DE1562123B2 - CIRCUIT ARRANGEMENT FOR CONTROLLING THE CONNECTION SETUP IN A REMOTE COMMUNICATION, IN PARTICULAR TELEPHONE SWITCHING SYSTEM - Google Patents

Description

The invention relates to a circuit arrangement for controlling the establishment of a connection in a telecommunications, in particular telephone exchange, the switching network of which is provided with a number of inputs different types (e.g. subscriber circuits, connection set inputs, connection set outputs), furthermore with a number of switching network connection paths of different types connected between Pairs of inputs of different types and running over one or more coupling stages, furthermore with Entrances of different types at at least one end of the connection paths and with a number Marker.

Such a circuit arrangement is known from Belgian patent specification 5 38 654. Everyone is there Coupling stage assigned an individual marker, so that in a switching system with very many Coupling stages also the number of markers is correspondingly large.

The object of the invention is therefore to provide a circuit arrangement of the type mentioned at the beginning to simplify the structure of the switching system with regard to the markers. This is done according to the Invention achieved in that the markers each have at least two control inputs or certain Coupling stages are assigned and connected to them, the connection paths of different types To belong.

According to a further embodiment of the invention, each marker selects one of its marking outputs which are assigned to the assigned inputs or to the marking inputs of the assigned specific copier

pelstufen are connected.

According to a further embodiment of the invention, each marker has a number of marking outputs that is at most equal to the total number of assigned inputs or at most equal to the sum of the Marking inputs of the assigned specific coupling stages is.

Telephone exchanges are known in which the switching network is formed by a number of matrix-shaped switching stages. Each switching stage has _[0] a number of inputs and outputs. The coupling stages are interconnected in such a way that there is only a single connection path between any pair of inputs. Such a switching network allows the crosspoints of each switching stage to be broken down into a small number of groups, each having a common marker input, and to establish a connection by marking an input of the switching group and a marker input in each switching stage belonging to the connection path. '

If such a marking process in the arrangement of the said Belgian patent too would have taken place, an individual marker would have to be assigned to each coupling stage, its Marking outputs are connected to the same number of marking inputs of the associated coupling stage. In this case the entire marking device of the coupling network would thus be formed by a large number of markers each of which marks a relatively small number of marker inputs. Such an arrangement would have the disadvantage, however, that each marker has a relatively complex structure. Besides, of the marking outputs, such a marker would have to have an individual memory for storing the binary code words of the marking inputs to be marked, an individual decoding circuit for decoding a binary code word into a number and at least one individual test circuit for testing the correctness of the stored code words.

Instead of proceeding in this way, according to the invention, all marking outputs, the certain, im Course of the connection paths of different types, for example the connection paths between connection record inputs and subscriber circuits and between connection set outputs and outgoing connection line transmissions, switching elements mark, arranged in a single marker, so that such a marker has a number Marked inputs marked, which is much larger than in the above case. Because of this, it won't only the code memory in comparison with the number of code memories to be provided individually in the case mentioned easier but it has also proven beneficial to have all of the marking outputs in a two-dimensional Arrange matrix, as this results in a simple decoding circuit and the matrix associated, simple Test circuits for checking the stored code words and for checking the switching status of the Crosspoint marking elements of the matrix can be used, so that the marker is not just simple is, but also works reliably.

If it is also necessary that a switching stage can be marked by two sources It has been found unnecessary to duplicate the markers completely. According to another Only the code memory, the decoding circuit and the code checking circuit are embodied in the invention duplicated while only a single marking matrix and a single test circuit for testing the Switching state of the matrix marking elements needs to be provided. This is made possible by that the individual marking matrix and marking element test circuit have an extremely reliable structure and that a marker error is immediately recognized by this test circuit and has no effect on the switching status of other marking elements in the matrix.

A further embodiment of the invention is characterized in that each marker making the selection one of its marking outputs connected to the marking inputs of the assigned specific coupling stages causes, has marker outputs, of which at least one with at least two marker inputs, in each case one in at least two of the assigned specific coupling stages is connected. In this way, the number of marking outputs to be provided is reduced in each marker.

According to a further embodiment of the invention, each marker that the selection of one of its with the assigned inputs causes marking outputs connected with its marking outputs to certain connected to these inputs.

Another embodiment of the invention is characterized in that the coupling stages of each connection path lie in series between these inputs and that the 'markers provide a connection path in such a way establish that the marker marking the entrances at one end of this connection path is first in Operation is set and is kept in operation as long as the connection path remains switched through got to. while the markers marking the coupling stages for this connection path mark the successive one Responding to the coupling elements connected in series in those associated with this connection path Initiate coupling levels.

Another embodiment of the invention is characterized in that

a) the selection circuit of each marker comprises a code memory, a second decoding circuit, that

b) the first decoding circuit has a number of marking elements, each with a first input, one having a second input and at least one output in a two-dimensional matrix are arranged that

c) In this matrix the first inputs of the marking elements line by line on line wires, the second The inputs of the marking elements are connected column by column to column wires and the marking outputs are formed by the outputs of the marking elements that

d) the second decoding circuit has a number of inputs and a number of outputs, these Outputs control the row and column wires of the two-dimensional matrix and these Inputs are connected to the code memory that

e) the code memory stores the identifier of one of the marking outputs and based on the storage such an identifier a corresponding row wire and a corresponding column wire of the Matrix and thus a marking element arranged at the intersection of these wires is excited, which Grants access to the marking exit,

whose code word is stored in the said code memory.

According to a further embodiment of the invention, the outputs of the second decoding circuit are each connected to a relay which, when actuated, applies a control potential to a certain row wire or Lay the column wire.

Further advantageous embodiments of the invention deal with the control circuit for the marking matrix and with the code checking circuit and the marker checking circuit.

The invention is explained in more detail on the basis of the following description of exemplary embodiments. It shows

Fig. 1 is a connection diagram of an automatic: telephone exchange,

; Fig. 2 shown in more detail coupling stages 571,575 '. in Fig. 1 are shown,

■ F i g. 3 shows a marker TM 1 shown in more detail, which in Fi g. 1 is shown

; Fig. 4 markers with test equipment according to , Invention.

The arrangement shown in Fig. 1 is part of an automatic telephone exchange in this 7th embodiment and has a number of connections of different types, for example inputs / and outputs O of connection sets JUC, subscriber circuits LIC and outgoing trunk transmissions OTC. She knows ^; furthermore a number of switching network paths of different types, which lie between pairs of inputs of different types and run through switching stages, and connections of different types at least at one end of these paths. For example, in the course of the switching network paths of one type there are switching stages 571 to 574 connected in series, these paths between pairs of connections /, LIC ; Various types of run while Koppelnetzwe- 'ge of another type via series-connected switching stages 575-578 between pairs of: run different terminals O, OTC type. The switching system also contains markers TM and TM 1 to TM 4, which are used to control the connections /, j O and the switching stages 571/575 or 572/576 or

■ 573/577 or 574/578 are used to create the so-called coupling network paths.

The connection set inputs /, the switching stages 571 to 574 and the subscriber circuits LTC are interconnected by intermediate lines a, b, c, d, e , while the connection set outputs O, the switching stages 575 to 578 and the outgoing trunk line transmissions OTC are interconnected by intermediate lines k, I, m, η, ο are interconnected.

Each connection set input / a connection set JLJC 'is connected on the one hand to a marker input Fl of this connection set and on the other hand via a decoupling diode d'ii and a normally open contact Λ1 of a Realis Hr in the connection set JUC to the earth terminal. Likewise, each connection set output O of a connection set JUC is connected on the one hand to a marking input PX of this connection set and on the other hand via a decoupling diode d'12 and the contact h 1 to the earth terminal. The winding of the relay Hr is connected with one connection to the earth terminal and the other connection on the one hand to a control input Q 1 and on the other hand via a normally open contact Λ 2 of the relay Hr to a terminal carrying a potential of -48V. Each connection set JUC thus has two marking inputs (Fi, Pi) and a control input (Qi), the marking inputs being connected to the input or output of the connection set. The connection set input and output are in turn connected to one of 128 intermediate lines a and to one of 128 intermediate lines k , respectively. Since there are 128 connection set inputs and 128 connection set outputs, these inputs and outputs can be identified by a 7-digit binary code.

As will be explained in more detail elsewhere, the coupling stage 571 has a total of 128 inputs which are connected to certain of the 128 intermediate lines a , further 256 outputs which are connected to certain of the 256 intermediate lines b , furthermore 4 marking inputs and 512 coupling elements, each with a first input to one of said 128 inputs, with an output to one of said 256 outputs and with a second input to one of the 4 marking inputs of the coupling stage 571. Each coupling element has the property that, after a marker has been applied via a marker input to its second input, it can establish a connection between its first inputs and its output, ie between an intermediate line a and an intermediate line b . Each coupling element is formed by a relay winding which is on the one hand in series with a diode between its first input and its second input and on the other hand in series with a normally open contact of the relay between its first input and its output. For example, the coupling element shown in the coupling stage 571 is formed by a winding of a relay Lar , on the one hand in series with a diode d'i between the shown intermediate line a and a marker input H and on the other hand in series with a working contact la between the shown intermediate line a and of the intermediate line b shown.

The number of coupling elements is twice as large as the number of outputs, which is due to that the outputs of the coupling elements are divided into groups of two, as will be explained later with reference to FIGS. 2 is explained. Because now the second inputs of the 512 coupling elements are connected to the four marker inputs mentioned are connected to the coupling stage 571, there are also 4 groups with 128 coupling elements each formed, the coupling elements of each group with the same marking input of the coupling stage 571 are connected. Each such group or each marking input can thus be replaced by a 2-digit Binary code.

The switching stage 575 has 128 inputs, which are connected to certain of the named 128 intermediate lines k , further 64 outputs, which are connected to certain of the 64 intermediate lines /, also 4 marker inputs and 512 coupling elements, each of which is a first connected to one of the named 128 inputs Input, an output connected to one of the named 64 outputs and a second input connected to one of the named 4 marker inputs of the coupling stage 575. These coupling elements are designed like those in the coupling stage 571, and the coupling element shown is formed, for example, by the winding of a relay Lkr which, on the one hand, is in series with a diode d'5 between the intermediate line shown.

609 551/4

device k and the shown marking input J of the coupling stage ST5 and on the other hand in series with a normally open contact / Ades relay Lkr between the shown intermediate line k and the shown intermediate line /. The number of coupling elements is eight times greater than the number of outputs, which is due to the fact that the outputs of the coupling elements are grouped together in groups of eight, as will be explained in greater detail below with reference to FIGS. 2 is explained. There are also 4 groups with 128 coupling elements each. The ι ο coupling elements of each group are connected to the same marker input of the coupling stage 575. Each such group or each such marking input can thus also be identified by a 2-digit binary code.

The marker TM has 256 marking outputs and 128 control outputs, which are connected to the 256 marking inputs or to the 128 control inputs of the 128 connection sets. For example, the marker TM has a marker output F2 connected to the marker input Fl by means of a marker wire f , a marker output P2 connected to the marker input Pi by means of a marker wire ρ, and a control input Q 2 connected to the control input Q 1 by means of a marker wire q . The marker 77Vi can select and mark a single marker output of its 256 marker outputs together with a single control output of its 128 control outputs by means of its timing circuits (not shown). This marker has a first selection circuit SC 1 which selects the pair of marker outputs and that control connection which is connected to that connection set from which the 7-digit binary code word has been stored in the first selection circuit SC1. The marker TM further includes a second selection circuit SC2, which selects a single Markierausgang of the already selected Markierausgangspaares due to the stored in the second selection circuit SC2 binären.Codewortes, which indicates that a junctor input or affected output, and the time circuits by means of said marks the selected marking outputs and the control output that has already been selected. For example, the selection circuit 5Cl selects the connection set JUC shown in that the normally open contacts r, s, t connected to the marker outputs F2, P2 and the control output Q 2 of the marker Tm are closed. The selection circuit 5C2 selects one of the marking outputs F2, P2 in that one of the corresponding normally open contacts T1, T2, for example the normally open contact T1, is selected. The timer closes the selected normally open contact Tl. When the normally open contacts Tl and r are closed, a marking potential of + 48V is applied to the marking output F2, while when the normally open contacts Tund fine control potential of -48 V is applied to the control output Q 2 .

The contacts T1, T2, T are each provided jointly for the 128 marking outputs connected to the 128 inputs /, for the 128 marking outputs connected to the 128 outputs O , and for the 128 control connections connected to the 128 connection sets. These contacts are preferably formed by the switching paths of transistors.

It follows from the foregoing that the marker TM can select and mark only one input of the switching network, namely one of the total number of 256 connection set inputs and outputs.

The markers TM1 to TM4 are identical to one another, so that only the marker TM1, for example, needs to be explained. The marker TM 1 has 4 marker outputs, each of which is connected to two marker inputs via marker wires - one marker input each in the coupling stages 5Tl, 5T5. For example, the marking output G is connected to the marking inputs wound / in the coupling stages 5T1 and 5T5 via marking veins g . The marker TM 1 selects and marks a single marker output of these marker outputs by means of its timing circuits (not shown), of which the 2-digit binary code word has been stored in the marker TM1. For example, the marker TM1 selects the marker output G by closing a normally open contact / f, while the timer marks the marker output G by closing a normally open contact T3. When the contacts It, 7'3 close, marker ground potential is applied to marker output G. Contact T3 is provided for all marking outputs.

The markers TM 2 to TM 4 have marking outputs that correspond to the marking inputs of the corresponding Pairs of coupling stages ST2 / Sr6 or 5T3 / 5T7 or 5T4 / 5T8 are connected, and can have a marking output of their marking outputs and thus two of the Select and mark the marking inputs of the assigned coupling levels, with the marking processes controlled by the timers.

The switching system described works in the following way. If, for example, a coupling network path is to be established between a predetermined connection set input / or an intermediate line a and a predetermined subscriber circuit L / C or an intermediate line / via predetermined intermediate lines b to d , a 7-digit binary code word characterizing this connection set input is stored in the selection circuit 5Cl of the marker TM , this binary code word indicating that a relevant connection set input is stored in the selection circuit 5C2 of the marker TM , and then the binary code words which identify the marker outputs which are assigned to the groups having the intermediate lines b to d are stored in corresponding markers TM1 to TM4. On the basis of the stored code words, the selection circuit SCl of the marker TM selects the connection set JUC shown by closing the corresponding contacts r, 5, t , while the selection circuit 5C2 selects the corresponding marking output F2 by closing the normally open contact Tl. Taps TMI to TM 4 select appropriate Markierausgänge by closing corresponding contacts, for example by closing such contacts as It in marker TM 1, from.

After the mentioned code words have been stored, the timing circuits are put into operation. After a predetermined time sufficient to close the contacts r, s, t, It , the contacts Tl, T of the marker TM are closed for a time sufficient to establish the coupling network path, ie to set the coupling stages STl to 5T4 , while such contacts as T3 of the markers TM 1 to TM4 are closed successively during such periods of time which are necessary for setting the corresponding

the coupling steps are sufficient. A working contact 73 of a marker TMi to TM 3 is only opened when the corresponding contact 73 of the next marker TM2 to 7M4 has been closed.

When the working contacts Ti, r close, the marking potential of +48 V is applied to the input / of the connection set / i / C via these working contacts, the marking output Fl, the marking wire / and the marking input Fl.

When the working contacts T, t close, the control potential of -48 V is applied to the control input Q 1 of this connection set JUC via these working contacts, the marking output Q2 and the control wire q . The application of the -48 V mark has no effect at times, but due to the application of the -48 V control potential to the control input Qi and thus to one connection of the winding of the relay Hr , this relay responds because the other connection is grounded is. Closing the normally open contact h 1 of this relay also has no effect for a time because the input / has a potential of +48 V and because the diode d'W is present, but when the normally open contact hl is closed, the relay Hr is at -48 V. held.

When the make contacts 73, It in the marker TMi are closed , marker ground potential is applied to the corresponding marker output G, which means that the relay Larin responds to the following circuit:

+ 48 V at connection set input /, intermediate line a, winding of relay Lar, diode d ' 1, marking input H, marking wire g, marking outputs C, working contacts / fund 73, earth.

When the normally open contact la of the energized relay Lar is closed, a coupling network path is established between the connection set input shown and the intermediate line b shown.

Although the marker TM 1 also marks the marker input / coupling stage 575, this has no effect on the state of the relay Lkr because the connection set output O has not been selected and marked by the marker TM.

In a corresponding manner, when a contact 73 controlled by the timing circuit is closed in the marker TM1, marker ground potential is applied to the marker output that has already been selected and thus to a marker input in each of the coupling stages 572 and 576. The relay switched on between the marked wire b and the marked marking input of the coupling stage 572 in the coupling stage 572 cannot respond, however, because both connections of this relay are grounded.

However, as soon as the timer opens the normally open contact 73 in the marker 7Ml, the mentioned short circuit is canceled, whereupon the said relay in the coupling stage 572 in series with the relay Lar due to the +48 V marking potential effective at the input / and the marker ground potential applied in the marker TMl appeals to. A coupling network path is therefore established between this input / and an intermediate line c via the intermediate line b shown and the two relays.

In a corresponding manner, the markers Tm 3 and 7M4 control the setting of the coupling stages 573 and 574, so that finally a connection path is established between the input / and a relay Cor . When this has happened, the timer opens the normally open contacts 71 and 7, so that the marker 7M is released for the production of another coupling network path. The established connection path remains connected, however, because a potential of -48 V is applied to one connection of the relay Cor and earth potential is applied to the connection set input / via the normally open contact h 1 and the diode d'ii , and the relay Cor thus remains energized.

In FIGS. 2 and 3, the coupling stages 571 and 575 (FIG. 2) and the associated marker TMi (FIG. 3) are shown in more detail.

The switching stage 571 in FIG. 2 has 64 identical switching matrices, only one of which is shown. This switching matrix is formed by eight relay windings working as coupling elements. One connection of each winding is connected to the anode of a diode di, i ... di, 4 or c / 1.5 . .. c / 1,8 connected, while a normally open contact Ia is connected to the common connection point of this winding connection with this diode. The other connection of each winding forms the first input of the coupling element, the cathode of the respective diode forms the second input of the coupling element, and the rest spring of the respective normally open contact la forms the output of the coupling element. For example, one of the eight coupling elements is formed by a relay winding Lari, which is connected to the anode of the diode di, i , and a normally open contact la 1, which is connected to the common connection point of the relay Lar 1 and the diode di, i is. The eight coupling elements mentioned are arranged in a two-dimensional matrix with two parts and four columns. The first inputs of the coupling elements of each row, i.e. the direct winding connections, are connected to a row wire, while the second inputs of the coupling elements of each column, i.e. the cathodes of the diodes of each column, are connected to a marking input via a column or marker input wire. Furthermore, the outputs of the coupling elements of each column, ie the rest springs of the normally open contacts of the relays of each column, are connected to a common output. In particular, the direct connections of the relay windings Lari to Lar 4 with a row wire a 1 and those of the windings Lar5 Lar to 8 with a row wire are connected al; the cathodes of diodes d 1,1 and i / 1,5 are via a column or marker input wire ei with a marker input Hi and the cathodes of diodes c / 1,4 and c / 1,8 are via a column or marker input wire c4 connected to a marker input H4 , while corresponding connections are present for the second and third columns; the rest springs of the working contacts la 1 and la5 of the relays Lari, Lar5 are connected to a common output b 1 and the rest springs of the working contacts la 4 and la 8 of the relays Lar4, LarS are connected to a common output b4 , while corresponding connections for the second and third column are present. The outputs b 1 to 64 are connected to four of 256 intermediate lines b , which lead to the neighboring coupling stage 572, while the 4 column or marker input wires c 1 to c 4 lead to 4 marker output wires g 1 to g4 of the marker * 7M1, where ei with gt, el is connected to g 2, etc. Likewise, the 4 column wires of every other switching matrix of switching stage 571 are connected to these marker wires gi to g4 , each of which is therefore connected to 64 column wires - one column wire in each switching matrix,

as indicated by the multiple arrow. The two row wires a 1, a 2 form intermediate lines a and are connected to the two inputs Ii, 12 of two connection sets. Likewise, the two row wires of the other switching matrices contained in the switching stage 5Tl form intermediate lines a, which are connected to the inputs of two other connection sets, with a total of 128 connection sets being available.

The switching stage 575 has 16 identical switching matrices, only one of which is shown. This switching matrix is made up of 32 switching elements which are identical to those of the switching stage STi and are arranged in a two-dimensional matrix with eight rows and four columns. The direct connections of relay windings LAxI to LAx 4 are connected to a row wire ArI and those of windings LAx29 to LAx32 are connected to a row wire A: 8, while corresponding connections are provided for the 2nd to 7th rows. The cathodes of diodes c / 5.1 to c / 5.29 are connected to a column wire el and ^ the cathodes of diodes d5.4 to i / 5.32 are connected to a column wire e4, while corresponding connections for the second and third Column are present. The rest springs of normally open contacts / ArI to Ik 29 are connected to a common output / 1 and the rest springs of normally open contacts Ik 4 to Ik 32 are connected to a common output 14, while corresponding connections are provided for the second and third columns. The outputs / 1 to / 4 are connected to four of 64 intermediate lines /, which lead to the neighboring coupling stage 576, while the 4 marking or column wires e 1 to e4 connected to the marking inputs / 1 to / 4 are connected to the four marking output wires g 1 to g4 of marker TM 1 (e 1 with ^ l; el with g 2, etc.) are connected. Likewise, the 4 column wires of every other switching matrix 'of the switching stage 575 are connected to these marking wires gi g4 , each of which therefore has 16 column wires

- with a column wire in each matrix

- is coupled, as indicated by the multiple arrow. The 8 row wires ki to k 8 form intermediate lines k and are connected to the outputs 01 to 08 of eight connection sets. Likewise, the 8 column wires of each remaining switching matrix of the switching stage S75 form intermediate lines k; these column wires are connected to the outputs of eight other connection sets out of the total of 128 connection sets.

The marker TM 1 in FIG. 3 is formed by a code memory CSCl and by a selection or decoding circuit DCl. The decoding circuit DCl consists of four marking elements, each of which is formed from a relay winding connected to the anode of a diode and a normally open contact connected to ground via the normally open contact 73. The terminal of the relay winding not connected to the diode forms the first input, the cathode of the diode forms the second input, and the spring of the make contact not connected to the make contact 73 forms the output of the respective marking element. For example, in the one marking element, a relay winding Ltri is connected with one terminal to the anode of a diode di , the cathode of which is connected to a column wire at; the other connection of the relay Ltri is connected to a row wire u , while a working contact It 1 belonging to this marking element is connected with the rest spring to the marking wire g \ and with the working spring to the contact T3. The four marking elements mentioned are arranged in a two-dimensional matrix with two rows and two columns. In this matrix, the first inputs of the marking elements are connected row by row to a row line u or ν. The second inputs of the marking elements are connected column by column to column wires χ and /, and the outputs of the marking elements are led to the associated marking wires g 1 to g \ . In detail, the relays Ltri, Ltri are connected with one connection to the row wire u and the relays Ltr3, Ltr3 with one connection to the row wire ν ; the cathodes of the diodes dl, d3 are connected to the column wire χ and the cathodes of the diodes d2, d4 are connected to the column wire y , while the normally open contact It 1 is connected to the marker wire gi, the normally open contact It2 to the marker wire gl, etc.

The code memory CSCl has two code memory circuits SS1, BSI with two stable switching states and a preparatory bistable circuit 553, these bistable circuits BSI to BS3 normally remaining in their 0 state. The 0 output of the circuit BS 1 is connected to the row wire u and the 1 output of this circuit is connected to the row wire ν of the decoding circuit DCl. The 0 output of the circuit SS 2 is connected to the column wire χ and the 1 output of this circuit is connected to the second connection of an AND gate G , the first connection of which is connected to the 1 output of the circuit 553. The bistable circuits 551 and 552 store the 2-digit code words which identify one of the four marker output wires gi to g4, ie a group of the four groups of 64 intermediate lines b or a group of the four groups of 16 intermediate lines /. The bistable circuit BS 1 is provided for one digit of the two-digit code and the bistable circuit 552 is provided for the other digit. The preparatory bistable circuit 553 is brought into its 1 state each time a code word has been stored in the circuits 551, 552 for reasons which will be explained later.

It is recalled that the switching stages 5Γ2, 573, 574, 576, 577, 578 as the switching stages 571, 575 and the markers TMI to 7M4 like marker TM are constructed. 1 The marker TM is formed by 256 marking elements which are arranged in a two-dimensional matrix and each have three working contacts, such as /; s, t in FIG. 1, the corresponding working contacts of all these marking elements being grounded via the corresponding common working contacts 71, 72, 7. The time circuits arranged in markers TM, TMi to TM4 are again not shown.

With reference to FIGS. 2 and 3, the already described production of a coupling network connection path between a predetermined connection set input and a predetermined subscriber circuit via the coupling stages 571 to 574 will now be explained in more detail, as far as the coupling stage 571 and the marker TMl are concerned, it being assumed; that code words are stored in the markers 7M and TM 1.

On the basis of the code word stored in the marker TM and on the basis of the control characters of the timer arranged in this marker, a

A potential of + 48V is applied to the input / 1 of a connection set and thus to the row wire a I of the coupling stage STi in the manner described with reference to FIG.

On the basis of the code word stored in the marker TMi in the bistable circuits BS1, BS2 of the code memory CSCl, the decoding circuit DCi of the marker TM selects one of its four marker output cores g 1 to g4 . For example, when the circuit BSi has been brought into the 0 state, the circuit BS2 into the 1 state and then the circuit BS 3 into the 1 state, the row wire u is energized and the column wire χ is de-energized. As a result, the relay Ltr 1 responds in the following circuit:

u, Ltri, di, x.

When the bistable circuits BSi, BS2 assume the switching states 0.0, 1.1 or 1.0, the corresponding relays Ltr2, Ltr3, Ltr4 respond , with the current flowing only to the de-energized 1 output of circuit 552 when the circuit SS3 controlling the AND gate G is in the 1 state. The AND gate G is necessary because the rest or O state of the circuits BSi, BSI would otherwise trigger the relay Ltr 2 in the following circuit:

u. Ltr 2, d 2, y.

After the relay Ltr 1 has responded and the normally open contact It 1 closes, the normally open contact Γ3 is closed by the timer for a certain period of time, as already mentioned. As a result, the marking potential is transmitted via the normally open contacts T3, It 1 to the marking output wire gi and thus to a column wire in each of the 64 coupling multiples of the coupling stage STl and to a column wire in each of the 16 coupling multiples of the coupling stage ST5, specifically to the marking inputs Hi, Ji and die Column or marker input wires egg, egg, laid out. Thereupon the relay Lar 1 of the coupling stage STi responds in the following circuit:

+ 48 V an / 1, a 1, Lar 1, di, 1, ci, gi, It i, 73, earth.

When the relay Lari responds and the normally open contact la i is closed, the input / 1 is connected to the intermediate line bi via the relay winding Lari , which leads to the coupling element ST2 .

No relay of the coupling stage ST5 connected to the column wire e 1 can respond because no column wire or no intermediate line k of this coupling stage is excited.

In the switching system described, the marker outputs of the marker TM i are each connected to two marker inputs, one of which each belongs to the coupling stage STi or ST5. Such a simultaneous control of these switching stages, which belong to switching network paths of different types, is only possible if the marker TM marks only a single input of the inputs of these switching network paths, ie one of the 256 connection set inputs and outputs, at a specific time. Only in this case is a switching network connection established at a given time. Since each marking output of the marker TM i is provided jointly for two marking inputs of the coupling stages ST1, ST5 , the marker 77W1 has a particularly simple structure.

The simultaneous establishment of two different switching network connection paths at a certain time would take place, for example, if the marker TMi were to simultaneously control one of the switching stages connecting the connection set inputs to the subscriber circuits and one of the 4 switching stages connecting the same connection set inputs to the incoming trunk line transmissions. Instead of providing two different markers TMl in this case, it has proven to be advantageous to use a single marker TMl and to provide this with a number of marking output wires which corresponds to the number of marking input wires of the coupling stages to be controlled. For example, if this number is equal to 32, then the number shown in FIG. 4 marker TM 1 shown can be used. The marker TMi in FIG. 4 contains two individual code memories CSCA, CSCB, two individual decoding circuits DCA, DCB, a common selection or decoding circuit DCAB, two individual test circuits CC4, CCB and a common test circuit CCAB, the test circuits being assigned to the common decoding circuit DCAB are. The circuits CSCB, DCB and CCB are indicated by a single block C.

The code memory CSC4 has five bistable code memory circuits BS 1 to BS5 and a preparatory bistable circuit BS6 . The bistable circuits BSI to BS5 each store a specific digit of 5-digit binary code words that identify the 32 marker output wires mentioned, and are divided into a first group with the three circuits BS 1 to BS3 and a second group with the two circuits SS 4, BS5 .

The code memory CSCB is constructed like the code memory CSCA and is therefore not shown in more detail.

The decoding circuit DCA comprises 12 AND gates G 1 to G 8 and G 9 to G 12, which are controlled by the bistable circuits BSX to BS3 and BS 4, BS5. For example, the O outputs of the bistable circuits BSI to ßS3 are connected to corresponding * · inputs of the AND gate Gi ; the 1 outputs of these bistable circuits lead to corresponding inputs of the AND gate GS; the 0 outputs of the bistable circuits BS4, BS5 are connected to corresponding inputs of the AND gate G9, while the 1 outputs of these bistable circuits are connected to the AND gate G12. The AND gates G 1, G9 are also controlled by the 1 output of the bistable circuit BS6. The output of AND gate G 1 is connected to a relay Rar via an amplifier (not shown) and the output of AND gate G 12 is connected to a relay RIr via an amplifier (not shown), the contacts ra, rl of these relays via the test circuit CC4 control the decoding circuit DCA.

The decoding circuit DC4ß comprises 32 marker elements which are arranged in a two-dimensional matrix with four rows and eight columns. Each marking element consists of a relay winding connected to the anode of a diode and a normally open contact connected to earth via contact Γ3. The other connection of the relay winding forms the first input, the cathode of the diode forms the second input, and the other connection of the normally open contact forms the output of a marking element. The one marking element is, for example, through the relay winding Ltri connected with its one connection to the anode of a diode di and through one with its one spring over the contact

609 551/4

T3 normally open contact It 1 connected to earth is formed. The first inputs of the marking elements are connected line by line with line wires / 1 to / 1. The second inputs of the marking elements are connected column by column to column wires a1 to Λ1, while the outputs of the 32 marking elements are connected to the associated marking output wires g 1 to g32. For example, the other winding connections of the relays Ltrl to Ltr8 arranged in the first row are connected to the row wire / 1; the cathodes of the diodes d 1 to d25 arranged in the first column are connected to the column wire a 1 and the other springs of the normally open contacts It 1 to It 32 are connected to associated MäYkierausgangsadern g \ to gZ2 .

The test circuit CCA has two voltage dividers. The first voltage divider is composed of the resistors Rl, Ra ... Rh , which are in series with a normally open contact ζ 1 of a control relay Zr (not shown) between the earth terminal and a terminal having a potential of -48 V. The resistors Ra ... Rh are assigned to the relays Rar ... Rhr and are each connected in parallel with the rest side of a changeover contact of the assigned relay. The working springs of these changeover contacts are each connected to assigned column wires a 1 to hl of the decoding circuit DCAB via assigned resistors R "a to R" h . The common connection point of the resistors R 1, Ra is connected to a potential evaluator PD 1. The second voltage divider consists of the resistors R2, Ri ... Rl, which are connected to a normally open contact ζ2 of the control relay Zr, not shown, between the earth terminal and a terminal carrying a potential of +48 V. The resistors Ri to Rl are each assigned to the relays Rir to RIr and are each parallel to the rest side of a changeover contact ri to rl of the assigned relay. The working springs of these switching contacts are each connected to an associated row wire / 1 to / 1 of the decoding circuit DCAB. The common connection point of the resistors R 2, Ri is connected to a potential evaluator PD 2 .

The test circuit CCB is constructed like the test circuit CCA and is therefore not shown in greater detail. The only difference is that it is controlled by contacts z '1, z'2 of a control relay Z'r, not shown. The relays Zr, Z'r form part of a blocking circuit that prevents these two relays from responding at the same time. The contacts ζ 1, ζ 2, ζ'X, z'2 are provided jointly for all markers 77Vf, 77VfI to 77Vf 4. Each of these relays, for example the relay Zr, is energized by the timer on the basis of the code words stored in the code memories of the markers TM, TMl to TM 4, and a marker relay of this marker can only respond after the contacts zl, z2 have been closed.

The test circuit CCAB has a voltage divider which is connected between the earth terminal and a terminal having a potential of -48 V. The voltage divider consists of the resistor R 3, the resistors R'i to R'l, the windings of the relays Ltr 1 to Ltr8 ... Ltr25 to Lrr 32, the diodes d 1 to d8 ... c / 25 to c / 32 and the resistors R'a to R'h together. The common connection point of the resistors R3 and R'i to R'l is connected to a potential evaluator PD 3. The diodes normally prevent current from flowing from the ground terminal to the -48 V terminal.

Preferred values for the resistances mentioned are 10 V £ 1, with the exception of R "a to R" h, the values of which should each be 1.1 WQ , with the potential evaluator PD 3 then responding to a potential of> -32 V.

The marker TMl in Figure 4 works in the following way.

If one of the 32 marking output wires g 1 to # 32 is to be marked, a corresponding 5-digit binary code word is stored in the bistable circuits BS1 to BS5 of the code memory CSCA and the preparatory bistable circuit BS6 is brought into its 1 state. As a result, the timer is started, which allows the relay Zr to respond and prevents the relay Z'r from responding. If the code word is, for example, 00011, the circuits BS 1 to BS3 remain in the 0 state, while the circuits BS4, BS5 go into the 1 state. As a result, the outputs of the gates Gl, G 12 are energized, so that the associated relays Rar, RIr respond. After switching over the contacts ra, / '/, the relay Ltr 25 responds in the following circuit:

Earth, z2, rl, l \, Ltr25, d25, a 1, R "a, ra, (rb ... rk), rh, zl, -48 V.

By closing the contact It 25, the marking output wire g 25 is connected to the open normally open contact T3 , which is then briefly closed by the said timing circuit in order to apply marking potential to this marking wire g 25.

The purpose of the CCA test circuit is to check whether only one relay in the group of relays Rar to Rhr and only one relay in the group of relays Rir to RIr is addressed. If this is the case, for example, in the relay group Rar to Rhr , the potential evaluator PD 1 is connected to the connection point of the resistor R 1 with a single resistor of the identical resistors Ra to Rh , these two resistors between the earth terminal and the -48-V -Clamp lie. In this case, the potential evaluator PD 1 does not react to the potential at the voltage divider tap. However, if no relay or two or more relays in the relay group Rar to Rhr have responded, the potential evaluator PD 1 reacts to the potential occurring at the voltage divider tap, because then no resistor or two or more of the resistors Ra to Rh are effectively switched into the voltage divider. The potential evaluator PD 2 works in a corresponding manner.

. With regard to the test circuit CCaB, it should first be noted that the state of the potential evaluator PD 3 is only queried when the decoder circuit DCAB is not actuated. If a marking element has actually been actuated in this circuit DCAB, e.g. B. the relay Ltrl, the potential evaluator PD 3 is connected to the common connection point of the resistors R 3, R'i , which has a potential of -24 V. This potential is sufficient for the potential evaluator PD 3 to respond, although no error has occurred in the decoding circuit. It should be noted here that the current flowing through the voltage divider R 3, R'i has no influence. exercises the switching state of relay Ltr 1. If, however, a diode, for example the diode d1, is faulty short-circuited in the decoding circuit DCAB, which was assumed to be not actuated, then a flow occurs

Current in the following circuit:

Earth, R'a, aX, dX, LtrXJX, R'i, R 3, -48 V.

As a result, the potential at the connection point of the resistors R3, R'i is approximately -32 V, which allows the potential evaluator PD 3 to respond. In this way, the presence of an incorrectly short-circuited diode dX can be recognized.

The presence of a faulty diode without continuity can be recognized by the fact that the assigned relay LtrX to Ltr32 does not respond when the corresponding row and column wire is excited.

Instead of designing the test circuit CCAB as described above, it can also be assigned to a number of asymmetrical impedances which are formed by diodes and which are arranged at the cross points of a two-dimensional matrix.

This matrix can have a number of row wires / 1 to / 1 and a number of column wires a1 to Λ 1, 2O ₁ , each pair of a row wire and a column wire being connected to a DC voltage source (earth, -48 V) in order to determine the state of the am J crossing point of this wire pair arranged impedance to change. In such a test circuit CCAB, each pair of a row wire and a column wire is connected in series with resistors R 3, /? 7 to R'I and R'a to R'h to a different DC voltage source (-48 V, earth) with opposite polarity The polarity of the first-mentioned DC voltage source is connected in such a way that the state of the asymmetrical impedances is not influenced. Such a test circuit also includes a potential evaluator PD 3 connected to the said resistors in order to be able to detect the rise of a current above a certain value, for example due to a faulty short circuit of one of these asymmetrical impedances.

The marker TM1 described in FIG. 4 is highly reliable. Since it actually has two code memories CSCA, CSCB, two decoding circuits DCA, DCB and two test circuits CCA, CCB , the individual decoding circuit DCAB can be controlled either via the circuits CSCA, DCA, CCA or via the circuits CSCB, DCB, CCB . Simultaneous control is prevented by the relays Zr, Z'r . In addition, a short-circuited or open diode in the individual decoding circuit, which is made up of extremely reliable elements, only acts on the associated marking element in the decoding circuit.

Said marker TM 1 is also constructed in an economical manner if one only considers the code memory CSCA and the decoding circuits DCA, DCAB . Due to the presence of these two decoding circuits, the present marker TMX is far simpler than a marker which only comprises a single decoding circuit which would then have to have 32 gates, each with 5 inputs to the: outputs of the bistable circuits BSX to BS5 and each with their Output to a specific relay of the 32 relays LtrX to Ltr 32 would have to be connected. In this case, not only would a larger number of gate inputs than in the arrangement according to FIG. 4 may be necessary, but because each gate must cause the associated relay to respond, a power amplifier would have to be inserted between each gate output and the associated relay, so that the number of power amplifiers required would be much greater than with the present marker. In addition, direct control of the relays LtrX to Ltr 32 has the disadvantage that if transistors are used for the power amplifier, no good decoupling is achieved between the code memory and the decoding circuit. In the present marker, each gate output controls an auxiliary relay, which in turn controls the decoding circuit via a normally open contact, so that excellent decoupling is achieved. In addition, the auxiliary relays form part of the code checking circuits, as described above, so that they fulfill a dual function.

It has been described how code words are stored in the markers TM X to TM 4, whereupon the marker relays arranged in the markers are actuated and then the timing circuit successively closes the normally open contacts T3 in these markers. This has the result that the normally open contact of each actuated marking relay is closed at a point in time at which none of the two connections to be connected is connected to a DC voltage source. As a result, the service life of these relay working contacts is very long in comparison with such an arrangement in which each of these contacts would connect connections, one connection of which is already connected to a DC voltage source.

Now instead of one after the normally open contacts to close T3 in the markers TMI to TM 4, the 'time circuits can include these contacts at the same time because this has on the sequential operation of the switching stages no influence. In order to achieve the advantage of the long service life of the marker relay work contacts, it is absolutely necessary to close all these work contacts before closing the work contacts T3 at the same time, because otherwise each relay work contact would connect connections, one of which would already be connected to a DC voltage source . This means that all the code words causing the matrix relay to respond must be stored in the corresponding code memories of the markers TM1 to TM4 within a relatively small time interval. If, on the other hand, the procedure is as described, the storage of the code words in the markers, in particular in the markers TM2 to TM4, can take longer without having to give up the advantage mentioned. Such a larger time interval may be required for the source emitting these code words.

For this purpose 4 sheets of drawings

Claims (16)

Patent claims: 1.Circuit arrangement for controlling the connection setup in a telecommunications, in particular telephone switching system, the switching network of which is provided with a number of inputs of different types (for example subscriber circuits, connection set inputs, connection set outputs), and also with a number of coupling network connection paths of different types that connect between pairs of inputs of different types and run over one or more coupling stages, furthermore with inputs of different types at at least one end of the connection paths and with a number of markers, characterized in that the markers (TM, TMi to TM 4) each have at least two control inputs (I, O) or certain coupling stages (STi, ST5; ST2, ST6; ST3, ST7; ST4, 578) are assigned and connected to these, the connection paths belong to different types. 2. Circuit arrangement according to claim 1, characterized in that each marker selects one of its marker outputs (F2, P2; G) which are connected to the associated inputs (I, O) or to the marker inputs (H, / j the associated specific coupling stages. 3. Circuit arrangement according to claim 2, characterized in that each marker has a number Has marking outputs that are at most equal to the total number of assigned inputs or is at most the sum of the marking inputs of the assigned specific coupling stages. 4. Circuit arrangement according to claim 3, characterized in that each marker (TM 1), which allows the selection of one of its with the marker inputs (H, J) causes marking outputs connected to the assigned specific coupling stages, of which at least one (G) is connected to at least two marking inputs, one in each case in at least two of the assigned specific coupling stages (STi, ST5) . 5. Circuit arrangement according to claim 4, characterized in that each marker (TM), which causes the selection of one of its marker outputs connected to the associated inputs, is connected with its marker outputs (F2, P2) to certain (I, (^ of these inputs). 6. Circuit arrangement according to claim 5, characterized in that the coupling stages of each connection path are in series between these inputs and that the markers produce a connection path in such a way that the marker (TM) marking the inputs at one end of this connection path is first put into operation and so is kept in operation for a long time as long as the connection path must remain switched through, while the markers (TM 1 TM 4) marking the coupling stages for this connection path initiate the successive response of the switching elements connected in series in the coupling stages associated with this connection path. 7. Circuit arrangement according to Claim 2 to Claim 6, characterized in that each marker which causes the selection of one of the associated inputs has two selection circuits (SCi, SC 2) . 8. Circuit arrangement according to claim 2 to claim 6, characterized in that a) the selection circuit of each marker (TM, TMi to TM 4) comprises a code memory (CSCA), a first decoding circuit (DCAB) and a further decoding circuit (T> C4j, that b) the first decoding circuit (DCAB) has a number of marking elements (Ltr 1 to Ltr 32) each with a first input, a second input and at least one output, which are arranged in a two-dimensional matrix that c) in this matrix the first inputs of the marking elements are connected line by line to row wires (71 to / 1), the second inputs of the marking elements are connected column by column to column wires (a 1 to h 1) and the marking outputs (g 1 to ir32) are connected to the outputs of the marking elements are formed that d) the second decoding circuit (DCA) has a number of inputs and a number of outputs j, these outputs being the line and! Control column wires of the two-dimensional matrix u and these inputs are connected to the code memory 'rather ("CSC4,") that e) the code memory stores the identifier of one of the marking outputs and based on the Saving such an identifier is a corresponding row wire and a corresponding one Column wire of the matrix and thus a marking element arranged at the intersection of these wires is excited, which grants access to that marker output whose code word is in said code memory was saved. 9. Circuit arrangement according to claim 8, characterized in that each marking element by a relay winding (Ltr 1 to Ltr32) and a diode (di to i / 32) which, connected in series, lie between the first input and the second input of this marking element , and the marker relay is formed by at least one working contact (It 1 to / i32) and that one spring of the working contact is connected to an output (g 1 to g4) of the marking element and the other spring is connected to a marking voltage source, so that after responding of the marking relay, a marking potential is applied to the output of this marking element. 10. Circuit arrangement according to claim 9, characterized in that in each marker (TM) causing the selection of one of the associated inputs, the other springs of the normally open contacts (r, s) belonging to the marker relays are connected in groups, each group belonging to different relays Contacts has that furthermore the contacts of each group are connected in parallel and in series with a certain second working contact (Ti, T2) connected to the marking voltage source and that a second selection circuit (SC2) causes the selection of one of these second working contacts. 11. Circuit arrangement according to claim 3'bis Claim 10, characterized in that a) each coupling stage (STi to 5T8) by a number of coupling elements (Lari to Lar8; Lkri to Lkr 32) each with a first input, a second input and an output is formed in a second two-dimensional Matrix are arranged that b) the first inputs of the coupling elements are connected row by row to row wires, the second inputs of the coupling elements are connected column by column to marker input or column wires (g \ to g4) and the outputs of the coupling elements are connected column by column to common outputs (b 1 to b 4; H to / 4) are, and that e) the simultaneous application of a control character to a row wire and a marker character to a column wire by the associated marker excites the first input and second input of a coupling element arranged at the intersection of these wires and thus causes this coupling element to respond, which has its output and the associated common Identifies output (b 1 to 64; / 1 to / 4) with a corresponding potential. 12. Circuit arrangement according to claim 11, characterized in that each coupling element by a relay winding (Lar \ to Lark; Lkrl to Lkr 32) and a diode (dl, l to d 1.4; dl to i / 32), both in Row between the first input and the second input of this coupling element, and by a working contact (la 1 to la 4; Ik 1 to Ik 32) of the coupling relay is formed and that this working contact on the one hand to the connection point of the relay winding with the diode and on the other hand is connected to the output of the coupling element. 13. Circuit arrangement according to claim 8, characterized in that the outputs of the second decoding circuit (DCA) are each connected to a relay (Rar to RIr) which, when actuated, apply a control potential to a specific row wire or column wire. 14. Circuit arrangement according to claim 8 or claim 13, characterized in that a further second decoding circuit (DCB) are provided with a number of inputs and a number of outputs, that these inputs are connected to a further code memory (CSCB) and these outputs are also the Control row and column wires of the two-dimensional matrix and that a blocking circuit (Zr, Z'r) prevents the two decoding circuits from working at the same time. 15. Circuit arrangement according to claim 13, characterized in that a) the relays are subdivided into a group (Rir to RIr) assigned to rows (71 to / 1) and into a group (Rarbls Rhr) assigned to columns (a 1 to h 1), that b) each relay has a changeover contact (ri to rl; ra to rh) that c) the series-connected quiescent sides of the changeover contacts of the first (second) relay group in series with a first resistor (R 1 or R 2) between the terminals of a first (second) DC voltage source, the quiescent sides of the changeover contacts each through a second resistor (Ri to Rl; Ra to ^ are bridged that d) the assigned row wires (H to / 1) resp. Column wires (a 1 to h 1) of the matrix are excitable and that e) the connection point of the first resistor (R 1 or R 2) with the adjacent second resistor (Ri or Ra) is connected to a potential evaluator (PD 2 or PD 1) which responds when there is no resistance or more than one Resistance of the second resistors is not short-circuited by the idle side of the associated changeover contact.
16. Circuit arrangement according to claim 15, characterized in that an additional test circuit (CCAB) of the following structure is provided; a) each column wire is connected to one pole of the second DC voltage source via an individual first resistor (R'a to R'h). b) each row wire is connected via an individual second resistor (R'i to R'I) and a common resistor (R 3) to the other pole of the second DC voltage source in such a way that the diodes (d1 to c / 32) are normally blocked , and c) the connection point of the individual second resistors with the common resistor is connected to a third potential evaluator (PD 3) , which detects an impermissible increase in the current through these resistors (R 3, R'a to R 'I) responds.