RU2140718C1 - System to exchange discrete information - Google Patents

Abstract

FIELD: communication technology. SUBSTANCE: proposed system can be used for exchange of discrete information with large separation of its parts. It has master station, adjacent slave station, remote slave station, adjacent and remote sections of interface main line with data and control line and interrogation for servicing line and communication channel. System is inserted with first and second devices of corresponding make expanding interface main line. EFFECT: simplified and accelerated logic of exchange of data between sections of interface main line. 3 cl, 4 dwg

Description

 The invention relates to communication technology, in particular to a system for exchanging discrete information located over a large area, i.e. with large spacings of parts from each other.

 Since such systems use existing paths to communicate with remote parts (laying special paths would be very expensive), it is necessary to provide for the possibility of accessing any remote object to the central point (station) of such a system, as well as the possibility of quick communication from a central point (station) ) with any deleted object and any two deleted objects between each other. Usually, so-called call concentrators or priority determination blocks are used for this. For example, US Pat. No. 3,917,908 (CL H 04 Q 3/60, 1975) describes a discrete information exchange system comprising a master station and a slave station connected to it by a communication line, at the output of which a call concentrator is installed, to which many telephone apparatuses.

 Closest to the claimed is a system for the exchange of discrete information containing a master station, at least one adjacent slave station, at least one remote slave station, at least one adjacent and at least one remote sections of the interface highway with a data and control line and with a service request line, each adjacent portion of the interface trunk connects the master station and at least one adjacent slave station, a remote portion of the interface mag the line is connected to at least one remote slave station (application EPO N 0005722, CL H 04 Q 3/54, 1979).

 The objective of this invention is to create such a system for the exchange of discrete information, which would simplify and speed up the logic of data exchange between sections of the interface highway and would be different from existing systems.

 To achieve this result, in a discrete information exchange system comprising a master station, at least one adjacent slave station, at least one remote slave station, at least one communication channel, at least one adjacent and at least one remote sections interface line with data and control line and service request line, each adjacent section of the interface highway connects the master station and at least one adjacent slave station, remote learning the current of the interface line is connected to at least one remote slave station, according to this invention, at least a pair of first and second expansion devices of the interface line is introduced, the first inputs and outputs of which are connected to each other by at least one communication channel, and the second and the third inputs and outputs of each of which are connected respectively to the data and control lines and to the service request line, respectively, of the adjacent and remote sections of the interface highway.

 In addition, in this system, the expansion device of the interface highway contains an addressable identification and control unit for switching, a switching unit, and an interface unit with a communication channel, the first inputs and outputs of which are the first inputs and outputs of the device, the first inputs and outputs of which are the first inputs and outputs of the device , the first inputs and outputs of the addressed unit of identification and control of switching and the switching unit, respectively, are combined and are the second inputs and outputs of the device, the outputs of the addressed block and The identification and switching control are connected to the control inputs of the switching unit, the second inputs and outputs of which are combined with the second inputs and outputs of the addressable identification and control unit and the second inputs and outputs of the interface unit with the communication channel, the third inputs and outputs of which and the third inputs and outputs of the addressed unit identification and switching control are combined in the third inputs and outputs of the device.

 At the same time, the interface block with the communication channel may contain nodes of duplex transmission of logical signals, a transmitter, a receiver, a node for monitoring changes in the logical state of the lines of the interface line, and a node for duplex transmission of electrical signals, the inputs and outputs of which are the first inputs and outputs of the block, inputs and outputs of all nodes of duplex transmission of logical signals, except for one, and the inputs and outputs of this one node of duplex transmission of logical signals form, respectively, the second and third inputs and outputs of the block, the outputs are all x nodes of the duplex transmission of logical signals are connected to the information inputs of the transmitter and the inputs of the control node for changing the logical state of the lines of the interface line, the output of which is connected to the control input of the transmitter, the output of which is connected to the input of the duplex transmission of electrical signals, the output of which is connected to the input of the receiver, the corresponding outputs which are connected to the inputs of the respective nodes of the duplex transmission of logical signals.

 At the same time, the addressable identification and switching control unit contains an address encoder, a logical signal combining unit, as well as first and second address transceiver interface nodes, the first inputs and outputs of which form the first and second inputs and outputs of the unit, the addresses of the address encoder are connected to the control the inputs of the first and second address transceiver interface nodes, the second inputs and outputs of which are respectively combined and are the third inputs and outputs of the unit, the outputs of the first and second addresses The solid transceiver interface nodes are connected respectively to the first and second inputs of the logical signal combining node, the outputs of which are the outputs of the block.

 From the current level of technology, objects of the same purpose are unknown, containing both the entire specified set of features and the set of only distinctive features of the invention, which allows it to be considered new and having an inventive step.

 The invention is illustrated by drawings, where in FIG. 1 shows a block diagram of a system for exchanging discrete information according to this invention, FIG. 2 shows an embodiment of an extension device for an interface line according to the invention, FIG. 3 is a block diagram of a communication channel interface unit of the present invention, and FIG. 4 is a block diagram of an address block identification and switching control according to this invention.

 The system for exchanging discrete information according to this invention comprises a master station 1, adjacent slave stations 2.1 and 2.2, the number of which can be any, starting from one, and remote slave stations 3.1 - 3.3, the number of which can also be any, starting from one. The master station 1 is connected to adjacent slave stations 2 through an adjacent section 4.1 of the interface highway. Remote slave stations 3 are connected (one or several) with their remote sections 4.2 -4.3 interface highway. Each (adjacent or remote) section 4 of the interface highway consists of a data and control line 5 and a service request line 6. Remote sections (4.2 and 4.3 in Fig. 1) of the interface line are connected to adjacent sections (4.1 in Fig. 1) of the interface line using communication channels 7.1 and 7.2, the number of which can be any, starting from one. Communication channels 7 at each end are connected to the corresponding sections 4 of the interface highway through the corresponding device 8 expansion interface bus.

 All these devices 8 expansion of the interface highway are of the same type and consist (Fig. 2) of the addressed block 9 identification and control switching, block 10 switching and block 11 pairing with the communication channel. The first inputs and outputs 12 of the block 11 of the interface with the communication channel are the first inputs and outputs 22 of the device 8 expansion interface bus. The first inputs and outputs 15 of the addressed block 9 identification and control switching and the first inputs and outputs 18 of the block 10 switching, respectively, are combined and are the second inputs and outputs 23 of the device 8 expansion interface bus. The second inputs-outputs 13 of the block 11 of the interface with the communication channel are connected to the second inputs and outputs 16 of the addressed block 9 identification and control switching and the second inputs and outputs 19 of the block 10 switching. The third inputs-outputs 14 of the block 11 of the interface with the communication channel are combined with the third inputs and outputs 17 of the addressed unit 9 of identification and control switching and are the third inputs and outputs 24 of the device 8 of the expansion of the interface highway. The outputs 20 of the addressed unit 9 identification and switching control are connected to the control inputs 21 of the switching unit 10.

 Master station 1 and slave stations 2 and 3 may be any devices that are capable of performing the functions prescribed by it in the present invention. For example, it can be interface devices of the interface system for measuring devices with byte-serial, bit-parallel exchange of information in accordance with GOST 26.003-80 or the recommendation of the CCITT (International Advisory Committee for Telegraphy and Telephony, now the International Telecommunication Union, MTS) IEC-625.

 Block 11 interface with a communication channel includes (Fig. 3) nodes 25 of the duplex transmission of logical signals, a transmitter 26, a node 27 for monitoring changes in the logical state of communication lines, a node 28 of the duplex transmission of electrical signals and a receiver 29. Inputs and outputs of all but one of the nodes 25 duplex transmission of logical signals (in Fig. 3 they have the reference position 25.1 - 25.n) form the second inputs and outputs 13 of the block 11 of the interface with the communication channel. The inputs and outputs of a separate node 25. (n + 1) duplex transmission of logical signals form the third inputs and outputs 14 of the block 11 of the interface with the communication channel. The outputs of all nodes 25.1 - 25. (n + 1) duplex logical signals are connected to the corresponding information inputs of the transmitter 26 and the corresponding inputs of the node 27 for monitoring the change in the logical state of the communication lines, the output of which is connected to the control input of the transmitter 26. The output of the transmitter 26 is connected to the input node 28 of the duplex transmission of electrical signals, the output of which is connected to the input of the receiver 29, and the inputs and outputs form the first inputs and outputs 12 of the block 11 of the interface with the communication channel. The outputs of the receiver 29 are connected to the inputs of the respective nodes 25 duplex transmission of logical signals. The nodes 25 of the duplex transmission of logical signals are designed to transmit and receive binary signals with TTL levels, while the nodes 28 of the duplex transmission of electrical signals are designed to transmit and receive linear signals with different voltage levels.

 Block 9 identification and control switching includes (Fig. 4) the first 30 and second 31 address transceiver interface nodes, a node 32 combining logical signals that implements a logical OR operation, and an address encoder 33. Addressed transceiver nodes 30 and 31 can be performed in the same way as the master station 1 or slave stations 2 and 3.

 A system for exchanging discrete information works as follows.

 Adjoining slave stations 2 exchange information with the master station 1 (for example, making and receiving phone calls, service signals, etc.) on the corresponding sections 4 of the interface highway to which these slave stations 2 are connected. A separate call from the terminal equipment (individual telephone set or testing circuit) is sent to the corresponding slave station, for example, 2.1, which at the same time issues a service request to line 6.1 of its section 4.1 of the interface highway. Leading station 1, in the process of polling its subscribers, which are all slave stations 2 and 3, detects this request and sends permission to exchange information on this request via the data and control line 5.1 that requested it. The exchange of information occurs through the line 5.1 of data and control of the same section 4.1 of the interface highway. Upon completion of the exchange, the request signal from the slave station 2.1 is removed from the service request line 5.1. If necessary, to exchange information from the master station 1 to any of the adjacent slave stations, for example, 2.2, the master station 1 sends an exchange command to this slave station 2.2 through the data and control line 5.1 of the corresponding section 4.1 of the interface highway and starts the exchange of information. Such a discrete information exchange scheme is known, for example, from the above application EPO N 0005722.

 If it is necessary to exchange discrete information with remote slave stations 3, the described general operation scheme does not change, however, new operations appear in it.

 Let the call come from the individual terminal equipment to the remote slave station 3.1, which, like the adjacent slave station 2.1, issues a service request to line 5.2 of the service request for the corresponding remote section 4.2 of the interface highway. This request signal is supplied to the third inputs and outputs 24 of the interface line extension device 8.2, in which it passes to the third inputs and outputs 14 of the interface unit 11 to the communication channel and passes through it to the communication channel 7.1. At the output of the communication channel 7.1, the service request signal enters the paired device 8.2 of the interface line extension device 8.1, where, after passing through the interface unit 11 to the communication channel, it goes to its third inputs-outputs 14, i.e., to the third inputs - outputs 24 of the device 8.1 extension interface bus. Thus, the service request from the remote slave station 3.1 is placed on line 6.1 of the service request for the adjacent section 4.1 of the interface line, from where it is read in the same way as for any adjacent slave station 2.

 Data exchange in the opposite direction, i.e. from the master station 1 to any remote slave station 3 occurs in the same way due to the symmetry (mirroring) of each pair of devices 8 expansion interface lines connected by their channel 7 communication, in relation to the incoming signals. That is, the exchange command from the master station 1 via the data and control line 5 of the corresponding adjoining section 4 of the interface line arrives at the second inputs-outputs 23 of the corresponding interface line expansion device 8 and enters the first inputs-outputs 15 of the addressed identification and control unit 9 switching. If the received command contains the address of the remote slave station 3, which is serviced through this interface line expansion device 8, the addressable unit 9 of this device 8 identifies this address and issues a corresponding command to its outputs 20, which is transmitted to the control inputs 21 of the switching unit 10, causing corresponding switching in it. As a result, the command from the second inputs and outputs 23 of the interface line expansion device 8 passes through the switching unit 10 to the second inputs and outputs 13 of the communication unit 11 and is supplied from its first inputs and outputs 12, i.e. from the first inputs and outputs 22 of the device 8 expansion of the interface line into the communication channel 7.

 The communication channel interface unit 11, the implementation of which is shown in FIG. 3, works as follows. In the initial state, at the second and third inputs of the outputs 13 and 14 of this block 11, for example, a high inactive level is present. If the master station 1 or any of the slave stations 2 or 3 sets a low level on the corresponding data line 5 or the service request line 6, it enters through the corresponding node 25 to the information input of the transmitter 26. The transmitter 26 converts the received parallel code into a serial and feeds it to the node 28 duplex transmission of electrical signals, which matches the signal code combination with the communication channel 7 and transmits this signal. At the opposite end of the communication channel 7, the transmitted code combination signal is received by a similar duplex unit 28 for transmitting electrical signals, which feeds it to a receiver 29, from which the code received in serial form is converted to parallel and fed to the corresponding node 25 for duplex transmission of logical signals, from the output which a low level is supplied to the corresponding inputs-outputs 13 or 14 of the block 11 of the interface with the communication channel. The unit 27 of the change in the logical state of the lines of the interface line included in the block 11 prevents the information from being read by the transmitter 26 when changing the byte of information on the data bus of the interface line and exchanging information between two objects connected to this line.

 Shown in FIG. 4 addressable unit 9 identification and control switching operates as follows. In the address encoder 33, the address of this interface extension device 8 is set. If a code word identical to the address set in the address encoder 33 is supplied to the first or second inputs-outputs 15 or 16 of the addressed block 9 for identification and control, then in this block 9 the corresponding address transceiver interface node 30 or 31 generates a signal at its output, which, through the combining unit 32 (OR circuit), enters the output 20 of this block 9. Due to this, the switching unit 10 of this device 5 for expanding the interface line passes to its second inputs-outputs 19, i.e. to the second inputs and outputs 13 of the block 11 of the interface with the communication channel, the code word received at the first inputs and outputs 18 of the block 10 switching. The connection of the address transceiver interface node 30 or 31 with the third inputs-outputs 17 of the addressed unit 9 of identification and control of switching serves to give a service request signal when sending them incorrect commands, i.e. at the time when they are addressed to receive data.

 In the event that the exchange is carried out between any two slave stations 2 and / or 3, the master station 1 during the interrogation of all its slave stations detects the corresponding service request signal, which is supplemented by a special indicator of which slave station should be connected , and designates the slave station 2 or 3 that made this request as the source of information for the duration of the exchange. After that, this slave station acts as a source of information for the exchange period (i.e., as the master station).

 From the above description it is obvious that the proposed system for the exchange of discrete information can be used both in existing and in developed communication networks. Therefore, this invention can be considered industrially applicable.

 The given specific example of the implementation and operation of the system for the exchange of discrete information is by no means a limitation, but serves only as an illustration of an inventive idea, which can be implemented with appropriate modifications within the scope of patent claims, which is determined by the attached claims.

Claims (4)

 1. A system for exchanging discrete information comprising a master station, at least one adjacent slave station, at least one remote slave station, at least one communication channel, at least one adjacent and at least one remote portions of the interface line with with a data and control line and a service request line, each adjacent section of the interface highway connects the master station and at least one adjacent slave station, a remote section of the interface highway under It is connected to at least one remote slave station, characterized in that at least a pair of the first and second expansion devices of the interface line is inserted into it, the first inputs and outputs of which are connected to each other by at least one communication channel, and the second and third the inputs and outputs of each of which are connected respectively to the data and control lines and to the service request line, respectively, of the adjacent and remote sections of the interface highway.  2. The system according to claim 1, characterized in that the expansion device for the interface highway contains an addressable identification and control unit for switching, a switching unit and a unit for interfacing with a communication channel, the first inputs and outputs of which are the first inputs and outputs of the device, the first inputs and outputs of the addressable the identification and switching control unit and the switching unit are respectively combined and are the second inputs / outputs of the device, the outputs of the addressed identification and switching control unit are connected to the control moves of the switching unit, the second inputs and outputs of which are combined with the second inputs and outputs of the addressed identification and control unit and the second inputs and outputs of the interface unit with the communication channel, the third inputs and outputs of which and the third inputs and outputs of the addressed identification and control unit are combined into third device inputs / outputs.  3. The system according to claim 2, characterized in that the interface unit to the communication channel comprises nodes for duplex transmission of logical signals, a transmitter, a receiver, a node for monitoring changes in the logical state of the lines of the interface line, and a node for duplex transmission of electrical signals, the input-outputs of which are the first inputs the block outputs, the inputs and outputs of all nodes of the duplex transmission of logical signals, except one, and the inputs and outputs of this one node of the duplex transmission of logical signals form the second and third inputs respectively block odes, the outputs of all nodes of the duplex transmission of logical signals are connected to the information inputs of the transmitter and the inputs of the control unit for changing the logical state of the lines of the interface line, the output of which is connected to the control input of the transmitter, the output of which is connected to the input of the duplex transmission of electrical signals, the output of which is connected to the input a receiver, the corresponding outputs of which are connected to the inputs of the respective nodes of the duplex transmission of logical signals.  4. The system according to claim 2, characterized in that the addressable identification and switching control unit contains an address encoder, a logical signal combining unit, and also first and second address transceiver interface nodes, the first inputs and outputs of which form the first and second inputs and outputs, respectively the unit, the outputs of the address encoder are connected to the control inputs of the first and second address transceiver interface nodes, the second inputs and outputs of which are respectively combined and are the third inputs and outputs of the unit, outputs rows of first and second address transceiver interface nodes connected respectively to the first and second inputs of the combining node logic signals, whose outputs are the outputs.

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