CH626209A5 - Mirrored switching network for telecommunications systems - Google Patents

Description

The invention relates to a mirrored switching network with switching matrixes with at least two incoming lines and at least two outgoing lines and the possibility of mirroring in each switching matrix for telecommunications systems.

A time switch is known from US Pat. No. 3,770,895 and a mirrored multi-stage switching network is known from US Pat. No. 3,963,872. Furthermore, a mirrored network is known from the picture 61 from the book "Nachrichtenvermittlung" by H. Oden, R. Oldenbourg, Verlag München, Vienna, 1975. This known network is shown in simplified form in FIG. 1A. This figure is briefly described for better understanding.

The line units 10 and 12 are connected to a switching matrix 14 via horizontal multiple lines 16 and 18 (inputs or incoming lines) with a vertical line 20 (output, outgoing line). Each line unit 10 and 122 can contain a small switching network to which a plurality of input / output lines 15 are connected. The reflection is achieved by the fact that the z. B. incoming traffic via line 16 in the switching matrix 14 via the vertical line 20 to line 18.

One possibility for expanding such a network is known from the magazine “Der Fernmelde-Ingenieur”, year 27, volume 1 (January 15, 1973) in picture 2 on page 15. This

The network is shown in a simplified form in FIG. To expand, the outputs of the two couplers are linked together in the last stage. A plurality of line units 22, 24, 26 and 30 are connected to switching multiples 40 and 42 via corresponding input lines 32, 34, 36 and 38. In the switching matrix 40, the line units 22 and 24 are connected to one another and in the switching matrix 40 the line units 26 and 30 are connected to one another by reflection. The multiples 40 and 42 connect the line units 22 and 24 to the line units 26 and 30 with the aid of the io connecting line 44.

The number (l) on lines 32 and 34 indicates the path of a connection with reflection in the switching matrix. The coupling points 46 and 48 are closed. Corresponding to the manner, the number (2) on the lines 34, 38, 44 indicates the route for a connection via both switching multiples 40, 42. With this connection, the coupling points 48 and 50 are closed and the coupling points 46 and 52 are open.

From Figure 3 on page 17 of the latter magazine, 20 it is also known to be able to mirror the traffic at every level. The traffic penetrates into the switching network only as far as is necessary for the connection.

A disadvantage of the known designs is that extensions to the number of inputs are not readily possible. The maximum size of the coupling network is limited. Extensions always require extensive switchover work on the existing cabling.

The aim of the invention is to create a switching network in which the same switching multiples can be used and which can be expanded without restriction.

According to the invention, this object is achieved by the measures specified in claim 1.

The switching network can be a four-wire switching network, where J5 each incoming and outgoing line has an input and an output and each input and each output is a time-division multiplex line.

The switching matrices can be space switching matrices, time switching matrices or combined space / time switching matrices 40.

The inventive design ensures that extensions are possible without having to change the existing wiring.

The invention is explained in more detail with reference to the exemplary embodiments shown in the accompanying drawings. Show it:

1A shows a simple switching matrix according to the prior art with a reversal point,

1B coupling multiples using reverse 50 point and vertical connections according to the prior art,

2A, B, C and D simplify network configurations to illustrate the expandability according to the invention,

3 shows a space switching matrix on the input side of a time slot switch using the reversal point technique,

4 shows a diagram to illustrate the blocking as a function of the number of coupling stages,

5A and B the expansion of a switching matrix by using reflection-going lines, FIG. 5A representing a single switching matrix and FIG. 5B an expanded switching matrix,

6A to E a multi-stage switching matrix in different expansion steps,

65 Fig. 7A is a sketch of a complementary delay device for four-wire traffic,

7B shows the control logic for a single entry or exit point,

7C is an equivalent logical representation of the control logic according to FIG. 7B,

8 shows the control of a timer for a four-wire delay line using the switching logic according to FIG. 7B,

Fig. 9 is a block diagram of a crosspoint of the network and

Fig. 10 is a block diagram of a crosspoint used in a network matrix.

For the following description, the terms input, output, incoming line and outgoing line are defined as follows. An input is a connection to a switching matrix or a combination of switching signals that leads from the outside into the switching matrix, while an output is a connection that leads signals out of the switching matrix. An incoming line is a connection to a switching matrix, which contains both an input connection and an output connection, which form the signals of the two transmission directions for a duplex connection path and is connected to one side of the switching matrix. An outgoing line is a connection to a switching matrix with both input and output for the transmission of signals in both directions of a duplex connection path and is connected on the opposite side to the incoming line to the switching matrix.

2A to D show a folded network with a reversal point and connection technology according to the present invention, in which the outgoing line of a switching matrix of a certain level is never connected to the same or a lower level and in the numbering of the levels from the input level represents an ascending sequence up to the reversal point.

The representation of the network configuration is greatly simplified to show the expandability. Each switching matrix consists of a number of levels of switching multiples, over which a connection runs between two end points. In a non-folded network, the connection runs through each stage only once and the path from the origin to the destination is only one-way in each stage. In a convoluted network, the path of connection between an origin and a destination can go through any stage in any direction and go through at least one stage at least twice, once in each direction.

According to the invention, the outgoing lines of the switching stage with the highest atomic number are the reversal points. However, these outgoing lines are still available to be connected to a switching stage that gets an even higher atomic number. There is no need to change the circuit. The outgoing lines are therefore used as connections to another switching matrix or serve as reversal points. A reversal point can be defined as the point in a switched network where a signal switched by the network reverses the direction through the network. The connection to a higher level is blocked. The switching and connection options of the switching matrix can be used on alternating connections.

2A shows a 2x2 line switching matrix 108 with two incoming lines 100 and 102 and two reversal points 104 and 106. The reversal points 104 and 106 are also connection verticals, as will be described. If the incoming lines 100 and 102 are each a twenty-four channel time-division line, then the switching matrix 108 can be a switch for one hundred and fifty lines with corresponding concentration, as is generally known, on an incoming line and up to twenty-four long-distance lines on the other coming line operate, with full accessibility between the626209

sen, as will be explained later. Another possibility for wiring is that the incoming line 100 is connected to a circuit in which six lines are concentrated, and that the incoming line 102 is a bidirectional connecting line to another exchange in analog or non-multiplex configuration. If only one of the reversal points 104 or 106 is used, either a line to another line connection or a line to a trunk line connection can be established. This network can be expanded continuously, e.g. B. on twelve lines and two long-distance lines, as shown in Fig. 2B. The incoming lines 100 each contain six lines and the incoming lines 102 each contain two long-distance lines. Additional extensions multiples 110, 112 and 113 are used for the extensions, which are identical to the switching matrix 108 and which result in an expansion to two levels. To explain the description, the switching matrixes that are required to expand to a second input switching matrix are marked with the number 2. If connections between channels within the switching matrix 108 are required, the outgoing lines 104 and 106 of the switching matrix 108 are used as reversal points. The reverse properties of the switching matrix 108 are used while calls between the new connections are switched in a corresponding manner. However, if a connection is to be established between a terminal which is connected to the switching matrix 108 and a terminal which is connected to the switching matrix 110, then the outgoing lines of the switching matrix become multiples 108 and 110, both of which form the first switching stage, switched through to a common switching matrix in the second stage, either to switching matrix 112 or to switching matrix 113. The reversal points 114, 116, 118 and 120 of the second stage are then used for switching the connection. For connections between the switching matrixes 108 and 110 of the first stage, the outgoing lines are interconnected in a switching matrix of the next stage, of which an outgoing line serves as a reversal point.

2C and 2D show the continuous expansion of the switching matrix to three or eight switching multiples in the first stage. This extension technology, in which neither internal nor external connecting lines have to be switched over, can be used for space multiples and time exchanges for switching multiples of any desired size. 2 shows the implementation for a multiple of rooms. With the three switching matrixes in the first stage, as shown in FIG. 2C, a further six lines 100 and a further two trunk lines 102 can be connected via the third switching matrix 126. Two thirds of the incoming traffic from the switching matrix 126 are statistically intended for the first two switching matrixes 128 and 130, since two thirds of the incoming lines and trunk lines of the switching network are connected to the switching matrixes 128 and 130. Since each incoming line generates a traffic unit, two thirds of the two switching multiples 128 and 130 are four thirds of a traffic unit which exceeds the traffic capacity of an outgoing line. For the third switching matrix 126 of the first stage, two switching matrixes 132 and 134 are therefore provided in the second stage. The outgoing lines that only serve as a reversal point are designated by UP. It can be seen from FIG. 2D that the addition of a fourth switching matrix does not result in the switching of existing connecting lines. The second stage switches 136 and 138 and the third stage switches 140 and 142 have the same configuration as the first stage switches. The expansion of the network to eight coupling multiples in the

3rd

5

10th

15

20th

25th

30th

35

40

45

50

55

60

65

626 209

4th

first stage is shown in Fig. 2D. Here, too, there is no need to switch over existing connecting lines. At each of the coupling multiples of the first stage z. B. in turn, six lines 100 and a double-directional trunk line 102 may be connected, as is indicated only for the first switching matrix. The eight switching multiples 150 to 164 of the first stage of the switching network can be identical in structure to the switching multiples of FIGS. 2A to C. In contrast to a single-stage folded network, a network according to the invention can be expanded more economically, since the costs of a single-stage folded network, expressed in crosspoints per line, increase linearly with the number of connections, i. H. with the number of incoming lines, while in the switching network according to the invention the number of coupling points per line increases approximately with the logarithm to the base 2 of the number of connections. This relationship is shown in the table below for the network with eight switching multiples of the first stage according to FIG. 2D.

Number of KV Number of total number of K.V N (N = 1st level (2n) additional of KV per KV of level KV 1st level number -1)

11 110

2nd

3rd

4th

2 1

3rd

5

9

3rd

4th

3rd

12

3 2

5

7

19th

3.8

6

5

24th

4th

7

5

29

4.1

8th

3rd

32

4 3

16

80

5 4

32

192

6 5

KV = switching matrix

The switching matrixes added to the network in levels 2, 3 and 4 are identified by numbers which correspond to the number of the switching matrix added in the first level and whose expansion has given rise to the expansion in the higher levels. By adding the coupling multiple 158, the fifth coupling multiple in the first stage, the additional coupling multiples 166 and 168 result in the third stage the coupling multiples 170 and 172 and in the fourth stage the coupling multiples 174 and 176.

A possible embodiment for a switching matrix, of which a large number forms the entire switching network, will now be explained with reference to FIG. 3. Each switching matrix must be able to work as a space switching matrix and be able to connect m incoming lines kL to n outgoing lines gL. Furthermore, each switching matrix must contain at least one time slot switch TSI230, 232 for each incoming or outgoing line. The number of timeslots TSI corresponds to the smaller number of m or n. If the number of timeslots TSI is equal to the larger number of m or n, or larger than the smaller of these numbers, the network is still working, but with reduced effectiveness . Furthermore, each switching matrix must contain release gates for signal reversal, which is critical in a four-wire network. The connection / reversal point gates are shown in Fig. 3 only in a simplified form. However, each of these gates corresponds to the logical implementations, which will be described further with reference to FIG. 7A. A space scope del stage that can switch m x n is also required. If n is greater than m, a concentration device can be installed, and if m is less than n, an expansion device. If a symmetrical (n x n) switching matrix is required, only n of the m incoming lines are required for the concentration. Failure to use the rest of the incoming lines will result in a small number of inexpensive gates that will not be used. An m x 2 n switching matrix can be obtained by connecting the coming lines of the additional switches to the coming lines 234 and 236. The values of m and n can vary widely, where m is a number of incoming lines and n is a number of outgoing lines.

4, the blocking B is plotted against the number of coupling stages N as a function of different traffic densities. The term blocking used here is defined as the impossibility of connecting free lines that are connected to a network for various reasons. The term non-blocking network defines a network in which there is at least one free path between any pair of free lines connected to it at all times, regardless of the number of paths already occupied.

Two important considerations for the operation of such a network are the ability of the network to respond to different traffic offers and the effect of an increased number of switching stages as the number of switching stages increases according to the present invention, each stage containing a plurality of switching multiples of which each have an identical parallel function to another switching matrix of the same level, the blocking does not increase continuously, but approaches an asymptotic value between zero and one, depending on the size of the switching matrix and the traffic density. The traffic density is defined as the amount of traffic on one or more traffic routes per time unit and is usually measured in Erlang. An Erlang is the traffic density on a route that is constantly busy or in one or more routes with an added traffic of one call hour per hour one minute per minute etc. The network blocking characteristic B for a certain number of switching stages N for low , medium and high traffic values is such that there is such a relationship between B and N that as soon as a maximum blocking level is reached, the network blocking does not continue to increase, that is to say the blocking curve becomes asymtotic. This is shown in FIG. 4 for four different traffic densities, curve 1 representing a low traffic density, curve 2 representing a low to medium traffic density, curve 3 representing a medium to high traffic density and FIG. 4 representing a very high traffic density. Since the paddock multiple size is increased in each stage, the blocking probability becomes lower for a given traffic density E.

The network expansion by means of the reflection / connection outputs is shown in FIGS. 5A and 5B. The voice connections in switching matrix 300 are achieved through time division matrix 302 and channel converters (CI) 304, 306 and 308. Each incoming line (e.g. 310,312,314) and each outgoing line (e.g. 322,324,326) has inputs and outputs that are Represent inputs and outputs of the four-wire connection. Instead of the expression channel converter, the term timing converter can also be used. Each of the coming lines has thirty-two channels. Data on the incoming lines 310, 312 and 314 at their inputs 311, 313 and 315, which are designated as incoming lines 0, 2 and 7 of eight incoming lines, can be routed via the switching matrix 302 and the lines 316, 318 and 320 to the inputs of the channel converters 304, 306 and 308 be switched through. Dates on

5

10th

15

20th

25th

30th

35

40

45

50

55

60

65

any of the coming lines can thus be selectively applied to any input of a channel converter for any channel time. The channel converters generate predetermined different delays, so that data is passed on from a time channel at the input to a different time channel at the output, and this ensures that two channels do not have the same time position at the output. So z. B. Data of the channel through the input 313 of the incoming line 312 through the coupling point 354 to the input 244 of the incoming line 318 of the channel converter 306. This data is then converted to channel 21 at output 328.

The output 328 of the outgoing lines 324 of the channel converter 306 can e.g. B. can be controlled so that it is connected to the input 330 of the outgoing line 324 of the channel converter 306, and thus forms the reversal point UP. In the channel converter, the data arriving via channel 21 of input 330 are then, for. B. converted into data of the time channel 9 at the output 334 of the incoming line 318. This data is then forwarded via coupling point 340 to the output 338 of the incoming line 314. This is the data path for one direction of the four-wire connection. The data path for the opposite direction is described below. The data at the input 315 of the coming line 314 at the channel time 9 are switched through via the coupling point 342 to the input 244 of the coming line 318 of the channel converter 306. The channel converter then converts this data from channel 9 to channel 15 at the output 334 of the coming line 318 and switches it at channel time 15 via the crosspoint 350 to the output 352 of the coming line 312.

The control is such that independent access from each of the incoming lines 310,312,314 etc. to the incoming lines of the channel converters is possible.

A connection path in a switching network with a plurality of switching multiples in two switching stages will now be explained with reference to FIG. 5B. Traffic from channel 15 of the coming line 2 of the switching matrix KV 10 is passed on in channel 21 of the outgoing line 6 of this switching matrix. This outgoing line is connected to the incoming line 0 of the switching matrix KV 26. The input channel 21 of the coming line 0 of the KV 26 is connected to the output channel 30 of the outgoing line 7 of the KV 26. This channel 30 then becomes the reversal point UP for the connection. The Verbin5 626209

dung is completed via the input channel 30 of the outgoing line 7 of the KV 26, which is switched through to the output channel 17 of the incoming line 7. This incoming line 7 is connected to the outgoing line 6 of the switching matrix 5 KV 17, which connects the input channel 17 on the outgoing line with the output signal 9 of the incoming line 7 of this KV 17. In this way, a connection from the input channel 15 of the incoming line 2 of the switching matrix KV 10 to the output channel 9 of the incoming line 7 of the switching matrix KV 17 is switched through by reversal in the channel 30 in the outgoing line 7 of the switching matrix KV 26. The complement of this sequence applies to the opposite direction of this four-wire connection. The route described with reference to FIG. 5A through the switching matrix 300 (KV 10) before the expansion of the network is also possible for this switching matrix after the expansion shown in FIG. 5B. Depending on the route required, either a reversal or a forwarding takes place on the outgoing line 6 of the switching matrix 300 (KV 10). The switching matrix according to FIG. 5A can therefore be expanded in a modular manner in a multi-stage design, and any required input connection can be established by the reversal technique, while at the same time the reversal points are available for further expansion by connection with a higher atomic number. The other switching matrixes KV 16, 20, 27 have the same configuration as the switching matrixes described above.

FIGS. 6A to E show quantitative examples of networks in which each switching matrix consists of a 30 2 × 2 switching matrix. In practice, of course, larger switching fields in the sizes of 8x8, 16x 16.32x32 etc. are used, depending on the packing density, the cabling and other economic considerations. For 192 lines on a 32-channel system with a 35 traffic density of 0.1 Erlang / line, there is a traffic density of 0.6 Erlang for each of the thirty-two channels. Assuming that fifty percent of the traffic remains in the exchange, long-distance traffic is 19.2 Erlang divided by 2 or 9.6 Erlang per 192 line systems. 40 If long-distance traffic is directed across a group in each direction, then each long-distance group needs the option of transmitting 4.8 Erlang per 192 lines. The following table relates to FIGS. 6A to 6E of the combined time and space multiple network.

15

20th

Fig. Number of long-distance line traffic Number of the total number

Lines Erlangen a Rieh-Fernlei- number of the lines Fernlei- Koppel-

(l% blockages - probable probability)

6A

192

19.2

9.6

4.8

11

22

1

6B

384

38.4

19.2

9.6

18th

36

4th

6C

576

57.6

28.8

14.4

25th

50

7

6D

768

76.8

38.4

19.2

31

62

9

6E

960

96.0

48.0

24.0

37

74

12th

A switching matrix can be implemented on a single LSI chip, for example, which combines both space and time switching. These multiples can then be connected and connected in series so that a continuously expandable network of e.g. B. 2000 to 100,000 lines.

The channel converter part of this switching matrix can be designed as a delay line, which is implemented either as a charge-coupled device (CCD) or as a MOS dynamic shift register and generates the complementary delay which is necessary to implement a four-wire connection. Such a delay device

626209

is shown in Fig. 7 A, which has two signal inputs S1 and S2 to lines 700 and 702. Different delays are assigned to the inputs S1 and S2. For example, S2 is represented by 706 and 708 with times between five and one hundred and twenty-five microseconds, while the delay for S1 is represented by 709. The total delay 706 plus 708 plus 709 is 125 microseconds.

The logic to implement this delay is shown in Fig. 7B. Each signal input / output point is able to insert a signal, extract a signal or switch a signal through the switch. A timing control signal C on line 710 is applied to AND circuits 712 and 714 and via an inverter 718 to AND circuit 716. A digital voice signal S1 is combined with the control signal in the AND circuit 712. The digital voice signal S2 is the output signal of the AND circuit 714. The digital voice signal output by the shift register 720 (SR) is applied to the UN D circuits 714 and 716 and is in the AND circuit 714 with the control signal directly and in the AND Circuit 716 combined with the inverted control signal. The outputs of the AND circuit 716 and the AND circuit 712 are combined in the OR circuit 722. Either signal S1 or signal S2 is thus forwarded to shift register 724. To simplify the illustration, the logic is shown as block 726 in FIG. 7C. This representation is used in the following for the logic. If the control logic described is for an incoming line, the control signal on line 710 is a selected stored control signal. If the control logic is for an outgoing line, the control signal is a reverse control.

8 shows a timer and the associated control for a multi-channel four-wire system. The input signal S1 is applied to the input 802 of the coming line 800 and the output signal S2, which comes from the opposite direction of the four-wire connection, is taken from the output 804 of the coming line 800. The outgoing line 806 has an input 816 and an output 818. The signal delay time for the signal S1 between the input 802 of the incoming line 800 and the output 818 of the outgoing line 806 can be set selectively by selecting the desired signal input point 802, 808, 810, 812, etc. or other non-illustrated input points the delay line, controlled by the control memory 814, which contains the addresses of the signal input points in a predetermined and variable order. By taking over the address of the desired signal input point from the control memory 814, the signal S1 is fed in at the desired point of the delay line and the signal S2 is extracted. The control memory 814 is controlled by a timing circuit 820, which receives synchronization signals Sy from the timing control. There is then a synchronicity with the delay line and the address selected for each input point of a signal S1 is transferred at the correct time from the control memory 814 via the line 822 to a series-parallel shift register 824. The outputs of register 824 are used to select and operate one of logic circuits 826 through 834. Such a gate circuit is provided for each of the thirty-two channels, but only the gate circuits for channels 1, 2, 3, 30 and 31 are shown to simplify the illustration. The parallel output signals of register 824 are applied to circuits 826 to 834 via line 836 to 844. Line 846 serves as a delay return from the reversal gate 848. A synchronization signal Sy applied to the timing circuit 820 ensures that the sampling speed for the speech and the control speed of the memory 824 coincide in time. The two speeds do not have to be bit-synchronous, since the two codes can be different, that is to say the voice samples can contain eight bits, while the control code contains only five bits 5. Each switch 850,852,854,856 and 858 for feeding, pulling out and switching through between the input and output delay devices 860 and 870 allows the selection of the desired point for the signals S1 and S2 by the desired amount of delay between incoming and outgoing line for S1 and the complementary delay to get back for the signal S1. The switch 848 enables the reversal on the outgoing line of the switching matrix, if the desired route between the calling and called subscriber demands that the route be successful at this point in the network.

If a particular connection is to be reversed, this is done by activating control line 872 of reversing gate circuit 848 at the desired time. It is e.g. B. a value of the signal S1 is applied to the input 802 of the upcoming 20 line 800 and, after reversing from the output 804 of the coming line 800, a predetermined time later, e.g. B. two channel times later than signal S1 + at the same channel time at which the complementary signal S2 + (this is a value of the signal in the other direction of the call) is applied to the input 802 of the coming line 800, the then thirty channel times later, corresponding to thirty-two minus two channel times, at the same channel time from output 804 of the incoming line, if the next value from S1 to 30 is applied to input 802. In order to achieve this, the logic gate 858 is activated by the selection gate circuit 826 in order to feed the signal S1 into the delay line. A channel time later, line 872 actuates reversing gate 848 to pass signal S1 on line 846. After another channel time, logic 850 is actuated via selector gate 834 to extract signal S1 and use it as a signal S1 + to be applied to the output 804, while at the same time the signal S2 is fed 40 from the input 802 into the shift register delay line 862. After a further thirty channel times, the logic gate 858 is switched on again by the selection gate circuit 826 in order to pull out the signal S2 + and to indicate it as signal S2 via the output line 804. At the same time, the next value of S1 is fed from the input line 802 into the delay 45 shift register 870. The switch described thus transmits and reflects signals S1 and S2 in accordance with the requirements of the desired path, as defined by the control memory 814. The necessary control information for the data memory is entered via the data input 5o.

Digitally encoded speech and control messages for selection of the switching paths and channel conversion delays are encoded in 55 sixteen serially transmitted bits for each channel. 8000 frames are transmitted per second, each frame containing thirty-two channels and each channel sixteen bits. It is envisaged that, for. B. Channel 0 always occupies the same time slot for both the input and the output connections. 60 Through channel conversion, the sixteen bits that make up each channel can be converted to another channel in a controlled manner by introducing a delay into the bit stream. In a thirty-two channel system, such a delay has a minimum value of one channel time 65 and a maximum value of thirty-one channel times. The reflection is obtained by controlled interconnection of the input and output of the outgoing line at the desired channel time.

7

FIG. 9 shows a time division crosspoint xy as used for the time division described above. This crosspoint 900 serves to connect the coming line x, which contains the input line 902 and the output line 904, to the outgoing line y, which contains the 5 input line 906 and the output line 908. The outgoing line leads to the associated channel converter. At one input of switch 910 there is a switch selection signal 911 from the control memory and at the other input via line 906 the signals from the associated io

Channel converter. The output is connected to the output line 904 of the upcoming line x. At one input of the switch 912 there is a switch selection signal 913 from the control memory and at the other input the signal from the input line 902 of the coming line x. The output signal of this switch leads via line 908 to the channel converter. Output and input switches corresponding to switches 910 and 912 of up to seven other incoming lines can be connected to lines 906 and 908 at multiples 924 and 926. The input and output lines 202 and 904 of the coming line x are also connected via AND circuits 918 and 920 to a test circuit 914 and a detection circuit 916. A control signal 919 or 921 is applied to these AND circuits via the second input in order to switch through the gate circuits at the desired times.

The test circuit 914 is provided to test whether messages pending at the input 902 are intended for the control circuits which are assigned to the outgoing line y. In addition, test circuit 914 checks the coding of the messages to ensure that these messages contain no errors and detects free channels in input 902 of the incoming line and sends signals via output 904 of the incoming line in order to Display the free state of the outgoing line y. The test circuit can receive commands from the 35 control circuits assigned to the outgoing line y, e.g. B. via line 925 the command to send a busy signal. After receiving this command, the test circuit sends a busy / error message via line 927. When test circuit 914 detects a selection request message on the input line that is intended for outgoing line y, it sends a priority selection signal 923 to a crosspoint priority control circuit that decides between simultaneous requests on more than one incoming line for outgoing line y. The detection circuit 916 determines whether there are free channels and gives a corresponding signal via line 922 to a circuit which selects free channels.

A matrix of the crosspoints xy explained with reference to FIG. 9 is shown in FIG. 10 with only one outgoing line 960 and its control from the possible eight outgoing ones

626209

Lines of a matrix with eight incoming lines and eight outgoing lines. This outgoing line is connected to two incoming lines 962 and 964 from the possible eight incoming lines 0 to 7. The crosspoint xy designated 900 corresponds to the crosspoint that was described with reference to FIG. 9. As was also already described with reference to FIG. 9, eight such crosspoints can be connected to the channel converter 928 via the lines 906 and 908. The channel converter 928 has been explained in detail with reference to FIG. 8. The test circuits 930 and 932 operate in the same way as the test circuit 914 which was explained with reference to FIG. 9, and the detection circuits 934 and 936 operate in the same manner as the detection circuit 916, which was also explained with reference to FIG. 9. The outputs 923, 938 and 940 of the test circuits 914, 930 and 932 respectively indicate the receipt of messages which require a connection to the channel converter 928. These outputs are individually and separately connected to crosspoint priority control circuit 942 in speech path controller 941. Upon receipt of simultaneous requests from two or more lines, the control circuit selects one of the requesting incoming lines and causes the transmission of busy signals to the other unselected requesting incoming lines by signals on lines 925, 944 or 948 to the corresponding test circuits 914, 930 and 932, respectively. of which busy signals are then applied to the corresponding output lines of the incoming lines de coupling points, as has already been described with reference to FIG. 9. The crosspoint selection circuit 950 receives and stores the crosspoint selected by the crosspoint selection circuit 942 for each of the thirty-two channel periods and opens and closes the selected crosspoint for in a control delay line contained therein, which is designed in the same way as the control memory 814, which was explained with reference to FIG each channel period by applying control signals to the corresponding control lines 952, 954, etc. Signals at the input 956 of the outgoing line 960 may include route selection control signals which are emitted from a higher level switching matrix after reflection. These signals are recognized by the test circuit 932 previously described. The outgoing line 960 forms one of the incoming lines of a switching matrix of such a higher level. With the coming lines 962 and 964, for example, seven matrices can be connected, which are identical to the matrix described with reference to FIG. 10. This connection occurs at the multiple points 966 and 968. Six additional incoming lines, the switching and connection of which are identical to the coming lines 962 and 964, can also be connected.

10 sheets of drawings

Claims (5)

626209 PATENT CLAIMS 1.Mirrored switching network with several switching stages, which consist of switching matrixes, each switching matrix having at least two incoming lines and at least two outgoing cables and is suitable for reflecting the traffic arriving at any input of the switching matrix to any other input of this switching matrix, for Telecommunications, in particular telephone switching systems, characterized in that the outputs (114, 116, 118, 120, Fig. 2B) of each switching matrix (112, 113, Fig. 2B; 140, 142, Fig. 2C) of the highest existing coupling stage (stage 2, Fig. 2B; stage 3, Fig. 2C) serve exclusively as reversal points (up) for the traffic between the inputs of the switching matrix (112, 113; 140, 142), without using other switching matrixes to be connected that these outputs are provided in order to be connected to the inputs of multiples of a further switching stage when the switching network is expanded, that the outputs of the switching multiples (132, 134, 136, 138) of the other switching stages (stage 2, Fig. 2C) as reversal points (up ) serve for traffic between the inputs of the same switching matrix (132, 134, 136, 138), and that these outputs of the switching matrixes of the other switching elements are either connected to inputs of switching elements (140, 142) of the next higher switching element (level 3, Fig. 2C) or no connection at all to other coupling multiples. 2. Switching network according to claim 1, characterized in that the switching network is a four-wire switching network and each incoming line (314) and each outgoing line (324) has an input (315,330) and an output (328,338), and that each input and each output is a time division multiplex line. 3. Switching network according to claim 1, characterized in that each switching matrix is a space switching matrix. 4. Switching network according to claim 1, characterized in that each switching matrix is a time switching matrix. 5. Switching network according to claim 1, characterized in that each switching matrix is a combined space-time switching matrix.