RU2106069C1 - System for testing and controlling of automatic systems using telephone networks - Google Patents

Abstract

FIELD: telephone communications. SUBSTANCE: device has first and second automatic controlled objects which are connected to each other through serial circuit of automatic phone exchange stations. Said first and second automatic objects have first and second phone sets, first and second control units, first and second continuous monitoring circuits, first and second keyboard equivalent units, first and second decoders, first and second receivers of telephone codes. In addition first automatic controlled object has first indication unit, while second automatic object has first and second call ring unit, first detectors unit and first unit of actuators. Goal of invention is achieved by first and second commutators, first and second transmitters, first and second software-control interrupters, first and second call acknowledgment units introduced to first and second automatic control objects respectively. In addition first automatic control object has second call ring unit, second detectors unit and second actuators unit. Second automatic control object has second indication unit. Group control of automatic controlled objects is achieved by use of call detection phone set by dispatcher. EFFECT: automatic transmission of error message between arbitrary automatic controlled objects, transmission of request and control commands from arbitrary phone sets which are located both inside controlled objects and outside. 2 cl, 4 dwg

Description

 The invention relates to telecommunications and may find application in telephony when presenting to subscribers an additional fee of a service for monitoring and managing automated objects.

 Automated objects are understood to mean such an object, which is equipped with a set of appropriate sensors and actuators and is connected to the telephone network.

 The automated objects may be apartments, office rooms, offices, warehouses, etc.

 For automation, sensors can be used to control entrance doors, windows, safes, sensors for fire alarms, short circuits in the mains, etc.

 Actuators can be electric locks, switches for a fire extinguisher, sirens, devices for listening to the room, etc.

 The telephone network with its equipment has unique capabilities to transmit discrete information from one subscriber to another.

These features are as follows:
1. Between two telephone sets (SLTs), a communication line (voice cable) is established, which is used to transmit discrete information [1, 2]
2. Prior to the establishment of this line, the PBX inductor transmits call signals to the called subscriber after dialing the subscription number, and the call confirmation signals, the number of which are the same [3, 4]
3. An established conversational loop using the TA dialer breaks for 60 ms and closes again for 40 ms, and the number of gaps corresponds to the dialed number. In this case, the formed loop is saved.

 All these possibilities are perfectly realized by the dispatcher (operator) when manually typing the considered discrete information on any type of SLT.

 But in the telephone network there is no equipment for generating this information at an automated facility in the absence of an operator, and there is no equipment for receiving and decoding.

 In the known system [2], button TA was used for these purposes, with additions of a number of blocks and devices that provide its interface with sensors, actuators, and a subscriber line, which makes it possible to form a conversational channel between the object and the control center, transmit reports and receive encoded commands telephone code. But in the telephone network, most subscribers are equipped with SLTs with disk dialers. These subscribers cannot be included in the control and management system.

 Using the above telephone network capabilities in the interests of monitoring and managing automated objects allows you to implement new functions in the system that are not available in existing systems of a similar class.

Close in technical essence in the proposed system is a control system for controlling the transfer of commands over telephone lines [2] selected as a prototype
The system contains telephone sets TA1, TA2, with push-button dialers, in the memory cells of which the corresponding subscriber number codes, reporting commands, the first and second control units 3, 4, the first and second decoders 5, 6, the indication unit 7, the interface unit 8 and telephone button simulations, control object 9, call receiving unit 10, telephone receiver simulating and lifting unit 11, first and second telephone code receiving units 12, 13, central telephone exchange 14, intermediate telephone exchange 15, terminal telephone exchange 16, subscriber line 17 and connector Line 18.

 Block 8 pairing and simulating the buttons of the telephone contains a block 19 for receiving signals of control and control commands, a block 20 for receiving signals from the control unit and block 21 for receiving signals from the control object.

 The system provides the transmission of all types of information by telephone codes through breaks and closures of the voice loop between TA1 and TA2. The system operates in transmission and reception of control commands and reports.

 In the first mode, the dispatcher picks up the telephone from the SLT and, using the buttons, selects the cell where the subscriber number code of the corresponding object is recorded. This number is transmitted to the PBX 14, from which the circuit is switched to the PBX 16, which sends call signals to the TA2 using the inductor. These signals are received by the call receiving unit 10, which, through the tube lifting simulation unit 11, simulates picking up the handset from TA2. Between TA1 and TA2 a line is formed (conversational loop), streamlined by direct current U 4 B, which is fixed by control unit 4. The latter brings the receiver 13 signals of the telephone code and the decoder 6 in readiness for receiving information. The dispatcher, using the TA1 keyboard buttons, selects the control command code from the corresponding memory cell, which transmits TA2 by breaking and shorting the loop, where the code is received (block B) and decrypted (block 6).

 The control signal from the decoder output through the control command signal reception unit 19 will turn on the actuating element of the control object 9, after executing the command from the control object 9, a signal will be transmitted to the pairing and simulation unit for pressing the TA buttons 8, which will switch the selection circuit from the memory of the corresponding report code. By this time, the control unit 4 will turn off the receiving devices, after which the selected code will be transmitted to TA1, where the first telephone code signal receiving unit 12, the first decoder 5 and the first control unit 3 will receive and decode the message code. A signal will appear at the corresponding output of the decoder, which on the display unit 7 will record the content of the received information. The dispatcher, having received the report, puts the handset on TA1, which will lead to the destruction of the formed line, control units 3, 4 will bring the system to its original (standby) state.

 The second mode of operation begins when one of the sensors for monitoring parameters at the control object 9 is triggered. The signal from the object enters the interface unit 8, which will switch the circuit for selecting the subscriber number of the control room and the reporting code for this situation. At the same time, the signal is supplied to the call signal receiving unit 10, which, through the tube lifting simulation unit 11, will switch the corresponding circuits. The included control unit activates the circuit for selecting the subscriber number, which will be transmitted to the PBX 16. A line is formed to the PBX 14, the inductor which sends a call to TA1. The controller will pick up the TA1 handset, which will lead to the formation of a spoken loop between TA1 and TA2. This fact will be fixed by the control unit 4, which uses the generated reporting code selection chains. This code will be transmitted to TA1, where it will be received and decrypted in the same way as in the case of receiving a report on the execution of a control command. After the analysis of information displayed on the display unit, the dispatcher places the handset on the TA1, the conversation loop circuit is broken, which will bring the system to its original (standby) state.

The system has the following disadvantages:
1. Automatic transmission of emergency reports is carried out only from an automated facility to a permanent dispatch center; there is no possibility of transmitting information between management facilities.

 2. Transmission of request commands and control commands is carried out by the operator only from the telephone of the control room an automated facility, the receiving devices of which are not protected from the reception and execution of commands generated by an outsider outside the control room.

 The present invention is aimed at solving the problem of automatic transmission of emergency reports between any two of n automated objects included in the system, as well as providing the ability for the operator to transmit the request and selection-protected control commands from any telephone sets located both at the control objects and for them outside, including from the payphone.

 This is achieved by the fact that in the monitoring and control system for automated objects over telephone networks, consisting of a first automated object containing a first telephone set, a first control unit, a first continuous monitoring circuit, a first keyboard equivalent unit, a first decoder, a first receiver of telephone indication codes, series-connected automatic telephone exchanges and a second automated facility containing a second telephone, a second control unit, a second circuit is not interrupt control, a second keyboard equivalent unit, a second decoder, a second telephone code receiver, a first call receiving unit, a first sensor unit and a first actuator unit, wherein the first inputs and first outputs of the first and second control units are connected to the first outputs and first inputs, respectively respectively, the first and second receivers of telephone codes, the second outputs of which are connected to the first inputs of the first and second decoders, respectively, the second inputs of which are connected to the second output by the first and second control units, respectively, the third outputs are connected to the first inputs of the first and second keyboard equivalent blocks, respectively, the second inputs of which are connected to the first outputs of the first and second continuous monitoring circuits, the input of the second continuous monitoring circuit is connected to the output of the first sensor block, the input the first display unit is connected to the first output of the first decoder, and the first input of the first call receiving unit is connected to the second input of the second control unit, entered into the first and second automated objects, respectively, the first and second switches, the first and second transmitters, the first and second programmable interrupters, the first and second call acknowledgment blocks, and the second call receiving block, the second sensor block, and the second actuator block are introduced into the first automated object and the second display unit is introduced into the second automated object, while the first and second switches are connected respectively to the first and second telephone set and to the corresponding automatic telephone exchange, the first output of the second call receiving unit is connected to the second input of the first control unit, the output of the second unit of sensors is connected to the input of the first continuous monitoring circuit, the output of the second display unit is connected to the first output of the second decoder, the second outputs of the first and second decoders are connected to the inputs of the second and first blocks of actuators, respectively, the first, second and third outputs of the first and second switches are connected respectively to the second inputs respectively the first and second receivers of telephone codes, respectively, to the inputs of the first and second call acknowledgment blocks, respectively, and to the inputs of the second and first call, respectively, whose second inputs are connected to the first inputs of the first and second programmable breakers, the second inputs of which are connected to the second outputs, respectively the first and second continuous monitoring circuits, and the third inputs and outputs are connected respectively to the fourth outputs and third inputs, respectively, of the first and second blocks controls, the fourth, fifth and sixth inputs of which are connected respectively with the outputs of the first and second blocks of acknowledgment of the call, respectively, with the third outputs of the first and second decoder, respectively, and with the first outputs of the first and second blocks of the keyboard equivalent, the second outputs of which are connected to the first inputs respectively, of the first and second transmitters, the inputs of which are connected to the first inputs of the first and second switches, respectively, the second inputs of which are connected to the fifth Exit of the first and second control units, sixth outputs coupled to second inputs of the first and second transmitters and first and second decoders and first and second keyboard units are made equivalent tunable.

 An additional n automated objects (where n 1, 2.M), which are identical to the first and second, can be introduced into the system for monitoring and managing automated objects via telephone networks, and the telephone set of one of the automated objects must be executed with an automatic caller ID.

 Comparative analysis with the prototype shows that the proposed system is characterized by the presence of fundamentally new blocks, namely: transmitters, switches, programmable breakers, call acknowledgment blocks, as well as the implementation of decoders and keyboard equivalent blocks that are tunable, which, together with the presence of new connections between system elements gives reason to assert that the proposed invention meets the criterion of "novelty."

 Comparison of the proposed system with systems of similar purpose shows that in the practice of remote monitoring and control of automated objects over telephone networks there are no technical solutions for managing and monitoring objects from any of them. There are also no solutions that provide the ability to interrogate the state of an object and submit control commands to it from any telephone connected to the telephone network.

The proposed system for monitoring and controlling automated objects over telephone networks, shown in FIG. 1 contains:
the first and second automated objects A, B, interconnected by a chain of series-connected automatic telephone exchanges 1, 2, 3 (ATS 1, ATS 2, ATS 3).

 The first and second automated objects contain, respectively, the first and second telephone sets 4, 5 (TA1, TA2), the first and second switches (com-r) 6, 7, the first and second control units 8, 9, (BU8, BU9) the first and the second display units (BI) 10, 11, the first and second decoders (DS) 12, 13, the first and second receivers 14, 15 of the telephone codes (PTK14, PTK15), the first and second blocks 16, 17 acknowledgment of the call (BTPV), the first and second programmable choppers 18, 19 (PPR), the first and second transmitters 20, 21 (PRD), the first and second continuous monitoring circuit 22, 23 (CSC), he first and second blocks 24, keyboard 25 equivalent (BEC).

 The second and first automated objects also contain, respectively, the first and second blocks 26, 27 of receiving a call (BPV), the first and second blocks 28, 29 of executive elements (IE), the first and second blocks of sensors 30, 31 (DB). Third telephone sets TAZ-32 can be connected to ATS1, ATS3.

 The first inputs and first outputs of the first and second control units 8, 9 are connected respectively to the first outputs and first inputs of the first and second receivers 14, 15 of the telephone codes, respectively, the second outputs of which are connected to the first inputs of the first and second decoders 12, 13, respectively. Second inputs the first and second decoders 12, 13 are connected to the second outputs of the first and second control units 8, 9, respectively, the third outputs of which are connected to the first inputs of the first and second blocks 24, 25 of the equivalent, respectively iatury. The second inputs of the first and second blocks 24, 25 equivalent to the keyboard are connected to the first outputs, respectively, of the first and second continuous monitoring circuits 22, 23, the inputs of which are connected to the outputs of the second and first sensor blocks 31, 30, respectively.

 The inputs of the first and second display units 10, 11 are connected to the first outputs of the first and second decoders, respectively, the second outputs of which are connected to the inputs of the second and first blocks 29, 28 of the actuating elements, respectively. The first outputs of the first and second call receiving units 26, 27 are connected to the second inputs of the second and first control units 9, 10, respectively, the third inputs of which are connected to the outputs of the second and first programmable circuit breakers 19, 18. The first, second, and third inputs of the first and second programmable breakers 18, 19 are connected respectively to the second outputs of the second and first call receiving units 27, 26, respectively, with the second outputs of the first and second continuous monitoring circuits 22, 23, respectively, and with fourth outputs mi, respectively, of the first and second control units 8, 9. The fourth, fifth and sixth inputs of the first and second control units 8, 9 are connected respectively to the outputs of the first and second blocks 16 17 for acknowledging a call, with third outputs of the first and second decoders, respectively, and with the first outputs of the first and second blocks 24, 25 equivalent keyboards.

 The first and second switches 6, 7 are connected respectively to the first and second telephone sets 4, 5 and to their corresponding ATS1 and ATS3. The first, second and third outputs of the first and second switches 6, 7 are connected respectively to the second inputs of the first and second receivers 14, 15 of the telephone codes, respectively, to the inputs of the first and second blocks 16, 17 of the acknowledgment of the call and to the inputs of the second and first blocks, respectively 27, 26 receive a call. The first and second inputs of the first and second switches 6, 7 are connected respectively to the outputs of the first and second transmitters 20, 21 and the fifth outputs, respectively, of the first and second control units 8, 9, the sixth outputs of which are connected to the second inputs of the first and second transmitters 20, respectively , 21.

 The first and second decoders 12, 13 and the first and second blocks 24, 25 of the keyboard equivalent are tunable.

 In FIG. 2 shows the functional diagrams of the first and second continuous monitoring circuits 22, 23 and the first and second programmable circuit breakers 18, 19.

 FIG. 3 contains functional diagrams of the first and second transmitters 20, 21 and the first and second tunable blocks 24, 25 of the keyboard equivalents in conjunction with the call receiving unit 27 (26) and the telephone code receiver 14 (15).

 In FIG. 4 is a functional diagram of a tunable decoder 12 (13) in conjunction with a display unit 10 (11) and an actuator element block 29 (28).

 The monitoring and control system for automated objects over telephone networks (Fig. 1) includes in the control loop from two (A and B) to n (A, B, C) automated objects, one of which currently temporarily serves as a control center. In the monitoring and control mode for a time T, between the dispatch center (for example B) and the facility (A), through the ATS1, ATS2 and ATS3, a channel is formed that ensures the transmission of information, which is manually generated by the operator using the TA2 at the control center, automatically at the facility with appropriate equipment, whose block composition is the same on all objects. The operator establishes the same channel from any TA (TAZ), including from a payphone for interrogation and control of any object (A, B, C).

The continuous monitoring circuit 22, (23) (Fig. 2) for five sensors contains five electronic keys K ₁ K ₅ , five RS triggers T ₁ - T _5, and an OR circuit. Key inputs K ₁ K _{5 are} connected to sensors, when triggered, the corresponding trigger is set to a single position, the key closes and excludes the sensor from further continuous monitoring. Through the OR circuit, an alarm signal is supplied to the control unit.

A single signal from the trigger output opens the corresponding key connected to the output of the shift register RG of the programmable chopper (19). Using the keys K ₁₁ K ₁₅ , the situation is recorded and programmed. This allows, when receiving call signals from the BPV, to carry out the RG shift through input C and interrupt the formation of the PBX of the call parcels (disconnecting the call receiving unit 27 (26) from the LAN) via the OR circuit and the BU 9 and form in in the eighth position, a voice loop (connecting 15 telephone codes to the receiver's LAN while opening the talk key). The subscriber has triggered the appropriate sensor by the number of call confirmation signals (3 - 7), will determine the situation at the facility, and then, if necessary, can send a control command to the facility.

From the outputs of T ₁ ^o CT ₅ when the sensors are triggered, the signal is sent to the keys K ₂₁ K _{25 of the} tunable block 25 of the keyboard equivalent 19 (Fig. 3), which ensures that the telephone code encodes the fact that the sensor was triggered.

PEC 19 (Fig. 3) contains two registers RG ₁ and RG ₂ , keys K ₁ , K ₂ and K ₂₁ ^o CK ₂₇ , CT counter, pulse generator G, two replaceable programming inserts connecting the corresponding outputs of the registers with the electronic dialer of the transmitter 21 .

RG ₁ with a programming insert generates a seven-digit subscriber number for the second object, and RG ₂ generates a telephone reporting code that includes a secret part (cipher) and an information part (conditional sensor number). The subscriber number 2314106, code 31, and the numbers of five sensors 1, 2, 3, 4, 5 are programmed in the presented diagram, so the PEC provides dialing of the subscriber number, the formation together with the transmitters of the conversational channel (loop) between the two objects, and the transmission of the encoding encoded by telephone code.

PEC 19 works in conjunction with a transmitter, which is represented by a standard telephone circuit with a keypad (Fig. 3). It includes a diode bridge, a pulse switch (IR), an electronic dialer, a talk key (PK), a resistor R (equivalent to a talk node) and an OR circuit [4]
Principle of operation:
when the sensor is triggered (for example, N 2), the continuous monitoring circuit will turn on BU9, which will set the circuit to its initial zero state, write 1 through the inputs D to RG, disconnect from the input of the BPV 23, and connect the IR, start the generator G, open the key K1. With a frequency of 1 Hz in RG ₁ , a shift in information begins, at the outputs of RG ₁ , single signals appear alternately, which are transmitted to the electronic dialer of the transmitter, the latter transmits the subscriber number to the exchange using IR.

In the seventh position P, the transmission of the subscriber number will be completed, the BU9 through the switch (P2) in the eighth position RG _{1 will} connect the call confirmation receiving unit and up to the 23 position will control the receipt of the call confirmation signal. If the subscriber number on the mating object is free, then in the 23 position the control unit through the switch (P2) will disconnect the call acknowledgment unit 16 and open the talk key PK. On the transmitting side, a part of the conversational loop is formed. In the 24th position, RG _{1 will be} reset. Key K ₁ will close.

The second part of the voice loop will be formed on the opposite side by means of the subscriber picking up the phone. If this is absent, then the voice loop is formed by the interrupter on the corresponding clock cycle by connecting the telephone code receiver 25 to the LAN. The loop between objects A and B is formed, the control unit opens the key K ₂ , RG ₂ starts to generate a message code, which with the help of the electronic dialer and IR will transferred to the opposite object with double repetition. Repeat is carried out by BU 9 through the input of the dialer (*).

 If the subscriber number is busy, then the control unit 9 implements the repetition of the transmission cycles of the subscriber number. The number of cycles is determined by the counter (in the case under consideration, sixteen repetitions are laid down).

The control and management system for automated objects over telephone networks operates in two modes:
1. Automatic transmission of an emergency report from one object and its reception at another object.

 2. The mode of manual dialing and transmission of the request and control commands at one object and their reception at another object.

 The first mode between object B and object A is implemented provided that BEC 24 of object A encoded the subscriber number TA2 using the insert, and at the object B, the subscriber number TA1. The second insert in BEC 23 and 24 recorded the same protective numbers. Decoding inserts in tunable decoders 13, 14 fixed this protective number.

 On volume A is the operator (object A acts as a control center), object B of the automated object.

Using the switch 6, the operator connected the TA1 to the telephone line; at the facility B, the TA2 is disconnected from the line. At object B, in the DB 30, the sensor N2 was triggered (Fig. 1). The continuous monitoring circuit 23 will turn on the BU9, generate a report code (312) in PEC 25, this situation will be recorded in the programmable chopper 19. The control unit 9 disconnects from the LAN through the BPV 26 switch 7 and connects the transmitter 21. A pulse generator is turned on in the PEC 25, which will ensure sequential recording of the subscriber number of the object A into the electronic dialer of the PRD 21. After transmitting the number by the transmitter 21, the BU 9 will connect the BPPV 17 to the LAN. From the inductor of the telephone exchange to the BPV 27 of the object A, the signals of the call will be received, and to the BPPV 17 to send the confirmation of the call. After hearing a call signal, the operator picks up the telephone receiver, which leads to the termination of the supply of call signals and call confirmation. In TA1, the spoken key will open, at the object B, the BPPV 17 will stop receiving call confirmation signals and through BU9 in the transmitter 21 will turn on the spoken key. Between TA1 and TA2 a conversation loop formed a channel for transmitting discrete information. In equivalent to the TA 25 keyboard, the control unit 9 will close K ₁ and open K ₂ , the pulses from the GI are fed to the input G of the register RG ₂ , which through the coding insert will write the code of the security number 31 and the number of the triggered sensor to the electronic dialer of the transmitter 21 (Fig. 3) 2. Code 312 will be transmitted to object B with a temporary pause twice. The operator, having heard clicks in the TA1 phone, after they have finished, the switch 6 toggles the TA1 off and connects the equipment to the LAN.

 By pressing the “receive” button, the operator connects the telephone code receiver 14 to the LAN. The PTK 14 together with the BU8 transmits to the tunable decoder 13 (Fig. 4) a bit-by-bit code of the security number, which with the help of a decoding insert compares with the same number 31 encoded by it, o than the signal will be supplied to the BU 8, which sends a signal to the DS 12, allowing the decoding of the second part of the report 2 that will result in the illumination in the BI 10 of the LED N 2.

 The control unit 9 of object B will turn off the control unit 21 and break the formed channel, the operator will record information and decide on further actions.

 If the subscriber number is busy in the process of channel formation, the dialing process is carried out the programmed number of times, which is described in the description of the programmable equivalent of SLT.

 If the operator is absent at the control room (object A), then instead of TA1, the equipment of the object is connected to the LAN. In this case, the transmission of the report will not take place, as there is no one to use the information.

 In the case of the presence of operators at both objects, control and management lose their meaning. When the object is changed by the operator, the function of the dispatch point is performed by object B. The mode of transmitting the message and its reception at object B is implemented in a similar way.

 The mode of manual dialing and transmission of the request and control command is carried out by the operator from any TA (TA1, TA2, TA3). In this case, the operator manually (for example, on the TAZ) dials the subscriber number of the object F, on which the sensor N 2 is triggered. The ATC inductor generates the call to object A, and the call confirmation to the TAZ, the number of parcels is monitored by the operator. The first signal is received by the BPV 24, which includes a control unit 8, the last programmable chopper 18, the shift register of which is set to the first position. After receiving four signals, a programmable chopper 18 is triggered, which, through the control unit 8, breaks the circuit for generating these signals. The operator by the number of call confirmation signals (four) determined the number of the triggered sensor (N 2). In this situation, you must give the command N 1 (command code 8).

 The operator again dials the subscriber number of object A, after receiving the next series of four pulses, the programmable chopper 18 is installed in the 8th position, which ensures the sending of a signal to the control unit 8, which disconnects the call receiving unit 24 and connects the PTC 14. The operator dials the number guard number 31 and the command number (8) on the dialer, which will be transmitted and received similarly to the reception and decryption of the reporting code. Only in this case will the actuating element in block 14 work and take the corresponding action on the object.

 Thus, using all two objects in the control loop, they get a personal monitoring and control system for one operator, which can go from object B to object A. When changing the location, the operator on the way can organize a short-term dispatch center at any SL. This became possible only when the codes of the given commands were classified by a protective number, which excludes the inclusion of an unauthorized person in the control loop.

 When you increase the controlled objects from two to n, the system is rebuilt from two-way to group control. Group control makes sense only with the constant presence of an operator at one of the sites selected as a control center. To organize group management, it is necessary to include all objects in the group management and control circuit. For these purposes, by changing the coding inserts on all equivalents of the keyboard, it is necessary to encode the subscriber number of the control room, and at the last install a SLT with an automatic number identifier. This allows any facility in the event of an emergency to establish two-way control with a control room according to the principle described above. The dispatcher, when receiving a call signal by automatic number identification, sets the number of the emergency object. This object implements with the control room two modes of operation discussed above.

 In addition, the system provides for a change in the protective number. For these purposes, it is necessary to change the second coding inserts in keyboard simulators, as well as decoding inserts in all tunable decoders.

 Thus, the control and management system for automated objects over telephone networks has the ability to rebuild the management and interaction structures of objects, which allows the automatic transmission of emergency reports both between any two of a group of n objects, and between one or several objects from the same group.

 In addition, the system provides a control survey and transmission to any object protected from selection of control commands from telephone sets of any type located both on automated objects and beyond, including from payphones.

Sources of information
1. Zinchenko P.A. etc. Control and backup control equipment for automated RTUs. -M. Communication, 1980.

 2. Auth. St. USSR N 1781838, class H 04 M 11/06, 1992 (prototype).

 3. Gubenko N.M. Kuchumov E.V. Telephone sets and payphones. -M. Radio and Communications, 1989.

 4. Bunin S.V. Telephone sets with push-button dialers. -M. Radio and Communications, 1987.

Claims (2)

 1. A system for monitoring and controlling automated objects over telephone networks, consisting of a first automated object containing a first telephone set, a first control unit, a first continuous monitoring circuit, a first keypad equivalent unit, a first decoder, a first telephone code receiver and a first indication unit, in series connected automatic telephone exchanges and a second automated facility containing a second telephone, a second control unit, a second continuous circuit control, a second keypad equivalent unit, a second decoder, a second telephone code receiver, a first call receiving unit, a first sensor unit and a first actuator unit, wherein the first inputs and first outputs of the first and second control units are connected respectively to the first outputs and first inputs, respectively first and second receivers of telephone codes, the second outputs of which are connected to the first inputs of the first and second decoders, respectively, the second inputs of which are connected to the second outputs, respectively of the first and second control units, the third outputs of which are connected to the first inputs of the first and second blocks of the keyboard equivalent, the second inputs of which are connected to the first outputs of the first and second continuous monitoring circuits, the input of the second continuous monitoring circuit is connected to the output of the first sensor block, input the first display unit is connected to the first output of the first decoder, and the first output of the first call receiving unit is connected to the second input of the second control unit, characterized in that the first and second switches, the first and second transmitters, the first and second programmable interrupters, the first and second blocks of acknowledging a call are introduced into the first and second automated objects, respectively, and the second block of receiving a call, the second block of sensors and the second are also introduced into the first automated object a block of actuating elements, and a second indication block is introduced into the second automated object, while the first and second switches are connected respectively to the first and second telephone set and to the corresponding automatic telephone exchange, the first output of the second call receiving unit is connected to the second input of the first control unit, the output of the second sensor unit is connected to the input of the first continuous monitoring circuit, the input of the second display unit is connected to the first output of the second decoder, second outputs of the first and second decoders connected to the inputs of the second and first blocks of actuators, respectively, the first, second and third outputs of the first and second switches are connected respectively to the second input I will give, respectively, the first and second receivers of telephone codes, to the inputs of the first and second blocks of acknowledgment of the call, respectively, and to the inputs of the second and first blocks of the call, the second outputs of which are connected to the first inputs of the first and second programmable breakers, the second inputs of which are connected to the second the outputs of the first and second continuous monitoring circuits, respectively, and the third inputs and outputs are connected respectively to the fourth outputs and third inputs, respectively the first and second control units, the fourth, fifth and sixth inputs of which are connected respectively to the outputs of the first and second blocks of call acknowledgment, respectively, with the third outputs of the first and second decoders, respectively, and with the first outputs of the first and second blocks of the keyboard equivalent, the second outputs of which are connected with the first inputs of the first and second transmitters respectively, the outputs of which are connected to the first inputs of the first and second switches, respectively, the second inputs of which s connected to the fifth output of the first and second control units, sixth outputs coupled to second inputs of the first and second transmitters and first and second decoders and first and second keyboard units are made equivalent tunable.  2. The system according to claim 1, characterized in that an additional n automated objects are introduced (where n 1, 2, M) are identical to the first and second, and the telephone of one of the automated objects is made with an automatic caller ID.

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