDM cross-connect from ingress to output TDM interfaces. Adapting all the ingress information streams to a common well known frequency before switching provides a cost-effective and safe egress FDV compensation avoiding the need to filter and clean the received flows to a set of unknown asynchronous ingress frequencies. From this point of view it will allow a TDM cross-connect emulation through a data fabric switch with improved performance and with a less expensive way obtaining in this manner an agnostic flexible high performance and low cost switch system.
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PCT/EP2007/064485 | 12/21/2007 | WO | 00 | 11/1/2010 |
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WO2009/080121 | 7/2/2009 | WO | A |
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Number | Date | Country | |
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20110044202 A1 | Feb 2011 | US |