RU2030838C1 - Method of and device for automatic switching in communication line - Google Patents

Abstract

FIELD: telephone communications. SUBSTANCE: system has one switching unit, N digital-information user terminals, K analog-information switching terminals, 2m data transmission channels, 2n analog information channels, one station computer, (N+K+2n+2n+1) interface units, (N+K+2n+2m+1) data-transmission equipment sets of station, (N+K+2n+2m+1) communication lines of interface units for standard sets of data-transmission equipment, (N+K) communication of lines for data-transmission equipment sets of station with remote data-transmission equipment, one physical-channels switch control channel, (N+K) remote data-transmission equipment sets, one peripheral data-transmission equipment set, K analog-information terminal-to-physical-channel switch communication lines, one physical switch channel, one peripheral data transmission equipment set-to-physical-channel switch communication line, N digital-information user terminal-to-remote data-transmission equipment sets communication lines, K switching terminal-to-remote data-transmission equipment sets communication lines. EFFECT: improved utilization efficiency of communication lines due to provision for transmission of priority groups of analog information over sonic-frequency channels as well as introduction of additional physical-channel switch and analysis of speech, agreement, and disconnection flags in line units. 2 cl, 23 dwg

Description

 The invention relates to the transmission of information in communication networks and can be used in integrated transmission networks of data packets and analog information without converting it into discrete signals, in particular for creating integrated information networks of industrial ACS (OASU) based on non-switched standard channels of tone frequency (PM) formed by analog type seal equipment.

 The aim of the invention is to increase the efficiency of use of the communication network by providing the possibility of transmitting packets in the switching network via inter-site PM channels of priority groups of analog information without first converting it to discrete signals and while maintaining high efficient packet data transmission in the packet switching network.

 Figure 1 shows the structural diagram of an automatic switching system; figure 2 is a structural diagram of a switch physical channels (KFK); figure 3 is a structural diagram of a station computer node; figure 4 is a structural diagram of a software control unit; figure 5 is a structural diagram of a unit for interfacing a host computer with outgoing inter-site communication channels; Fig.6 is a structural diagram of a computer interface unit with incoming inter-site communication channels; figure 7 is a structural diagram of a unit for interfacing a host computer with data transmission equipment of subscriber lines of subscribers with discrete information; in Fig.8 is a structural diagram of a unit for interfacing a host computer with the data transmission apparatus of the KFK control channel; in FIG. 9 is a structural diagram of a block for fixing the state of a route connection; in FIG. 10 is a structural diagram of blocks for fixing signs of "speech", "consent", "disconnection"; figure 11 is an example implementation of a control circuit KFK in blocks of code control KFK; 12 and 13 are state tables implemented in the CPK code control unit; on Fig.14-22 is an example of a functioning algorithm in the communication of subscribers with analog information; in FIG. 23 are graphs illustrating the effectiveness of the proposed method and system of automatic switching in a communication network and their place according to this criterion among the known methods and systems.

An automatic switching system in a communication network that implements the proposed method includes a switching node 1, terminals of subscribers with discrete information 2 ¹ -2 ^N , terminals for switching subscribers with analog information 3 ¹ -3 ^k , terminals (telephones) of subscribers with analog information 4 ¹ -4 ^k , groups of analog channels to adjacent nodes 1 of stations J, S only for data transfer 5 _j ¹ -5 _j ⁿ ; 5 ¹ _s -5 _s ⁿ , groups of analog channels to adjacent nodes 1 of stations J, S for transmitting analog information (speech) and data 6 _j ¹ -6 _j ^m ; 6 _s ¹ -6 _s ^m , stationary computer 7, interface blocks between the station computer and the station sets APD 8, station sets the ADF or modems with controllers 9; a communication line between the interface blocks with the station sets of the ADF or modems with the controllers 10, lines 13 and 11 of the connection of the station sets of the ADF 9 and the remote sets of the ADF, the channel 12 for controlling the switch of physical channels (KFK) 12, the remote sets of the ADF or modems with controllers 13, the peripheral set ADP 14 of the KFK control channel, 15 communication lines of the terminals with the KFK analog information, switch 16 physical channels, communication of the 17th peripheral set of the KFK control channel ADF with the physical channel switch, 18 communication lines of the abone terminals nt with discrete information with remote sets of ADF, line 19 communication terminal switching with remote sets of ADF.

 KFK 16 contains the coordinate connectors 20 and 21, the control unit 22; block 23 interface with the control channel KFK, blocks interface with connectors 24 and 25.

The station computer contains a program unit 26 for interfacing with the ADF of subscriber lines of terminal groups 2 ¹ -2 ^N , 3 ¹ -3 ^k , a program unit for interfacing with the ADF for incoming channels of groups 6 and 27, a program unit for interfacing with the ADF for outgoing channels of groups 6 and 28, and a program block 29 interface with the ADF 14 control channel KFK, program block 30 control, program blocks 31-33 initiate the formation of call packets, consent, disconnection, program blocks 34-36 receive and analyze call packets, consent, disconnection, program blocks 37-39 formation call packets, with consents, disconnections, program blocks 40-42 for fixing the signs of "speech", "consent", "disconnection", program block 43 for fixing route connections, program block 44 for generating physical switching signals 44.

 The control software unit 30 comprises an operating system core 45, a task supervisor 46, an I / O manager 47, a memory 48.

 The interface block with outgoing inter-site communication channels contains a program package 40 and session and transport level memory, a packet switching manager 50 and memory, an alternative outgoing lines distribution pseudo driver 51, a driver processing section 52, a driver 53 communication section 53, a 2K hardware-software interface 54.

 The interface unit with incoming inter-site communication channels contains a program package 49 and session and transport level memory, a packet switching manager 50 and memory, a driver processing section 52, a driver communication section 53, a hardware-software interface “2K” 54, a pseudo driver 55 of the group of initiative devices ( incoming lines).

 The unit for interfacing with the equipment for transmitting data of subscriber lines of subscribers with discrete information comprises a hardware-software interface “2K” 54, a driver 56 of initiative devices, a driver processing section 57, a driver communication section 58.

 The block interface with the equipment of the control channel KFK contains hardware-software interface "2K" 54, driver 59, driver processing section 60, driver communication section 61.

 The block for fixing the state of the route connection contains a register 62 status words, logical elements And 63 and 64, decoders 65-68.

 Each of the blocks 40-42 contains decoders 69 asynchronous signals, triggers 70, the logical element And 71.

 KFK control circuits (blocks 20 and 21) are implemented, for example, on the set of open and closed relay contacts of the corresponding lines.

An example implementation of the control circuit shown in Fig.11. It can be seen from the example that, in the initial state, the contacts, relay of the internode links channels, the corresponding channels are connected to the station sets of the ADF or modems with controllers. When two relays are triggered, for example, P _i and P _{j, the} corresponding lines in block 20 are disconnected from the ADF station sets, and in block 21 they are interconnected.

When the relay of subscriber lines of subscribers with analog information, for example, P _l and P _m , in block 21, the corresponding lines are interconnected. At the same time, the connection between the inter-site channels with the ADF station sets is not broken.

On Fig and 13 shows an example of a table of states implemented in block 44 "formation of physical switching signals". It is seen that, for example, for the interconnection of lines i and j, simultaneous operation of the relay R _i and P _{j of the} lines l and m is necessary - simultaneously the operation of the relay P _l and P _m .

 As the computer 7 uses a mini-computer, for example, SM-2M, containing software layers, namely drivers that implement the physical layer; pseudo-drivers implementing the linear control level; network level of user programs; transport layer of user programs; session and representative level of user programs.

 Block 30 (see figure 3) is the operating environment and the operating memory of the minicomputer.

 Blocks 31, 32, and 33 for initiating call, consent, and disconnect packets are representative level software modules that analyze the corresponding service messages from subscriber lines of discrete data terminals and call terminals. Their implementation is similar to that, for example, in the terminal subsystem of the information network of the Siren-2 fragment.

 The blocks of reception and analysis 34-36 of the formation and transmission of 37-39 packets of call, consent and disconnection are the corresponding program modules of the session level, respectively, for incoming and outgoing communications of this level with the transport level. Their implementation is similar to that for the mechanism of securing to this pair of recipients of the switched transport station ROS ASPO.

 The software modules also include modules for outputting consent and calling packets to local subscribers with analog information (to terminals 3). Their implementation is similar to that in the terminal subsystem of the information network of the Siren-2 fragment.

 Blocks 40-42 for fixing the signs of "speech", "consent", "hang up" are the corresponding hardware or software modules that implement logical operations I. All of these blocks are implemented in the same way. An example implementation is shown in Fig.10.

 Due to the fact that asynchronous signals are supplied to the And circuits, each of them is preliminarily fixed by a corresponding trigger 70. These triggers are returned to their initial state by a signal from block 30.

The route connection fixing unit 43 is a hardware or software representation of the Status Word of the corresponding route connection in the route table. From a logical point of view, this is a decoder whose inputs from block 30, initiation units 31-33 of reception and analysis 34-36 receive signals about numbers of incoming N _in , outgoing N _output lines, about the number of virtual connection, N _sun ; on the sign of information to be transmitted “speech”, on the sign of “consent”, on the signs of the end of “local hang-up”, “remote hang-up”.

Signs N _in , N _out , N _all are entered into the decoder from block 30. Figure 9 shows an example of a structural diagram of block 43.

Block 44 is a block for generating signals of physical connection or disconnection of the corresponding incoming N _input and outgoing N _output lines transmitted from the computer 7 to block 16.

 The switching terminal 3 can be implemented similarly to the terminals of the Siren-2 system or simplified in accordance.

 The notification of the subscriber with analogous information about the incoming connection in the switching terminal 3 can be implemented in hardware and software in blocks 7 and 3, similar to those, for example, in the Siren-2 system used in the nodes of the information network to notify of the presence of an incoming message in the queue "Email".

 As connectors 20 and 21 can be used, such as, for example, in coordinate exchanges.

 The subscriber terminal with analog information 4 is a regular telephone set with a microphone circuit powered by a local battery.

 The process of functioning of the automatic switching system in relation to switching subscribers with discrete information does not differ from that in the prototype.

 The process of functioning of the system in relation to switching subscribers with analog information is considered based on the algorithm of operation shown in Fig.14-22.

 Let the subscriber of group 4 of this node want to establish a physical connection with the subscriber of group 4 of node Ψ separated from the given one through one transit node S.

 First of all, all active subscribers of group 4 before starting work (shift) confirm their "activity" by performing on the switching terminal of group 3 the operations preceding in Figs. 14-22, 1, the condition "You can work", 2.

 If the answer is “Yes”, the terminal of group 3 of this subscriber of group 4 is ready for operation.

 If the answer is “No”, the preparation operations are repeated. If necessary, in a telephone conversation (or in transferring data according to the principle of "direct connection"), the initiating subscriber in the terminal of group 3 dials the address of the subscriber-recipient and the sign "Speech" on the keyboard of his terminal in group 3 and initiates the formation of the initial data of the Call Request packet by pressing the “Initiation of the Call Request” packet key (9-11). Then, presses the “Transfer” keys, after which a machine message of 3V packet initiation is transmitted from the group 3 terminal to the computer 7 of this node.

 After receiving the replica "Message 3B is accepted for delivery" from computer 7, in terminal 3 either the replica itself is displayed or the acoustic signal "Wait" appears.

 If the replica "message 3B received for delivery" is not received, the listed operations 10-14 initiate sending a packet are repeated.

 If everything is in order and computer 7 of this node receives confirmation of the replica reception in the terminal of group 3, operation 18 is performed on the computer of this node, the sign “Speech” is recorded in block 40 and the formation of this route connection in block 43 begins.

 At the same time, the “Speech” sign, the number of the outgoing logical channel, the type of the burst packet is fixed in block 37 (see Fig. 3), where the burst packet is formed.

 The following is a set of operations 23 and 24 of the transmission of an ST packet to the outgoing inter-node communication channel of group 5 and receipt of acknowledgment of its reception at the transit station. With a positive confirmation at the transit station in block 34 of the computer 7, operation 25 is performed - analysis of the packet of pollutants. After the analysis, in block 40, the sign “Speech” is fixed, in block 43, the formation of the status word of this logical route connection begins.

 Next, the packet of pollutants in the computer 7 of the transit station is transmitted to block 37, from which it is transmitted to the outgoing channel to the destination end station, during which the set of operations 29 and 30 is performed.

 With a positive confirmation in the computer 7 of the end station in block 34 (see Fig. 3), the analysis operation 31 of package 3B is performed, as a result of which the sign "Speech" is fixed in block 40, and in block 43 the formation of the status word of this route logical connection begins.

 The analysis results from block 34 are also transmitted to block 31, as a result of which the control unit 30 checks the condition “The called subscriber is free”. If it is free, operations 36 and 37 are performed, as a result of which a packet is formed in block 38. The call is “Accepted” and transferred to the outgoing channel.

 Further, two processes simultaneously occur at the terminal station. In accordance with the first computer 7 generates in block 31 a call signal to the switching terminal 3 of the given telephone subscriber 4. As a result of operations 39-41, this signal is received at the switching terminal 3 of this telephone subscriber 4 and an optical and / or acoustic signal appears at terminal 3 "Call".

 In accordance with the second process, operations 43 and 44 are performed in computer 7 and condition 45 is analyzed. If the result is positive, physical switching is performed by blocks 20 and 21 in the CPK, during which the called subscriber’s subscriber line is connected to group 6 inter-site communication line from the bundle of lines to this transit node.

 At the transit station in the computer 7 in block 35, the sign “Call received” is analyzed (operation 48), the packet “Call received” is transmitted from block 35 to block 38 and then to the outgoing channel.

 The sign “Call accepted” (consent) is fixed in block 41, in block 44, operation 52 is performed, in block 20 and 21, operation 55 of physical switching of analogue RF channels included in this route connection is performed.

 After condition 60 is satisfied, operations 61 and 62 are performed at the initiating station of the connection in the computer 7, and then operations 56, 58 and 63, as a result of which the subscriber line of subscriber 4, the initiator of communication, is connected to the physical connection of this pair of correspondents.

 At the same time, operations 64-66 are performed at the initiating station in the computer 7 and the signal “You can talk” is generated in the group 3 switching terminal to the initiating subscriber of the connection. Further, condition 67 is expected to be fulfilled. Once this has happened, the initiating subscriber presses the “Initiate complete packet” button on the switching terminal (this operation can be combined with the “Handset Broadcast” operation). As a result, operations 70 and 71 are automatically performed in the group 3 switching terminal of this subscriber and condition 72 is expected to be fulfilled, after which the switching terminal of this subscriber returns to its original state.

 After checking condition 74 at the initiating station in the computer 7 in block 33, the formation of the “End of communication” packet (disconnection) is initiated.

 The sign "Disconnect" is fixed in block 42, in block 39 is fixed and transmitted to the outgoing channel of group 5 packet ZS. At the same station, in block 44, a signal is used to return the CPK for the given connection to the initial state and operation 86 is performed to return the CPK for this communication to the initial state; in the ST block, the sign of the freedom of this subscriber is recorded. As a result, the initiating station for this communication goes into the initial state of waiting for the initiation of the next communication.

 After condition 83 is fulfilled at the transit station in block 36, the sign “Disconnect” is executed, which is fixed in block 42. Next, two processes are performed in parallel: transmission of the ST packet from block 36 to block 39 and then to the outgoing channel towards the destination node of this connection ( operations 92 and 93, condition 94); return KFK transit station for this connection to its original state (operations 86, 87 and 89, condition 88).

 After condition 94 is met at the destination station in block 36, the sign "Disconnect" is detected, which is fixed in block 42. Next, two processes are performed in parallel: returning the destination terminal station to its initial state on this connection (operations 91, 97, 99 and 100, condition 98 ), the transfer of the “Communication completed” replica to the switching terminal of the destination subscriber (operations 101 and 104, conditions 102 and 103). As a result, in the computer 7 of the destination station in blocks 31-33, the sign "Subscriber is free" is recorded.

 The automatic switching system for this connection is returned to its original state.

 All operations and conditions performed in the computer 7 of the initial, transit and final nodes are performed under the control of block 30.

 When establishing a connection between local subscribers with analog information after operations 18-20, operations 63, 56 and 58 are immediately performed for this pair of subscriber lines. Similarly, operations are performed to return these subscriber lines to their original state.

 In this case, the switching packets in the host computer 7 are not formed and the inter-node communication channels from the station sets of the ADF (modems with controllers) are not disconnected, since the switching process of local telephone subscribers is implemented only by the connector of the block 21 (Fig. 2).

Claims (3)

 METHOD OF AUTOMATIC COMMUTATION IN A COMMUNICATION NETWORK AND A SYSTEM FOR ITS IMPLEMENTATION.  1. A method of automatic switching in a communication network, which consists in transmitting by the subscriber-sender via the subscriber line to the starting station the signals of his number and the subscriber-recipient number, broadcasting the above-mentioned signals over the tonal frequency (PM) channels between adjacent stations, receiving and analyzing them at all stations along the route of transmission to the end station of the recipient subscriber with recording at each station signals characterizing the numbers of the incoming and outgoing pre-transmission lines through this station, analysis of the signal at the end station and the status of the subscriber-recipient and the subsequent transmission to the starting station of the consent signal when the subscriber is unoccupied and disagreement when busy with the analysis of the status signal at each station and choosing the same route for each station on the previously recorded signals characterizing the numbers of the incoming and outgoing signal transmission lines subscriber numbers, characterized in that, in order to increase the efficiency of the use of the communication network by providing the ability to transmit priority groups of analog information on PM channels, one alternately with the signals of the subscriber and recipient subscriber numbers, additional signals about the type of information to be transmitted are transmitted and recorded at each station along the transmission route to the recipient subscriber, the recorded additional signals at each station are analyzed together with the status signals received from the recipient subscriber, and, in the case of the need to transmit analog information and the consent of the subscriber-receiver, they transmit inside each station the shutdown signals of the said incoming, outgoing lines from among the characteristics connected by a recorded signal from the station, the connections of these lines between themselves at transit stations and with subscriber lines at the start and end stations, and when they hang up at the start and end stations, they receive hang-up signals along subscriber lines, transmit these signals, as well as hang-up confirmation signals, similar to transmission status signals to the correspondent station, and upon receipt of the end signals inside each of the stations, signals of the return of said incoming-outgoing and subscriber lines to the initial state are transmitted.  2. An automatic switching system in a communication network, containing terminal and intermediate stations interconnected by inter-node tonal frequency (PM) channels, each station containing a switching node, N terminals of subscribers with discrete information, connected by inputs and outputs via remote sets of transmission equipment data (ADF) to the first inputs and outputs of the switching node, while the switching node contains a station computer with corresponding interface units, a group of N station sets of ADF and two groups of m station ADF sets, connected by inputs / outputs with the corresponding interfacing units of the station computer, and outputs connected to the corresponding PM inter-node communication channels, while a group of N station ADF sets is connected by the first inputs and outputs to the corresponding interface units of the station computer, and the second inputs and outputs - to the corresponding N inputs of the switching node, and the station computer contains a software control unit, program blocks for initiating the formation of call packets, consent and disconnection, p program blocks for receiving and analyzing call packets, consent and disconnection, program blocks for generating call packets, consent and disconnection, program blocks for fixing signs "Consent" and "Disconnect", program block for fixing route connections, program block for interfacing with ADF of subscriber lines of terminal groups, software blocks for interfacing with the ADF of incoming and outgoing channels, the inputs and outputs of which are connected respectively to the incoming and outgoing channels, while the information outputs of the interface with the ADF are incoming x channels are connected to the first inputs of the blocks of reception and analysis of call, consent and disconnect packets, the second inputs and outputs of which are combined with each other and with the first inputs and outputs of the software control unit and the interface block with the ADF of the incoming channels, and the outputs of the blocks of reception and analysis of packets calls, consent and disconnection are connected to the first inputs of the respective program blocks for initiating packet formation, packet forming blocks, block fixing signs, and the second input-output of the software block The control unit is connected to the combined second inputs and outputs of the program blocks for initiating the formation of call, consent and disconnect packets and to the first input and output of the program block for connecting with the ADF of subscriber lines of terminal groups, the second inputs and outputs of which are connected respectively to the third inputs and outputs of the program blocks call, consent, and disconnect packets, the outputs of which are connected to the second inputs of the corresponding software blocks for forming packets and blocks for fixing signs, whose interconnected inputs and outputs are connected to the third input-output of the software control unit, the fourth input-output of which is connected to the combined third inputs and outputs of the software package forming units and to the input-output of the interface unit with the ADF of the outgoing lines, the information inputs of which are connected to the outputs of the program blocks for generating call, consent, and disconnect packets, and the outputs of the software blocks for recording signs of consent and disconnection are connected respectively to the first and one to the other inputs of the program block for fixing the route connection, the third and fourth inputs of which are connected respectively to the third input-output of the program control unit and the output of the program block for receiving and analyzing call packets, and the fifth input is connected to the output of the program block for initiating the formation of call packets, the third inputs being the outputs of the program unit for interfacing with the ADF of subscriber lines of terminal groups are the outputs of the station computer connected to the corresponding station sets of the ADF, I mean that, in order to increase the efficiency of using inter-node PM channels by transmitting priority groups of analog information through them, K subscriber switching terminals with analog information were introduced at each station, connected by inputs and outputs through the corresponding remote sets of ADFs to the corresponding first K inputs and outputs switching node, as well as K terminals of subscribers with analog information connected by inputs / outputs to the corresponding second K inputs / outputs of the switching node, and to each switching node given K additional station sets of ADF, the first inputs and outputs connected to the corresponding interface units of the station computer, the switch of physical channels (KFK), the peripheral set of ADF, the first input-output of which is connected to the input-output of the KFK control, and the second input-output is connected through station set ADF and the corresponding unit for interfacing the station computer to the control output of the station computer, and the KFK contains the first and second coordinate connectors (KS), a control unit (CU), an interface unit with a control channel KFK (BSKU), the first and second blocks of interface with connectors (BSS), and the second K inputs and outputs of the switching node are the first inputs and outputs of the KFK, in the second inputs and outputs of which are connected the corresponding additionally introduced two groups of n analogue RF channels of the interstitial communication, while the third inputs and outputs of the KFK are connected to the first inputs and outputs of the corresponding station sets of the ADF of the additionally introduced analogs of the PM channels of the inter-node communication, while the input-output of the control of the KFK through the BCSC is connected to the first input-output BU house, whose second inputs and outputs are connected through the first and second BSS to the corresponding control inputs of the first and second KS, with the first and second KFK inputs and outputs being the first and second groups of inputs and outputs of the second KS, and the third KFK inputs and outputs are inputs and outputs of the first KS, at the same time the program unit for recording the sign “Speech”, the program block for generating physical switching signals and the program block for interfacing with the ADF of the KFK control channel, the first input-output of which is is the control computer output of the station computer, and the second and third inputs are connected respectively to the third input-output of the software control unit and the output of the software unit for generating the physical switching signal, the first and second inputs of which are connected respectively to the output of the program unit for fixing the route connection and the third input-output of the software control unit, while the first input-output of the software block fixing the sign "Speech" is connected to the output of the software block receiving and analyzing call packets, and the second the th input-output is connected to the third input-output of the software control unit, while the third input-output is combined with the fifth input of the software block fixing route connections and connected to the output of the software block initiating the formation of call packets, and the output is connected to the sixth input of the software block fixing route connections.

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