DE1168501B - Time division multiplex switching system with a two-wire multiplex rail for telecommunications, in particular telephone systems - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

LEGEND 1168 501

library

of the German
fatshtamtes

Boarding school Class: H 04 w

German class: 21 a3 - 46/10

Number:
File number:
Registration date:
Display day:

S 75936 VIII a / 21 a3
September 26, 1961
April 23, 1964

The invention relates to time division switching systems for telecommunications, in particular telephone systems, d. H. on switching systems which the messages of individual pulse trains to be exchanged among the individual participants are modulated, which are offset from one another and are therefore nested in one another in time on multiplex rails can be combined, whereby a multiple use of connection paths is made possible. In particular, the invention relates to time division switching systems a two-wire multiplex bus to which the connection lines of the time division multiplex switching system can be switched on periodically in pulses with the aid of time channel switches.

In such time division multiplex switching systems, those used for the exchange of messages often have to be used Telecommunication signals, in particular voice signals, via connecting and connecting lines are very different Length and texture are transferred. Those transmitted over such lines Telecommunication signals have different strengths depending on the length and nature of the telecommunication line muffled. Such different attenuation is generally undesirable because, for. B. with consideration on the often in the vicinity of the electroacoustic transducer two over the communication line interconnected end points prevailing noise as well as interfering sidetone signals the reference attenuation such a transmission system within very specific limits, e.g. B. from 1 to Should be 2.5 N. For this, however, it is necessary that the telecommunication line running between the two terminals, which may possibly consist of different line sections, has a line attenuation that is largely independent of the length and nature of the line.

In order to achieve the same reference attenuation of transmission systems as possible independently of the lines lying between the end points, it is already known to compensate for the differences in attenuation of different lines. So it is z. B. known to insert a non-linear resistor in the subscriber stations between the two wires of the subscriber line, which is controlled by the DC feed transmitted via the subscriber line and dependent on the line attenuation, so that with increasing loop current (with a shorter line or larger conductor cross-section) the attenuation contribution of the non-linear resistance increases and decreases with decreasing loop current, whereby a compensation of the time division multiplex switching system with a
Two-wire multiplex rail for telecommunication,
in particular telephone systems

Applicant:

Siemens & Halske Aktiengesellschaft,

Berlin and Munich,

Munich 2, Witteisbacherplatz 2

Named as inventor:

Dipl.-Ing. Max Schlichte, Munich

Attenuation level is achieved. With such a measure, however, one can only achieve that the reference attenuation of a transmission system does not become too small. It is also known for undamping to use negative, series resistances or negative transverse conductance values of lines. Here you can however, with the help of a negative series resistance only losses can be avoided that would otherwise be caused by direct to this end, series ohmic series resistances are produced; with help of a negative transverse conductance, losses can only be avoided that would otherwise be directly caused by this ohmic transverse conductance values lying in parallel are caused. In this way one can only achieve that the attenuation of a transmission system is reduced. If you were to use the amount of the negative resistance or negative conductance greater than that of the loss resistance or conductance make, then undesired vibrations would arise in the relevant transmission system. Negative resistances and conductance values can also be used together as so-called NLT amplifiers can be inserted into the line. With the help of such an NLT amplifier, in principle as a T-link bridged by a negative series resistance with a negative one Transverse conductance can be built up, losses from ohmic series resistances as well be balanced by transverse conductance values. The NLT amplifier is correspondingly amplified the attenuation level of the line in which it is inserted, fixed. The gain measure, that can be achieved without undesired vibration

genes occur, the higher the echo attenuation in the transmission system in question is. This implies largely reflection-free

409 560/86

Line joints ahead; the wave resistance of the NLT amplifier must be as equal as possible to that Characteristic impedance of the connected line can be made. A change in the amplifier setting is not easily possible; rather, both the negative series resistance and the negative transverse conductance can also be changed, but with a certain mutual dependency must be observed between the two in order to maintain the original adaptation relationships as far as possible. If the known measures are used, depending on what is already in place Attenuation of a line uses different attenuation compensation circuits, depending depending on whether additional attenuation or undamping is to be achieved.

In addition, such known measures are very complex to the extent that they are used in a switching system one for each connection line leading to a subscriber or to a remote exchange own attenuation compensation circuit must be provided. However, there are already time division multiplex switching systems known, in which amplifiers can be switched on in the multiplex rail to raise the level again. The amplifiers are to a certain extent at a central point and amplify the speech signals of all in the same way Speech circuits routed via the relevant multiplex rail, whereby of course the gain factor of the amplifier must be chosen so that the gain is also strongest for the speaking circuit Line attenuation is still sufficient. However, in such time division switching systems because of the insertion of amplifiers in the multiplex rail to train this as a four-wire multiplex rail. In many cases, however, it is desirable to use not only the connection lines of the time division multiplex switching system, but also its multiplex rail to train two-wire, which is just with the mentioned known time division multiplex switching systems is not the case. In addition, however, such a known gain is incorporated into the multiplex rail by means of a The inserted central amplifier often does not even meet the actual requirements fair, since the amplification for speech circuits with only low line attenuation is unnecessary and multiple is even impermissibly high, so that further requirements placed on the telecommunications connection in question, z. B. with regard to crosstalk, can no longer be fulfilled. However, one would get the reinforcement choose lower, so that such demands are still met, that would be the case now the gain for the speaking circuit with the strongest line attenuation is no longer sufficient.

The invention shows a way to overcome such difficulties and also in time division multiplexed switching systems With a two-wire multiplex bar, an attenuation compensation that is individually adapted to the individual connection lines without any special effort being required. The invention relates to a Time division multiplex switching system with a two-wire multiplex bus, to the connecting lines periodically pulse-wise with the aid of time channel switches can be switched on and which is connected to a coupling network via which connections a connection line of the time division multiplex switching system with another connection line both the same as well as another time division multiplex switching system can be performed for telecommunications, especially telephone systems; this time division switching system is characterized in that in the multiplex rail between that multiplex point in which the time channel switch are summarized, and the coupling network an attenuation compensation device is inserted, which to

ίο each pulse phase to which a connection line is connected to the Multiplex rail is switched on. by one corresponding to the line attenuation of the connection line in question Control signal is controllable in their degree of attenuation.

In the time-division switching system according to the invention, it is thus possible to use the damping and / or damping. Gain in the two-wire multiplex rail inserted damping compensation device in each case, d. H. for each pulse phase, to be determined as is the line attenuation of the connection line connected to the multiplex rail during this pulse phase requires. In this way, each connection can be independent of the type and length of the line sections used by the connection, achieve the same line attenuation without the need for each line section, in particular for each connection line leading to a subscriber, one own attenuation compensation device with an individual corresponding to the line section in question dimensioned attenuation or gain is required.

The invention will now be explained in more detail on the basis of exemplary embodiments.

In Fig. 1 shows a time-division multiplex telephone exchange system to the extent necessary to understand the invention, to which the connection lines Ltg leading to η terminals Tn (subscribers, other offices, etc.) are connected. Via the synchronously controllable time channel switch ZSa , the connecting lines Ltg can be connected to the multiplex bus P operated in two-wire fashion. The time channel switches ZSa are controlled in a known manner by control pulses which are supplied with the help of circulating memories. The call numbers of each of the terminals Tn involved in a connection circulate in the circular memory US in coded form. These call numbers, which are available in coded form, are called addresses. The control decoder D , which has as many outputs as there are terminals Tn in the relevant switching system, is connected to the output of the circulating memory US. Each of these η outputs is assigned to a specific terminal Tn . When the address of a terminal Tn is fed to the control decoder D , it emits a pulse at the output assigned to this terminal. This pulse is used to control the time channel switch ZSa assigned to this terminal Tn. If a terminal Tn

6a is involved in a connection, its connecting line Ltg is briefly connected to the multiplex rail P in this way. This repeats itself periodically with the circulation period of the addresses circulating in the circulating memory US. In this way, the intended connection between the relevant connection line Ltg and another connection line is established, which is connected synchronously to its multiplex rail, which in turn is connected to

is connected to the first-mentioned multiplex bus P at least at the relevant connection times. This connection can be established with the aid of the coupling network KF , to which the multiplex rail P is connected with its terminal P (2) and which has a coupling point KP with a coupling point contact connected to the relevant multiplex rails for each pair of multiplex rails P to be connected to one another. Such coupling networks have already been proposed and are not the subject of the invention. In this way, if necessary, with the aid of speech energy stores, which can optionally be connected to the multiplex rail of the relevant switching system in a separate time division multiplex switching system instead of subscribers or remote offices, connections between connecting lines Ltg of one and the same time division multiplex switching system can be established, for which purpose then the two connection lines Ltg are connected to the multiplex rail P at different times and the time spans in between are bridged with the aid of the speech energy storage. However, this measure has also already been proposed and is not the subject of the invention. It is also possible that a time division switching system comprises two multiplex rails, one for outgoing traffic (connection setup) and one for incoming traffic, and for connections between leads Ltg and the same time-division multiplex switching system for at least the time period of the turned ON one of the two connecting lines Ltg are connected to the respective multiplex rail in question in the coupling network KF ; Such a connection can optionally also be designed as a fixed connection.

The attenuation compensation device A is inserted between the points F (I) and P (Z) of the multiplex rail P. The attenuation compensation device here consists of m sub-devices for attenuation compensation, each of which is assigned to a speech phase (pulse phase) to which a connection line Ltg can be connected to the multiplex bus P. The m sub-devices each have a controllable damping compensation element α and two switches ZS'a and ZS "a , with which they can be connected to points P (I) and P (2) of the multiplex rail P. One of these sub-devices is thus one the m speech phases, to each of which one of the η leads Ltg to the multiplex rail P is periodically pulsed connectable assigned that to the same talkspurt ρ j (see. Fig. 3) their switch ZSA is periodically pulsed operated, whereby the part of body in question aj (cf. Fig. 2) is connected to Punkt.P (l) of the multiplex rail P at this particular speech phase and is connected via this to the connecting line Ltg which is connected coincidentally with it. The attenuation compensation device A is controlled in its attenuation or undamping degree by a control signal corresponding to the line attenuation of the relevant connection line Ltg during each speech phase for which a connection line Ltg is connected to the multiplex rail P. For this purpose, the multiplex rail P has the additional control line PC , to which, with the aid of the additional contacts ZSc of the η time channel switch, only line points of the η connecting lines Ltg through which the loop direct current flows can be periodically connected in pulses. Such a line point can, for example, be in the DC feed for the relevant connection line Ltg , as shown below with reference to FIGS. 4 will be shown in more detail. The control signal corresponding to the loop direct current is derived from the line transmission Ue , which between the respective connection line Ltg and the

ίο the associated time channel switch ZSa upstream low-pass filter TP with the storage capacitor c is inserted and terminates the connecting line Ltg. The control input of the switch ZS'a, ZS'c, which also has an additional contact ZS'c , is connected to the control line PC of the multiplex rail P during the same speech phase at which a connection line Ltg is connected to the multiplex rail P (I) can be switched on for this speech phase due to a pulse- wise actuation of the relevant switch ZS'a, ZS'c effective subdevice of the damping compensation device A , so that its damping compensation element α is supplied with a control signal which corresponds to the amplitude of the in the momentarily to a certain speech phase to the multiplex rail P connected connection line Ltg corresponds to flowing loop direct current. The control signal for a speech phase is thus newly formed in each sampling period, ie each time the contact ZSa of the associated time channel switch ZSa, ZSc connecting a connection line Ltg to the multiplex bus P is closed, since the additional contact ZSc of the time channel switch is closed at the same time. This control signal is fed to the attenuation compensation device A and, in this case, to the subdevice assigned to the relevant speech phase, the switches ZS'a, ZS'c of which are periodically closed in pulses for this speech phase and which are therefore switched on periodically in pulses with a speech phase to the multiplex bus P. Connection line Ltg is connected. It should be noted here, however, that the damping compensation device A may also consist of a single damping compensation element, the degree of damping or undamping of which is controlled for each speech phase. In any case, the damping compensation means A to each talkspurt, consists of a compound having a terminal Tn of the time division switching system, operatively connected to a damping or amplification degree corresponding to the induced by the relevant subscriber line Ltg damping, so that a total of a desired Attenuation is achieved regardless of the nature and length of the connection line in question.

The m sub-devices of the attenuation compensation device A according to FIG. 1 can, according to a further invention, each be formed by an energy storage device with a time constant that can be changed as a function of the control signal and that is operated at the connection point of two switches ZS that are inserted in series in the multiplex bus P and are periodically offset from one another 'a and ZS "α is connected. Such a subdevice has the advantage that with it either a de-attenuation or an additional attenuation of a two-wire line can be achieved without affecting the circuit structure of the relevant

the oscillating circuit L, C, R, can be transmitted. The signal energy picked up by the resonant circuit L, C, R causes an oscillation in this that is more or less damped or undamped by the controllable parallel resistor R : depending on whether the value of the parallel resistor R is positive, infinite or negative , there is a damped, an undamped or a swaying oscillation, which is shown in FIG. 3 a through a

Given the possibility of being able to change the attenuation or gain in a simple manner without this having a disruptive effect on the adaptation conditions in
relevant transmission system. In addition, as will be explained in more detail below, such an energy storage device is capable of all of it at the time a switch closes

Partial setup would have to change anything. Rather, it is only sufficient with the aid of the control signal the time constant of the energy store contained in the partial device, d. H. the time constant used for the speed of the decrease or the increase of signal energy stored in the memory is decisive is. to change to a larger positive time constant either with a more or less large positive time constant or less attenuation or with more or less

large negative time constant to achieve a larger or io short-dashed, a solid and a long smaller undamping. The dashed curve is indicated. Accordingly

is after half an oscillation period, ie to phase Pj _{+ ml2} , where m is the number of speech phases of the time multiplex switching system to be assigned to a connection, the signal energy stored in capacitor C is now correspondingly smaller, equal to or larger than that at the time of closing of the Switch ZS'a, d. H. recorded by the resonant circuit for phase p _h

absorb offered signal energy; there will be 20 signal energy. For phase Pi _{+ mli} the switch is therefore no reflections in the multiplex rail ZS "a closed pulse-wise," so that the now just called, which is of particular advantage in terms of stored signal energy via the switch ZS "α to the achievable back loss of the relevant side P (2) of the multiplex rail transmission system is. can. Depending on the resistance value of the parallel

In Fig. 2 shows such a damping compensation resistor R and thus according to the time constant, direction a-, in which the energy store with which the signal stored in the resonant circuit decreases or increases with the energy through the parallel resonant circuit L, C is now open the control signal controllable parallel resistor R side P (2) of the multiplex rail of the signal power is formed. The parallel resonant circuit L, C is at the level lower, equal to or higher than before on the connection point of the two in the multiplex rail 30 side F (I) of the multiplex rail. These processes between their points P (I) and P (2) in series are repeated periodically with the switching frequency joined switches ZS'a and ZS "α connected. The switches ZS'a and ZS" a, these two switches ZS'a and ZS "α can thereby qualified as an electronic switch according to the sampling theorem, the transmission switch. Dar parallel resonant circuit L, C technique at least at twice the frequency which is tuned to a natural frequency equal to the 35 highest ever, to be transmitted signal frequency switching frequency with which the two switches ZS'a and must be closed in pulses.
ZS "α offset from one another uniformly in time The above explanations of the mode of operation

are closed pulsed or equal to one of the in F i g. 2 shown is an integral multiple of this frequency. The direction α _; · For the transmission of signal energy parallel resistance R is dependent on the 40 from the side P (I) of the multiplex rail to the side control signal so controllable that its value is positive, un- P (2) apply because of the symmetrical structure of the finite or negative is. For this purpose, the parallel damping compensation device can also be formed for the resistance R by an ohmic resistance and transmission of signal energy in the reverse direction of a negative resistance connected in parallel, ie from side P (2) to side P (I). The negative resistance can be in 45 of the multiplex rail. Here, as in FIG. 3b

h h d d Shl

Formed in a manner known per se by a feedback amplifier circuit with a transistor be who, as shown in FIG. 4 will be explained by the control signal in his Working point is controlled.

With reference to Fig. 3, in which the voltage u _LC occurring at the oscillating circuit L, C, R is shown as a function of time for various boundary conditions, it being assumed that the oscillating

can be found in the phase

g to which the switch

_{i 2}

ZS "α is closed in pulses, signal energy is transmitted from the side P (2) of the multiplex rail P into the oscillating circuit L, C, R , which again excites an oscillation in the oscillating circuit L, C, R The control signal controlling the resistor R is damped or undamped or swings up. For phase p, the switch ZS'a is pulsed

Circuit L, C just closed to the switching frequency of the switch 55, whereby the at this point in time in the ZS'a and ZS "a is matched, the resonant circuit should first of all be stored energy via the operation of the damper switch ZS shown in FIG 'a to the side P (I) of the multiplexing compensation device a, are explained.

The transmission should first be based on FIG. 3a. As can be seen from FIGS. 3a and 3b, if only

of signal energy can only be viewed from the P (I) side of the multi-60 in one direction signal energy across the multiplex plex rail to the P (2) side. To rail is transmitted, in the resonant circuit L, C, R of a phase ρ j (see. Fig. 3d), which compensates the damping device a _t according to F i g only during one half of the switching period. 2 is assigned, the switch ZS'a and ZS "α stored energy, since the switch ZS'a is briefly closed by a suitable control after a storage of signal energy via pulse , so that during this 65 one of the two switches ZS'a or ZS "α after the closing time signal energy from the side P (I) of half the switching period the respective other switch ZS" a multiplex rail to the energy store of the damping or ZS'a is closed in pulses, the voltage compensation device _{a s} according to FIG. 2, ie for oscillating circuit L, C, R the then just saved

Releases energy through this switch. If signal energy is now transmitted in both directions via the two-wire multiplex rail, when a switch is closed, not only is signal energy transmitted from one side of the multiplex rail to the energy store or vice versa from the energy store to one side of the multiplex rail, but there is an exchange in each case of signal energy between the resonant circuit L, C, R and the relevant side of the two-wire multiplex rail. The voltage u _LC occurring at the resonant circuit L, C, R then has z. B. a time course as shown in FIG. 3 c can be found. This time course of the voltage u _LC according to FIG. 3c results from a superposition of the one in FIG. 3 a and 3 b illustrated voltage curves; For the sake of simplicity, it is only shown for one of the curves (R = σο) . The attenuation compensation device α, - according to FIG. 2 thus acts because of its symmetrical structure and the time-symmetrical control of its two switches ZS'α , and ZS "a - the two switches ZS'a and ZS" α are each half the sampling period of the time division multiplex. Vermittmngssystems offset against each other and closed in pulses - for the signals to be transmitted in both directions, each as a controllable attenuator, which increases the signal voltage level by the amount of attenuation

^T 7th

2r

ARC

belittles. Here, T is the sampling period of the time-division multiplex switching system and thus the switching period with which a switch ZS'α or ZS "α is closed in pulses, while τ = 2RC is the respective time constant of the oscillating circuit.

As mentioned, the damping factor can also be negative, namely when the resonant circuit is undamped with the aid of a negative parallel resistor. The negative parallel resistance can be formed by a feedback amplifier circuit with a transistor, as can be seen from FIG. 4. The transistor Tr is controlled by the signal supplied from the control line PC of the multiplex control signal rail forth in its working, wherein the transconductance of the transistor Tr is changed. However, this also changes the degree of undamping of the resonant circuit L, C, because the negative resistance occurring parallel to the ohmic resistance W has the amount

_ ü

^r "the ^

where u _LC denotes the voltage occurring at the resonant circuit L, C , u _BE denotes the base-emitter voltage and i _c denotes the collector current of the transistor Tr , ü is the transformation ratio of the transformer ü and S represents the steepness of the transistor Tr .

The damping compensation device shown in FIG. 4 consequently has a degree of damping

a ---

A-C

I.
W.

by which it changes the signal voltage level of the signals to be transmitted via the multiplex rail. The degree of attenuation can be positive or negative depending on the selected operating point of the transistor Tr , with a change in the sign or the amount of the resistance connected in parallel to the resonant circuit L, C made by controlling the operating point of the transistor Tr without disturbing the adaptation conditions is in the relevant transmission system.

The change in slope at the operating point of the transistor Tr is achieved in the excerpts illustrated time division switching system of FIG. 4 in that at a certain talkspurt Pj to which a connecting line Ltg by means of the pulse-wise periodic closing of the associated time channel switch ZSA to the multiplex point P ( I) the two-wire multiplex rail is switched on and at the same time also the switch ZS'α connected to the multiplex point P (I) of this speech phase ρ; associated attenuation compensation device Oj is closed, at the same time the further contacts ZSc and ZS'c of the two switches mentioned are closed, whereby a conduction point of the connection line Ltg through which only the loop direct current flows is connected to the control electrode of the transistor Tr . In this way, a base bias voltage for the transistor Tr is generated, which is dependent on the loop direct current of the connecting line Ltg and thus on its line attenuation; the transistor Tr is therefore operated at a very specific operating point in which it has a very specific steepness which, as explained above, influences the degree of undamping of the resonant circuit L, C. In this way, the current flowing in the connection line Ltg is sampled synchronously with each closing of the time channel switch ZSa assigned to a connection line Ltg , the signal obtained, namely a unipolar pulse with an amplitude dependent on the loop current, via the control line PC of the multiplex rail and via the at the same phase ρ j actuated further contact ZS'c of the first switch of the attenuation compensation device O _{1 is} transmitted to the control electrode of the transistor Tr. It should be noted here that the control line PC of the multiplex rail is already required to monitor the loop status of the subscribers and can be used for the purpose of attenuation compensation described here, so that no additional effort arises.

Half a sampling period after a talkspurt ρ j of the time channel switch ZSA an on-circuit line Ltg and the switch ZS'a α of this talkspurt associated damping compensation organ had been closed in pulsed fashion, is added to the talkspurt p _{j + m / s} the switch ZS "α this damping compensation element a _t closed in pulses, which connects the oscillating circuit L, C with the coupling network KF (see corresponding point of the multiplex rail of another time division multiplex switching system, in which the connection line leading to a subscriber, to a remote office or to a speech energy store, with which a connection is desired, is located of the individual connecting lines Ltg not coincident m with the crosspoint contacts

409 560/86

of the coupling networks KF (cf. FIG. 1) interconnecting several such time-division switching systems, but they are actuated offset by half the sampling period of such a time-division switching system. It follows from this, however, that the time channel switches of two connection lines located in different time division multiplex switching systems, which are connected to one another, are nevertheless operated at one and the same speech phase.

As can be seen from FIG. 1 and FIG. 4, the time channel switches ZSa assigned to one of the connecting lines Ltg are connected in a manner already known per se to reactance networks which each contain the coils or inductances H and / and the capacitors or capacitances K and c exhibit. The inductances / represent longitudinal inductances; they are used in a known manner as a flywheel inductors and achieve the object, during the closing of a switch ZSA in which acts as a storage capacitor capacitor C signal stored energy completely through the switch ZSA to transmit or pulse-wise fed in the reverse direction via the switch ZSA energy completely in to transfer the storage capacitor c. For this purpose, the resonant circuit formed from a coil with the series inductance / and a capacitor with the transverse capacitance c is to be tuned so that the period of its natural oscillation is twice as long as the respective closing time t of the switch ZSa. The switching elements K, H and c are to be dimensioned in a known manner so that they each form a low-pass filter TP whose fundamental frequency is at most half the switching frequency with which the switches ZSa are operated in pulses. The wave resistances of the low-pass filters TP are each to be adapted to the connected line Ltg . When this condition is met, very specific values result for the various switching elements of the reactance networks belonging to the switches. It then emerges that the low-pass filters TP allow the vibrations associated with the messages to be exchanged to pass, but not the vibrations of higher frequencies associated with the switching pulse sequences. These oscillations with higher frequencies therefore do not reach the terminals Tn connected to one another by the connecting lines Ltg and therefore cannot cause any interference there either.

In the time division switching system, as shown in part in FIG. 4, an inductance V ₁ is now also filled between the connection point of the two switches ZS'α and ZS "α and the resonant circuit L, CW of the damping compensation element aj of the damping compensation device A. This inductance V ₁ acts with the switching elements of a reactance network explained above together in order to completely transfer the signal energy stored in the capacitor c, which acts as a storage capacitor, to the energy store LC of the attenuation compensation device a- or vice versa when the switches ZSa and ZS'α are closed named coil with the series inductance V ₁ and the energy storage L, C formed resonant circuit so that its natural oscillation period is twice as long as the respective closing time t of a switch ZSa or ZS'a or ZS "a. The energy store L, C formed by a parallel resonant circuit can be viewed as a capacitively complex impedance, since its natural frequency is matched to the sampling frequency of the time-division multiplex switching system, ie to the switching frequency of the switches ZSa, ZS'a, ZS "α , the switching period T but larger than the respective

ίο switching duration t is the switch. Through this interaction of a reactance network assigned to a switch and the energy store L, C together with the inductance I _{1 connected} upstream of it, there is practically attenuation-free transmission of the signal energy supplied from one side of the multiplex rail into the energy store L, C and of stored signal energy to the other Side of the multiplex rail reached. The energy store L, C, the time constant of which can be changed as a function of the control signal, therefore absorbs the entire signal energy offered from there at the time when a switch ZS'a or ZS "a closes; therefore, no reflections are caused in the multiplex rail .

This is of particular advantage in that it results in a high level of feedback loss in the time-division multiplex switching system can be achieved according to the invention in the known attenuation compensation circuits would be difficult and difficult to achieve.

Claims (10)

Patent claims: 1. Time division multiplex switching system with a two-wire multiplex bus. To which connection lines can be connected periodically with the help of time channel switches and which are connected to a coupling network, via which connections of a connection line of the time division multiplex switching system with another connection line of the same as well as another switching system can be routed, for telecommunication systems, in particular telephone systems , characterized in that in the multiplex rail (P) between that multiplex point [P (I)], in which the time channel switches (ZS) are combined, and the coupling network (KF) a damping compensation device (A) is inserted, which for each pulse phase, to which a connection line (Ltg) is connected to the multiplex bus (P ), the degree of attenuation can be controlled by a control signal corresponding to the line attenuation of the relevant connection lines (Ltg). 2. Time division multiplex switching system according to claim 1, characterized in that the damping compensation device consists of a single one There is a damping compensator. 3. Time division multiplex switching system according to claim 1, characterized in that the attenuation compensation device (A) consists of several sub-devices (α), each of which is assigned to a pulse phase to which a connection line (Ltg) can be connected to the multiplex rail (P) . 4. Time division multiplex switching system according to claim 3, characterized in that a partial device (aj in Fig. 2) by an energy store (L, C) with a function of the control signal variable time constant is formed, which is connected to the connection point of two switches (ZS'a, ZS "d) inserted in series in the multiplex rail (P) and periodically offset from one another in time. 5. Time division multiplex switching system according to claim 4, characterized in that the two switches {ZS'a, ZS "a) are each closed in pulses offset from one another by half the sampling period of the time division multiplex switching system. 6. Time-division multiplex switching system according to claim 5, characterized in that the energy store is closed by a parallel resonant circuit (L, C) with a natural frequency equal to the frequency with which the two switches {ZS'a, ZS "d) are closed evenly offset in time , or is formed equal to an integer multiple of this frequency, which has a parallel resistance (R) controlled by the control signal. 7. Time division multiplex switching system according to claim 6, characterized in that the controlled parallel resistor (R in Fi g. 2) is formed by an ohmic resistor (W in Fig. 4) and a negative resistor (Tr) connected in parallel thereto. 8. Time division multiplex switching system according to claim 7, characterized in that the negative resistance is formed by a feedback amplifier circuit, the amplifier element (Tr) can be controlled in its operating point by the control signal. 9. Time division multiplex switching system according to one of the preceding claims, characterized in that the multiplex bus (P) has an additional control line (PC) to which only loop direct current flows through the line points of the connecting lines (Ltg) with the aid of each additional contact (ZSc) having time channel switches (ZSa, ZS'c) can be switched on periodically in pulses, and to the same pulse phase (pj) to which a connecting line (Ltg) is connected to the multiplex rail [(P (I)], with the help of a likewise one additional contact (ZS'c) having switch (ZS'a, ZS'c) the control input of the attenuation compensation device (a) effective for this pulse phase can be switched on. 10. Time division multiplex - switching system according to one of claims 4 to 9, characterized in that to achieve a lossless exchange of energy between the energy store (L, C) and one side [(P (I) or P (2)] of the multiplex rail (P ) a coil (/ in Fig. 2, Ij in Fig. 4) is inserted between the connection point of the two switches (ZS'a, ZS''a) and the energy store (L, C) and that the period of a natural oscillation of the oscillating circuit consisting of this coil and the energy store (L, C) is twice as long as the duration of the closing of one of the switches (ZS'a, ZS''a) . Considered publications:
German patent specification No. 947 249. 1 sheet of drawings 409 560/86 4.64 © Bundesdruckerei Berlin