NZ251727A - Transmitting ancillary information in time division multiplex system - Google Patents

Description

251727 New Zealand No. 2 51727 • International No. PCT/FI93/00176 TO BE ENTERED AFTER ACCEPTANCE AND PUBLICATION Priority dates: x.z. • s • ^2.

International filing date: 2.-3.. c*. is. ;Classification: v-voh-o3\ .-j. ;Publication date: 2 8 AUG 1995 ;Journal Noj i3«* y • NEW ZEALAND PATENTS ACT 1953 COMPLETE SPECIFICATION Title of invention: Method for transferring ancillary information in a basic time-division multiplex system Name, address and nationality of ' applicant(s) as in international application form: NOKIA TELECOMMUNICATIONS OY, Makkylan puistotie 1, FIN-02600 Espoo, Finland, 251727. 1 Method for transferring ancillary information in a basic time-division multiplex system The invention relates to a method for trans-5 ferring ancillary information, such as channel-associated signalling, in a basic time-division multiplex system, where ancillary information is transferred in a predetermined timeslot of each frame, and where information associated with more than one 10 channel is transferred in at least one timeslot of the basic system. The method according to the invention is especially intended for use in connection with the European 2048 kbit/s 30-channel basic multiplex system, but it is not restricted to this standard 15 only.

In the 2048 kbit/s basic multiplex system defined in the CCITT specification G.704, channel-associated signalling CAS is transferred in a timeslot TS16 by grouping successive frames into larger multi-20 frames containing 16 frames. The timeslots TS16 of successive frames in the multiframe are assigned one at a time to a signalling channel corresponding to two separate speech channels. Accordingly, there are four bits available for each signalling channel in the 25 timeslot. The signalling channels occupy the timeslots TS16 of fifteen frames contained in the multiframe. The timeslot TS16 of the remaining frame 0 contains e.g. a multiframe synchronizing signal, as will be described below.

The basic system described above allows the transfer of 30 speech channels having a capacity of 64 kbit/s. Today, however, it is possible to use advanced speech coding methods by which the capacity of the 2048 kbit/s system can be increased up to 60 or even 35 120 speech channels. In such a case it is necessary to 251727 WO 93/25017 PCr/FI93/0017f code the information of the speech channels by a transcoder.

The CCITT specification G.761 defines a 32 kbit/s ADPCM transcoder vjith accurately specified 5 fixed timeslot mapping, signalling transfer and alarms handling. This transcoder cannot, however, be connected to the 2048 kbit/s basic system as the bits it employs for alarm transfer are reserved for national use in the specification G.704. A reliable transfer of 10 alarms cannot therefore be guaranteed.

On the other hand, even though the CCITT specifications G.726 and G.727 define 16 kbit/s speech coding, a transcoder realizing it has not yet been specified. One reason for this is that the transfer 15 capacity of the timeslots TSO and TS16 is not adequate for conventional transfer of the channel-associated signalling of 120 channels.

The specification G.761 also defines alarms, such as forward and backward AIS (Alarm Indication 20 Signal) alarms. However, the approach defined in the specification is not feasible when using a 16 kbit/s codec as the number of available bits is not sufficient for the transfer of alarms. This is because the network management also utilizes free bits available 25 in the timeslot TSO, wherefore they are not available for the purpose specified in G.761.

The object of the present invention is to provide a method which avoids the above-mentioned shortcomings and allows the transfer of ancillary informa-30 tion, especially the transfer of signalling and alarms, in a conventional basic multiplex system up to a capacity of 120 speech channels. This is achieved by means of a method according to the invention which is characterized by assembling a superframe having a 35 length of several multiframes, at least part of the 251727 ancillary information being transferred in said predetermined timeslot so that the number of the multiframe is transmitted in addition to said ancillary information, the number indicating with which 5 channel the ancillary information is associated.

The basic idea of the invention is to employ a lower signalling rate and to utilize the "extra" bits remaining in the timeslot transferring channel-associated ancillary information as "address bits" 10 indicating which one of the transfer connections is being served.

According to a preferred embodiment of the invention, part of the ancillary information is transferred by changing the sequence of the multiframe 15 numbers. The idea is thus to utilize the sequence of the multiframe numbers or a change in the sequence for transferring part of the ancillary information, such as alarms. It is to be noted that even though the term superframe will be used in the text below to 20 illustrate the operation of the method to the reader, the operation of the method as such does not require a single superframe sync in all timeslots but the phase or sequence of the multiframe numbers may vary from one timeslot to another.

The solution according to the invention is also compatible with n x 2048 kbit/s networks as the "address bits" used in the invention eliminate delay deviations (the delay varies from one timeslot to another) occurring in cross-connect devices. 30 A further advantage of the invention is that the bits of the timeslot TSO normally used for the network management are not utilized but they are still available for the network management purposes, as distinct from e.g. the above-mentioned specification G.761, 35 where they are used for another purpose. 251727 In the following the invention will be described in more detail with reference to the examples shown in the attached drawings, in which Figure 1 illustrates the assembly of superframes 5 from multiframes; Figure 2 Illustrates the transfer of ancillary information in the timeslot TS16 in successive multi-and superframes; Figure 3 Is a block diagram illustrating a 10 transmitter section in a codec applying the method according to the invention; and Figure 4 is a block diagram illustrating a receiver section in a codec applying the method according to the invention.

In the following, a 2048 kbit/s basic multiplex system transferring 120 speech channels by a 16 kbit/s speech coder will be used as an example. Each speech channel timeslot (the timeslots TS1...TS15 and the timeslots TS17...TS31) thus contains 4 coded speech 20 channels.

Figure 1 shows a frame 10 in a basic multiplex system. The frame 10 comprises 32 timeslots TSO... TS31. As is well-known, the timeslot TS16 of the frame is used by two signalling channels so that there are 25 four bits abed available for each channel. In the system, sixteen successive frames F0...F15 form a multiframe 11 having a length of 2 ms. In a conventional system, service can thus be offered for 30 speech channels.

In a multiplexer providing conventional tele phone service, the number of signalling bits actually transferred per channel can be reduced to two (the bits a and b hereinbelow). The other bits (the bits c and d hereinbelow) are typically connected to a fixed 35 state, and so it is not normally necessary to send 251727 them at all.

According to the invention, a superframe structure of four multiframes and having a length of 8 ms is assembled from the 16-frame multiframes 11. The 5 above-mentioned bits c and d are used in such a manner that the transmitter unit always sends not only the actual signalling bits a and b but also the bits c and d indicating the number (1...4) of the multiframe in the superframe. This number indicates which one of the 10 speech channels is being served currently, that is, the receiver employs the "address bits" c and d to update the signalling data of the appropriate speech channel. The signalling data of only one of the four speech channels is updated during the multiframe, and 15 so the signalling of all speech channels will be updated once only after the superframe. In the arrangement according to the invention, the updating sync is thus reduced from the normal value of 2 ms (multiframe sync) to 8 ms. (When using a 32 kbit/s coder, the 20 updating sync is correspondingly 4 ms. ) In practice, the reduction of the sync even to one quarter of the original has no detrimental effects, as even a slower rate is adequate for normal telephone network signalling.

Figure 2 illustrates channel-associated sig nalling for the timeslot TS1. This is done by showing the content of the timeslots TS16 (there are 64 such timeslots in the superframe 12) in those of the successive frames where the signalling data of the 30 timeslot TS1 is transferred. The third and fourth bit in the timeslot TS16 in the second frame F1 of each multiframe 11, that is, the above-described bits c and d indicate by the number (00, 01, 10 or 11) of the multiframe 11 to which speech channel of the timeslot 35 TS1 the corresponding bits al and bl are assigned. 251727 PCT/F193/00176 Figure 2 further shows the first four bits abed of the timeslot TS16 of the first frame FO of each multi-frame. These bits form the synchronizing signal, being all zeros. Correspondingly, the bits c and d (not 5 shown) following the bits al7 and bl7, for instance, indicate to which one of the four speech channels of the timeslot TS17 the bits are assigned. In the time-slot TS1 the bits cd form a sequence 00, 01, 10, 11, as described above. The superframe structure according 10 to the invention may be incoherent, that is, the phase of the respective "1-4 counter" may be different in each timeslot.

According to the preferred embodiment of the invention, the cyclically changing bits c and d are 15 used for the transfer of alarms so that a certain normal cd bit sequence, such as the above-described normal-state sequence 00, 01, 10, 11, is replaced with another sequence in an alarm situation. There are six (4!/4) possible sequences; in practice, this is suf-20 ficient for the transfer of all required alarms. Some alarms, such as the forward AIS alarm, can be given so that the bits c and d become fixed (e.g. 10). In other words, the number of the multiframe stops rotating intermittently. In such a case the signalling does 25 not, of course, take place as described above; in an alarm situation, however, this is not significant.

Figures 3 and 4 show one way of realizing a codec so as to apply the method according to the invention. These embodiments correspond to the 30 Applicant's ADPCM codec, which is a member of the product family sold under the name DYNACARD™.

In Figure 3, the input of the transmitter section 30 comprises a line interface circuit 31 where a data signal and a clock signal are separated from 35 the incoming PCM signal PCMin. The data and clock 251727 WO 93/25017 PCT/FI93/00176 signal are then transferred to corresponding inputs in a demultiplexer unit 32. In the demultiplexer unit, the signalling bits to be transferred in the timeslot TS16 are separated and applied to a copying unit 35.

In addition, data is applied from the demultiplexer unit to a coder unit 33, and a frame synchronizing signal is applied to a coder control unit 36 which informs the coder of the coding rate (64/32/16 kbit/s) used in the system. The c and d bits of the incoming 10 signal are eliminated in the copying unit 35. Coded data (speech) and signalling data from the copying unit (from which the original c and d bits have been removed) are connected to a cross-connect circuit 34 which rearranges the timeslots to an outbound bus TX 15 BUS. The signalling output of the cross-connect circuit comprises a sequence changing means 38 for the bits cd in which new signalling bits c and d are added to the signalling data. The sequence changing means changes the normal sequence of the cd bits to another 20 sequence (under the control of a processor unit 37) if an alarm has to be transferred. The sequence changing means is controlled by a cd bit sequence generator which is a counter stepping forward at intervals of one multiframe (and being reset at intervals of one 25 superframe). The sequence generator derives the multiframe sync from the bus.

On the receiver side (Figure 4) data (speech) and signalling is obtained from a receiver bus RX-BUS to the corresponding inputs in a cross-connect block 30 41. The cross-connect block arranges the timeslots under the control of a processor unit 47 according to the user's selections, and applies the speech data to a decoder unit 42, the signalling bits a and b to a multiplexing unit 43, and the bits c and d to a 35 comparison block 45. Each received speech channel is 251727 8 ADPCM decoded into a normal PCM speech channel. This requires channel-associated control data which is so generic that the internal cross-connect data of the timeslot can also be disassembled on the basis of it.

This also produces local c and d bits. The comparison block 45 compares the locally generated c and d bits with the received c and d bits. If they match, the comparison block applies an enable signal to the multiplexer. The enable signal updates the signalling 10 memory in the memory of the multiplexer unit 43 for this particular channel. If the received cd bits and the locally generated cd bits do not match, the signalling of the channel is maintained unchanged until the comparison indicates that the cd bits match. 15 The comparison block also determines whether the sequence of the cd bits is normal or whether it indicates an alarm. The processor unit 47 selects the timeslot to be monitored.

Accordingly, it is not necessary to get locked 20 to the superframe on the receiver side but the receiver uses received signalling bits to update the signalling information of the appropriate speech channel.

After ancillary information has been transferred 25 as described above between the transmitter and receiver sections, a conventional PCM signal PCMout where the bits c and d are fixed can again be produced at the output of the receiver unit. For this purpose, the processor unit 47 assigns the multiplexer unit 43 with 30 fixed cd bits cdout. However, if some of the timeslots are not decoded in the decoder 42, the c and d bits can be connected forward.

The method according to the invention can, of course, be realized by various different device con-35 figurations. However, only some minor modifications 251727 are required in existing devices, mainly means for providing a freely rotating two-bit multiframe counter in the transmitter section for the signalling bits.

Even though the invention has been described 5 above with reference to the example shown in the attached drawings, it is clear that the invention is not restricted to it but it can be modified in many ways within the inventive idea disclosed above and in the accompanying claims. Even though the invention has 10 been described above with reference to an example in which the signalling and alarms of 120 speech channels are transferred, the invention also has other applications. In place of the speech connections it is possible to transfer 16 kbit/s data channels with 15 other associated information. The number of channels may also be e.g. 60, so that the superframe can be formed of only two multiframes. As already mentioned in the beginning, the inventive idea is not restricted to the European 2048 kbit/s basic multiplex system but 20 the invention can also be applied to other systems of the same type. 251727

Claims (6)

Claims:

1. Method for transferring ancillary information, such as channel-associated signalling in a basic 5 time-division multiplex system, where ancillary information is transferred in a predetermined timeslot (TS16) of each frame, and where information associated with more than one channel is transferred in at least one timeslot.(TS1...TS15, TS17...TS31) of the basic 10 system, characterized by assembling a superframe (12) having a length of several multiframes (11), at least part of the ancillary information being transferred in said predetermined timeslot (TS16) so that the number of the multiframe is transmitted in 15 addition to said ancillary information, said number indicating with which channel the ancillary information is associated.

2. Method according to claim 1, characterized in that part of the ancillary 20 information is transferred by changing the sequence of the multiframe numbers.

3. Method according to claim 1 or 2, characterized in that the assembled superframe is incoherent so that the phase of the superframe is dif- 25 ferent in different timeslots.

4. Method according to any of claims 1 to 3, characterized in that the superframe is assembled from four multiframes.

5. Method according to any of claims 1 to 3, 30 characterized in that the superframe is assembled from two multiframes.

6. Method according to any of the preceding claims 2 to 5, characterized in that part of the ancillary information is transferred by WO 93/25017 11 251727 PCT/F193/00176 changing the bits (c and d) indicating the number of the multiframe (11) into fixed bits.