DE2839893B2 - Time division multiplex transmission - Google Patents

Description

The invention relates to a time division multiplex transmission method and a time division multiplex system in which several plesiocnrune digital signals are transmitted on the transmission side be combined according to a stuffing process to form a time division multiplex signal, in which the time division multiplex signal 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 for the receiving-sensitive the time-division multiplexed signal back into the individual plesiochronous digital signals with the associated

Bit files is resolved. Such a time division multiplex transmission method

so is from DE-AS 26 22 107 and the "communications journal" (NTZ), 30 (1977) 2, pages 138 to known. This turns thirty 64 kbit / s Da-Kin signals Combined to 2048 kbit / s digital signals of the first hierarchy level

A synchronous known from the magazine "Cables et Transmission" 32 (1978) 2, pages 152 to 191 The time division multiplex system can not only accomplish this bundling z / j, but also an 8 kHz bit group pool to transmit the data signals. This

w bit group feature particularly advantageous for switching forms groups of 8 bits, for example, and is then called octel clock. The transmission of this clock is easily possible in the synchronous system because the 8 kHz frame rate of the 2048 kbit / s data

h ¹ »signal is synchronous with the 8 kHz bit group clock of the data signal. The latter can therefore easily be derived from the frame clock in the demultiplexer. The object of the invention is to provide a time-division multiplex over-

to indicate the contract with which such a Bit group clock also via a time division multiplex system for plesiochronous digital signals such as the PCM 30 D system can be transmitted.

Issued by 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, to each plesiochronous digital signal is transmitted in such a way that in the time division multiplexed signal for each plesiochronous Digital signal further additional bits for a second additional information about the phase position of the bit group clock 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 license plate channels, it is advantageous to if the further additional bits are transmitted in one or more identifier channels.

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

An arrangement for carrying out the transmission-side Method with an adaptation device for each plesiochronous digital signal, which turns this into a synchronous main signal and generates a first synchronous addition 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 of the individual plesiochronous digital signals dissolves, and with recovery facilities, the original from the respective synchronous main signals and the respective first synchronous additional signals Generating a plesiochronous digital signal with the associated bit clock is advantageous characterized in that an extended synchronous demultiplexer is provided for each plesiochronous Digital signal also derives a second additional synchronous signal, and that an extended recovery device is provided, which additionally evaluates the second additional synchronous signal and the bit group clock 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 1: m , and an evaluation device are provided in the extended recovery device, which evaluates the second additional synchronous signal and divides the divider into the correct phase position.

It is advantageous for carrying out the second variant of the method if a special divider b% with an output at each ^p r stage, if a special evaluation device with test inputs is provided, if these outputs and test inputs are connected to one another and if the extended evaluation method is used Compares the phase position of the special divider with the received second additional information and only sets the special divider anew after two or more inconsistencies

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

Fig. 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, F i g. 4 shows a pulse frame,

5 shows a table of the code words in sixteenth period of the basic framework,

6 shows a table of the additional information in an upper superframe,

7 shows a pulse plan for the case of Positiv-Stoyfens and

F i g. 8 shows a table of the zuvizbits of the first and second additional information in the super-superframe.

F i g. 1 shows a time division multiplex system according to the invention for plesiochronous digital signals with a transmitting part I and a receiving part H. The transmitting part I contains adapting devices A 1 to An and a synchronous multiplexer SM. The receiving part II contains a synchronous demultiplexer SD, recovery devices R 1 to Rn, as well as a monitoring device and plesiochronous digital signals are denoted by D 1 to Dn, bit clocks with 7 * 1 to Tn and bit group clocks with Tim to Tnm Designations 1 'to n', the reference symbols 1 "to n" for first synchronous additional signals and reference symbols r'bisij "'for second synchronous additional signals.

The adapter A 1 is supplied with the plesiochronous digital signal Dl, the bit clock 7 * 1 and the bit group clock TXm. The latter is derived from the bit clock Ti by dividing it with the ratio l / m. The adaptation device A 1 converts these signals into the synchronous main signal 1 ', the first synchronous additional signal 1 "and the second synchronous additional signal Γ". The bit rate of the plesiochronous data signal D 1 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. The additional information for the stuffing procedure is transmitted additional signal in synchronism 1 "in the first This consists of stuffing information which indicates, as has been and at what points stuffed and taken out from the leg negative stuffing information bits Di:.. Vieiteren matching devices Al to Aa generate further synchronous main and synchronous additional signals, which are combined in the synchronous multiplexer 5Ai to a time division multiplex signal. This is in the receive portion II the synchronous demultiplexer SD supplied to it dissolves again into single synchronous main and synchronous additional signals, the recovery means R 1 supplied to Rn. These are derived in turn from the synchronous main and synchronous additional signals plesiochronous digital signals with an associated bit clock and Bitgruppentakt from. a Überwachungseinric'itung Ü monitors the time division multiplexed signal to interference and engages to Rn in the recovery means R 1, as is explained in more detail with reference to FIG.

Fig. 2 shows in detail a recovery device

tung R 1, which is constructed as well as the further rock obtaining means R2 to Rn. The recovery unit R 1 includes a conventional recovery unit R '\, of the synchronous main signal 1' and the first synchronous addition signal is supplied to 1 "and the plesiochronous Digital signal D 1 and the bit clock Π outputs. further, a divider TE 1 and an evaluation device .DELTA.U.sub.i is provided. the divider TEX divides the bit clock Π in the ratio l / m. Here, m different phase positions are possible. Thus, the output from the divider TEi clock coincides in phase with the bit group clock Tim , it contains set inputs 51 to Sq, which are connected to the evaluation device AUi . This evaluates the phase information of the second synchronous additional signal I "'and sets the divider TEX in the correct phase position. Since the evaluation device AUX sets the expensive TEi in the correct phase position every time phase information is received by the second additional synchronous signal Y " , it is advantageous to transmit the phase information protected against bit errors. This prevents individual bit errors in the multiplex signal disturb the bit group clock.

3 shows a second variant of the recovery device R 1, in which the phase position of the divider TE'X is transmitted to the evaluation device A U '\ via the outputs Pi to Pp . Each time phase information is received, the evaluation device AU'X compares the phase position of the divider TE'X with the received second additional information. The divider TE'X is only set again in the event of two or more inconsistencies.

Has the monitoring device Ü in F i g. 1 recognizes a disturbance of the entire time division multiplex signal, this sends a signal via a control line a to the evaluation device AU'X, which now sets the divider TE'X again with the first received phase information The phase position of the clock is immediately restored

The invention can be used to transmit the bit group clock or octet clock of 8 kHz in the PCM 30 system 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

F i g. 4 shows the basic frames of a system PCM 30, denoted by the numbers I to XVI. In the time segments 1 to 15 and 17 to 31 of each basic frame, coded telephone signals are transmitted. A frame code word is transmitted in each time segment 0 of each odd-numbered basic frame I, III, V ... and a message word is transmitted in each time segment 0 of an even-numbered general frame II, IV, VI .... D is a message bit for urgent alarm, N is 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 XVI forming an upper frame. 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 6 and 7 are used to transmit a message word. Bits 5 -> and 8 are unused. In the time segments 16 of the basic frames II and XVI, two identifier words of four bits are transmitted, each of which is assigned to a voice channel.

F i g. 5 shows a table of the occupancy of the time lapse

Section ZA 16 of the base frame GR I to XVI.

Each of the thirty channels have four flag channels assigned with the nominal bit rate of 500 bit / s. Becomes a channel for the transmission of 64 kbit / s data signals are used, the four identification codes are

5 channels are available for the transmission of additional synchronous signals. In the PCM 30 D system, the first synchronous additional signal, which contains the additional information for the Siopf method eninäii, scricii in Kennzciencnkanai a X, is transmitted. Since the first synchronous additional signal four

Contains bits, a super-superframe is formed from 4 * 16-64 basic frames. The first synchronous additional signal is accordingly in the first bit a X of the time segment 16 of the basic frames GR II, XVIH, XXXIV and L.
F i g. 6 is shown in a further table, like the bit a I

of the base frame * II is occupied in the over-superframe, if there is no plug "0", positive plug "+" or NegaU plug "-" In the first three bits each additional information contains the protected two-valued stuffing information. The fourth bit contains im

In the case of negative stuffing, a information bit I. With the PCM 30 D system, three identification channels are still available for the transmission of additional additional signals.
7 shows the transmission of the 64 kbit / s data signal for the case of positive stuffing. 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 S is inserted at the beginning of a time segment ZA . There are eight different possibilities for the position of the start of an octet OT in a time segment ZA. These eight options correspond to eight code words of the additional information, for example 001,010,011,100,101,110,111,000, depending on whether the first, second ... eighth bit of the octet is at the beginning of the time segment ZA. With the help of this second additional information, the evaluation circuit AU or AU ' in the recovery device R 1 to Rn identify the beginning of the octet and set the divider TE in the correct phase. The identification channels b, e and </ are available for the transmission of this second additional information.

As an example, FIG. 8 shows the serial transmission in the identifier channels a to 6. In a super-superframe, 4-bit code words are also transmitted in the identifier channel b. The first three bits contain the second synchronous additional format km. The fourth bit X is not evaluated. As long as stuffing is not taking place, the second additional information remains unchanged. The change in the additional information during a positive stuffing process is shown.

See S sheet drawings

Claims (6)

Patent claims: 1. Time-division multiplex transmission method in which a plurality of plesiochronous digital signals are combined on the transmission side using a stuffing method to form a time-division multiplex signal, in which the time-division multiplex signal contains the information bits of the individual plesiocbronous digital signals, frame identification and service bits as well as additional bits for a first additional information signal for the stuffing method and in the case of the receiving side the time division multiplexing 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 1, characterized in that that the second additional information is transmitted protected against bit errors. 3. The method according to claim 1 or 2 with a time division multiplex signal in f-inem superframes Contains identifier channels, characterized in that the further additional bits in one or in several license plate channels are transmitted (Fig. 4 to 7). 4. The method according to claim 3, characterized in that the first. Additional bits in a first Identification channel and the further additional bits are transmitted in a second identification card »· '. 5. Arrangement for carrying out the transmission-side method according to claim 1 or 2 with an adapter for each plesiochronous digital signal, which generates a synchronous main signal and a first synchronous additional signal from this, and with a synchronous multiplexer, the main signals and first additional signals for the stuffing composed with the insertion of the framing bits and the service bits to the time division multiplex signal, characterized in that an expanded adjustment means is provided (a 1 to an) including a second synchronous addition signal for each plesiochronous digital signal (Di to Dn) (1 '"to n '") is generated for the bit group clock (Tim to Tmn) , and that an extended synchronous multiplexer (SM) is provided which also inserts the second additional synchronous signals (1"' to n '") into the time-division multiplex signal (F i g . 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 additional signals of the individual plesiochronous digital signals, and with recovery devices, which from the respective synchronous main signals and the respective first Svnehron additional signals generate the original plesiochronous digital signal with the associated bit clock, characterized in that an extended synchronous demultiplexer (SD) is provided, which for each plesichronous digital signal (D I to Dn) also a second synchronous additional signal (Γ " to n '") , and that an extended recovery device (R 1 to Rn) is provided, which additionally evaluates the second additional synchronous signal (1"' to n '") and outputs the bit group clock (Timbxs 7iwj; (Fig, I ). 7, arrangement according to claim 6, characterized in that in the extended recovery device (RX to Rn) a non-extended recovery device (A'1), a divider (TE X) which divides the bit clock in the ratio 1 : m , and an evaluation device (AUi) are provided, which evaluates the second additional synchronous signal (1 '"to n'") 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'i) with an output at each stage and an extended evaluation device (AWX) with test inputs are provided, that these outputs and test inputs are connected to each other, that the extended evaluation device (AU'X) compares the phase position of the special divider (TE'X) with the received second additional information and sets the special divider (TE 'X) again only after two or more non-correspondence 9, arrangement according to claim 8, characterized in that a central monitoring device (U) is provided on the receiving side, which is connected via control lines (a) to all of the extended evaluation devices ( AU'i to AU'n) and which, after the end of a disturbance of the whole The time-division multiplex signal causes the extended evaluation devices (AW \ to AU'n) to set the extended dividers (TEi to TEn) as soon as the first non- agreement occurs (FIG. 1).