CS245781B2 - Connection of switching devices in group leadings namely in telephone control systems - Google Patents

Abstract

The invention relates to a circuit arrangement for switching systems controlled on party line systems, in particular for telephone dispatcher systems, which contains a programmed control unit and also an address and data bus system between the control unit and the different functional and peripheral units. A line set is provided to ensure the signal flow between the line and the peripheral units, and furthermore a sensing unit indicating the condition of the peripheral units, a programmable selector unit, an audio-frequency signal receiver, a programmable signal transmitting unit and a tone caller and ringing unit are provided. The activation and deactivation of the secondary stations associated with the party line are performed in the control unit connected downstream of the party line. The control unit processes the information received from the functional and peripheral units according to the used, stored and/or hard-wired program, and performs the control functions relating to the operational requirements imposed on the system. In this way, the functional and peripheral units can be simplified, and there is no need for the direct link between the units, which in any case prevents the possible system variations and would require complicated wiring.

Description

The invention relates to the connection of switching devices in group lines, in particular telephone dispatching systems, with a programmed control unit, an address and data bus system between the control unit and between various functional and peripheral units, with couplers providing signal flow between lines and peripheral units, with a sensor unit indicating the status of the peripheral units, with a programmable selector unit, a tone-frequency signal receiving unit, a programmable signaling transmitting unit, and a tone and calling unit.

In group-wide dispatching systems that are arranged sequentially and sequentially and where the individual switching and control devices are organized decentralized, the controlled switching devices must be designed to process the signals coming from the line or from the subscriber station in advance program and sent control signals depending on the state of the subscriber stations.

Extremely group management systems must be designed to be usable both in centralized and in a. in a decentralized transmission organization, that is, in a centralized transmission, it must ensure the transmission of a selective call of the central dispatcher to the subscriber station, whereas the subscriber stations can only call the central dispatcher. In a decentralized organization of operations, on the other hand, subscriber stations in series within a group management system can call each other directly.

An important requirement for these systems is that the line should have a fast signaling system, but at the same time there must be appropriate call and noise protection. In addition, the signaling system for the subscriber stations connected to the group lines should allow connection to another system, for example a direct dial connection to a remote telephone system without the need for an operator connection.

Both in the centralized and decentralized transmission organization, · the status of linkv must be sent to the subscriber station after each call, but at the same time there must be the possibility of forced connection for the subscriber stations and even the forced disconnection from the network in the decentralized network.

In addition to the above, it is absolutely essential that after the unsuccessful call of the subscriber stations the call is stopped, or if there are other failures, the line is stopped.

Another requirement for these systems is the possibility of a conference call. In the case of a collective conference call, it is necessary to ensure that the subscriber stations located in the same location can be connected to any of them. conference group.

Dispatcher device connections are known, such as those described in Hungarian Patent No. 177,698, wherein each individual line circuit of the line apparatus comprises a separate logical unit and the logical units perform individual control and storage functions, such as connection, memory recording, call recording, and automatically and independently of each other.

The disadvantage of this involvement is that it does not take full advantage of the advantageous opportunities offered by program management. The wiring does not contain a system of address or data buses, so the control unit cannot keep track of the status of line devices. As a result, line devices are very bulky and expensive, and measurement and maintenance are difficult.

Further, solutions are known according to Hungarian patent No. 170 868, wherein the central control unit uses individual current circuits to record information. As a result, the design is complex and bulky, cabling is complicated, and equipment can only be operated with a centralized organization of operations.

The purpose of the present invention is to provide a circuit which makes it possible to eliminate the above disadvantages and to satisfy all the stated conditions. It is an object of the invention to provide wiring so as to allow both centralized and decentralized mode of operation in group-line devices to have a rapid signaling system conforming to CCITT recommendations, allowing subscriber stations to be connected to another network, for example a telephone a general purpose direct-dial network, without a special operator connection, to be resistant to · transmission line disturbances and malfunctioning in occupancy protection, and · to assure network occupation when establishing connections.

It is a further object of the invention to allow for the forced connection of subscriber stations and a predetermined forced disconnection of these stations. In addition, the requirement is that the subscriber stations are, according to the program, capable of being involved in any of the conference groups.

The invention is based on the realization that the stated objective can be achieved if the connection and disconnection of the subscriber stations belonging to the group line are carried out by the control units which are connected to the group line.

The control units have the task of processing, in accordance with a predetermined program, information coming from functional or peripheral units, for example, line subscriber line circuits, line connection circuits, signal reception circuits, etc., and to conduct control signals appropriately and optionally transmit these signals. into functional and peripheral units.

The controllers process the used, recorded and / or cabling-determined program according to the information received from the functional and peripheral units and perform control functions that correspond to the system operation requirements. In this way, the functional and peripheral units can be simplified, and there is no direct connection between the units, which among other things reduces the variability of the system and requires complex connections.

Connection of switching devices in group lines, especially in telephone dispatching systems, with programmed control unit, with address and data bus system between the control unit and between various functional and peripheral units, with a set of lines providing signal flow between lines and peripheral units, with sensing unit indicating the state of peripheral units, with a programmable selector unit, a tone-frequency signal receiving unit, a programmable signaling transmitter and a tone-calling unit, according to the invention, characterized in that the control unit and the signaling transmitting unit comprise sensing circuits whose inputs are connected via sensing line to sensing outputs of line current circuits, control unit has 2xn address inputs, r- | -k- | -s control outputs and setting inputs, where n address inputs are connected via address control to the selector, while the other m address inputs are connected to the selector via the address line and the other n address inputs are connected via the next address line to the signaling transmitter, the setting inputs are connected via the command line to the selector, г control outputs are connected via control line to signaling unit, with control outputs connected via control line to tone and transmitter unit, to control outputs connected to other control lines to line circuits, other common inputs of control unit and selector units connected via pulse pulse line with clock pulse output of the signaling unit, the control output of the signaling unit that triggers the dial tone is connected via the control line to the input of the tone and calling unit, the tone frequency output is connected via the signal line line k (m + l) -the asymmetric input of the line set, the line set is connected to m asymmetric inputs and outputs, where m is the number of connected subscriber stations aa = 1, via voice lines; input amplifier and distortion compensation, coupled to lines, while the asymmetric input of the line set is connected via the signal line to the tone and call unit, (m + 1) - the asymmetric output is connected via another signal to the signal receiver input coded, for example the data and control outputs of the signal receiver are connected via the data line and the control line to the inputs of the selector unit, the other outputs of the tone and call unit are connected via the signal line to the common input of the line current circuit; devices and telephone exchanges.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be explained in more detail with reference to the accompanying drawings, in which: FIG. 1 shows a circuit diagram according to the invention; FIG. 1 and 4 shows the circuit of the wiring of FIG. 1.

The circuit according to the invention is used in controlled switching devices connected to a group line, in particular in telephone dispatching systems.

According to FIG. 1, the circuitry comprises a programmed control unit 1, a programmable selector 11, a tone-frequency signal receiver 12, a programmable transmit signaling unit 13, a tone and call unit 14, a line set 22 that provides a signal current between lines and peripheral units. 21a to 21m and the subscriber stations 23a to 23m connected thereto, for example, subscriber station apparatuses, telephone exchanges, where m represents the number of subscriber stations and a = 1.

The sensing inputs of the control unit 1 and the signal transmitting units 13 are connected via the sensing lines 31, 31a to 31m to the sensing outputs of the current circuits 21a to 21m. The coupling outputs of the line current circuits 21a to 21m are connected by lines 47a to 47m to the subscriber stations 23a to 23m.

The control unit 1 has 2xn address inputs, of which n address inputs are connected via address lines 36 to the selector 11, the other n inputs via another address line 37 to the signaling transmitter 13. The setting inputs of the control unit 1 are connected via the setting line 35 s selector unit.

Furthermore, the control unit has 1 + + k + s control outputs, wherein the 2 control outputs are connected via the control line 33 to the signaling unit 13, the control outputs are connected via the control line 32 to the tone call unit 14 and the control outputs are connected via control lines 34, 34a to 34m with line current circuits 21a to 21m. The common inputs of the control unit 1 and the selector 11 are connected via the pulse pulse line 38 to the pulse pulse output of the signaling transmission unit 13.

The control output of the signaling transceiver 13 that triggers the dial tone is connected via the control line 39 to the input of the tone and calling unit 14, while the tone frequency output is connected through the signal line 40 _{] П + 1} к (m + l) -the asymmetric input cable sets 22.

The line set 22 is connected to the I / O lines 21a to 21m via sm inputs and outputs via voice lines 41a to 41m and 40a to 40m. The symmetrical input and output is coupled to and through the amplifier and equalizer circuit (not shown) and lines 42, 43. (m + 2) - the asymmetric input of line set 22 is connected via signal line 40 _{m + 2} to tone and call unit 14, (m + 1) -the asymmetric output is connected via another signal line 41 _{m + 1} to the signal receiver input

12.

The coded, preferably four-bit data and signal outputs of the signal receiver 12 are connected via the data line 44 and the control line 45 to the inputs of the selector 11. The other outputs of the tone and selector 14 are connected via the signal line 46 to the common input of the current circuits 21a to 21m.

In the wiring according to the invention, an operating set is connected downstream of the voice lines 40a to 40m and 41s to 41m, downstream of the signal lines 46, downstream of the control lines 34, 34a to 34m and downstream of the sensing lines 31, 31a to 31m.

The circuit according to the invention comprises, as shown in FIG. 2, a coding counter 53 programmed in the signaling unit 13, a memory 54 and a phase register 56. It further comprises a damping circuit 52, a signaling transmitter 55 and is preferably provided with sensing circuits 51 , 62.

The sensor circuit inputs 51, 62 are connected to the sensor lines 31. The output of the sensor circuit 51 is connected to the input of the damping circuit 52, while the address inputs are connected to the address lines 37 and to the address outputs of the shift circuit 60.

The parallel write inputs of the shift circuit 60 and the address inputs of the read circuit 62 are connected to the address outputs of the second shift circuit 61.

A further shift input write input 60 is coupled to common output points of the read circuit 62 to a shutdown output of the second shift circuit 61 and a phase register setting input 56. The shift input shutdown input 60 is coupled to a shutdown output of the timing circuit 58. circuit 58, shifting circuit 61, and damping circuit 52 are coupled to the clock pulse generator 63.

The state output of the damping circuit 52 is coupled to the shift input of the counter 53 and the pulse output is coupled to the start input of the timing circuit 58. The start input or timing output of the timing circuit 58 is connected to the start output or timing input of the memory circuit 59 the timing circuit 58 is coupled to the shift input of the phase register 56.

The control inputs of the phase register 56 are also connected to the control lines 39 and to one control input of the memory circuit 59, while the release output is coupled to the release input of memory 54, the control outputs are connected to the address inputs of memory 54 and to the code outputs of the counter 53 and connected to the counter input of counter 53.

The code outputs of the memory 54 are coupled to the common code inputs of the signal transmitter 55 and the code outputs of the memory circuit 59.

The signal frequencies outputs of the signal transmitter 55 are connected via the adaptation circuit 57 to the signal line 40 _{m +} i. The control outputs and inputs of the memory circuit 59 are also connected to the control line 33. Calls coming via lines 47a to 47m, i.e. subscriber station apparatus If the system is unoccupied, it controls the line circuit sensors 21a to 21m following the lines 47a to 47m, through the sensor lines 31a to 31m and 31 the sensing circuit, which is located in the signal transmission unit 13.

By applying a control signal, the signaling unit 13 transmits a busy indication code comprising simultaneously two frequencies simultaneously through the signal line 40 _{m + 1} and via the set of lines 22 to line 43, simultaneously detecting the address of the calling line circuit 21 and routing this address through address line 37 to control units

1.

As a result of the received address, the control unit 1, via the control signal sent to the control line 34 via the line current circuit 21, blocks the subscriber station 23, for the duration of the busy signal via the command line 35. a tone and calling unit 14 which, via signal line 46, causes a dial tone to be transmitted to the subscriber station 23.

During reception of the dialing tone, the subscriber station 23 communicates with the dialing, i.e., the DC loop interruption, the selection information which, in the manner described in connection with the call initiation, occurs via the sensing circuit 51 and the damping circuit 52 to the signaling unit 13 and the memory circuit 59 2.

The low frequency code records the information and occurs after some delay in the manner described in connection with the transmission of the busy signal to line 43.

WITH

After the second digit is dialed, the information is stored in memory and a signal is sent as described above. When the third digit is selected, the signaling transmission unit 13 sends a busy signal again to line 43, depending on the state of the phase register 56 (FIG. 2).

When the fourth and fifth digits are selected, the signal is transmitted in the same way as for the first and second digits. Given that two digits are required to call the slave stations 23a to 23m, dialing the fourth and fifth digits means calling the other subscriber station.

In the circuit according to the invention, the control unit 1 evaluates the received information only when the busy signal also appears before the reception of the information within a predetermined interval. In this way, in the solution according to the invention, on the one hand, special interference protection can be achieved and, on the other hand, the same signal combinations can be used to transmit signaling both during calls inside and outside the system.

The three-digit phase register 56 of the signaling transmitter 13 controls the number of certain selection information according to the signaling transmitter through the coding circuit.

The wiring signal system according to the invention also includes codes that cannot be transmitted directly by traditional dialers. These codes are used to break the conference call, call, force disconnect, etc. These special signals can be selected by dialing zero and the first digit.

In a particular embodiment of the invention, the signal transceiver 13 controls its signal register 56, according to some first digit dialing information over a separate coding circuit area, while at the same time recording the phase register into memory some second digit information [digits 9] and blocking transmission. other busy signals until disconnected.

In the circuit according to the invention, this solution enables direct dialing to another external network after selecting the subscriber station to be connected to the external network.

In a group line system, the signal reception path passes through devices that are connected to the line, identically through line 42, through a set of lines 22, and through call lines 41 _{ni + 1} to the signal receiver 12.

The signal receiver 12 transmits the coded data corresponding to the signal via the data line 44 to the selector 11 and at the same time controls the selector 11 over the control line 45.

The received bus signal controls the control unit 1 via the respective command line 35, which records the control signals for a predetermined interval and simultaneously transmits the bus control signals to the line circuits Z1a to Z1 through the control lines 34, 34a to 34m. If another signal does not appear within a certain period of time, the control unit 13 actuates, thereby sending a disconnect signal as described above.

As a result of the disconnect signal, the occupation of the system ceases, the subscriber station that was previously connected disconnects and enters the lock state.

If two signals arrive within a certain period of time, the selector 11 controls, according to a predetermined program, via the address line 36 and the respective command line 35, the control unit 1, which sends via the control lines 34, 34a to 34m to Zim the line calls the call signal, i.e. call, loop blocking, etc., and at the same time sends a call echo signal to line 43 via control line 32, call and tone unit 14, signal line 40 _{m + 2} and line set Z2.

When only one subscriber station 23a to 23m receives a call signal during a certain interval, the current circuit 21a to Zim actuates the line via the read line 31m or 31 to operate the signaling unit 13 and the control unit 1. As a result, the signaling unit 13 sends a reverse signal code. thereby connecting the subscriber station 23a to 23m via line circuit 21a to Zim, and via voice lines 40a to 40m and 41a to 41m and via line 22 to lines 42, 43.

The system switches to the busy state for an indefinite period of time by the action of the reverse signal code, which busy lasts for the duration of the connection.

The connection is canceled by the disconnect signal code.

In a specific exemplary embodiment, the signal code controls the feedback via signal line 40 _{m + 1} or via line 42, signal line 41 _{m + 1} , signal receiver 12, data line 44, selector 11 and respective command line 35, control unit 1, which casting time.

The termination of the connection established between the two subscriber stations 23a to 23m can be made from the two subscriber stations 23a to 23m in an identical manner by breaking the loop, i.e. by laying the telephone. When placing the handset in the subscriber stations, resp. at the subscriber station 23a to 23m, the loop current of lines 47a to 47m is interrupted, and then the current circuit Z1a to 21m transmits a signal to the control unit 1 via a common sensing line 31a to 31m or 31, respectively, unit

13. The signaling transmitting unit 13 then sends a signaling code to terminate the connection.

When a connection is established between a plurality of subscriber stations 23a to 23m, for example in a conference connection, a group conference, and the like, only the subscriber station that initiated the call initiates the connection.

In this case, the common sense line signal 31 in the control unit 1 is disabled, and the interrupt signal code is then transmitted based on the control signals to the individual sense lines 31, 31a to 31m, which are connected to the sensing output of the line current circuit 21a to 21m.

However, when the system is busy, the subscriber station 23a to 23m cannot make a call and receives a busy signal as described above.

When a certain digit, for example, zero, is selected, the busy current circuit 21a to 21m records the information coming from the lines 47a to 47m, controls the switching circuit and some common sensing line 31, and simultaneously actuates the signal transmitter 13 from the concealed input of the transmission control circuit.

Forced connected subscriber stations 23a to 23m, if authorized, dials additional certain digits, such as zeros, through certain individual sensing lines 31a to 31m of both signaling circuitry 51, 62 of the signaling unit 13. As a result of the control signal, the signaling unit 13 sends disconnectors and then a busy combination of signals to line 43.

The blocked state of the line circuits 21a to 21m is recorded in the control unit 1. When the control unit 1 is called, the tone and call unit 14 is actuated via the control line 42 and sends a differentiated signal tone through the line 40 _{in + 2} to the set of lines 22. in contrast, control signals are not transmitted to the line current circuits 21a to 21m.

The function of the signaling transceiver 13 will be explained in the following with reference to FIG. 2. The signaling transceiver 13 processes the signals coming along the sensing line 31 and the control signals available on the control lines 33, evaluating them and conducting coded 2-frequency signals or single-frequency signal tones to signal lines 40 _{tn +} ia and, via control lines 33, 39, send signals and via address line 37 select information to control unit 1 and to tone and call unit 14, and provide a comparative clock pulse that synchronizes the function of each wiring unit .

The signal arriving at one sensing line 31 is controlled by a sensing circuit 51 (multiplexer) whose sequential control is performed by the shift circuit 60. The sensing circuit 51 connects its input to the input of the damping circuit 52 by shifting. shifting the phase register 56 '(state 1) and, on the other hand, shutting off the shifting circuit 60 and, in addition, transmitting the control signal via the memory circuit 59 to the designated control line 33.

As a result of shifting, phase register 56 returns counter 53 back to the zero position and controls, for a certain period of time, timing circuit 58, memory 54 which controls signal transmitter 55 at the address determined by counter 53 with the code recorded in memory. The signal transmitter 55 sends a two-frequency signal code through the adaptation circuit 57 to the signal line 40 _{m +} 1.

The damping circuit 52 takes, at intervals determined by the pulse pulse, samples of the sensing signal coming into the input and actuates the timing circuit 58, which shifts the phase register 56 to the second state. The counter 53 unlocks and feeds the information received from the damping circuit 52 to the address input of the memory 54 and to the corresponding inputs of the phase register 56.

If there is no change at the output of the damping circuit 52 during the delay time of the timing circuit 58, except for the differentiated information corresponding to, for example, the dialing of the first digit 0 and recorded in the phase register 56, the phase register 56 allows reading from memory 54 The signal transmitter 55 transmits the output signal in the manner described.

When additional information appears on the sensing line 31, damping, delay, timing, and control occur as described, thereby moving the phase register 56 to the third ground state. In this way, the memory 54 controls the signal transmitter 55 by a code that is recorded at the address of the memory field selected by the contents of the phase register memory 56. At the same time, the memory 54 checks the information transmitted by the counter 53 and locks on receiving the differentiated information in the third or basic condition.

In this case, the additional information coming from the sensing circuit 51 does not shift the phase register 56, and as a result, the memory 54 controls the signal transmitter 55 in the manner described in relation to the third or basic state of the phase register 56.

When the information is not differentiated, the three-digit phase register 56 shifts to the first state again as a result of the following information, and the signal is transmitted as described in relation to the first state. In this way, the process of transmitting signals of any number may continue.

In individual states, the phase register 56 connects the control line 39 with various lines, for example for dial tone, clear, signal transmission, etc. The control signals coming through the control line 33 directly control the signal transmitter 55 via the memory circuit 59. These control signals that come < to the inputs with the same sequence number of the sensing circuits 51, 62, they arrive at a suitable position of the sliding circuit 61 at the output of the sensing circuit 62.

The control signals that appear at the output of the sensing circuit 62 both enter the phase register 56 and disconnect the shift circuit 61. In addition, the state of the shift circuit 61 is rewritten to the shift circuit 60 as a result of the received pulse. sensor circuit 62 a control signal that has come to its input.

The phase register 56 records the control signal as differentiated information, goes to its second state independently of the previous state, and controls, according to the information stored in memory, the signaling circuit 55, which sends a one-tone tone signal to the signal line 40 _{rn +} i.

If the following information is to be differentiated, i.e. when dialing zero, the phase register 56 controls the successive transmission of two signal codes and goes to its first state.

FIG. 3 shows an exemplary embodiment of the control unit 1. The control unit 1 consists of a trip control circuit 75, a call control circuit 73, a switching circuit 74 for switching current lines 36, 37, and a logic network 72 determining the function of each circuit. and from the sensing circuit 71.

The sensing circuit inputs 71 are connected to the sensing line 31, the output is connected to one control input of the logic network 72, while the address input of the sensing circuit 71 is connected to one address input of the switching circuit 74 and the call control circuit 73 is connected to the address line 37 The second address input of the switching circuit 74 is coupled to the second address line 36, while the control inputs of the switching circuit 74 are coupled to the output of the logic network 72. The inputs and outputs of the call control circuit 73 are coupled to the inputs and outputs of the switching circuit 74 they are connected to inputs of the control circuit 75 for tripping.

The outputs of the control circuit 75 are coupled to the control inputs of the call control circuit 73 and to the outputs of the logic network 72 that control the connected current circuits and are connected therewith to the control lines 34 that control the switching current circuits 21. to the command line 35, while the outputs of the logical network 72 that control the tone and call unit 14 are connected to the control line 32. The output of the logical network 72 that controls the call is connected to the control input of the call control circuit 73 and other control outputs; the inputs are connected to the control line 33 of the signaling transmission unit 13.

The control unit 1 checks the status of the group lines on the basis of the information coming on the command lines 35 and the signals coming from the sensing lines 31 and controls the signaling unit 13, the current circuits and other functional units according to this condition.

The operation of the control unit 1 will be explained on the basis of FIG. 3 in connection with both modes of operation.

At the connection that wakes up the call, the logical network 72, as a result of the received control signal, sends a signal from the control line 33 to the switching circuit 74, which controls the memory of the control circuit 75 of the connection control. The memory is selected according to the address on the address line 36, whereupon the memory via certain control lines 34, 34a to 34m actuates the corresponding current circuit.

When the called subscriber station is disconnected, the signal, i.e., the busy signal coming on the command line 35, is recorded in the logical network 72 and at the same time the status of the control line 33, i.e. checking the transmission status of the signaling transmitter 13, is checked. or * when the received control signal ends before the signal on the command line 35, the logical network 72 sends a predetermined length control signal to the common control line 34 and the logical network 72 (first digits).

If another signal (second digit) arrives at a predetermined interval, the timing of the logical network 72 is reactivated, wherein the logical network 72 evaluates the information content of the previous signal and the output signal from the sensing circuit 71 according to a predetermined recorded program. a signal to the call control circuit 73.

This control circuit 73 records the control signal at a location corresponding to the address or addresses passing through the address line 37, and transmits the control signal to the respective control line (s) 34.

When within a predetermined interval a signal comes from the sensing line 31 through the sensing circuit 31, the logic network 72 conducts the signal further to the switching circuit 74 which, depending on the status of the call control circuit 73, sends a signal to the control line 34 via the trip control circuit 75. activates the current circuit or circuits. At the same time, the corresponding memories of the call control circuit 73 that control the call are brought to the home position (connection). The wired state is recorded in the trip control circuit 75.

After the connection has been made, the signal coming through the command line 35 interrupts the timing of the logical network 72 (indefinitely busy).

If during the time interval determined by the timing of the logical network 72 no further signal (first digit, second digit, feedback) arrives on the command line 35, the logical network 72 sends a control (interrupt signal) to a specific control line 33.

It is clear from the foregoing that the circuitry of the present invention is capable of very effectively preventing a permanent line occupation that occurs by incorrect operation or for other reasons, since a correct evaluation of four different information is necessary for a permanent line condition.

An example of a circuit circuit 21 according to the invention is shown in FIG. 4. Line circuit 21 includes a counter 82, a sequential circuit 83, a switching circuit 85, a sensing circuit 81 and a logic network 84. The line 47 coming from the subscriber station 23 is connected to common points. a sensing circuit 81 and a switching circuit 85.

The output of the sensing circuit 81 is connected to the input of the logical network 84 and the counter 82. The counter input 82, which returns the counter content to zero, is connected to the deletion output of the logical network 84, while the counter output 82 is connected to the shift input of the sequential circuit 83. and the outputs of the sequential circuit 83 are coupled to the inhibiting inputs and outputs of the logical network 84.

The signal outputs of logic network 84 are connected to sensing lines 31, 31a to 31m, while the controlled inputs are coupled to control lines 34, 34a to 34m and the control output is coupled to the control input of the switching circuit 85. The asymmetric inputs and outputs of the switching circuit 85 are connected. to call lines 41, 41a to 41m, 40, 40a to 40m.

FIG. 4 shows a positive connection circuit. When the group line system is occupied, the occupation receives a busy tone as a result of the control signal on the control line 34 when called from the subscriber station 23, while the next signal line of the sensor from the signal line 31 of the signal transmitter is prevented.

The information communicated by dialing one number indicating the subscriber station 23, for example zero, is passed from the sensing circuit 81 to the counter 82, which stores this information in memory. The encoded signal at the output of the counter 82 shifts the three-digit sequential circuit 83, which arrives at its second position, actuating the switching circuit 85 via the logical network 84 and transmitting the signal to a common sense line 31.

The re-selection of certain information allows the sequencer 82 to further advance the sequential circuit 83, which reaches its third state and sends a signal through the logical network 84 to a single scan line 31a to 31m and to cancel the signal sent to the common scan line 31.

Further information or selection signals come via the sensing circuits and via the logical network 84 to the individual sensing lines 31a to 31m. Resetting the sequential circuit 83 to the home position or to the first state from its second state occurs as a result of the permanent current loop circuit interruption, while the connection from the third state occurs as a result of the control signal on the control line 34 via the logical network 84.

Thus, it can be seen that the circuitry according to the invention can be used in a variety of ways in both centralized and decentralized group telephony dispatching systems, since by using the solution according to the invention it is possible to satisfy all the demands placed on the device and realize the required functions.

The solution according to the invention is of particular importance in the creation of special purpose networks, for example networks along oil, gas and rail lines, but it is also applicable to the creation of village exchanges which are connected to networks with a serial system.

The solution according to the invention is simple, the programming can be carried out quickly and the whole construction can be extended. The set of controlled signaling codes enables, by means of a selective call, also call identification, which allows for flexible adaptation to different consumer requirements.

Claims (5)

1. Connection of switching devices in group lines, in particular telephone dispatching systems, with a programmed control unit, with an address and data bus system between the control unit and between different functional and peripheral units, with a set of lines providing signal flow between lines and peripheral units a sensor unit indicating the status of the peripheral units, with a programmable selector unit, a tone-frequency signal receiving unit, a programmable signaling transmitter and a tone-and-calling unit, characterized in that the control unit (1) and the signaling unit (13) comprise sensing circuits ( 71, 51, 62), whose inputs are connected via sensing lines (31, 31a to 31m) to sensing outputs of current circuits (21a to 21m) of the invention, the control unit (1) has 2xn address inputs, rJ-k + with control outputs and setting inputs where n address The input inputs are connected via the address line (36) to the selector unit (11), while the other n address inputs are connected via another address line (37) to the signaling transmitter (13), the setting inputs are connected via the command line (35) to a control unit (11) is connected via control line (33) to the signaling transmitter (13), is connected to the control outputs (32) via a control line (32) to the tone and transmitter unit (14) to the control outputs via other control lines (34, 34a to 34m) to the line current circuits (21a to 21m), the other common inputs of the control unit (1) and the selector unit (11) are connected 24 5 78.1 over. pulse line. (38). p. . pulse pulse. output · signal / transmit ·. units. (13), the control output of the signaling transmission unit. (13), which. starts dial tone, is connected via. control. a line (39) to the tone input. and the calling unit (14), the tone frequency output is. connected via a signal line (40 _{m +} 1) to the (m + 1) -team. the asymmetric input of the wiring set (22),. set of guides (22). is connected to km asymmetric inputs and outputs, where m · is the number of connected. subscriber stations (23a. to 23m). aa = l, over. call lines (41a ... to 41m, 40a to 40m) to. current circuits (21a to 21m) of the line, moreover, it is symmetrical inputs and outputs, for example via an input amplifier and a distortion equalizer. connected to the lines (42, 43), while the (m + 2) -th asymmetric input of the line set (22) is connected via a signal line (40 _{m +} 7) to the tone and call unit (14), (m-jl) -th the asymmetric output is connected via another signal line (41 _{m +} i) to the input of the signal receiver (12), coded, preferably four-bit data and control outputs of the signal receiver (12) are connected via data line (44) and control line (45) to the inputs of the dialing unit (11), the other outputs of the tone and calling unit (14) are connected via a signal line (46) to a common current input. The line circuits (21a. to 21m) of the line and the coupler outputs of the line circuits (21a to 21m) of the line are connected to the subscriber stations (23a to 23m), their apparatuses and telephone exchanges. Wiring according to claim 1, characterized in that the signal transmission unit (13) comprises a sequentially programmed counter (53) performing coding, a memory (54), a phase register (56), a damping circuit (52), a signal transmitter (55). and sensing circuits (51, 62), wherein the sensing circuit inputs (51, 62) are connected to the sensing line (31), the output of one sensing circuit (51) is connected to the damping circuit input (52), while the address inputs are connected to the address line (37) and the address outputs of the shift circuit (60) and the parallel write inputs of the shift circuit (60) and the address inputs of the second sense circuit (62) are coupled to the address outputs of the second shift circuit (61); ) is connected to common nodes of the blocking input of the second shifting circuit (61), the output of the second sensing circuit (62) and the setting input of the phase register (56), tup is connected to the blocking output of the timing circuit (58), the common clock pulse inputs of the shifting circuit (61), and the damping circuit. . the state output of the damping circuit (52) is connected to the shift input of the counter (53), the pulse output is connected to one start input of the timing circuit (58) while the other. the start input of the timing circuit (58) or the timing output is connected to the. starter. memory circuit output. (59). . eventually k. a timing input of the memory circuit (59) while a shift output. is connected to the phase input. . registry. (56), phase control outputs. The registers (56) are connected to the control lines. (39),. and one control input. a memory circuit (59), a release output. Yippee . connected to the memory release input. (54), the control inputs are connected to common memory input address nodes. (54) and code. counter outputs (53), while the output returning to zero is coupled to, counter reset (53) input, memory code outputs (54) are coupled to common code input nodes of the signal transmitter (55), and memory circuit code outputs (59), tone the frequency outputs of the signal transmitter (55) are via matching. circuit (57) connected to a signal line (40 _{П1. И)} and control inputs and outputs of the memory circuit (59) are connected to the control line (33). Connection according to Claim 1, characterized in that the control unit consists of a control circuit (75) for switching off, a control circuit (73) for calling, a switching circuit (74) for switching over multiple lines (66), 37), from the logic network (72) determining the function of the current circuits and from the sensing circuit (71), the inputs of the sensing circuit (71) being connected to the sensing lines (31) and the output to the control input of the logical network (72) the input is connected to a common node of the control circuit (73) and one address input of the switching circuit (74) and is connected to the address line (37), the other address input of the switching circuit (74) is connected to the second address line (36J). while the control input is connected to the logic network output (72), the data inputs and outputs are connected to the inputs and outputs of the call control circuit (73), and the control outputs are connected to the control circuit inputs (75), the control circuit outputs For tripping, they are connected to the common nodes of the control outputs of the call control circuit (73) and the control outputs of the logical network (72) and are connected to the control lines (34) controlling the switching circuits, while the setting inputs of the logic network (72) are connected to the command lines (35) and the outputs of the control tone and calling unit (14) are connected to the control lines (32) connected to the control input of the control circuit (73) for calling and the other control inputs and outputs of the control line (33) are connected to the signaling transceiver (13). 4. The circuit according to claim 1, wherein the at least one line current circuit (21a to 21m) comprises a counter (82), a sequential circuit (83), a switching circuit (85), a sensing circuit (81) and a logic network. (84), wherein the line (47a to 47m) coming from the subscriber station (23a to 23m) is connected to the common nodes of the sensing circuit (81) and the switching circuit (85), the output of the sensing circuit (81) is connected to the logical network (84) ) and to the counter signal input (82), the counter reset input (82) is connected to the logic network clearing output (84), while the output is coupled to the sequential input of the sequential circuit, (83), control outputs and sequential inputs circuit (83) are connected to blocking inputs and outputs of logical network (84), signal outputs of logical network (84) are connected to sensing lines (31, 31a to 31m), controlled inputs are connected to control lines (34, 34a to 34m) and the control output is coupled to the control input of the switching circuit (85) and the asymmetric inputs and outputs are connected to the voice line (41, 41a to 41m). Connection according to Claims 1 to 3, characterized in that for the voice line (40a to 40m, 41a to 41m), the signal line (46), the control line (34, 34a to 34m) and the ike pickup line (31), 31a to 31m) an operating field is connected.