DE1913989C2 - Method and circuit arrangement for outputting data signals, in particular formed by switching indicators, from a PCM transmitting station and receiving such data signals in a PCM receiving station of a PCM telecommunications network - Google Patents

Description

In telecommunication systems working according to the time division multiplex principle and in particular in PCM telecommunication networks there is often a desire to have data signals in addition to actual message signals from transmitting stations to receiving stations. These data signals are either to receive signals that are independent of the respective communication links or signals which are associated with the respective communication links. In the case of the last-mentioned data signals it is in particular a switching indicator relating to the respective communication link. Such switch indicators are used to control telecommunications systems in general Switching operations, such as B. the release of connections.

For the transmission of Dulensignnlcn from a sending point to a receiving point in a PCM telecommunications network it is already known, within each time slot of a time channel from a series of pulse frames comprising time channels to use one line of each time channel (see »NTZc, ! 967. No. 11 pp. 667 to 682; "The Telecommunications Engineer", March 1960, p. 19). In pulse frames with one period each comprising 32 time slots from 125 / (S is often called the "data channel" as the channel I ^ hvvi: 17 k-7.1- <-loc · In ,,, ία, -! "/" 7. ^ ι f ™ j-J-; ~., j -1-- IK of the respective heart rate frame. In the time slots dicjec data channel are then all Transmit data signals from the sending point to the receiving point. The relevant data signals are included in the timeframe of the respective Transfer time slots, these are individual time segments within the respective time slots. So embraced z. B. a time slot with a duration of 5.2 ns 8 time slot elements, within which a total of 8 bits can be transmitted.

It is also known ("IEEE Transactions on Communication Technology". October 196S. Vol. 16, No. 5. Pages 636, 637). with a PCM system pulse frames each encompassing 32 time slots a time slot for synchronization and a time slot for signaling iierau / u /. Each line subject comprises 10 time slot elements and is thus able to transmit 10 bits. The duration of a pulp frame is chosen to be 83 «s, which is a pulse train frequency of 3.84 MHz.

The invention is now based on the object of showing a way of proceeding to each a number of time slots occurring in time slots of communication links used Data signals concentrically from a PCM transmitting point of a PCM telecommunications network to a PCM receiving point of the PCM telecommunications network concerned. To solve this problem the invention is based on a method and circuit arrangement for delivering a number in each case of data signals, in particular formed by switching indicators, from a PCM transmission point of a PCM telecommunications network in the bit positions provided for this purpose as a data channel Time channel from a series of time channels that occur cyclically and repeatedly in a pulse frame a PCM transmission link to a PCM receiving station and forwarding of the relevant data signals via separate data signal lines PCM receiving station, with the data signals on the SCndc side in each case in the time subjects of the ülvigen, in particular used by communication links Time channels occur. According to the invention, this method is now characterized in that from Pulse frame to pulse frame in each case in different time channels occurring data signals in a dei Recording register associated with the PCM transmitting station is saved and used for the duration of the de> the next data channel is stored and sent to the PCM receiving station, ir

which the relevant data signals into a corresponding one belonging to the PCM receiving station? The exception register is stored and individually associated from these via the individual time channels Buffer to the individual data signal lines are delivered.

The method according to the invention is characterized on the one hand by the advantage ύ-: τ ^Λ η using a 'simple principle. The ones from the PCM-Sendest: · !! to be transmitted to the PCM receiving station ;; ·:

Data signals only need to be in a send; · beiii! intended admission register and stored at the appropriate times; and from an Ai provided at the receiving end ;: ' Tolling to be accepted. For andc

Ren, the method according to the invention involves the fact that with the help of a single recording register belonging to the PCNi Sc ".Jc:, tc !! c and m ^{: the} help of a single receiving register belonging to the PCM reception position a large number of data signals from the PCM Sendcstcl'c, ". the "" PCM receiver: can. The method according to the invention is thus suitable for ile use in an advantageous manner;? ■ a PCM telecommunications system in which the respective PCM transmission points send the individual message connections to each other message sign ^ l ·. each together with the respective message connection associated data signals are supplied

and in the case of the Aiiswerle devices connected to the PCM receiving points dk relevant message signals together with the respective communication links. Höriizen data signals are to be fed.

To carry out the Vcr according to the invention In terms of driving, it is advisable to use a circuit arrangement which is associated with the PCM Scndestcllc Contains acceptance registers that start with scrnerr Angling input to a data signal transmission device isi, soft each belonging to a data signal Signal elements in each case during the duration of a Zeitfachcs of that Zcitkanals one after the other outputs, which is occupied by a connection to which the data signal in question belongs and the output is connected to a PCM transmission line and connected to this jcwcil · during the time threading of the data channel! emits the previously recorded data signals. This circuit arrangement also includes a cJei Recording register belonging to the PCM receiving station, which is connected to the PCM transmission line on the input side is connected and that in each case during the duration of the time slots of the Datcnkanal data signals takes. This admission register is the starting point

«5 with in one of the number of next to the data channel existing time channels are connected to the corresponding number of buffer stores provided, the icwcil: record corresponding data signals. Hicrdurcr

I 913

there is the advantage of a relatively low level of technical training Effort.

Ocmüß an expedient embodiment of the circuit arrangement according to the invention, the recording register connected to the data signal transmission device for a data signal recording is acted upon with control signals emitted by a counter that has a counting capacity that is equal to the sum of the number of times contained in a pulse frame and that in a time slot of the data channel is the maximum number of data signals that can be transmitted. In its counting capacity, the counter emits such control signals at least during a number of time slots resulting from the maximum number of data signals that can be transmitted in a cell of the data channel . Bring this measure! with the advantage of a simple circuit structure for recording .in data signals in time from pulse to pulse frame other time channels with it. According to an expedient embodiment of the circuit arrangement according to the invention, when using a shift register with a signal input .. ing. a shift input and a signal output ι-, sending-side recording register with the sliding gate in addition to a control pulse for pushing in and out the data signals into and out of gege-, -in register emitting control means' ■■ rien may still die another Steuercinrichi'm ", the i of a Ausspeicherimg the Daiensij: ile effected from the shift register" that immediate b ir with. Beginning of the unloading data signals are stored out of vk'm shift register. This has the advantage that data signals are each: stored out of the end of the receiving register at the beginning of the time slot of the data signal and then through the PCM transmission line "to the PCM receiving station can be transferred, -o Jass otherwise necessary special monitoring and evaluation devices dispensed with h, with the help of which it would be possible to determine in each case. : at which point within the respective time slot Jl ¹ S data channel the respectively desired data signals have been transmitted.

According to a further expedient embodiment of the circuit arrangement according to the invention, each data signal line in the PCM receiving station has associated therewith a number of flip-flops corresponding to the number of signal elements each forming a data signal. This advantageously enables data signals belonging to other connections to be transmitted to the PCM receiving station in consecutive pulse frames without losing data signals exceeded in the preceding pulse frame for their forwarding and possibly subsequent evaluation. According to yet another useful embodiment of the circuit arrangement according to the invention, corresponding flip-flops of the respective flip-flops forming a group, each provided for the acceptance of the data signals transmitted in a time slot of the data channel via the PCM transmission line, are each corresponding flip-flops to the same outputs of the receiving register connected, the Füp-FIops belonging to these groups being able to take over data signals that have just been issued by separate activation of the receiving registers on the receiving side. In this way, ei, de advantage a stored data signals are a particularly simple distribution of the I cmpfangsseitigen pickup register each candidate coming outgoing lines.

The invention is based on drawings He explains in more detail below using an exemplary embodiment.

Fig. 1 shows a circuit arrangement for through implementation of the method according to the invention;

Fig. 2 illustrates in a diagram at dei In Fig. 1 shown circuit arrangement running processes.

The circuit arrangement shown in FIG. 1 comprises a PCM transmitting station Ss with an associated data signal output device Ds and a data signal recording device Dc belonging to a PCM receiving station. The PCM triangle is not shown next!.: R. The data signal recording device Dc is connected to the data output device Ds via a PCM transmission line /. PCM data signals and PCM data signals are output via this PCM transmission line L from the PCM transmission station Ss and the data terminal output device / Jv associated therewith. As will be seen in greater detail below, the PCM data signals are recorded and forwarded by the data signal recording device Dc.

The PCM transmission point Ss , only indicated in FIG. 1, contains a PCM transmission line. are transmitted via the PCM-Nachrichlensiciiale in Zeitfäi.iern of communication links assigned time channels. The time slots of the total available time channels appear cyclically and repeatedly in pulse frames. Together with the message signals associated with the respective message connections, the PCM transmitting station Sv in the present case may also emit data signals associated with the respective N; vhrich-'cn connections. In the present case it is assumed that the data signals associated with the message connections are each formed by two signal elements (bits). For this purpose, as shown in Fig. 1, two file signal senders are provided with fast changeover switches (JSd and USb, each of which is able to send a binary "I"or> ^s (k) from its switching arm. These binary signals are present the switching contacts of the respective changeover switch uS and USB constantly in. the signal elements thus occurring at the switching arms of the switch USU and USh of the respective data signal are supplied via separate Signallcitungen SMa and SMb to the inputs of two switches .SV /. Sh, which are operated alternately in succession . on the other side, the two switches Sa, Sh are interconnected and connected to a ellten to g in F i. 1 Darges> data signal output means Ds belonging receiving register SRs to a also referred to below as data signal input input Ed. is at this input of the Aufnahmercgisturs SRs it is the input of this Regi intended for a data signal recording sters. The signal elements belonging to a data signal each occur one after the other for the duration of a time multiple of the communication channel used by the connection which the relevant Dnlenshmnl / m-Miör! "Iti n-il ·.»: Ι · - - «

the actuation input /; «of the switch Sa, for example, by selecting one part of the first half of each time slot of the time slots occurring on the PCM transmission line L ', a control signal making the switch Sa transferable is supplied, while the control input pb of the switch Sb during a part df, A corresponding control signal can be supplied to the second half of each of the mentioned time slots.

In order to be able to store the data signal elements respectively supplied to the data signal input Ed of the recording register SRs in this recording register, corresponding control signals or control pulses must also be supplied to this recording register SHs. For this Aweck a control input Es of the recording register SRs via an OR gate GOl from the output of an AND gate Gl / 1 corresponding control signals are fed. The AND gate GU1 is connected with its one input to the output za of a counter Zs , each of which emits an output signal for a certain duration within each pulse frame of the time fan occurring on the PCM transmission line L '. The other input of the AND gate is used to receive control pulses which occur at specific points in time within each time division of the time period occurring on the PCM transmission line L '. In the present case - assuming the presence of eight signals in each case - elcmcnte encompassing time fans - the input of the AND gate GU 1 last viewed, e.g. B. in the third and fifth Zcitelement each time, a control pulse b 3, b 5 are supplied. If a corresponding control signal is present at the other input of the AND gate GU 1 from the output of the counter Zs , the control pulses b 3, b 5 reach the control input ^ of the recording register SR and cause the data signal input Ed the Auinahmeregisters SRs trains led Datensignalelemcnte are stored in the respective receiving registers SRs, respectively the duration of the third and fifth Zcilclemcnls the respective time times. In this case, the storage is preferably carried out using the edges of control pulses occurring during this period of time.

The output of the receiving register SR on the transmission side, which is expediently designed as a shift register and is also referred to below as a shift register, is connected to one input of an AND gate GU 4. The other input of the AND gate GUA is used to receive control signals ί 16 that occur during the duration of the time slots (16th time slot within each pulse frame) of the data channel used on the PCM transmission line L. These control signals are also fed to the blocking input of a blocking gate GS , the signal input of which is connected to the PCM transmission line L 'which only carries message signals. The PCM transmission line L is connected to the outputs of the blocking gate GS and the AND gate GU 4 via an OR gate GO 2. The control signals ί 16 supplied to one input of the AND gate GU 4 and the blocking input of the blocking gate GS mean that for the duration of the time slots of the data channel on the PCM transmission line L / any signals that do occur are transmitted to the PCM transmission line L are prevented, and that data signals shifted out of the shift register SRs can reach the PCM transmission line L only during the duration of this time fan. This will be discussed in more detail below.

Control signals supplied to the control input Es of the shift register from the output of an AND gate GU 3 via the OR gate GOt are used to shift out the data signals stored in each case in the shift register .ST?. *. These control signals occur during the duration of the time slots of the data channel used. For this purpose, the control signals <16 are also fed to one input of the AND gate GU 3. The other input of the AND gate GU3 are fed control pulses tb whose Folgefreqtienz corresponds to the repetition rate at which the time elements in the individual time slots follow one another, these control pulses occurring with a bit Folgcfrcqucnz reach tb ί during the occurrence of the control signals 16 to the control input It of the shift register SRs and have the effect that the data signals contained in this shift register are stored and sent to the PCM transmission line L via the AND gate GU 4.

After the storage and retrieval of data signals in and out of the shift register SRs has been briefly examined, the processes associated with the storage of the data signals in the relevant shift register SRs will now be discussed in more detail. The storage of data signals in the shift register SRs takes place, as will be remembered, under the control of the control signals emitted by the output zc of the counter Zs. The counter Zs emits control signals for such a duration that at the end of the respective storage process a maximum of one number of data signals corresponding to the number of data signals that can be transmitted in a time slot of the data channel is stored in the shift register SRs. Based on a PCM system with eight time elements each for the transmission of eight signal elements and the use of D: iensignalen each with two bits, the counter Zs outputs an output signal at its output za for the duration of four time slots. The data signals or data signal elements occurring during the duration of these four time slots at the data signal input Ed of the transmission-side shift register SRs are stored in this shift register. The relevant data signals or data signal elements are stored for the duration of the next time slot of the data channel used.

The counter Zs carries out a counting process on its count input via counting signals supplied to an AND gate GU 5. These counting signals appear at the output of the AND gate GUS whenever the relevant AND gate is capable of transmitting control signals tf supplied to its one input. This is the case when a flip-flop FFs connected with its output to the other input of the AND gate GU 5 is set. The control signals tf occur in the present case with a repetition frequency which corresponds to the repetition frequency.

with which the time fans on the PCM f.7hertTas>ur>i> steitung /. ' hz.w. /. appear. The flip-flop / r ν is set!.! Ann when a control signal .'21 is fed to a Se '/ c input. Such control signals are! Em Set / .eina.ing d.-s F - "! I; - i -! < .Ps FFs in each case in if Auf-

■ ^ta 21st /..-!!!"aches each Pnisrahmens /.nge- 'Jii.'T. This will continue no "," be closer singeiar-fieii below. At the reset:; gang of the Plip-Hop / - '/ -' f: s; -jin ^; ND C ^\: he dl ¹ 7 r>.! ioiiier, -, Aus: a; vj! iiuesohlosseu. The one thing!> This ... ND- '. All :; (HJ 7 become ν.Ui: -, signals 16 z; u> i * i ^: iihrt..-Ese Sleuersiijnale triMiTi., Remembered,, rweils ■ "■ i.-if.M-.d the duration of / .eiti'äehi: r des 'jcnui / .ten ■ ^: Ί! "l'tana's on. D ^; e Z ^, fan of this Dalenkanal .'Πι:: i: he each through there :;!':. Zeufach inside ι ;, ■: <■ ·.; ^ Α · ο! ίιμι; η Piii: ;; -. ii ': niet; :: jeh-'iilet.' -Λ. Mierin P.in- / änut-n. im vor! iegciiiie: i; -: i: l /.wc·, -, further F'.in- '■ i ^ iü-ri des ' , ND-! latter-; (, <' 7 become Si.ii '- - s) GNAIE .r i' ugefiilirt these iienersignaleu ia ii ecause it '■■ <''' HTI of learning counter / .. ', whose -.n' .iner /.!.. ähler- m ^.; ■: iϊ ^: ιπιΐ ah ·· 'iHMv: r, e Steuer.i:.': iaie. ί ficrauf will. ■ ^ ■. ■ nl '.- iils ■ · "below nc.i; ■ ueh- · -jinueijüngen

V ;: Jen counter Zv is nc: ci! cm! . ^{! N)} '.- <"ia !! i: r CU fi ^i;:. :: gi i: hli> KISSING This AND Gait he Gi, 6 guide, taking -15 ni.'Ii'incin output / 11 return changes from the ..üiit ·: - /.-,·! -Ikiendi-n Z.iiilcrsiul'en. Ι Jii-sc. Counter- • li \ '.: i get a control on their return 1 ¹ I / .'un'jiiigr: i in a bi.vaimmien state, and ■ w-ir pre-lately in the counting state. '"Ii .'aien entrance of the! !.. .'ND - 'Fiat'; ers 'L'6 ^are: ler.ignaie ::' 32 /.ugcführ 'This Stetiersignaie ■ 12 are of ontspreclienden outputs of ■ i'; ¹¹ ·, /.eiitralen channel - or frame /: ". and -war; sometimes when the counter Zv \ r,

• in <\ icizle Zeifach within each pulse frame •• ". ■ gives a leaning Aasganessiunal. Under the arrangement ¹ i ¹ '; ie des Voriietiens :: nes iZ-Zeitkanal-Sysiems ■.:; Chnen dii: control signals: .- ( '.12 the ". Zettfächer occurring within the Ίΐ · .frames. How .hole •: siciuiii: h will become, iiie control signals .-;' 32 ¹ '-, ii ^ -. Ii after each, not Pnlsralimen occur. !. are the Ήίίι-.Γ · :! input of the AND Gatiers GUβ fed iiMeirijinaie hH These control signals occur ewojis währcriii the duration of the eighth time element ks t; it-s time subject to order iritl at the output of ^ IV ^r jaiters (. IVft receives an output signal for the duration of the>Z> :: tciementp iiz.w. bit of the 32nd time channel of the ifctzien Puisrahmeiis of the respective Gberra.frame. This output signal is used to synchronize the counter Zs .

After the structure of the in F i g. PCM transmission point Ss and the associated data signal Ds dispenser has been explained shown 1, will be explained in more detail with reference to the example shown in Fig. 2 diagram, the operation of the data signal Ds now dispenser. According to FIG. 2 are marked with * da « the data signal output device Ds according to FIG. 1 illustrates the processes taking place in the recording and outputting of data signals. With "za" according to FIG. 2 denotes the output signals occurring at the output za of the counter Zs according to FIG. According to FIG. 2, it is assumed that there is a 32-time channel system in which the 16th time channel is used as a data channel. It is also assumed that eight signal elements are transmitted in each of the individual time slots and that the data signals transmitted in the time slots of the data channel are each formed by /, wsi bits. This means that four data signals relating to connections can be transmitted in each digit of the data channel. The data signals occurring in the time slots k 29 to £ 32 of the pulse frame preceding the pulse frame RH indicated in Fig. 2 are, as in F i 3. 2 in connection with mi! the preceding explanation / iir F i t>. 1 can be recognized after recording, in the shift register on the transmission side -> ■ (. · .9,1 s 1 -, VP? Mi next time slot k 16 of the date; channel, ms stored in the shift register SRs ) οη the helivnVnden Abieaeben ΡΓ'Μ transmission point. This may be; in the Pnlsrahmen RR. The / enfächern in the k 1 to <4! It following pulse frame /? I occurring data signals are forwarded by the PCVi transmission>! E.llij during the duration of the time slot k 16 of the Dute channel in the relevant pulse frame R 1. P, this pulse frame R \ is, as will become clear, the first Pnlsrahmen of the pulse ranges R 1 to. The data signals occurring in the time slots k .5 to / f8 of the following pulse frame R 2 are in the time slot k 16 of the data channel in the relevant pulse frame R2 . submitted to the PCM broadcasting station. In a corresponding manner, the data signals occurring in the time frames k 9 to A: 12 of the following pulse frame /? 3 and those in the time frames / cI3 to k 15 of the subsequent section /? 4 are each during the duration of the time frame k \ 6 des Data channel in the relevant ',' ■ ' ' imitate R 3 or R4 from the PCM transmitting station. During the duration of the 7 times k 16 of the data channel in the pulse frame /? 4! Ed, only three message connections are transmitted data signals from the PCM transmission element, namely data signals relating to connections which time channels with the; _> itfächem ν 13, 14 and Use k 15. In order to ensure in this case that during the duration of the time slot k 16 in the pulse frame R 4 only the data signals associated with the relevant communication links are emitted by the PCM station, the method shown in FIG. 1 data output device Ds shown also has three inputs t; ND gate G'L ^; 2 on. This AND gate is one input to the output za of the ZaIi- ^! ers Zs connected. With a second input, the AND gate GU Z receives control signals ί 15, which occur during the duration of the 15th time in each pulse frame. At the third input, the AND gate GU 2 receives two additional control signals b6 and bl which, for. B. occur during the 6th and 7th time element within each pulse frame. This means that two control pulses or control signals appear at the output of the AND gate (71/2 for the duration of the 15th time factor of that pulse frame. An output signal occurs at the output za of the counter Zs . This is shown in FIG. 2 can, during the pulse frame R 4, the case, the over the duration of 15 time multiple A:.. control pulses occurring 15 during the pulse frame A4 at the output of the AND gate GU 2 of Figure 1 will cause the contents of the transmission-side shift register SRs two Digits is shifted further so that data signal elements previously contained in this register and relating to another communication link through the in the time slots

ίο

Carrying out the above-mentioned tasks a counting volume which is equal to the sum of the number of time slots occurring in a pulse frame plus the number of time slots in which data signals to be outputted k 16 can be recorded in a time slot. Based on the numerical values given above, this means that the counter Zs must have a counting volume of 36. The counter Zs is designed so

fcl3 to A15 of the pulse frame R 4 recorded data signal elements are overwritten and only these data signals are stored in the shift register SRs.

The data signals stored in the shift register /? * During the duration of the time slots k 13 to klS of the pulse frame R 4 are output from this shift register for the duration of the following time slot k 16 (within the! • pulse frame / <4).

• stores. The occurrence of the time slot k 16 implies that in normal counting operation it gives a selection of the pulse frame R 4, as already indicated above for the duration of eight time slots, the AND gate shown in FIG. 1 emits output signals. . This to a simplified counter assembly GU 7 at its output a "!" - signal from, the leading counter operation is permissible without any further because out the set flip-flop FF is reset. As can be seen, it only responds to the fact that the output of a "1" output signal ceases to arrive at the shift register. The counter on. This has the consequence that the AND gate GUS Zs is also designed so that it no longer operates the other input supplied to its other input during normal counting, ie in the event that it is not stopped control signals // the counting of the counter Zs capable of feeding one in each counting cycle for the duration of one. The counter Zs thus remains in ao pulse frame (32 time slots) no output signal apart from its last counter position in which there is. In other words, this means that it emits an output signal from its output za. the distance between the occurrence of an output signal is output signal at the output of the counter Zs and the gain until the set input of the flip-flop FFs a new occurrence of a corresponding output control signal <21 is supplied. This is during 35 signals the number of time slots of a pulse frame of the occurrence of the 21st time slot within the plus the number of time slots in which pulse frame R 4 is the case. in each case in a time slot of the data channel coming back to the one shown in FIG. Output data signals shown in FIG. 2 can be recorded. The diagram means that in the time fan k 17 this distance is shown in FIG. 2 with Iz be to k 20 of the pulse frame R 4. The output signal that occurs at the output of the counter Zs during signals - in the shift register on the transmission side of the pulse frame R 4 is SRs - are excluded. With the beginning of the output 21, which is longer than the other times. Time slot Ot21) signals within the pulse frame A4. In Fig. 2 is the one that actually occurs, the one that is shown in FIG. 1 flip-flop FFs shown again with sets trailing edge of the output signal of the counter Zs. Thereupon the counter Zs works again in its 35 y designated. The trailing edge of the normal counting rhythm from the counter Zs. With regard to FIG. 2 output output in normal operating mode, this means that when the time factor k 21 occurs, the signal is denoted by χ . The reason for the Verim pulse frame R 4 in the transmission-side shift register lengthening the delivery of the output signal from the SR no more data signals are stored. Output is the counter Zs, as already led upwards out-The previously eingespei- in this shift register SRs 40, the fact that the counters are Zs with occurrence of the cherten data signals, as shown in FIG. 2 hervor- time multiple k 16 in the pulse frame R 4 goes to one, while the duration of the time slot k 16 of the fol- further counting is prevented.

constricting frame pulse RS from the shift register after previously stores structure and operation of the SRs and from the PCM transmission site in F i g. I shown the PCM transmitting station 5s and the die. The data signal output device Ds pulse frame R 5 belonging to the time fan k 21 to A 24 of the 45 ser have been explained in the shift register on the transmission side , the data signals recorded with these SRs should now be PCM-Emplich connected to the time slot k 16 of the following Pulse frame catch parts and in particular the R 6 associated therewith released. In a corresponding manner, the data signal recording device De will be considered in more detail in the time fans k 25 to k 28 of the pulse frame R 6 50. This data signal recording device De is recorded in the transmission-side shift register SRs according to FIG. 1 with one input of an AND-mene data signals during the time slot k 16 of the gate GU 8 to the PCM transmission line L on the subsequent pulse frame R 7. The data signals (concentrated data signals are then trated in the time slot k 16) are transmitted in closed, via which from the data signal output of the time slots k 29 to Λ32 of the pulse frame R 7 device Ds each time for the duration of the time slots of the data channel recorded in the transmission-side shift register SRs will. The other entrance de *

of the following pulse frame, namely the pulse frame RS from the relevant shift register. This is in the upper part of the in FIG. 2 illustrates the diagram shown.

To the above basically explained inclusion of in the individual time subjects of the respective Pulse frame occurring data signals and the forwarding of these data signals in a time slot

AND gate GUS will carry control signals f 16 trains that occur during the duration of the 16th time fan de: pulse frame, ie during the duration de 60 time fan of the data channel. An AND gate GU 9 with one input is connected to the output of the AND gate GU 8. The data signals transmitted via the AND gate GU 8 are fed to this input of the AND gate GU9

a time channel used as a data channel within 65. The other entrance of the AND gate

of the respective heart rate frame. Control pulses tb are fed to GU 9. The following

is in the circuit arrangement according to FIG. 1 the frequency of these control pulses ib is equal to the following «

Counter Zs used. This counter Zs has the frequency (bit repetition frequency) in a Zertfac

the existing time slots occurring time slot elements. The input of a receiving-side recording register SRe is connected to the output of the AND gate GU 9 , which, like the transmitting-side recording register SRs, is a shift register. The receiving-side shift register SRe , like the transmitting-side shift register SRs, has a storage capacity of eight bits (corresponding to the number of data signal elements occurring in a time slot A16 of the data channel). The data signal elements occurring at the output of the AND gate GU 9 are thus stored in the shift register SRe at the receiving end. The data signal elements stored in this shift register SRe are available via a number of register data signal lines corresponding to their number. According to FIG. 1 z. B. formed by so-called D-flip-flops flip-flops FFl to FF8 connected with one input each. This input is in each case an input designated as a data signal recording input D. With their respective other input, designated as the clock input T , the flip-flops FF 1 to FF8 are jointly connected to an output ArI of a central counter Ze which is also used in the data recording device De. This counter Ze represents a so-called pulse frame counter or superframe counter which emits an output signal at one of its outputs ArI to Ar8 for the duration of a pulse frame. The organization of the counter Ze is such that this counter emits an output signal at its output ArI when the time slots of the pulse frame R1 of a superframe comprising eight pulse frames appear on the PCM transmission line L. An output signal occurs at the output Ar8 of the counter Ze during the duration of the pulse frame R 8 of the respective superframe. The output signal appearing at the output A rl of the counter Ze causes the data signal elements stored in the individual register stages of the receiving-side shift register SRe to be re- stored in the flip-flops FF 1 to FF8. Of these flip-flops, the flip-flops FFl and FF2 belong to a data signal line Ll. This is the data signal line via which the data signal elements which are currently stored in the first two register stages of the shift register SRe and which together form a data signal. be delivered. In a corresponding manner, the flip-flops FF3 and FF4 belong to a data signal line L2, the flip-flops FF5 and FF6 belong to a data signal line L3 and the flip-flops FF7 and FF8 belong to a data signal line L 4. Two flip-flops are associated with each data signal line L1 to L 4, that is to say one of the number of data signal elements forming a data signal to be output via one of the data signal lines.

With storing of time-compartment k 16 of the following pulse frame (pulse frame Rl) data signals or data signal elements occurring, the counter Ze from another, the pulse frame R 2 within each superframe associated output an output signal, in response to which the results shown in Fig. 1 Flip-flops FFl to FF 8 take over the data signal elements stored in the shift register SRe corresponding to flip-flops.

The flip-flops in question are associated with other data signal lines. In this way, the data signals stored in the receiving-side shift register SRe can be fed to the respective data signal lines; n, such as the data signal lines L 1 to L 4.

Claims (6)

Patent claims: ίο 1. Procedure for submitting a number at a time of data signals, in particular formed by switching indicators, from a PCM transmission point a PCM telecommunications network in the designated Bit positions of a time channel used as a data channel from a series of time channels, which occur cyclically in a pulse frame over a PCM transmission path to a PCM receiving station and forwarding the relevant data signals via ao separate data signal lines of the PCM receiving station, whereby the data signals on the sending side occur in the time channels of the other time channels, especially those used by communication links, characterized in that data signals occurring from pulse frame to pulse frame in different time channels are transferred to one of the PCM transmitting station ( Ss) associated recording register (SRs) are stored and stored out of this for the duration of the next following data channel and sent to the PCM receiving point, in which the relevant data signals are stored in a corresponding recording register belonging to the PCM receiving point and from there via the individual time channels individually associated buffers (for example FFl to FF8) are delivered to the individual data signal lines (for example Ll to L4). 2. Schahungsanordnung for performing the method according to claim 1, characterized in that the PCM transmission point (Ss) contains a recording register (SRs) , the input of which is connected to a data signal transmission device (USa, USb) , each of which is connected to a Signal elements belonging to the data signal each emit one after the other for the duration of a time slot that is occupied by a connection to which the - ^ corresponding data signal is associated, and which is connected on the output side to a PCM transmission line (L) and to this during the duration the time fan of the data channel emits the previously recorded data signals, that the PCM receiving point contains a recording register (SRe) which is connected on the input side to the PCM transmission line (L) and which receives data signals during the duration of the time slots of the data channel, and that this Recording register (SRe) on the output side with one of the number next to the date nkanal available time channels corresponding number of provided buffers (e.g. B. FFl to FF 8) is connected, each receiving corresponding data signals. 3. Circuit arrangement according to claim 2, characterized in that the recording register (SRs) connected to the data signal transmitting device (USa, USb ) for a data Signal recording is acted upon with control signals, which a counter (Zi) emits, which has a counting capacity which is equal to the sum of the number of time slots contained in a pulse frame and the maximum number of data signals that can be transmitted in a time slot of the data channel is, and the corresponding in its counting capacity cycles in each case at least during one by the maximum number of data signals that can be transmitted in a time slot of the data channel given number of time slots emits such control signals. 4. Circuit arrangement according to claim 2 odur 3, characterized in that when using a shift register with a signal input (Ed), a shift input (Es) and a signal output as a transmission-side recording register (SRs) with the shift input (Es) in addition to a control pulse for input and / or shifting the data signals into or out of the register (SRs) outputting control device (GOl. GU 1, Ct / 3, Zs), possibly a further control device (GU 2) which is connected before the data signals are saved from the The effect of the shift register (SRs) is that data signals are stored out of the shift register (SRs) immediately at the start of the removal. 5. Circuit arrangement according to one of claims 2 to 4, characterized in that each data signal line (eg Ll, Ll) in the PCM receiving point has a corresponding number of flip-hops (FFl, FF 2) corresponding to the number of signal elements forming a data signal is. 6. Circuit arrangement according to claim 5, characterized in that of the each forming a group, in each case for the takeover of the data signals transmitted in a time slot of the data channel via the PCM transmission line (L) provided flip-flops (2. B. FFI to FF8 ) each corresponding fip-flops are connected to the same outputs of the receiving-side recording register (SRe) and that the I-hp-flops belonging to these groups are able to accept data signals that have just been issued by separate control from the receiving-side recording register (SRc). For this 1 sheet of drawings