DE2839893C3 - Time division multiplex transmission methods - Google Patents

Description

The invention relates to a time division multiplex transmission method and a time division multiplex system, several plcsiochronous digital signals on the transmitter side le according to a stuffing method to a time division multiplex signal are summarized, in which the time division multiplexed the information bits of the individual plesiochronous Digital signals. Frame identification and service bits as well as additional bits for initial additional information for the stuffing process and in the case of the receiving side the time division multiplex signal back into the individual plesiochronous digital signals with the associated bit clocks is resolved.

Such a time division multiplex transmission method is from DK-AS 2b 22 107 and »Nachnchtentech niche magazine «(NTZ). 30 (1977) 2. Pages 138 to known. This uses thirty 64 kbii / s file signals to 2048 kbit / s digital signals of the first Composed hierarchy level

A synchronous known from the magazine "Cables et Transmission" 32 (1978) 2. Pages 152 to 191 Time division multiplexing can not only accomplish this bundling, but also an 8 kHz bit group clock of the data signals? .u transmitted. This bit group clock, which is particularly advantageous for switching forms groups of 8 bits, for example, and is then called the octet clock. The transmission of this clock is easily possible in the synchronous system because of the 8 kHz frame rate of the 2048 kbit / s data signal is synchronous with the 8 kHz bit group clock of the data signal. The latter can therefore easily be im Demultiplexer can be derived from the frame clock.

The object of the invention is to provide a time-division multiplex over-

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specify transmission method with which such a bit group clock also over a time multipiex system for plesiochronous digital signals, such as the PCM 30 D system, can be transmitted.

Based on a time division multiplex transmission method of the type described in the introduction, this object is achieved according to the invention in that a bit group clock forms the groups of m bits, is transmitted to each plesiochronous digital signal in such a way that in the time division multiplex signal for each plesiochronous digital signal further additional bits for a second additional information the phase position of the bit group clock can be inserted.

An advantageous variant results when the second additional information is protected against bit errors is transmitted.

In the case of a time-division multiplex signal which, like that of the PCM 30 system or the PCM 30 D system in one Superframe contains identifier channels, it is advantageous if the further additional bits in one or in several license plate channels are transmitted.

It is also advantageous if the first additional bits in a first identification channel and the additional additional bits are transmitted in a second identification channel will.

An arrangement for carrying out the method on the transmission side with an adaptation device for each plesiochronous digital signal, which turns this into a synchronous main signal and generates a first synchronous additional signal, and with a synchronous multiplexer. the Main signals and first additional signals for the stuffing process with the addition of the frame identification bits and which combines service bits to form the time division multiplex signal is advantageously characterized in that that an extended adapter is provided, which for each plesiochronous digital signal a second Additional synchronous signal generated for the bit group clock. and that an extended synchronous multiplexer is provided which also inserts the second additional synchronous signals into the time-division multiplex signal.

An arrangement for carrying out the method at the receiving end with a synchronous demultiplexer, the synchronous main signals and the first synchronous additional signals which resolves a plesiochronous digital signal, and with recovery devices, those from the respective synchronous main signals and the respective first additional synchronous signals the original plesiochronous digital signal with the associated Generate bit clock again is advantageously characterized in that an extended synchronous demultiplexer is provided that for each plesiochronous digital signal also a second additional synchronous signal and that an advanced recovery device is provided. which also evaluates the / wide additional synchronous signal and the bit group record gives away.

For the practical implementation, it is advantageous if a non-extended recovery device, a divider that divides the bit clock in the ratio I: m , and an evaluation device are provided in the extended recovery device that evaluates the /.wide additional synchronous signal and converts the divider into sets the correct phase position.

For carrying out the second variant of the method, it is advantageous if a special divider is used with an output at each stage, if a special evaluation device with test inputs is provided if these outputs and test inputs are connected to each other and if the extended Evaluation device the phase position of the special divider with the received second additional information compares and the special divisor again only after two or more mismatches puts.

The invention is explained in more detail below on the basis of exemplary embodiments

F i g. 1 shows a time division multiplex system according to the invention,

F i g. 2 shows a first recovery device,

F i g. 3 shows a second recovery device, FIG. 4 shows a pulse frame,

F i g. 5 shows a table of the code words in the sixteenth time segment of the basic frame,

Fig. 6 shows a table of the additional information in a super-superframe,

F i g. 7 shows a pulse schedule in the case of positive stuffing and FIG

8 shows a table of the additional bits of the first and second additional information in the ÜL «.r superframe.

Fig. I shows a Zcitmultiplexsysem according to the invention for plesiochronous digital signals with a transmitting part I and a receiving part II. The transmitting part I contains adaptation devices AX to An and a synchrcii multiplexer SM. The receiving part II contains a synchronous demultiplexer SD. Recovery devices RX to Rn, as well as a monitoring device O. Plesiochro ie digital signatures with DX to Dn. Bit clocks with TX to Tn and bit group clocks with TIm to Tnm . The designations Γ to n ' stand for synchronous main signals. for first additional synchronous signals the reference symbols 1 "to n" and for second additional synchronous signals reference symbols Γ "to π '".

The adaptation:> device A 1 is supplied with the plesiochronous digital signal DX, the bit clock 7 "! And the bit group clock 7" Im. The latter is the result of division with the ratio Mm from the bit clock TX . The adapter AX sets these signals into the synchronous main signal Γ. the first synchronous additional signal 1 "and the second synchronous additional signal Γ" to. The bit rate of the plesiochronous data signal DX is adapted to the bit rate of the synchronous main signal Γ by a stuffing process. For this purpose, filling bits are inserted in the positive stuffing and information bits are removed in the negative stuffing consists of the stuffing information, which specifies how and at which Stellon was stuffed and from the information bits removed from negative stuffing. ”The further adjustment devices A 2 to An er7eu _c , and other synchronous main and synchronous auxiliary signals which are combined in the synchronous multiplexer SM to form a multiplexer signal; i. This is fed in the receiving section II to the synchronous demultiplexer SD , which breaks it down again into individual synchronous main and synchronous additional signals, which are fed to the recovery devices R I to Rn These in turn derive plesiochronous Dig'taU from the synchronous main and synchronous additional signals ignale with the associated bit rate and bit group rate. A monitoring device 0 monitors the time-division multiplex signal for interference and intervenes in the recovery devices RX to Rn , as shown in FIG. 3 is explained in more detail.

Fig. 2 shows in detail a recovery device

treatment R 1, which is constructed in the same way as the other recovery devices R 2 to Rn. The recovery device R 1 contains a conventional recovery device R '\, to which the synchronous main signal 1' and the first synchronous additional signal i "is fed and which is the plesiochronous Digital signal D I and the bit clock T 1 emits. further, a divider TE 1 and a Auswertc device is .DELTA.U.sub.i provided. the divider TE 1 divides the bit clock T \ relative Mm. Here, m different phase positions are possible. Thus, the from the divider TE 1 The output clock corresponds in phase to the bit group clock TIm, it contains set inputs S t to Sq. which are connected to the evaluation device AUi, which evaluates the phase information of the second additional synchronous signal I "'and sets the divider TEi to the correct phase position. Since the evaluation device AU I sets the divider TE 1 in the correct phase position every time phase information is received by the second syncronization / signal I ", it is advantageous to transmit the phase information protected against bit errors. In this way this prevents individual bit errors in the multiplication signal from interfering with the bit group clock.

Fig. 3 shows a second variant of the recovery device R i. in which the phase position of the divider TE ' 1 is transmitted via the outputs Pi to Pp to the evaluation device AUi , lcdesmal when receiving phase information, the evaluation device AlJ i compares the phase position of the divider TE 1 with the received second additional information. The divider TE I is only set again in the event of two or more inconsistencies.

If the monitoring device (7 in E i g. 1 has detected a fault in the entire time division multiplex signal, it sends a signal to the evaluation device AU ' 1 via a control line; i, which now already sends the divider TE' 1 with the first received phase information As a result, the correct phase position of the clock is immediately restored after a disturbance in the time division multiplex signal.

The invention can be used to transmit the bit group. nnfr OWt (Mt-TaI ₁ -KK. unn H LH /

»M PCM 30 superframe forms. The first four bits of the sixteenth time segment of the basic frame I are used to transmit the license plate frame identifier and bits b and 7 are used to transmit a message word. Bits 5 and 8 are not used. In the time segments 16 of the basic frames II and XVI, two code words of four bits are transmitted, each of which is assigned to a voice channel.

Fig. 5 shows a table of the occupancy of the time segment ZA 16 of the basic frames GR I to XVI.

Each of the thirty channels is assigned four identification channels with a nominal bit rate of 500 bit / s. If a channel is used for the transmission of 64 kbit / s data signals, the four identification channels are available for the transmission of additional synchronous signals. In the PCM JO D system, the first synchronous additional signal is. which contains the additional information for the stuffing process, transmitted serially in the identifier channel; i I. Since the first additional synchronous signal contains four bits, an Uber superframe is formed from 4 * 16 = 64 basic frames. The first Synehron additional signal is accordingly in the first bit a I of the time segment 16 of the basic frame GR II. XVIII. XXXIV and L.

F i g. 6 shows in a further table how the bit a I of the basic frame II is occupied in the super-superframe if there is no plugging "0". Positive plug "+" or negative plug "-" is present. The protected two-value stuffing information is contained in the first three bits of each additional information item. In the case of negative stuffing, the fourth bit contains an information bit I. With the PCM 30 D system, three identification channels are still available for the transmission of additional signals.

7 shows the transmission of the 64 kbit / s data signal in the case of positive justification. The 64-kbit / s data signal is broken down into 8-bit segments, which are each transmitted in a time segment ZA. From time to time a stuffing bit Sam is inserted at the beginning of a time segment ZA. There are eight different possibilities for the position of the beginning of an octet OTm in a time segment ZA. Eight code words of the additional information correspond to these eight possibilities.

* - ** nni mn ritt tnn in tin tit

D can be applied. The pulse frame of this system is from the basic frame of the PCM 30 system for Telephone signals built up.

E ι g. 4 shows the basic frame of a system PCM 30, denoted by the numbers I to XVI. In the time segments I to 15 and 17 to 31 of each basic frame, coded telephone signals are transmitted. In each time segment 0 of each odd-numbered basic frame I. II. V ... w: / d a frame code word and in each time segment 0 of an even-numbered basic frame II, IV. Vi ... a message word is transmitted. D is a message bit for urgent alarm. A / a message bit for non-urgent alarm. X is a reserved bit for international use and not a reserved bit for national use. The time segment 16 of each basic frame is used to transmit the identifier, the sixteen basic frames I to XV! one depending on whether the first, second ... eighth bit of the octet at the beginning of the. Period of time ZA lies. With the help of this second additional information, the evaluation circuit AU or / U "in the recovery device R 1 to Rn can identify the beginning of the octet and set the divider TE in the correct phase. The identifier channels b, e and c / are available for the transmission of this second additional information.

Fig. 8 shows as an example the serial transmission in the identifier channels a to b. In a super-superframe, 4-bit code words are also transmitted in the identifier channel £. The first three bits contain the second additional synchronous information. The fourth bit X is not evaluated. As long as there is no stuffing, the second additional information remains unchanged. What is shown is the change in the additional information during a positive stuffing process.

For this 5 sheets of drawings

Claims (9)

Patent claims: J. Time-division multiplex transmission method in which a plurality of plesiochronous digital signals are combined to form a time-division multiplex signal according to a stuffing method on the transmission side, in which the time-division multiplex signal contains the information bits of the individual plesiochronous digital signals, frame identification and service bits as well as additional bits for additional information for the stuffing method, and the time division multiplex signal on the receiving side is resolved again into the individual plesiochronous digital signals with the associated bit clocks, characterized in that a bit group clock, which forms groups of m bits, is transmitted to each plesiochronous digital signal in such a way that in the time-division multiplexed signal for each plesiochronous digital signal further additional bits for a second additional information the phase position of the bit group clock can be inserted. 2. The method according to claim I, characterized in that the second additional information against Bit error protected is transmitted. 3. The method according to claim 1 or 2 with a time division multiplex signal in a Überrahnien Contains identifier channels, characterized in that the further additional bits in one or in several license plate channels are transmitted (F i g. 4 to 7). 4. The method according to claim 3, characterized in that daw the first additional bits in a first identification channel and the other additional bits in transmitted on a second flag channel. 5. Arrangement for carrying out the method on the transmission side according to claim 1 or 2 with an adaptation device for each plesiochronous digital signal, which generates a synchronous main signal and a first synchronous additional signal therefrom, and with a synchronous multiplexer. the main signals and first additional signals for the stuffing process by inserting the frame identification bits and the service bits to form the time division multiplex signal, characterized in that an extended adapter (A 1 to A ^ is provided, which for each plesiochronous digital signal (D 1 to Dn) a second Additional synchronous signal (I '"to n") generated for the bit group clock (Tim to Tmn) , and that an extended synchronous multiplexer (SM) is provided which also carries the additional additional synchronous signals (1'"toη") Time division multiplex signal inserts (Fig. 1). 6. Arrangement for carrying out the receiving-side method according to claim 1 or 2 with a synchronous demultiplexer, which resolves the synchronous main signals and the first synchronous target signals of the individual plesiochronous digital signals, and with recovery devices which are derived from the respective synchronous main signals and generate the original plesiochronous digital signal with the associated bit clock again for the respective first synchronous additional signals, characterized in that an extended synchronous demultiplexer (SD) is provided, which for each plesichronous digital signal (D 1 to Dn) also has a second synchronous Additional signal (V " to n '") derives, and that an extended recovery device (R 1 to Rn) is provided, which also the second synchronous addition signal (V " to n '"; evaluates and outputs the bit group clock (TXm to 7> wnj (Fig. 1). 7. Arrangement according to claim 6, characterized in that in the extended recovery device (R 1 to Rn) a non-extended recovery device (R 't), a divider (TEt) which divides the bit clock in the ratio 1: m , and an Au value device (AUi) are provided, which evaluates the second additional synchronous signal (V " Lis η '") and sets the divider (TEi) in the correct phase position (FIG. 2). 8. Arrangement according to claim 7, characterized in that a special divider (TE ' 1) with an output at each stage and an extended evaluation device (AW 1) with test inputs are provided that these outputs and test inputs are connected to each other that the extended evaluation device (AW 1) compares the phase position of the special divider (TE ' 1) with the received second additional information and sets the special divider (TE' 1) again only after two or more times non-agreement. 9. Arrangement according to claim 8, characterized in that a central monitoring device (0) is provided on the receiving side, which is connected via control lines (a) to all the extended evaluation device (AW 1 to A Wn) and which after the termination of a disturbance of the entire time-division multiplex signal extended evaluation devices (AW 1 to AWn) veraniast to set the extended dividers (TEi to TEn) at the first mismatch (Fig. 1).