DE4129543C1 - Transmission of async. additional data over audio channels in time multiplex system - adding data to some of audio channels and inputting to multiplexer receiving signals from other channels handling only audio signals - Google Patents

Abstract

The transmission circuit has a differentiator (DS), logic decision stage (ENT), code converter, buffer memory (SP1) and a multiplexer (MX). The multiplexer has inputs from other channels such that additional signals (ZDS1-5) can be handled over a number channels handling audio signals (TS1-TS5). The signals are transmitted (MS) and are received by a circuit with a demultiplexer with a buffer coupled to a separating circuit having a clock control stage. ADVANTAGE - Simplifies transmission of additional signal data together with audio data.

Description

The invention relates to a method and an arrangement for Transmission of asynchronous additional data, the sound channels in are assigned to a time division multiplex system.

Several 64 kbit / s time slots are used to form audio channels of the time division multiplex system combined to sound signals with a bandwidth of 7 or 15 kHz. About that In addition, these sound channels can be combined into stereo sound channels will. In the magazine "telcom report", SPEZIAL, March 1987, pp 69 to 74, this sound transmission system is described. By using data reduction methods but it is also conceivable to have an audio signal in a 64 kbit / s time slot transferred to. In addition to the sound signals, these should be assigned asynchronous data signals are transmitted, their maximum data rate with a 15 kHz audio channel be at least 1200 bit / s should.

From German published patent application DE 34 45 419 A1 is a Method for transmitting additional information known, at which the additional information by logical connection with the Parity bits is transmitted. This is in this special case possible because the parity bits in the form of bytes are multiple be transmitted.

The inventive method according to claim 1 is the problem based on asynchronous additional data assigned to sound channels in to transmit a time division multiplex system.  

In the independent claim, a suitable circuit arrangement with little circuitry to carry out the Procedure specified.

Advantageous developments of the invention are in the sub claims specified.

Advantageously, the time slot 16 of the pulse frame previously used for the transmission of the license plate is used for the transmission of the asynchronous additional data. The maximum permissible data rate is determined by dividing a superframe period into several frame sections. Each frame section is divided into several sampling intervals and the sampling interval in which a change in state of the additional signal occurs is transmitted as a digitally coded combination. A combination that marks the beginning of the superframe must be avoided. This is advantageously achieved by dividing it into seven sampling intervals, since the eighth 4-bit combination is not required in this way.

The arrangement can advantageously be integrated by a few Circuits can be realized.

The invention will be explained in more detail using an exemplary embodiment purifies.

Figures used here show:

Fig. 1 shows a pulse frame with 64-kbit / s time slots,

Fig. 2 shows a pulse frame of audio channels,

Fig. 3 is a detailed illustration of the time slot 16,

Fig. 4 is a detailed illustration of the time slot 16 at Tonkanalübertragung,

Figure 5 is a division intervals. Abtastinter in a superframe,

Fig. 6, 7 is a schematic representation of an arrangement for implementing the method, and

Fig. 8, 9, an arrangement according to the invention.

Each pulse frame R0 to R15 in FIG. 1 comprises 32 time slots, Z0 to Z31, in each of which one byte is transmitted. 16 of these pulse frames R0 to R15 are combined to form an overframe UR. A frame identification word RKW is transmitted in the first byte of each pulse frame. The 17th time slot Z16 is used in the first pulse frame to transmit an overframe identifier URK ( FIG. 3) in the first four bits and in the following pulse frames for the transmission of identification information when telephone signals are each transmitted in a telephone channel which is each a 64 kbit / s time slot in the pulse frame - in the superframe of a column - corresponds. The identifier information is no longer required when transmitting audio channels and can therefore be used to transmit the additional data signals.

In FIG. 2, the same superframe is illustrated, but in which in each case 2 × 3 time slots of each pulse frame are combined to form a 15 kHz audio channel TK. A total of 5 sound channels TK1 to TK5 are formed, of which two, z. B. TK1 (TK1a, TK1b) and TK2 (TK2a, TK2b) can be summarized to form a stereo audio channel.

In Fig. 3 the time slot 16 belonging to the frame of Fig. 1 is shown enlarged. For each column of time slots (64 kbit / s channel) there is once a half byte (4 bits) in the superframe for the transmission of additional data ZS1, ZS2,. . . to disposal. When transmitting 15 kHz audio channels - this requires 6 time slots each - there is a 6x transmission capacity of 3 × 8 for the transmission of additional data signals ZDS1, ZDS2,. . . Bytes available, as can be seen from Fig. 4. The use of time slot 16 for the transmission of additional data signals and the assignment of the transmission capacity of parts of this time slot to the other time slots can be chosen arbitrarily, but it suitably corresponds to the recommendations according to CCITT.

In the time chart of Fig. 5, each superframe UR, 3 divided frame sections specifically a superframe period, N = which are each divided into seven sampling AI. The shortest time period (1 bit) of the additional data signal ZDS must correspond to at least the length of a frame section RA.

If the additional data signal ZDS changes, in which the sampling interval the change (from the logical "0" to logical "1" or vice versa) took place. For this are three bits necessary to form an interval code word IVC; a fourth bit, e.g. B. the status bit (here also in fourth position) shows the new state of the additional signal. Does not take place State change of the additional signal, so any Ab keying interval can be coded. The first is expediently Transfer sampling interval, since the additional data signal already here its condition maintained throughout the frame section has reached.

The transfer code words used for transmission are

where x = 1 or 0. The "superframe identifier" This prevents 0000.

This division of FIG. 5 corresponds to a combination of three time slots to one audio channel with a proportion of three nibbles in the time slot 16. With a superframe period of 2 ms, an additional data signal ZDS can thus be transmitted with a data rate of 3 bits: 2 ms = 1500 bits / s.

When transmitting additional data within a pulse frame in accordance with FIG. 1 / FIG. 3, a single frame section (N = 1) is assigned to an superframe in accordance with the transmission capacity of half a byte available for the transmission of additional data for a time slot, said frame section being divided into seven sampling intervals is divided.

Accordingly, there is only one nibble to transfer the addition data signals with a data rate of 500 bit / s for ver addition.

If six nibbles are available for the transmission of the additional data signal, as in the superframe according to FIG. 2, the superframe is divided into N = 6 frame sections, which in turn are divided into seven sampling intervals. By dividing it into 6 frame intervals in a PCM-30 system, an assigned additional data signal ZDS1 can be transmitted with the six times the data rate of 6 × 500 bit / s = 3 kbit / s.

In addition to the additional data signal ZDS, other additional signals can also be used be transmitted when the transmission capacity is divided. So, in order in the above embodiment to stay, three, four or five nibbles for transmission of the additional data signal are used, and the rest one to three nibbles to transmit one or more Additional signals can be used. The prerequisite is the division a subframe in a smaller number from three to five frame sections.

If only additional data signals with a maximum data rate of 1.5 kbit / s are to be transmitted in the superframe shown in FIG. 2, a pulse frame can also be divided into only three frame sections, each frame section then being able to be divided into up to 240 sampling intervals . Then additional data signals can be transmitted practically without jitter. In general, however, fewer sampling intervals will be chosen for reasons of complexity. If the maximum possible transmission rate for the additional data signal ZDS is halved, which corresponds to a halving of the number of frame sections, then a doubling of the number of sampling intervals in each case results in a halving of the distortions.

Because extremely low distortion is usually not necessary are redundant coding of the status bit or / and of the interval code word. So the status bit at for example, triple transmission or there may be an error corrective code can be used.

In Fig. 6 and Fig. 7 arrangements are indicated for implementing the method. The arrangement is designed for the transmission of additional data signals to five audio channels, in which an overframe is divided into six frame sections. The transmission arrangement shown in FIG. 6 consists of the chain connection of a differentiating stage DS, a decision stage ENT, a code converter CU, a first buffer memory SP1 and a multiplexing device MUX. For the sake of clarity, the arrangement was only shown for an additional data signal. The multiplex device MX also has other arrangements for further additional data signals ZDS2. . .ZDS5 and the actual information, the sound signals TS1 to TS5, leads.

The differentiating stage DS is switched on via a first input E1 first additional data signal ZDS1 supplied. Through the differentiation level step change impulses SUI formed, which are fed to a decision level ENT. In this is determined in which sampling interval a step change falls into it. For this purpose, the decision level of one Clock supply TV1 corresponding sampling interval signals AIS delivered. The relevant sampling interval is in the code converter converted into a 3-bit interval code word IVC and together with the additional data signal ZDS as a 4-bit transfer code word TCW in the Buffer memory SP1 stored. By the multiplex device MX will use the correct codeword in the superframe Position inserted and with the multiplex signal MS over the Output A1 sent out.  

In Fig. 7 a corresponding receiving device is Darge. This consists of the chain circuit of a demultiplexing device DX, a second buffer memory SPZ and an output device AE which has a clock multiplexer TM and an output flip-flop AK which contains the additional data signal emitted by the second buffer memory SP2 and the clock multiplexer, which in turn is derived from the interval code word IVC is controlled, one of the clocks supplied by the clock supply T1 to T7 is supplied.

The received multiplex signal MS is the demultiplex DX fed via their input E2, which initially the Separated transfer code words TCW of the additional data signal ZDS1 and written into the second memory SP2. That here contained interval code word IVC controls - if necessary via a decoder - the clock multiplexer TM, which is one of the of the clock supply provided dividing the frame section seven output clocks T1 to T7 at the clock input of the output flip-flop switched through and thus one status bit ZB of the additional data signal ZDS via the output A2.

Determining the sampling interval at which a state change of the additional data signal ZDS falls, can also by sampling of the signal. This results in a low-cost arrangement.

FIG. 8 shows the transmitting part and in FIG. 9 the receiving part of the arrangement according to the invention, which uses this principle.

The transmission part consists of a 7-bit shift register SR1, the parallel outputs of which are connected to the inputs of a read memory used as a code converter RCU1, the four parallel outputs of which are connected via a first memory SP1 to the inputs of a multiplex device MX. According to the arrangement in FIG. 6, further additional data signals and the audio signals are fed to this multiplex device. The multiplex signal is transmitted via output A1 to the receiving part of the arrangement. This is constructed inversely to the transmission device, that is to say it has the chain connection of a demultiplex device DX, a second memory SP2, a second code converter RCU2, likewise implemented as read memory, and a second 7-bit shift register SR2. The transmitting part and the receiving part are in turn controlled by clock supplies TV1 and TV2.

In the transmission arrangement, the additional data signal TDS1 is fed to the serial input E1 of the shift register SR1 and sampled with the sampling clock AT1. When an additional data signal ZS is transmitted in accordance with the superframe according to FIG. 1, the frequency of the sampling clock is 3.5 kHz at a superframe frequency of 500 Hz (data rate = 2048 kbit / s). When transmitting an additional data signal ZDS corresponding to the pulse frame of FIG. 2, the sampling frequency is 21 kHz.

At the end of a frame section is at the parallel exits the shift register R1 the sampled additional data signal AZS, which forms a certain bit pattern, as an address for the code converter RCU1 issued the complete transfer code word TCW that generates the sampling interval and the state of the addition data signal includes. The transfer code word TCW is marked with a transmission side frame section clock RAT1 in the first memory SP1 buffered by the multiplexing device MX in known way inserted in the superframe and over the first Output A1 sent out.

The additional data signals are first in the receiving device by the demultiplexing device DX as transfer code words TCW separated, converted into parallel data and over the second memory SP2 and the second code converter RCU2 with a reception side frame section clock RAT2 into the second Shift register SR2 stored. Because the second code converter  RCU2 has a function inverse to the first code converter RCU1, becomes the same combination in the second shift register SR2 written at the end of an associated frame section in first shift register. Accordingly, by the Sampling clock AT1 corresponding output clock AT2 the same bit combination, d. H. output the same signal change at output A2. The same bit combination was used at the outputs for clarification of the first shift register and the second shift register shown, although this is at the parallel outputs of the second Shift registers at a later time after implementation, Transfer and reverse implementation pending.

This solution also makes it possible to hide short signal interference by programming the code converter accordingly.

Claims (8)

1. Method for the transmission of asynchronous additional data signals (ZDS), each associated with a sound signal (TS), in a time-division multiplex system, the superframe (UR) of which is formed from a plurality of pulse frames (R0 to R15), a signaling time slot ( Z16) is provided for the transmission of assigned information,
characterized by
that the superframe (UR) is divided into one frame section (RA) or more (N = 2, 3...) frame sections (RA),
that each frame section (RA) is divided into several sampling intervals (AI),
that an interval code word (IVC) is assigned to each sampling interval (A1),
that when the state of the additional data signal (ZDS) changes in a sampling interval (A1), the assigned interval code word (IVC) and a status bit (ZB), which indicates the state (log. 0, log. 1) of the additional data signal (ZDS), to a transfer code word (TCW) is added,
that if there is no change in the status of the additional data signal (ZDS) within a frame section (RA), one of the interval code words (IVC) and the status bit (ZB) is added to the transfer code word (TCW), the transfer code words (TCW) always being coded in such a way that a superframe identifier (URK) does not appear at the designated position,
that the transfer code words (TCW) have been inserted and transmitted in a predetermined location of the signaling time slot (Z16) and
that on the receiving side, corresponding to the sampling interval (AI) determined by the interval code word (IVC), an additional data signal (ZDS) corresponding to the status bit (ZB) is generated and output. 2. The method according to claim 1, characterized, that each 64 kbit / s time slot of a sound channel (TK1, TK2,. . .) a nibble (4 bits) within a superframe (UR) in the signaling time slot (Z16) to transmit the Additional data signal (DS1, DS2,...; ZDS1, ZDS2,...) Assigned will. 3. The method according to claim 1, characterized in
that a 15 kHz audio channel, which includes six 64 kbit / s time slots (Z1, 2, 3, 17, 18, 19), three bytes of within an extra frame (UR) in the signaling time slot (Z16) for transmission assigned to the additional data signal (ZDS),
that an overframe (UR) is divided into six frame sections (RA),
that a frame section is divided into seven sampling intervals (A1),
that an interval code word (IVC) comprises three bits,
and that the binary combination (0000) corresponding to the superframe identifier (URK) is not used. 4. The method according to claim 1, characterized in
that a 15 kHz audio channel, which comprises six 64 kbit / s time slots (Z1, 2, 3, 17, 18, 19), three bytes are allocated within a superframe (UR) in the signaling time slot ( 16 ) ,
that up to five nibbles of this are used to transmit an additional data signal (ZDS),
that the remaining nibbles are used to transmit one or more additional signals,
that an superframe (UR) is divided into 3 to 5 frame sections (RA) in a proportion of up to 5 nibbles corresponding to the proportion of the transmission of the additional data signal (ZDS),
that a frame section is divided into seven sampling intervals (A1),
that an interval code word (IVC) comprises three bits,
and that the binary combination (0000) corresponding to the superframe identifier (URK) is not used as a transfer code word (TWC). 5. The method according to claim 1, characterized in
that three 15 bytes are assigned to a 15 kHz audio channel which comprises six 64 kbit / s time slots (Z1, 2, 3, 17, 18, 19) within a superframe (UR),
that a superframe (UR) is divided into three frame sections (RA) and each frame section is divided into more than 13 sampling intervals,
that a transfer code word (TCW) comprises 8 bits, a binary combination (0000XXXX) corresponding to the superframe identifier (URK) not being included. 6. The method according to claim 5, characterized, that the status bit (ZB) and / or the interval code word (IVC) (A1) is transmitted redundantly coded. 7. Arrangement for the transmission of additional data signals (ZDS) in a time-division multiplex system, the superframe (UR) of which is formed from a plurality of pulse frames (R0 to R15), a signaling time slot (Z16) being provided in each frame for the transmission of assigned information, thereby featured,
that on the transmission side for the transmission of an additional data signal (ZDS) a first shift register (SR1) is provided with parallel outputs, the serial input (E1) of which is supplied the additional data signal (ZDS1) and with a sampling clock (AT1) with a clock frequency that is at least seven times higher than the data rate of the additional data signal is scanned,
that the parallel outputs of the first shift register (SR1) are connected to inputs of a first code converter (RCU1) which converts the input combination into a transfer code word (TCW),
that the outputs of the code converter (RCU1) is connected to a first memory (SP1) which clocks from a frame section (RAT1) with N times (N = 1, 2, 3,...) clock frequency of the superframe repetition frequency (f _U ) is clocked,
that the outputs of the code converter (RCU1) is connected to a multiplex device (MX), which also the sound signals (TS1, TS2,...) and further additional data signals (ZDS2.. .5) are supplied,
that a demultiplexer device (D) is provided at the receiving end,
that for each additional data signal (ZDS1,... ZDS5) a second memory (SP2) is provided, in each of which a transfer code word (TWC) is stored,
and that the parallel outputs of the second memory (SP2) are connected via a second code converter (RCU2) to the inputs of a second shift register (SR2), into each of which a binary combination corresponding to a frame section clock (RAT2) on the receiving side corresponds to a binary combination corresponding to the time of the assigned frame section clock (RAT1) is stored; and
that the additional serial data signal (ZDS) is output at the serial output (A2) of the second shift register (SR2). 8. Arrangement according to claim 7, characterized, that read memory is provided as a code converter (RCU1, RCU2) are.