DE2221254C3 - PCM time division multiplex telecommunications network with a plurality of PCM time division exchanges connected to one another via PCM time division lines - Google Patents

Description

each of the binary words to be sounded through / make available correctly for their transmission, this prerequisite is not \ on from the outset fulfilled, since the individual to a PCM-Zeiimuliiplex- Determination center of a PCM signaling network leading PCM time multiplex lines as a rule have different maturities, that too subject to temperature-related fluctuations, and because the hit cycles of the individual PCM time division multiplexing exchanges at least not readily agree with each other To the stated requirement In principle, three tasks have to be solved: There are those that arise on the transmission path eliminate small phase fluctuations (so-called jitter) and there are the bit frequency differences between on different PCM time division multiplex lines. d. H. from different directions to balance transmitted signals: after all, is. ι! '. with all time channels having the same communication number coincide in time within the respective pulse frame ir. incoming and outgoing direction and thus the connection through-connection for both transmission directions at the same time kanii (so-called isochronous operations) take place. to carry out a so-called pulse frame compensation.

The first-mentioned task can be solved with a so-called flywheel circuit, in which the transferred Bits trigger a high-quality resonant circuit that determines the rate of the regenerated bits (Proc.! Et ·! 113 (1966) 9. 1420 to 142 «. 1422: Informations Telephony switching technology 5 (1969) 1. 48 to 59. 51): the last-mentioned task can be by inserting correspondingly dimensioned term elements into the individual for the individual PCM time division exchanges Loosen the PCM receive Zcitmultiplexleitung, through each of the runtime on the relevant PCM Zeitmuhiplexleitung to a whole multiple of Information frame duration is supplemented, so that the pulse frame of all to the respective PCM time division multiplexing switching stations leading PCM receive time division multiplex lines with one another and with the one through the office pulse frame of the relevant PCM time division multiplex switching center given pulse frame of all PCM scan time multiplex lines leading away from this exchange coincide in time (see BSTJ. XXXVIII (1959) 4. 909 to 932. 922; Proc. U.E. Ill (1964) 12. 1976 to 1980. 1976. r.Sp.o .: Proc. IF.h. 113 (1966) 9, 1420 to 1428. 142i. I.Sp.o .; Information telephone switching technology 5 (1969) I. 48 to 59, 52, 53). In connection With the above-mentioned framework compensation, it is expedient to also compensate for the temperature l. made for fluctuations in time (see e.g. Proc. IHI- :. 113 (1966) 9, 1420 to. 1428, 1421, r.Sp ,; Information telephony switching technology 5 (1969) 1, 48 to 59. 53).

Various solution principles are known for compensating for bit frequency differences (see Proc. IEE. 113 (1966) 9, 1420 to 1428, 1421; information Telephone switching technology 5 (1969) I, 48 to 59. 51):

With the servo syncronization process (homochronous process, master-slave process), a central one determines Clock generator the bit frequency of the individual PCM-Zcit multiplex exchanges of a PCM telecommunications network.

With the autosvnehron method ί phase averaging

driving) show the individual PCM time division switching centers individual clock generators which, however, are not independent of one another, but rather synchronize each other.

In the Asvnehron method (heterochronous method, each PCM time division switch has one own independent clock generator. and each receive time division multiplex line opens into one called full memory, the storage capacity of which corresponds to the number of bits per pulse frame and in which the received binary words are held until they are in the pulse frame of the relevant PCM time division switching center fit (the full memory at the same time causes the above-mentioned frame adjustment).

With the quasi-synchronization method (hereinafter also referred to as the blind bit method / finally, the PCM time division switching stations in a PCM telecommunications network also has its own independent clock generator. but the information bit frequency is d. i.e. the average number of bits per second carrying information for all PCM time division exchanges of the entire PCM telecommunications network by making the original difference between the bit clock frequencies of the individual PCM time division multiplex exchanges and uniform information bit frequency through the insertion of informationless Bits, so-called blind bits, are compensated:

For this purpose, each receive time division multiplex line ends in a buffer memory of limited storage capacity. The writing in a buffer memory is always done with the on the PCM receive time division multiplex line leading to it decisive so-called external information bit clock in front of you, yes readout from the buffer memory with the so-called internal information bit clock of the associated PCM time division multiplex exchange. If the storage time in such a buffer storage tank falls below a minimum limit, the so-called dummy bit limit so the associated PCM time division multiplex exchange generates a dummy bit, by placing them at a certain point in their clock pulse frame for the duration of one bit on the receiving side

interrupts reading from the buffer memory, with which the storage time increases, and an information-less bit on the transmit side. the so-called blind bit, transmits: in the opposite direction of transmission interrupts a PCM time division multiplex switching station

5c Receipt of such a dummy bit for the duration of this Writes to the buffer memory, but continues to read from uem buffer storage. with which its memory'cit is reduced. It comes later on Cjrund of the different clock frequencies again result in an undershooting of the dummy bit limit, so repeat themselves the operations described. This results in a uniform information bit frequency for the entire PCM telecommunications system, which is equal to the base frequency of the slowest PCM time multiplex switching center of the PCM-Fcrnmcldcnctzcs is (Proc. IEF 113 (1966) 9. 1420 to 1428. 1427).

The extent to which it is possible to compensate for bit frequency differences through such a dummy bit generation. depends on it. how often dummy bits can be generated: The difference between the maximum permissible bit frequency / _mn / in the PCM time division multiplex telecommunications network and the minimum permissible bit frequency / ", 1" is equal to the maximum dummy bit

frequency fniimaj- The current Ulindbitfrequen /. a PCM time multiplexer of the I ¹ C ¹ M- / eilnHiltiplexfernmeklenel / it is Niels equal to the DiITeren / / between the current liilfrequen / of the relevant exchange and the one through the Uitfrequcn / the slowest PCM Zeitnuiltipleweriniltlungssielle of the l'C'C given information bit frequencies /. / ,, i / ·

It has now proven desirable to provide such a PCM Zcitmultiplexfernmcldenct /. with after PCM time-division exchanges operating with the dummy bit method to be able to impress a certain information bit frequency from the outside; the invention is therefore based on the object of providing such an externally impressed information bit frequency enabling dimensioning of the PCM multiplex switching centers such a PCM time! THiUiPIeX-I-CnImCIdCnCtZeS.

The invention relates to a PCM-Zcitmultiplcxfcrnmcldcnetz with a plurality of PCM multiplex switches connected to one another via PCM multiplex lines, in which a compensation of bit frequency differences with the help of buffers is carried out by when the buffer storage time falls below a minimum limit (dummy bit limit) from the PCM time division multiplexing agency concerned a dummy bit is generated; According to the invention, such a PCM-Zcitmultiplcxfcrnmeldcetznetz is characterized in that to achieve an information bit frequency, which is equal to the Uitfrequency of an outside of the PCM time-multiplier communication network bit clock is the minimum permissible Uitfrequcnz a PCM-Zcitmultiplcxvermittc of the PCM time multiplex telecommunications network is greater than the maximum permissible bit frequency of the bit clock and the number of in such a PCM-Zcitmultiplexvermitllungsstcllc to compensate for bit frequency differences per pulse frame available dummy bits at least equal to that with the quotient of the number of information bits contained in a pulse frame and the minimum bit rate of the bit clock multiplied by the difference between the maximum permissible bit frequency of a PCM time division multiplex exchange of PCM time division multiplex telecommunications and the minimum bit frequency of the bit clock.

The invention has the advantage, solely through appropriate dimensioning, without one via the circuit-technical.cn that is already required for the implementation of the blind bit process Additional effort in the PCM time division multiplex exchanges of the PCM time division multiplex telecommunications network from these exchanges to be able to impress a certain information bit frequency on the outside. This can in particular from a higher-level PCM time division multiplex telecommunications network happen here, in which the maximum permissible bit frequency of a PCM time division multiplexing center less than the minimum permissible bit frequency of a PCM time division multiplex switching center of the subordinate PCM time division multiplex telecommunications network is in its PCM time division exchanges the number of to compensate for bit frequency differences per pulse frame available dummy bits at least the same with the quotient of the number of information bits contained in a pulse frame and the minimum bit frequency of a PCM time division multiplex switching center of the superordinate PCM time division multiplex telecommunications network multiplied the difference between the maximum permissible frequency of a PCM time of the subordinate PCM time division multiplex Fernnieldenel / es and the minimum bit frequency of a PCM time multiplex exchange of the superordinate Zeitmiilliplexfemmeldenetzes is.

In a further embodiment of this principle can then even in the case of a plurality of PCM time-multiplex remote reporting units which are superordinate to one another in the manner of network levels one effective from network level to network level

ίο Imprinting an information bit frequency, thereby be made possible that the in a PCM Zcitmultiplcxfcrnmeldcnctz minimum permissible bit frequency each greater than that in the order of precedence PC M time multiplexer η mcldcnetzc next higher PCM time multiplcx telecommunications network maximum permissible Bit frequency is and the number of times in a PCM Zcitmultiplex switchstelle of such a PCM time division multiplex telecommunication network to compensate for bit frequency differences Blind bits available per pulse frame are at least equal to those with the quotient of the number of those contained in a pulse frame Information bits and those in the highest-ranking PCM-Zcitmultiplcxfemmcldcnetz minimum permissible bi-frequency multiplied difference between the maximum permissible bit frequency of the telecommunications network concerned and the one in the highest-ranking PCM multiplex telecommunications network is the minimum permissible bit frequency. On the one hand, this creates a hierarchical network structure with one common for all networks or network levels Information bit rate enabled, but on the other hand in the event of a failure of the Between such networks or network levels running connections the individual networks each for nevertheless remain functional, each with its own information bit frequency.

The invention will be explained in more detail with reference to the drawings. 1 shows the interconnection of a PCM time division multiplex radio with a higher-level PCM time division multiplex telecommunications network; Fig. 2 shows a hierarchical network structure with three network levels.

Fig. 1 shows two in each case a plurality of PCM Zcitmultiplexvermittlungscn comprehensive PCM-Zcitmultiploxfcrnmeldenitzc I and II; dabai is a PCM time division switching center of the PCM time division multiplex telecommunications network I denoted by VSt 1, and a PCM time division multiplexing center of the PCM multiplex telecommunications network II is denoted by ^ St 2. The individual PCM time division exchanges may each have their own, independent bit clock generators; further like they have buffer memories with the help of which bit frequency differences are compensated when the buffer storage time falls below a minimum limit, the so-called dummy bit limit, from the PCM time division multiplex switch concerned Dummy bits are generated so that there is one for the relevant PCM time division multiplex telecommunication network uniform information bit frequency results, which under the relationships indicated in Fig. 1 for the PCM time division multiplex telecommunications network II is equal to the bit clock frequency of the slowest PCM time division multiplex switching center this PCM time division multiplex telecommunications network II is.

In Fig. 1 it is now indicated that the PCM time division multiplex switching center VSt 1 of the PCM time division multiplex telecommunications network 1 with the PCM time division switching center VSt 2 of the PCM time division multiplex telecommunications

denelzes Il is connected. and let it be assumed that in d'-m I'CM-Zeitimiliiplevfernmeldenelz I not ti ic through the !!! that in the l '(' M-Zeilniulliplexfernmeldenelz I a inionnationsbitfrequenz / ', to ground »/ er / iCLL". the / ",", the PCM Zeitmulliplevfernmcldenetzes Il is equal to the Informationsbitfrequenz. This can see now reach a result. that in the l'CM-Z.eitniulUple.weimiiilimgssielle of the subordinate PCM time division multiplex telecommunication network I at least one Uitfrcqucn / / '«,,,, is permitted which is greater than the maximum permissible ISilfrequency I", "« superordinate PCM-ZcitmultiplexfernmeldeiK't / cs II. and that in the PCM-Zeilnuilliples exchanges of the subordinate PCM-Zeitmultiplcxfernmeldenelzes I the number .v 'of the blindbils available for the compensation of Bilfrequeiizuntcrschicden per pulse frame at least equal to the difference between the maximum permissible bit frequency / ', »« ι, multiplied by the quotient of the number of information bits contained in a pulse frame and the minimum bit frequency /'"", in a PCM Zeitnuilliplewermittlungsstclle of the higher-level PCM Zeitimiltiplexfernmeldenct / es 11 a PCM time multiplex switch of the sub. assigned PCM-Zeitnuiltiplcxfernmcldenetzcs I and the minimum permissible bit frequency / "," / "of a PCM time multiplex exchange of the higher-order PCM Zeitmultiplcxfernmeldenctzes 11. For the bit frequency tolerance ranges of the two PCM time multiplex telecommunications I and II must be the condition

J wft.r '- J min

be fulfilled, d. h .. the frequency ranges of the two PCM communication networks may differ do not overlap: also must in the PCM Zcitmultiplexvermittlungsstcllen of the subordinate PCM time multiplier remote network I for compensation of bit frequency differences, at least such a number 5 'of dummy bits is available per pulse frame be that of the condition

a PCM- / eitmultiple \ fernmcldenctz Ul superordinate is. where another PCM time multiple \ lernmeldenetz Ub in the same network as the PCM Zeiiniulliplcxfcrnnieldenel / Il cherishes and with further PCM / eilmultiple \ fernincldenetze Ib and Ic in a and the same network level with the I'CM-Zeilmulliple \ telecommunication network I lie.

I'm at such a plurality of network level arranged PCM Zcilmultiplexfernmeldenetzeii in

in i \ i: n your highest-ranking PCM-Zcitmiiltiplexfemmcldenetz III subordinate PCM-ZcitmiiltiplexfernmeUlenetz II. lib, I, Ib. Ic to achieve an information hit frequency which is equal to the information bit frequency of the highest-ranking PCM time division multiplex telecommunications network III. a minimum bit frequency is now permitted in the PCM Zcitmultiplexvermittlungsstellen of the subordinate PCM Zeilmultiplexfernmcldenetztz, which is greater than the maximum permitted in the order of precedence of the PCM Zcitmultiplexfernmcldcnctze each next higher PCM time division multiplex Fernmcldenctz. In turn, the bit frequency of a PCM time division multiplex switching center of the PCM time division multiplexing station is denoted by / "and the bit frequency of a PCM time division multiplexing center of the PCM time division multiplex telecommunication network with a PCM time division multiplex telecommunication network and the multiplexing telecommunication network of the PCM time division multiplex telecommunication network with 111 _ / '"' and if the indices min and max are again used to denote the minimum and maximum bit frequency

./ mar ^K 1 min and / mar '- ^: j min

be fulfilled; The same applies to the network configuration according to FIG. 2 also for the PCM Zcitmultiplcxfernmeldennetnetz Ic as well as Ib and lib. Also must the number of each in a PCM Zcitmultiplexvermittlungsstclle of the PCM time division multiplex telecommunications network At least 1 dummy bits available to compensate for bit frequency differences per pulse frame

K-B

J min

\ J mar - / min)

K · B

(/ mn.1 / min)

45

Sufficient, where with K the number of time channels in the pulse frame and with B the number of bits per PCM binary word referred to as. (It makes sense to use no more than 1 blind bit in a pulse frame provide, so that depending on whether a blind bit is made available in each pulse frame or only in not immediately consecutive pulse frames. 5 'will be equal to or less than 1.)

The above statements also apply in a corresponding manner if, in the arrangement according to FIG Bit clock generator reduced, the bit frequency of which is to be impressed on the PCM time division multiplex telecommunications network I as the information bit frequency J'inf .

In 1 ig. 2 it is indicated that the PCM time division multiplexed terminal network I according to FIG. 1 superordinate PCM-Zcitmulliplcxfernmeldenmeldenetz II for its part This formula is also used in a corresponding manner for the PCM Zcitmultiplex switching centers of the PCM time division multiplex telecommunications networks! b and Ic applies in the network configuration according to FIG. 2, and it must be the number of each in a PCM time division multiplexing center of the PCM time division multiplex telecommunications network II to compensate for bit frequency differences per pulse frame available dummy bits at least

max - J min)

be, this formula in a corresponding manner for the time division exchanges of the PCM time division multiplex telecommunications network lib in the network configuration according to Fig. 2 applies. In general, therefore, the number of in a PCM time division multiplexing center a subordinate PCM time division multiplex telecommunications network to compensate for bit frequency differences per pulse frame available dummy bits at least equal to that with the quotient of the number of information bits contained in a pulse frame and that in the highest ranking PCM time division multiplex telecommunications network minimum permissible bit frequency multiple

309 650/443

ed difference between the maximum permissible bit frequency of the relevant PCM time division multiplex remote mcldcnclzcs and the one in the highest-ranking PCM-Zcitmultiplo.fernnieldcnet / minimal permissible bitfrcqucn /. being.

As from Fig. 2 can also be seen several PCM Zcitmultiplexvermiltlungsstcllen one PCM time division multiplex network with a PCM time division multiplex exchange of a higher-level PCM time multiplex remote network and thus its information bit frequency can be applied from there: From the PCM line division multiplex switching center VSt 3 of the highest-ranking PCM time division multiplex telecommunications network III according to the arrangement Fig. 2 runs both a connection to the PCM time division switch VSt 2 as well as to a further PCM time division multiplexing agency PCM time division multiplex telecommunications network II. If one of these falls both connections off, the information bit frequency / "'fn / of the PCM time division multiplex telecommunications network III in the PCM time division multiplex telecommunications network II (and in the subordinate PCM time division multiplex telecommunication networks I and Ic) maintained; if both connections fail, the PCM time division multiplex telecommunications network works II and with it the PCM time division multiplex telecommunications networks I and Ic still continue, now with their own information bit frequency / "in / of the PCM time division multiplex telecommunications network II, which is given by the bit frequency of its slowest PCM time division multiplex switching center.

It is also possible that one or more PCM time division multiplex exchanges a PCM time division multiplex telecommunications network with PCM time division exchanges two different higher-level PCM time division multiplex telecommunications networks are connected. So can in Fig. 2, for example, the PCM time division multiplex switching center VSt I via the connection shown in the drawing to the PCM Zcitmulliplexvermittliingsstcllc VSt 2 also has a connection to a PCM-Zeitniulliplexvcrmittlјsslelle des PCM-Zcitnuiltiplcxfcrnmcldcnctzcs Have Ub. With the situation otherwise unchanged compared to the representation in FIG individual PCM time-division multiplexers transmit an information bit frequency / <“/ One that is equal to the one

ίο of the highest-ranking PCM time-multiplier communication network III is. Then fall the connections between the PCM Zcitmultiplexfernmcldcnctzcn II and Hb on the one hand and the PCM time division multiplex telecommunications network III, on the other hand, work the subordinate to the PCM time division multiplex telecommunication network 111 up to that point PCM time division multiplex telecommunication networks independently further, again with a common information bit frequency, which is now determined by the bit frequency the slowest in the network level

ao PCM time division multiplex telecommunications networks Il and lib lying PCM time division exchanges is.

Finally, it should be noted that the invention described above in corresponding This can also be used if bit frequency differences are not compensated by fading in of dummy bits at the faster PCM time division exchanges, but through Suppression of existing dummy bits in the slower PCM time division multiplex exchanges is made; in this case the conditions given above apply in each case to modify that minimum bit frequencies in place of maximum bit frequencies and vice versa and take the place of a rule “greater than” with a rule “less than” and vice versa.

1 sheet of drawings

Claims (3)

Patent claims: 1. PCM time multiplex telecommunications network with a plurality of PCM time multiplex exchanges connected to one another via PCM time multiplex lines, in which, with the help of buffer memories, bit frequency differences are compensated by reducing the paver memory to below a minimum limit (dummy bit limit) of the relevant PCM time division multiplex switching center, a dummy bit is generated, characterized in that to achieve an information bit frequency (/ ', · ,, /). which is equal to the bit frequency of a hit clock generator outside the PCM time division multiplex communication network (I). the minimum permissible bit frequency (/ ', "," ι eir.r PCM time multiple weight determination center (VSt I) of the PCM time division multiplex telecommunications network (I) is greater than the maximum permissible bit frequency {(mn.) of the bit clock and the number (s) the dummy bits available in such a PCM Zeitmultiple.wermittlungsstelle (\ 'St I) / um compensation of bit frequency differences per pulse frame at least equal to that with the quotient of the number of information bits contained in a pulse frame and the minimum bit frequency (J'"min) de - Bit clock multiplied difference between the maximum permissible bit frequency if war) of a PCM time multiplex exchange (VSt I) of the PCM time division multiplex telecommunications network (1) and the minimum Bitf.equ..nz (f " _m i") of the bit clock. 2. PCM time division multiplex telecommunications network according to claim I. characterized in that the bit clock generator is provided by a superordinate PCM time division multiplex telecommunications network (II) in which the maximum permissible bit frequency (/ ","") of a PCM time division multiplex exchange (VSt 2) is less than is the minimum permissible bit frequency. (/ ', "(") of a PCM time division multiplex switching center (VSt 1) of the subordinate PCM time division multiplex telecommunication network (I), in whose PCM time division multiplex switching centers (VSt 1) the number {s') of the to compensate for Bit frequency differences per pulse frame available blind bits equal to the quotient from the number of information bits contained in a pulse and the minimum bit frequency (f "" nn) of a PCM time division multiplex switching station (VSt 2) of the superordinate PCM time division multiplex telecommunications network ( II) the multiplied difference between the maximum permissible bit rate (/', ““.,■) of a PCM Zcitmultiplexvermittlungsstelle (VSt 1) of the subordinate PCM Zcitmu ltiplexfernmcldenetzcs (I) and the minimum hit frequency (f'min) of a PCM line division multiplexing network (VSt 2) of the higher-level PCM time division multiplex remote network (II). 3. PCM Zcitinultiplexfernmcldenctz according to claim 2, characterized in that with a plurality of neizebcncnartig each superordinate PCM time division multiplex telecommunication networks (I, II, III) in a PCM time division multiplex telecommunication network (I) minimum permissible bit frequency (I min) is greater than the next higher PCM-Zcitmultiplexfcrnmcldenctz in the rank order of the PCM-Zcitmultiplexfernmeldenetz.e. (II) is the maximum permissible bit frequency (f " _m nr) and dl · · the number (.v ^r ) of the dummy bits available in a PCM line division multiplexing exchange (VStI) of such a PCM time division multiplex telecommunications network (I) to compensate for bit frequency differences per pulse frame at least the same of the quotient of the number (KB) of the information contained in a Piilsrahmcn in the runnhöchsten PCM Zeitmiiltiplexfer: ,, register network (III) minimum allowable bit rate (F'min) multiplied difference between the maximum zulässiiien Bitrrequenz </ ', " ., -) of the telecommunication network in question 1 u, id the minimum permissible bit frequency ( I "" mm) in the highest-ranking PCM time division multiplex telecommunication network (III) is in conventional communication systems Newer telephone exchanges do not make use of the multiple principle, but rather of the time multiplex Use of the iplex principle, whereby analog signals that are discontinuous in time are transmitted. Recently, telephone exchanges in which digital signals are transmitted (also discontinuous in time) have become increasingly important: in this context, pulse code modulation (PCM), in which the instantaneous amplitude values of the voice signal are mapped using binary words at periodically successive points in time, has become increasingly important which are then transmitted. The basic task of a PCM Zcitmultiplexvermiitlungs.telle is then to route the binary words that appear on the PCM reception time division multiplex lines leading to the exchange in time channels that are assigned to the individual connections on these lines to the desired connection and lead away from the exchange PCM transmission time division multiplex lines to be switched through to the time channels that are allocated to the individual connections on these lines. Corresponding to the four-wire operation of the PCM time-division multiplex lines arriving or departing from the PCM time-division multiplex exchange, this is always a four-wire connection, ie. When switching through, both transmission directions must be considered separately. For the transmission of the binary words to be transmitted in the course of a call connection via a four-wire PCM time division multiplexing line connected to such an exchange (taking into account control simplifications with regard to the association of the time channels used for the two transmission directions in the individual call multiplexing exchanges) Both transmission directions use the same time channel within the respective pulse frame based on the exchange pulse frame of the relevant network-side exchange (see e.g. Proc. IEE 111 (1964) 12, 1976 to 1980, 1976, r.Sp.M.) . A prerequisite for perfect switching through in a PCM Zcitmultiplexvcrerschstelle is that