SE513509C2 - Device for routing data packets in a DTM network - Google Patents

Abstract

The present invention refers to a circuit board to be connected to a switch core. According to the invention, the circuit board comprises: an interface (111) for receiving one or more input DTM channels from said switch core and for transmitting one or more output DTM channels to said switch core; means (115) for deriving at least a portion of a data packet received, divided into DTM time slots, in one of said input DTM channels; routing means (117) for selecting, based upon information provided in said at least a portion of a data packet, if said data packet is to be transmitted in one or more of said output DTM channels and, if so, which one or more of said output DTM channels said data packet is to be transmitted in; and output means (116) for providing one or more output DTM channels with said data packet, divided into DTM time slots, in accordance with the selection of output DTM channels made by said routing means.

Description

15 2O 25 30 35 513 509 2 two groups, control time slots and data time slots. Control time slots are usually used for transmitting signaling messages between the nodes of the network's internal function. The data time slots are usually used for the transmission of data between end users connected to the various nodes.

Each node is set up to dynamically set up, take down and modify DTM channels by dynamically allocating time slots.

When a DTM channel is used to transmit asynchronous traffic, such as TCP / IP packets, a mechanism is often needed to route the packets through the DTM network. In the prior art, such a mechanism is usually provided by the addition of a dedicated router station, either directly connected to the DTM network or indirectly connected to the DTM network via, for example, an Ethernet link, which connects the router station to a DTM access device.

In this context, the use of a dedicated router station naturally entails extra costs and increased network complexity. An object of the invention is therefore to provide a routing solution in a DTM network which reduces the cost of introducing dedicated router stations.

Summary of the Invention The above and other objects are achieved by the invention as defined in the appended claims.

According to a first aspect of the invention there is provided an electronic circuit board which is to be connected to an exchange core and which is provided with an interface for receiving one or more DTM input channels from the exchange core and for transmitting one or more DTM output channels to the exchange core. . Furthermore, the electronic circuit board comprises means for deriving at least a portion of a received data packet, which is divided into DTM time slots, on one of the DTM input channels. The circuit board is also provided with routing means for selection, based on information provided in the at least a portion of the data of whether the data packet is to be sent on one or more of the packet, by the DTM the output channels and, if so, which one or more of the DTM output channels the data packet is to be transmitted on, and with output data means for providing one or more DTM output channels with the data packet, divided into DTM time slots, according to the choice of DTM output channels; made by the rotating body. The invention is thus based on the idea that, in a DTM network, in order to be accommodated as a separable module in an exchange, an electronic circuit board, which is an output device and for communicating via its exchange core, is provided with a routing mechanism. Thus, a network operator can add a routing mechanism to a DTM network by inserting only an electronic circuit board according to the invention in a switch already existing in the network.

Accordingly, according to a second aspect of the invention, there is provided an apparatus for exchanging data in a communication network, the apparatus comprising: an exchange core; one or more electronic circuit boards, each of which provides access to one or more network links; one or more circuit boards of the kind mentioned above; and means for receiving the electronic circuit boards and for establishing connectivity between the electronic circuit boards and the switch core.

Furthermore, further advantageous aspects have been found in the design of the interface between the switch core and the electronic circuit board in such a way that complete DTM frames are replaced.

Thus, according to a preferred embodiment in accordance with the first aspect of the invention, the interface of the electronic circuit board comprises: means for receiving sequential incoming DTM frames from the exchange core and for transmitting sequential outgoing DTM frames to the exchange core; and means for determining the existence of one or more DTM input channels transmitted in the incoming DTM frames, and of one or more DTM output channels which are transmitted in the outgoing DTM frames. the output data means comprising the frame generating means for generating the sequential outgoing DTM frames and for providing DTM time slots thereof, defining a DTM output channel, with the data packet divided into DTM time slots, according to the selection of the DTM time slots. output channels made by the routing device.

Similarly, the exchange core is preferably arranged to provide time and space switching between DTM frames, said one or more electronic circuit boards providing access to the network links, each comprising an interface for receiving sequential incoming DTM frames from the exchange core and for sending sequential outgoing DTM frames to the exchange core.

An advantage of using such an interface between the electronic circuit board and the switch core is that the protocols used to handle DTM frames in the interface, if desired, can be designed very similarly to the protocols used for any other DTM interface. a “DTM network” time-multiplexed network of the type where By definition is, as referred to here, a circuit-switched, information is transmitted between nodes in the network on bit streams.

Each bitstream is divided into regularly recurring so-called and one includes a number of fixed size time slots, fixed size frames, "DTM frames", which are where the time slots are divided into control time slots and data time slots.Thus defines a time slot position in either a control slot. a DTM frame, at any given time, troll time slot or a data time slot, is used for control signaling between nodes in the network, and data time slots are used for the transmission of user data (often referred to as payload traffic).

Furthermore, the write access in a DTM network is distributed among nodes connected to the bitstream carrying the DTM frame, each node usually having write access 10 to at least one control time slot and a dynamically adaptable set of data time slots in each recurring frame. Having writing access to a time slot position in a frame also means having writing access to the time slot position within each recurring frame.

In a DTM network, a node will use the data time slots to which it has write access to set up so-called DTM channels by allocating one or more of the data time slots to each DTM channel. Therefore, as referred to herein, a DTM channel is defined by one or more time slots occupying the same time slot position within each DTM frame by the bitstream from which the DTM channel is carried. However, if a DTM channel, for example, goes over two bit streams, the channel can of course be defined by different sets of time slot positions on the two bit streams. Furthermore, a DTM channel can be either a control channel or a data channel, depending on whether control or data time slots are allocated to the channel. In addition, a DTM channel can be a one-to-one channel (unicast channel), a one-to-many channel (multicast channel) or a one-to-all channel (broadcast channel).

When the requirement for network capacity changes, DTM channels can be set up, taken down or modified, the latter by changing the number of time slots allocated to a DTM channel. Furthermore, the distribution of write access to time slots between the different nodes can be dynamically modified when different nodes develop different needs for control signaling and data transmission.

Accordingly, an electronic circuit board according to the invention is typically provided with means for determining which input and output channels are to be handled by the routing processor and which are to be bypassed, i.e. not routed via the routing processor.

The above-mentioned and other aspects and features of the invention, such as the use of a switch core memory shared by all switch ports and the use of a router memory shared by all channels accessed by the router means, will become apparent from the following description of embodiments of the invention.

Brief Description of the Drawings Exemplary embodiments of the invention will now be described with reference to the accompanying drawings, in which: Fig. 1 schematically shows an example of the construction of a DTM frame on a bitstream in a DTM network; Fig. 2 schematically shows transmission of asynchronous traffic on one of the DTM channels shown in Fig. 1; Fig. 3 schematically shows a gear unit equipped with an electronic circuit board according to the invention; Fig. 4 schematically shows an exemplary embodiment of an electronic circuit board according to the invention; Fig. 5 schematically shows a gear core connected to an electronic circuit board according to an embodiment of the invention; and Fig. 6 schematically shows another gear core connected to an electronic circuit board according to another embodiment of the invention.

Detailed Description of an Exemplary Embodiment An example of the construction, or structure, of a DTM frame on a bitstream in a DTM network will now be described with reference to Fig. 1.

As shown in Fig. 1, a bitstream B which, in a DTM network, interconnects at least two bitstream access units is divided into recurring DTM frames of substantially fixed size, the beginning of each DTM frame being defined by a frame synchronization time slot F. Each DTM frame has typically the length l25us.

Each DTM frame is further divided into a plurality of fixed size time slots, the time slot size 64 bits and the bit typically 64 bits. When using the frame length l25ps, ll 10 15 20 25 30 35 513 509 7 the speed 2 Gbps, the total number of time slots in each frame will amount to approximately 3900.

The time slots are divided into control time slots C1, C2, C3 and C4, and data time slots D1, D2, D3 and D4. The control time slots are used for control signaling between the nodes in the network, while the data time slots are used for the transmission of useful traffic. Each node connected to the bitstream B typically has at least one allocated control time slot, ie each node will have write access to at least one control time slot. Furthermore, the write access to data time slots is distributed among the nodes connected to the bitstream B. As an example, a first node (which is connected to the bitstream B) will have access to a control time slot C1 and a set of data time slots D1 in each DTM frame of the bitstream, while a second node (which is also connected to the bitstream) will have access to a control time slot C2 and a set of data time slots D2 in each DTM frame of the bitstream, and so on. The set of time slots allocated to a node such as control time slot (s) and data time slot (s) occupy the same respective time slot positions in each DTM frame of the bitstream. Thus, for example, the control time slot C1 of the first node will occupy the second time slot in each DTM frame of the bitstream.

During operation of the network, each node can increase or decrease its access to control time slots and / or data time slots, thereby redistributing access to control time slots and / or data time slots among the nodes. For example, a node that has a small need for transmission capacity can give away its access to data time slots to a node that has a greater need for transmission capacity.

Furthermore, the time slots allocated to a node do not have to be successive time slots, but can be located anywhere in the DTM frame.

Also note that each DTM frame typically begins with the frame synchronization time slot, which defines the frame rate of the bitstream and ends with one or more padding time slots G.

In Fig. 1, at (c), it is further assumed that the second node, which has access to its control time slot C2 and its area of data time slots D2, has set up four channels CH1, CH2, CH3 and CH4 on the bitstream. each channel each allocated a set of time slots. As shown, the example has the transmission capacity on channel CHI greater than the transmission capacity on channel CH2, since the number of time slots allocated to channel CHI is greater than the number of time slots allocated to channel CH2.

The time slots allocated to a channel occupy the same time slot positions in each periodic DTM frame of the bitstream.

An example of the transmission of asynchronous traffic on one of the isochronous channels carried by the bitstream B shown in Fig. 1 will now be described with reference to Fig. 2. In Fig. 2 it is assumed that the channel CH3, is established to carry asynchronous traffic in the form shown in Fig. 1, of sequentially transmitted variable size data packets, which may be, for example, TCP / IP packets or Ethernet frames. (Note that Fig. 2 only shows the sequence of sequential time slots transmitted within the channel CH3).

Since Fig. 1 schematically indicates that the channel CH3 comprises seven time slots in each DTM frame on the bitstream B, the first seven time slots transmitted on the channel CH3, i.e. the first seven time slots in Fig. 2, will be transmitted in a DTM frame. frame, das in the next DTM frame and so on. The next seven time slots will transmit Fig. 2 shows three data packets transmitted on the channel CH3.

Each data packet is encapsulated according to a predefined encapsulation protocol. In Fig. 2, it is assumed that the encapsulation protocol defines that each data packet is to be divided into a number of data blocks of 64 data bits (which corresponds to the size of a time slot), that a start_of_packet-time slot S is to be added at the beginning of each data packet , and that an end_of_packet time slot E is to be added to the end of each data packet, in order thereby to form encapsulated data packets P1, P2, the bitstream is provided with so-called idle slots, and P3. In case of gaps between packages - which identify the gaps as if they do not contain any valid data. A gear unit equipped with an electronic circuit board according to the invention will now be described with reference to Fig. 3. Fig. 3 shows a gear device 50 comprising a gear housing 52, a gear power and control unit S4, an electronic circuit board 56 , which provides a routing mechanism according to the invention, and a card with a DTM network interface 58, which provides access to a DTM network link. As shown schematically in Fig. 3, the electronic circuit board 56 and the board with the DTM network interface are separably connected to a gear core (not shown), which is arranged inside the gear housing 52.

An embodiment of an electronic circuit board 110 according to an embodiment of the invention will now be described with reference to Fig. 4. In Fig. 4, the electronic circuit board comprises a port III, comprises an interface 113 for incoming channel and which in turn has an interface 114 for outgoing channel. , which receives or transmits time slot data on DTM channels from / to an exchange core (not shown). The interfaces for the incoming and outgoing channels provide synchronization of the work of the electronic circuit board 110 in relation to the DTM frame rate in accordance with the exchange core.

Interface, incoming and outgoing channel interfaces are connected to one channel manager 115 for incoming channel and one channel manager 116 for outgoing channel, respectively.

The channel managers 115 and 116 for incoming and outgoing channels, respectively, are both connected to a routing processor 117, a shared memory 119 and a buffer manager 120.

The routing processor 117 is connected to a routing memory 118. Furthermore, a control unit 121 is connected to both the channel manager 115 for the incoming channel and the channel manager 116 for the outgoing channel. 10 15 20 25 30 35 513 509 10 In operation, the incoming channel interface 113 (arrow 1) takes channels monitored by the interface. Each data packet is received from data packets, for example TCP / IP packets, from those typically encapsulated according to a predefined protocol, as described with reference to Fig. 2, and is typically received as a set of successive, 64-bit sequential data blocks . The number of data blocks that form a data packet will depend on the size of the actual data packet.

The incoming channel interface 113 then forwards, while maintaining sequential order, each received data block to the incoming channel manager 115 (arrow 2). Each data block passed to the incoming channel manager 115 is accompanied by a channel identifier indicating that channel. from which it was received.

After receiving enough blocks at the front of a data packet to be able to derive information indicating the size of the data packet, the incoming channel manager will send a request (arrow 3) containing the size of the data packet to the buffer manager 120. . The request will thereby inform the buffer manager 120 that the channel manager 115 for the incoming channel needs to store a data packet of the specified size in the shared memory 119.

The buffer manager 120 will then allocate an address in the shared memory 119 for the data packet, the allocated address space being not less than the data packet. The buffer manager 120 will respond to the request by returning (arrow 4) a start address corresponding to the start of the address space of the channel manager 115 for the incoming channel.

After receiving the start address from the buffer manager 120, the incoming channel channel manager will start writing the data blocks constituting the associated data packet in the shared memory 119 (arrow 5), starting with the start received from the buffer manager 120. The address, and increment the address one step for each data block written in the shared memory 119.

At the same time, the incoming channel channel manager 115 sends the start address received from the buffer manager 120, together with the address specified in the start portion of the data packet, to the routing processor 117 (arrow 6).

Using the routing memory 118 (arrow 7), based on the destination address received from the incoming channel interface 115, the routing processor determines whether the associated data packet is to be sent from the outgoing channel interface 114 and, if so, which outgoing channel. to be used when sending the data packet.

After determining the outgoing channel for the data packet, the routing processor 117 sends a signal to the outgoing channel manager 116 (arrow 8) which contains an identifier and the start address received from the incoming channel manager. The channel identifier identifies the outgoing channel to be used when the associated data packet address is transmitted, and the start address indicates where in the shared memory 120 the associated data packet is to be read from.

After receiving the outgoing channel identifier and the start address from the routing processor 117, the outgoing channel manager 116 accesses it (arrow 9) and starts reading (arrow 10) data blocks constituting the associated data packet from the shared memory memory 119 beginning with on the start address received from the routing processor 117 and increments the address one step for each data block read from the shared memory 119.

At the same time, the outgoing channel channel manager 116 (arrow 11) for data blocks for each outgoing channel receives from the outgoing channel requests 114 continuously, which requests are sent from the outgoing channel interface at the rate that DTM frames 10 15 20 25 30 35 513 509 12 is requested for transmission to the exchange core connected to the outgoing channel interface 114.

The channel manager 116 for outgoing channel forwards (arrow 12), when the requests refer to a channel identified by a rar triggered by the requests for data blocks, channel identifier received from the routing processor 117, with preserved sequential order, each data block of the associated data packet from which it is read the shared memory 119 starting from the specified start address, to the outgoing channel interface 114. The output channel interface 114 (arrow 13) then in turn forwards the received data blocks to the respective channels on the output bitstream.

After reading the last data block in an outgoing channel data (arrow 14) channel manager 120, the associated packet from the shared memory 119 returns the start address received from the routing processor 117 to the buffer manager 120. the processor of the data packet which This informs the buffer manager of the address area associated with the start address has been completed and that the buffer manager is now free to allocate the address space to a new data packet received via the incoming channel interface. It is understood that, based on the information provided. It will be appreciated that the purpose of the controller 121, other, is to be kept when controlling signaling received on a channel from the incoming channel manager, it is determined which channels are to be handled by the incoming channel manager 115. channel and by the channel manager 116 for outgoing channel, ie which channels are to be directed to / from the routing processor 117. If there is a channel which is received by the channel manager for the incoming channel but is not to be sent to the routing processor, that channel is bypassed in the input / output interfaces 113, 114.

A gear core 203, which is connected to an electronic circuit board 110 according to an embodiment of the invention, will now be described with reference to Fig. 10 15 25 25 35 513 509 13 5. As shown in Fig. 5, the gear core 203 receives time slots in DTM frames from two input ports 20la and 201b, and sends received time slot data to two output ports 201b and 20lc.

Each input port 201, 202a is arranged to write each received DTM frame in each frame buffer in a shared frame memory 204. Time slot data from the time slots in a DTM frame is written sequentially in the corresponding time slot data field in each frame buffer, i.e. a data field for each incoming time slot .

At the same time, two time slot data selection units (not shown) are arranged to select the time slot data to be transmitted in outgoing DTM frames by, for each outgoing time slot to be transmitted in the respective outgoing and from which (ie among the currently legal) DTM frame, decide from which frame buffer, time slot data field in the row time slot data from both currently stored DTM frames), time slot data is to be retrieved, to the respective outgoing DTM frame. Thus, each forwarding unit is or is forwarded connected to both frame buffers for selecting and retrieving time slot data from them.

To know which frame buffer or field thereof is to be used for a specific outgoing time slot, each selector unit has access to its own time slot mapping table (not shown) which, for each time slot of each outgoing DTM frame and in each field, provides a field indicating which field in the memory is to be used for retrieving the given outgoing time slot.

Accordingly, the selector unit retrieves time slot data for a given outgoing order for each time slot of the outgoing DTM frame to receive time slot data. Of course, the exchange will only transmit time slot data in the time slots of the outgoing DTM frame allocated for that purpose. Furthermore, as shown schematically in Fig. 5, electronic circuit board 110 according to the invention, which is thus equipped with routing means, for example as has been described with reference to Fig. 4, connected to the switch input / output port 202a, 202b and is thus arranged to receive DTM frames from, and send DTM frames to, the unit which time slots enter the DTM frames supplied to the electronic circuit board 110. In the one defined the switch core 203. In addition, the above-mentioned well situation shown in Fig. 5 determines a channel read by time slot 7 in the DTM frames received in port 20la, out to the output port 202b, more specifically to the second time slot in the DTM frame delivered from there, and received by the electronic routing circuit board 110.

Based on routing decisions, the electronic routing circuit board 110 will send data packets received in the DTM frame time slot 2 in the port 202b to either a channel defined by time slot 2 or a channel defined by time slot 3 in the DTM frame on the port. 202a, the channels then being mapped into the time slots 6 and 7, respectively, in the outgoing DTM frame on the port 201b.

Accordingly, a data packet received on the channel defined by time slot seven on port 20la will be routed to the channel defined by time slot 6 or to the channel defined by time slot 7 on output port 20lb. As will be appreciated from Fig. 5, the electronic circuit board will receive and transmit entire DTM frames from / to the exchange core. However, it will only read data from and transmit data to time slots that the electronic routing circuit board 100 is arranged to provide routing of. Time slots of the DTM frame at port 202a that are not currently used as part of a channel handled by the electronic routing circuit board 110 are usually provided with idle data.) Furthermore, in the situation shown in Fig. 5, the selector unit is set to time slot seven of the DTM frame received at port 201b also, in addition to what has been described above, be mapped to time slot five in the DTM frame of port 20lb. Thus, data packets received on the channel defined by time slot seven at port 20la are always transmitted in a circuit-switched manner on the channel defined by time slot five at port 20lb, regardless of which routing is requested. lye taken from the electronic routing circuit board 110.

As will be appreciated, the channels defined in the description with reference to Fig. 5 with a single time slot could include any number of time slots within each frame, as dynamically selected in a DTM network.

Fig. 6 shows a similar solution where the gear core 203 of the exchange is realized in the form of a divided medium, more specifically a divided DTM ring / bit stream 205 which connects all the ports, the ports acting as nodes in the internal DTM rings. As shown schematically, each time slot from the input ports 201a and 201b is written in a corresponding time slot in the internal DTM bitstream frame. 202b then reads selected time slots from the internal DTM bitstream 205 as they transmit Each output port 20lb, outgoing DTM frames. Furthermore, the electronic routing circuit board connected to the exchange core is arranged to read data packets from channels defined by time slots on the internal DTM bitstream 205 and route these data packets to channels defined in the same way by time slots on the internal DTM bitstream.

For example, in the situation shown in Fig. 6, an input channel defined by the time slots five and six at the port 202a is mapped into the time slots 12 and 13 of the internal DTM bitstream 205, the district circuit board 110. 110 then routes the data packets to, for example, a channel and The electronic routing circuit board defined by time slot 17 on the internal bitstream, the channel then being mapped into both an output channel defined by time slot five and an output channel defined by time slot six in the DTM frame at port 202b. .

(Note that each of the outgoing channels at gate 201a in this case has only half the bandwidth of the incoming channel at gate 201a.) Although the invention has been described above with reference to exemplary embodiments thereof, it should be 513 509 16 these are not to be construed as limiting the scope of the invention. Accordingly, as will be appreciated by those skilled in the art, various modifications, combinations and changes may be made within the scope of the invention as defined in the appended claims.

Claims (12)

lO 15 20 25 30 35 513 509 17 PATENTKRAV An electronic circuit board (56; 110) for connection to an exchange core, comprising: an interface (111) for receiving one or more DTM input channels from the exchange core and for transmitting one or more DTM output channels to the exchange core; means (115) for deriving at least a portion of a data packet that has been received, divided into DTM time slots, on one of said DTM input channels; routing means (117) for selecting, based on information provided in said at least a part of a data packet, whether the data packet is to be transmitted on one or more of said DTM output channels and, if so, on which of the one or more multiple DTM outputs the data packet is to be transmitted; and output means (116) for supplying one or more DTM subdivided into DTM time slots, in accordance with the selection of DTM output channels made by said routing means. output channels with the data packet, The electronic circuit board of claim 1, wherein the interface comprises: means (113, 114) for receiving sequential incoming DTM frames from the exchange core and for transmitting sequential outgoing DTM frames to the exchange core; and means (121) for determining the existence of one or more DTM input channels transmitted in the incoming DTM frames, and of an electrolyte DTM output channels transmitted in the outgoing DTM frames, and said output means (114) comprises: frame generating means for generating the sequential, outgoing DTM frames and for providing DTM- which define a DTM output channel, divided into DTM time slots, time slots therein, said data packets, according to said routing means selection of DTM output channels. 10 15 20 25 30 35 513 509 18 An electronic circuit board according to claim 1 or 2, comprising a memory (119) for temporarily storing data packets at respective memory locations therein, the interface comprising means (115) for writing the data packet at an allocated memory location in the memory upon receipt of the data packet and wherein said frame generating means comprises means for reading the data packet from the allocated memory location for transmission in accordance with said routing means's selection of DTM output channels. The electronic circuit board of claim 3, further comprising a memory manager (120) adapted to temporarily allocate a memory location in the memory for storing the data packet and for providing the interface with information indicating the memory location. An electronic circuit board according to claim 4, wherein the memory location is allocated by the memory manager for storing the data packet as a result of a request made by the interface upon receipt of the data packet. Electronic circuit board according to any of the preceding (121) input and output channels to be handled by the routing processor requirements, comprising means for determining which and which are to be bypassed. An electronic circuit board according to any one of the preceding claims, wherein the data packet, when transmitted within the channel, is encapsulated in accordance with a DTM encapsulation protocol. (50) comprising: a gear core (203); one or more electronic circuit boards (58), Device for exchanging data in a communication network, each of which provides access to one or more network links; one or more electronic circuit boards (56; 110) according to any preceding claim; and means for receiving the electronic circuit boards and for providing connectivity between the electronic circuit boards and the gear core. The apparatus of claim 8, wherein the switch core is adapted to provide time and space switching between DTM frames and said one or more electronic circuit boards providing access to the network links, each comprising an interface for receiving sequential, incoming DTM frames. frames from the exchange core and for transmitting sequential, outgoing DTM frames to the exchange core. The apparatus of claim 9, wherein the switch core comprises a memory (204) having a plurality of memory locations associated with each electronic circuit board, and wherein said means for providing connectivity between the electronic circuit boards and the switch circuit the core comprises DTM frame receiving and generating means, which are associated with each electronic circuit board and have write access to each memory location of said memory locations, for writing therein DTM frames received from each circuit board, and which have read access to all memory locations, for reading time slot data from selected time slot fields thereof when generating DTM frames to be delivered to the respective electronic circuit board. 11. ll. Apparatus according to claim 10, comprising means for setting up DTM channels between the electronic circuit boards by determining which memory fields in the memory said DTM frame receiving and generating means are to read data from when generating DTM frames to be delivered to the respective electronic circuit board. Device according to one of the preceding claims, wherein the gear core is circuit-switched.