SE520080C2 - Method and apparatus for communication between a TDM network and a data packet or cell-based network - Google Patents

Abstract

A method of transparent transmission between a TDM network and a packet or cell based network is disclosed, comprising the following steps performed in a unit interconnecting the TDM network and the packet or cell based network: storing each byte received on a channel in a buffer, comparing the content of the buffer to a predetermined bit sequence. If every byte in the buffer matches the bit sequence, the content of the buffer is discarded; otherwise the content of the buffer is packed in a packet or cell and transmitted through the packet or cell based network.In a corresponding unit interconnecting the packet or cell based network and the TDM network it is determined when a packet or cell relating to a particular channel should be expected and, if an expected packet or cell is not received, a frame is generated and transmitted in the TDM network.

Description

Summary of the Invention This object is achieved according to the invention by means of a first device for communication between a Time Division Multiplex (TDM) network and a data packet or cell-based network, comprising buffer means for receiving and storing bytes, or words, emanating from a connection in the TDM network, comparing means for comparing the contents of at least one of the bytes, or words, of the buffer with a predetermined bit sequence when the buffer is full; cell or data packet transmission means for transmitting or rejecting the contents of the buffer depending on the result of the comparison, and clock means for determining when a data packet or cell related to a particular connection in the TDM network can be expected from the data packet or cell-based The net.

A second device for communicating between a TDM network and a data packet or cell-based network, comprises frame generating means for generating a frame comprising bytes, or words, with a predetermined pattern if an expected data packet or cell is not received; and TDM transmitting means for transmitting the generated frame.

The object is also achieved according to the invention by means of a method for compressing the information transmitted from a TDM network through a data packet or cell-based network to the same or another TDM network, characterized in that it comprises the following steps performed in a unit connecting the TDM network. the network and the data packet or cell-based network: - for each channel in the circuit-switched network to store each byte, or word, in a buffer, - when the buffer is full, compare the contents of the buffer with a predetermined bit sequence, 10 15 20 25 If each byte, or word, in the buffer corresponds to the predetermined bit sequence to reject the contents of the buffer, - if at least one byte or word, in the buffer does not correspond to the predetermined time sequence to packet the contents of the buffer in a buffer. data packet or cell and transmit the data packet or cell through the data packet or cell-based network, and - that in another device connecting the same or another TDM- network with the data packet or cell-based network determine when a data packet or cell related to a particular channel can be expected.

Preferably, the method also comprises the following steps: if an expected data packet or cell has not been received to generate a frame with the predetermined bit sequence and transmit the frame in the TDM network.

These devices and this method ensure that a bit sequence that frequently occurs in the network does not have to be transmitted through the data packet or cell-based network and thereby save bandwidth in this network. This is achieved without any need for tables. Unlike other compression methods, this compression function enables 100% bit recovery.

Preferably, the first and second devices such that the first device removes passive cells when traffic enters the data packet or cell-based network and the second device reinserts the cells when the traffic re-enters the TDM network.

In a preferred embodiment of the first device, the comparing means is arranged to compare the contents of each byte, or words, in the buffer with the predetermined buffer and the transfer means is arranged to reject the contents of the buffer only if each byte in the buffer corresponds to the predetermined bit sequence. In this embodiment, the frame generating means in the second device 10 is arranged to generate a frame of bytes with a particular bit sequence when an expected data packet or cell is not received.

In another embodiment, the transfer means is arranged to reject the contents of the buffer only if each byte, or word, in the buffer corresponds to the last byte in the previous cell and the frame generating means is arranged to generate a frame of bytes similar to one of the bytes in the last data packet or cell received and related to the connection.

In this way, bit sequences of more than one kind can be removed, still without the need for tables.

Brief Description of the Drawings In the following, embodiments of the invention will be discussed in more detail with reference to the accompanying drawings, in which Fig. 1 illustrates a typical telecommunication network in which the invention can be applied: Fig. 2 shows the connection between an access network, or a local station, and a cell or data packet-based transport network according to the invention.

Detailed Description of Embodiments Fig. 1 illustrates a type of network commonly used in telecommunications today.

Subscribers (not shown) are connected to an access network or an access node 1. The access network is, via a transport network 3, connected to a local station 5. The local station 5 is connected to other units in the network, such as other stations and / or other transport networks, in a manner well known per se. Several access networks and / or stations can be connected to the transport network; but for the sake of clarity, only the units needed for the discussion are shown. In the embodiment shown in Fig. 1, the transport network is assumed to be an Asynchronous Transfer Mode (ATM) network, capable of transmitting with Constant Bit Rate (CBR) or Variable Bit Rate in real time (VBR-rt ) service type. In order for the transport network 3 to be transparent, the bit stream at a point A between the access network 1 and the transport network 3 and at a point B between the transport network 3 and the local station 5 must be exactly the same.

The access network 1 performs, among other things, a concentration function. It also multiplexes traffic coming from a number of subscribers on a cable. The procedure that is mostly used for this is called Pulse Code Modulation (PCM). With PCM, 32 connections of 64 kbit / s each are multiplexed with a bitstream of 2 Mbit / s. In the United States, instead, 24 connections are multiplexed with a bitstream of 1.5 Mbit / s. The actual number of channels, or bit rates, are not important to the method of the invention.

On a 64 kbit / s connection, the information is carried in bytes of 8 bits or octets each. A 2 Mbit / s PCM frame comprises 32 time slots numbered from 0 to 31, and each of these can carry an octet. The time slots having the same number in a sequence of PCM frames form a channel corresponding to a 64 kbit / s connection.

In the access network 1, the traffic is circuit-switched and therefore arrives at the data packet or cell-based transport network at a fixed speed. In the transport network 3, traffic is handled according to the ATM protocol. At the interface between the access network 1 and the transport network 3 there is therefore a first conversion unit 7. At the interface between the transport network 3 and the local station 5 there is a second conversion unit 9, similar to the first conversion unit 7. Associated with the first conversion unit 7 is a first buffer unit ll. Associated with the second conversion unit 9 is a second buffer unit 13. As is known in the art, the buffer unit 11 has a buffer for each channel. Each buffer stores the number of bytes entering a cell so that the entire buffer will be filled with bytes, or octets, received on the relevant channel. When the buffer is full, it is packed as a cell and sent through the transport network and the procedure starts again from the beginning.

While the traffic is received at a fixed speed, the buffer is filled and its contents are packed as a cell or data packet and transmitted at regular, well-defined intervals. The second immigration unit 9 therefore receives cells corresponding to a particular one. PCM channel in the transport network l at regular intervals, with a predetermined maximum deviation.

According to the invention, the first conversion unit 7 includes logic for examining each buffer, or each cell to be transmitted, and determining whether it contains useful information. If each octet in the buffer, or cell, includes “no informationWbit sequence, the entire cell is rejected, i.e. it is not sent. The bandwidth that would have been taken up by this cell can then be used for other information. If, on the other hand, one or more of your octets includes a bit sequence that differs from the “no information” sequence, the entire cell is transmitted. In the second conversion unit 9, cells corresponding to a particular buffer in the first conversion unit 7 are expected to arrive at substantially regular intervals.

Therefore, if a cell is not received as expected, or after a predetermined maximum delay, the second conversion unit determines that the cell was probably not transmitted from the first conversion unit 7 because it contained only “no information” bit sequences. The second conversion unit 7 therefore adds to the bitstream either an ATM cell in which the payload contains only such bit sequences, or a sequence of so many such bit sequences entering a cell or a data packet, depending on the point in the network where the information was added.

Typically, some channels in a PCM link, such as channel 16, are used to carry control information. Cells corresponding to this channel will therefore always be sent. In the opposite direction, information can be handled in the same way, stored in the second buffer unit 13 transmitted through the access network and received by the first conversion unit 7, which adds information in the same way as described above if a cell does not received. The transport network can of course be located, and perform the same function, between two local stations or between two access networks.

The invention has been discussed above using 2 Mbit / s connections as an example. As already pointed out, the person skilled in the art could easily apply the teachings to 1.5 Mbit / s connections. The method according to the invention can also be applied to higher order connections, ie. multiples of 2 Mbit / s or 1.5 Mbit / s used in telecommunications. In each case, the received PCM frame is demultiplexed into individual 64 kbit / s channels before the handling according to the invention.

It would of course be possible to use a solution according to the invention to remove more than one type of bit sequence. However, this would require a code to be added to the deleted sequence to indicate which sequence had been deleted and a cell to be sent nonetheless. The recovery is therefore more advantageous if only one type of bit sequence is removed.

In an alternative embodiment, sequences of each bit sequence may be removed. The first cell or data packet containing only a particular bit sequence must be transmitted, but then previous cells or data packets containing only this particular bit sequence would be retained. Only in the case of a change will there be a need to send a cell. In this way, the receiving conversion unit will always know that if no cell or data packet has been received, a cell or a data packet similar to that last received will be generated. Alternatively, only the last byte in a cell or a data packet must be examined and there is then no need to transmit a cell which consisted of only one of the predefined bit sequences. This can be done for any bit sequence as soon as one or more of your cells or data packets comprises only one particular bit sequence, or can be limited to a number of predefined bit sequences.

Fig. 2 shows in more detail the interface between the TMD network and the data packet or cell-based network according to the invention. The interface is designed by a conversion unit similar to the one shown in fi g. 1, as in fi g. 2 is designated 107.

For transmission from the TDM network to the cell- or data-packet-based network, the conversion unit 107 has at least one input opening 109 for receiving incoming TDM frames from the TDM network. The frames have already been demultiplexed into single channels, each usually carrying a 64 kit / s connection. The conversion unit also includes a buffer 111, 111 ", 111" for each channel that can be received from the TDM network. In each buffer 1 1 1, 11 l ", 1 1 l" the bytes received are stored on the appropriate channel until the buffer is full. Comparative means 113 are provided for comparing the bytes in a buffer with a predetermined pattern once the buffer is full. The predetermined pattern is stored in a memory unit 115 in or adjacent to the comparator. If all bytes in the buffer correspond to the predetermined pattern, the entire contents of the buffer are discarded, if not, the contents of the cell are packaged and sent to a suitable output port 117 in a manner common in the art.

The predetermined pattern may be a specific pattern, or one of a number of predetermined patterns, as described in connection with fi g. 1. If more than one predetermined pattern is used, the memory unit 115 must be able to store the last byte transmitted for each channel, and, if applicable, the predetermined bit rates that can be rejected.

For transmission in the opposite direction, the conversion unit 107 also comprises means, i.e. one or more input ports 19 for receiving data packets or cells from the cell or data packet-based network and clock means 121 for determining when a cell or a data packet is to be received for a particular connection.

The clock means cooperates with frame generating means 123 in such a way that if the clock means 121 determines that a cell which would have been received has not been received within a predetermined maximum delay period, it commands the frame generating means 123 to generate a frame which is transmitted via an output port 125. the frames are multiplexed to the appropriate level in the manner commonly used in TDM systems.

The content of the generated frame depends on the design. In the simplest embodiment, where only bytes with a particular bit sequence are rejected, the content is always the same. Alternatively, if more than one bit sequence is discarded, the frame generating means 123 includes or is connected to memory means 127 for storing the last byte transmitted for each connection.

The conversion means 107 can of course be implemented as two different units, one for each transmission direction.

Claims (10)

10 15 20 25 30 520 080 10 Patent claims Device for communication between a TDM network and a data packet or cell-based network, characterized in that it comprises buffer means (1 1 1, 1111 °, lll ") for receiving and storing bytes, or words, which emanate from a connection in the TDM network, comparing means (113) for comparing the contents of at least one of the bytes, or words, of the buffer (1 1 1, 111 °, 11l ') with a predetermined bit sequence when the buffer is full; cell or data packet transmitting means (117) for transmitting or rejecting the contents of the buffer depending on the result of the comparison, and clock means (121) for determining when a data packet or cell related to a particular connection in the TDM network can expected from the data packet or cell-based network. . Device according to claim 1, characterized in that the comparing means (113) is arranged to compare the contents of each byte, or words, in the buffer (11 l, lll ", ll1") with the predetermined bit sequence and that the transfer means (117) is arranged to reject the contents of the buffer only if each byte, or word, in the buffer corresponds to the predetermined bit sequence. . Device according to claim 1 or 2, wherein the transfer means (117) is arranged to reject the contents of the buffer only if each byte, or words, in the buffer corresponds to the last byte, or words, in the preceding cell. . An apparatus according to any preceding claim, comprising frame generating means (123) for generating a frame comprising bytes, or words, with a predetermined pattern if an expected data packet or cell is not received; and TDM transmission means (125) for transmitting the generated frame. 10 15 20 25 520 080 ll. The apparatus of claim 4, wherein the frame generating means (123) is arranged to generate a frame of bytes, or words, of a particular bit sequence when an expected data packet or cell is not received. . The apparatus of claim 4 or 5, wherein the frame generating means (123) is arranged to generate a frame of bytes, or words, similar to one of the bytes, or words, in the received last data packet or cell related to connection. . Method for compressing information transmitted from a TDM network through a data packet or cell-based network to the same or another TDM network, characterized in that it comprises the following steps, performed in a unit connecting the TDM network and the data packet or cell-based network 2- to store for each channel in the circuit-switched network each byte, or word, in a buffer, - that when the buffer is full compare the contents of the buffer with a predetermined bit rate, - that if each byte, or words, in the buffer corresponding to the predetermined bit sequence discarding the contents of the buffer; that if at least one byte, or word, in the buffer does not correspond to the predetermined bit rate, packet transmitted the contents of the buffer in a data packet or cell and to send the data packet or cell through the data packet or cell-based network, and - that in another device connecting the same or another TDM network to the data packet or cell-based network determines when a data packet or cell belonging to a particular channel can be expected. 520 080 12 The method of claim 7, comprising the steps of, if an expected data packet or cell is not received, generating a frame with the predetermined bit sequence and transmitting the frame in the TDM network. 5 The method of claim 7 or 8, wherein the predetermined bit sequence is an fixated bit sequence stored in a memory unit (115). A method according to claim 7 or 8, wherein the predetermined bit sequence is the same as in the last byte, or word, in the last data packet or transmitted for the channel.