DE1295638B - Method for message transmission in the unidirectional or bidirectional range - Google Patents

Description

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The invention relates to a method for subsequently ensuring a reliable differentiation of the signal pulses directional transmission in one-way or two-way operation from the synchronous pulse train,
via a time-division multiplex channel and at least one. Conversely a) To transmit the additional information, periods of one channel each are assigned by channel distribution to the channel and transmitted in multiple, the signal directions arranged after the relevant channel clocks in the time-division multiplex channel in the form of pulse frames of successive pulse frames previous pulse frames are transmitted whose io see

each a number corresponding to the channel number of b) each period of the one assigned to a channel Channel clocks and a synchronous pulse location includes, and signal pulse locations in successive pulse frames wherein each channel clock contains a plurality of messages, a plurality of with respect to the synchronous direction pulse locations different signal pulses and messages for the transmission of the after-pulse train and a signal pulse point for the transmission 15 at least one further, the additional information bevon Additional voice signal pulse assigned to the relevant channel.

information such as B. control information, according to feature a) of such a method

while the content of the synchronous pulse points in one that extends over several pulse frames

successive pulse frames a synchronous pulse period of signal pulses for the transmission

sequence forms. 3 ° of the additional information used, this

In the time bundling of a channel multiple superperiods as a result of the ratio of signals, each channel within the bundled information pulses to synchronous pulses according to feature b) information flow apart from the messages that are clearly distinguishable from the synchronous pulse train as useful information and transmitted as additional information. Appropriately, each period of the z. B. control information for monitoring and 25 signal pulse points assigned to a channel a control of the transmission operation od Carrying time bundling in the form of pulse groups over against signal overlap and signal mix-up, with this being associated with such a pulse group. The pulse schedule can be referred to as the “channel cycle” in particular for the next time interval. can also advantageously be laid out in such a way that each consecutive period of the signal pulse channel clocks assigned to a channel in the time bundling of all channels of the channel multiple form a period called "pulse frame" in consecutive pulse frames contains the mentioned channel clocks with their 35 signal pulses. In each signal message and signal pulse point there is a sync pulse period of at least one pair of consecutive synchronous pulse points that follow a special pulse for the purposes of matching signal pulses, and the synchronization in time bundling or in contrast to the LO synchronous pulse train .
the channel distribution leads. Another development of the successive pulse frames according to the invention form a certain 4 ° transmission method for a LO synchronous pulse pulse train, the "synchronous pulse train", z. B. an age sequence is characterized by the fact that each renating LO pulse sequence, which is to be transmitted within the useful period of the signal pulse information assigned to a channel, extends over four successive pulse frames over a longer succession of pulse frames and stretches two matching signal pulses does not occur in channel clocks, since it contains a comparison frame 45 in each case successive pulse frame, contains high-frequency spectral components outside of the frequency band. In the usual case of inserting a single, advantageously low circuit complexity for the over-signal pulse point in each channel cycle, control information can be transmitted in numerous annually per channel. 50 turn cases are sufficient. Expediently, one of the key problems associated with the security of the message transmission in each period is the avoidance of signal pulse points in the last two pulse frames that correspond between the signal pulses and the syn signal pulses.

chronic pulses on the other hand. Furthermore, if a larger 55 In the following description, the pulse number of additional information for each channel frame is referred to as "frame" for short, while is to be transmitted, according to the usual additional tech information, for example, control information a correspondingly large number of additional functions are required.

Signal pulse locations required in each channel cycle. Further features and advantages of the invention

whereby not only the circuit complexity, but also go out from the following description of an output

also that for the transfer of a given example of use, shown in the drawings

amount of information increases considerably. is illustrated. It shows

The object of the invention in this context is F i g. 1 shows a pulse plan to illustrate the creation of a method for messaging the operation of a method transmission according to the invention of the type mentioned at the outset, which multiply the 6g rensausführung with time bundling of a channel transmission of more than two additional information and pulse code modulation,
for each channel of the multiple channel with only one F i g. 2 enables the block diagram of a device for signal pulse point per channel cycle and the same execution of the method according to FIG. 1,

F i g. 3 shows the structure of a circuit part of the device according to FIG. 2 and

FIG. 4 shows the structure of a further circuit part of the device according to FIG. 2.

F i g. In line A, FIG. 1 schematically shows the pulse sequence of a 24-channel multiple with pulse code modulation, time-bundled on a time-division multiplex channel, for the procedure according to the invention. For the sake of simplicity, only the synchronous pulse points FR and the signal pulse points D 1 for the channels CH1, CH1 and CH 24 are indicated for a period of four successive frames. In this representation, the binary signal L corresponds to an existing pulse, and the binary signal 0 corresponds to a non-existent pulse. In Fig. 1, the signal pulses L in the signal pulse points D 1 are indicated by hatching. Pulses and associated pulse locations are labeled identically without any particular information.

According to line A in FIG. 1 is the first pulse point Fi? of each frame is provided for a synchronous pulse, which is followed by a signal pulse point D 1 assigned to the last channel CH 24. Eight message pulse points each of the channels CHI, CH1 to CH 24 then follow. In each of the channels except for channel CH 24, the first seven pulse locations D1 to D are 8 message pulse locations, while the pulse location D is 1 signal pulse location. In the last channel of each frame, however, a synchronous pulse position Fi? Occurs between the last message pulse position and the signal pulse position. In all channels, the successive message pulse positions are assigned to arithmetic binary positions of decreasing weight. The content of the synchronous pulse points FR according to line A is indicated again in line B for itself. After that, the pulse train is an alternating L-0 train. With a frame repetition frequency of 8 kHz, which is often used in practice, the repetition frequency of the L synchronous pulses is thus 4 kHz.

The corresponding content of the signal pulse positions of a four-period period is indicated for the channels CH 1, CH1 and CH 24 in lines C, D and E, respectively. It can be seen from this that in the last two frames of a four-period period the signal pulse positions have the content zero. In the first two frames of a four-period period, up to four binary combinations can be transmitted in the two-digit signal pulse sequence as indicators of a corresponding number of control information items. Because the binary signal zero is impressed in the signal pulse positions of the last two frames of a four-period period, it is impossible for the 4 kHz synchronous pulses to penetrate the signal pulse positions of any channels, regardless of the combinations of signal pulses transmitted during the remaining frames.

With the device according to FIG. 2 24 channels in the form of audio frequency lines, e.g. B. between two telephone exchanges or between a telephone exchange and a private exchange, in time can be transmitted in a bundle. In the example case, two-way communication channels are used, 2-wire lines shown as a single pole in FIG. 2 are provided which, in addition to the audio-frequency network information various control information such as "loop open", "loop closed", "normal battery", "Counter battery" and the low-frequency alarm signal are transmitted.

In the first station, indicated on the left in Fig. 2, the channels CH 1 to CH 24 within a connection bank W each end in an input control information converter 11 responsive to the control information and an output control information converter 12, the outputs of which to a message converter 13 are connected. The converters 11 and 12 are shown in FIG. 2 shown as separate elements for each channel, but can actually be designed as a closed circuit unit. The converters 11 respond to the control information entered by the exchange facility in the relevant channels and convert them into binary combinations at the outputs A 1 and A. These binary combinations appear in pulse form at outputs A 1 and A once per channel cycle.

On the other hand, the converters 12 respond to binary combinations supplied in pulse form at their inputs B1 and B and set these e.g. B. over ao suitable relay circuits in control information for the exchange. The binary combination corresponding to control information also appears at inputs B 1 and B once per channel cycle.

As a hybrid circuit is provided in the message converter 13 for each channel, which splits the two transmission directions and assigns them to a transmission channel and a reception channel. The converter 13 also contains a sampling gate for each channel for combining information from successive channels in a time division. The converter 13 also contains an encoder in the common transmission connection and a decoder in the common reception connection, both for converting from or into the pulse code modulation. Finally, a distributor gate and a low-pass filter for restoring the audio-frequency information in analog form are provided in the code converter for each channel. From the converter 13, the information flow arrives in pulse form via a transmission line 14 with amplifiers 15, 16 regenerating the pulse form to the terminal bank E in the on the right-hand side of FIG. 2 indicated second station. Here, a corresponding message converter 17 converts the incoming pulse trains back to analog form and distributes them to the associated channels CHl to CH 24. For the reverse transfer device is provided between the two messages converters 17 and 13, a further transmission line 20 with repeaters 21, 22nd The transmission between the two stations therefore takes place in four-wire mode, ie with two time-division multiplex channels running in opposite directions, each working in directional mode. The part of the device described so far is essentially of the usual construction.

For the inventive insertion of the synchronous pulses and the coded control information between the useful information to be transmitted according to line A in FIG. 1 is according to FIG. 2, a control information multiplexer 23 is provided, which is connected on the output side together with the message converter 13 to the transmission channel 14. For the opposite direction of transmission, a corresponding control information multiplexer 24 is connected on the output side together with the message setter 17 of the right station to the transmission channel 20. On the input side, the multiplexers 23 and 24 are connected to the outputs A 1 and A of the input control information.

5 6

tion converter 11 or 19 connected. To obtain a first input of a further AND gate 37, the control information from the bundled information stream is supplied to the right station A 1 of the associated multiplexer, a common control information channel distributor -Gatters

25 is provided, the input side together with the 5 36 the pulse sequence FO, F1, FO, FO, since the first input message converter 17 to the transmission line 14 at this AND gate, the pulse sequence F 0, F 1, F 0, closed is. In the left station bezug- Fl is obtained from the binary counter 31st The output signal borrowed from the transmission line 20 and the message conversion of the AND gate 36 is therefore only provided during the second channel distributor 26 arranged in a corresponding manner in a period of four successive ones. On the output side, the channel distributors are 10 frames positive and are fed to a last AND gate 25 or 26 connected to the inputs B 1 and B of the output 38 for passing the control information from the input control information converter 18 or 12 connected to output A of the associated multiplexer, sen. Both stations are not in any closer detail. The input ^ 4 1 of the multiplexer leads during

The illustrated manner with circuits for regaining the sampling of each channel by the addition of the synchronous pulses and for the corresponding 15-ear converter according to FIG. 2 the pulse or synchronization between transmit and receive zero. Provided according to the internal circuit of such a multi-page. plexers according to FIG. 3 is the A1 input with a

The in F i g. The logic circuit shown in simplified form 3 is connected to the second input of the AND gate 37, the main component of the multiplexer. The input ^ 4 is connected to a second input of the 23 and 24. To explain the mode of operation, the AND gate 38 is connected and also leads consistently positive pulses according to the end of the query time of each channel wall the pulse L binary L, missing pulses correspond to the binary or zero. The two AND gates 37 and 38 have assumed zero. The existing binary counters each have a third input, which is each connected to the signal pulse points D 1 according to FIG. 1 through the first positive input. 1 switched together pulse in the state shown. ²⁵ falling signal pulses D1 'are supplied. On the left side of the logic circuit after AND gates 37, 38 of the AND gates 35, 36 F i g. 3, the input of a binary counter 31 with supplied pulse trains is used to limit the frame rate corresponding synchronous the signals at the inputs A 1 and A to the additional pulses FR ' , which z. B. with the synchronous the first frame of a period of four, while the pulse points FR of FIG. 1 coincide. The 30 signal pulses D1 ', the concentration of the corresponding binary counter 31, has two outputs, of which the pulses on the signal pulse points D1 of the associated upper, designated L through the first input channels cause. The outputs of the AND gate pulse are switched to a positive output voltage 37 and 38 are connected to two inputs of the OR-tet, while the output voltage of the lower gate 39 is connected to the input labeled 0 and simultaneously disappears in F i G. 3 denoted with PCM, bundled INDET. Formation flow supplied during a period of four consecutive times. In this way, the following frames can lead to the output L of the receiving station each up to four ver binary counters 31 the pulse sequence Fl, F 0, Fl, FO, with different signal pulses being transmitted. The frame Fl a menu pulse sequence pending for the duration of a frame is the flow of information such as a positive voltage and F 0 a for the same time 40 suspects from the output of the AND gate 32 over a space pending zero voltage. During the own input of the OR gate 39, the same period leads to the output zero of the binary. According to the invention, the pulse trains to the counter 31 are the complementary pulse train FO, Fl, outputs of AND gates 35 and 36 continue to FO, Fl. Imprinting of the pulse zero in the signal pulse points To generate an alternating synchronous pulse 45 D 1 of the last two frames of a period sequence, the output L of the binary counter 31 and of four consecutive frames are used, sen input, ie the synchronous pulses FR ' on As a result, the erroneous occurrence of an age-speaking inputs of an AND gate 32 annoying pulse sequence with the frame rate is closed. The one that prevents the alternating pulse train. The outputs of both AND gates lead output of AND gate 32 is connected to an input 5 ° during this frame the voltage zero and separate OR gate 39. ren thereby the AND gates 37 and 38 for the The alternating pulse sequence at the output of the binary transmission of any occurring binary signals L during counter 31 is in addition to the AND gate 32 the one of the corresponding signal pulse positions, output of a second binary counter 34 and a die AND -Gates 35 and 36 are supplied to the first input of an AND gate 35 in the example. The circuit according to FIG. 3 is reproduced as separate elements of the complementary pulse sequence at the output 0 of the binary. It goes without saying, however, that this counter 31 is fed to a first input of a further two gates just like the gates 36 and 38 of each AND gate 36. because they are combined into one circuit component. The output L of the binary counter 34 leads during can.

a period of four frames the pulse sequence F1, 60. The logic circuit according to FIG. 4 represents in unified-Fl, FO, FO and is connected to the second inputs of the multiple way the structure of the channel distributors 25 and AND gates 35 and 36. As the first 26 is shown in FIG applies is added, the output of the AND gate 65 leads to the assumption that the first positive pulse on the pulse sequence Fl, FO, FO, FO. That only control input S of this flip-flop is activated during the first frame of a four-period period,
positive output signal of AND gate 35 is on the left side of the circuit of FIG

the coded information flow PCM on the one hand and the synchronizing pulses FR ' corresponding to the frame rate on the other hand are fed to two inputs of an AND gate 41. From the total information flow, the pulses attributable to the synchronous pulse locations are thus blanked at the output of the AND gate 41. The output of the AND gate 41 is connected to the set input S of the bistable flip-flop 42, whose reset input R is ίο acted upon directly by the synchronous pulse sequence FR '. The output L of the flip-flop 42 is switched to a positive voltage by a pulse at the setting input S and to zero voltage by a pulse at the reset input R. The output 0 of the flip-flop 42 is switched accordingly in phase opposition. The pulse sequences F1, F 0, F1, F 0 or FO, Fl, FO, Fl appear at the outputs L or 0.

To recover the signal pulses of all channels as well as all synchronous pulses from the in FIG. 4 supplied, receiving-side information flow PCM , this is supplied to the first input of a further AND gate, the second input of which receives the signal pulses D1 '. The pulse combinations thus sampled in the signal pulse points, which contain not only the actual control information within the first two frames of a four-period period, but also the binary signals 0, according to the invention, within the last two frames of such a period, are then each assigned to a first input of two AND gates 44 or 45, which distribute the signal pulses to the inputs B1 and B of the associated channel distributor. The AND gate 44 is controlled via a second input from the output L of the flip-flop 42 by the pulse sequence Fl, FO, Fl, FO and consequently only passes on a signal during the first frame of a four-period period. The controlling pulse sequence is positive again during the third frame, but the binary signal 0 impressed in the corresponding signal pulse position blocks output B1. In a similar way, the AND gate 45 is controlled by the pulse sequence FO, Fl, FO, Fl from the output 0 of the flip-flop 42 and can therefore only pass a binary signal L during the second frame of a group of four. Output B is also blocked here by the applied binary signal 0 during the fourth frame of a group of four, despite the positive voltage of the controlling pulse train. The AND gate 43 can be combined with the AND gate 44 or 45 to form an AND gate with three inputs.

Claims (5)

Patent claims: 1. Method for message transmission in unidirectional or bidirectional operation over a time division multiplex channel and at least one channel group that can be coupled with this, the messages being sent from the channel group by time bundling to the time division multiplex channel or vice versa from be transmitted to this by channel distribution on the channel multiple, and the messages are transmitted in the time division multiplex channel in the form of successive pulse frames, each of which has a number of channel clocks corresponding to the number of channels and a synchronous pulse position comprises, and wherein each channel clock comprises a plurality of message pulse locations for the Transmission of the messages and a signal pulse point for transmission from the relevant Additional information assigned to the channel, such as B. Control information includes during the The content of the synchronous pulse locations in successive pulse frames is a synchronous pulse train forms, characterized by the following features: a) for the transmission of the additional information, periods of signal pulse points (D 1) of consecutive pulse frames (frame 1 to frame 4) that are assigned to one channel and are arranged in the relevant channel clocks (CH 1 or CH1 ... CH24) are provided, b) each period of the signal pulse points assigned to a channel in successive pulse frames (frame 1 to frame 4) contains a plurality of signal pulses that differ with respect to the synchronous pulse sequence (FR) and at least one further signal pulse determining the additional information. 2. The method according to claim 1, wherein the content of the synchronous pulse locations in successive Pulse frame forms an L-0 pulse train, characterized in that each period of the one A plurality of signal pulse locations assigned to one another and which correspond to one another are assigned to the channel Contains signal pulses. 3. The method according to claim 1, characterized in that each period of the one channel assigned signal pulse points in each successive pulse frame a plurality of contains mutually matching signal pulses. 4. The method according to claim 1, characterized in that each period of the one Signal pulse points assigned to the channel over four consecutive pulse frames (frames 1 to Frame 4) extends and two matching signal pulses in each successive pulse frame contains. 5. The method according to claim 4, characterized in that each period of the one channel assigned signal pulse points in each case in the last two consecutive pulse frames contains matching signal pulses. 1 sheet of drawings 909 521/465