RU2029378C1 - Telesignalling system - Google Patents

Abstract

FIELD: guard signalling systems. SUBSTANCE: signalling system provides storage of signals at short-time failures of guard stubs. In order to improve truth of information, the mode of dynamic inspection of serviceability of members of the system is introduced. Units are brought into the circuit which helps to indicate signals of stub disturbances. Signal processing channel units are brought into the system; the units characterize condition of guard stubs as well as commands for taking and rejecting objects of guard. The channel units provide automatic transmission of set commands for new mode of operation, inspection and indication of serviceability of equipment which forms information signals and commands. Members are introduced into the system which provide transmission along the same transmission line which is used for output of telesignals of stubs condition. There is unit for checking of doing of commands ordered in the system. Number of objects under guard, temporal characteristics and other parameters of the system are determined by composition and connections among the units introduced into it: clock pulse generator, the first and the second telesignal detectors units, data processing channel units and parallel/serial code converter. EFFECT: improved truth of information of operation. 6 cl, 6 dwg

Description

 The invention relates to telemechanics systems for burglar alarms and can be used for sporadic and cyclical transmission of signals from sensors characterizing the status of security loops, as well as from sensors corresponding to commands for taking or disarming objects.

 A known system for transmitting and receiving information [1], containing at a controlled (stopping) point an information transmission unit that receives information from sensors, a converter of a parallel sensor status code into a serial, program-time unit for generating control commands and a data transmission unit to a central control point .

 A disadvantage of the known system is the lack of reliability control and memory elements for storing short-term signals, which does not allow its use in alarm systems.

 The closest in technical essence to the proposed one is a device for sporadic transmission of television alarms [2], containing a program-time block, blocks of sensors of television signals, a parallel to serial converter, information inputs of which are connected to the outputs of blocks of sensors of television signals, one output of which is the output "Transmission ”of the device’s data, and one of the inputs is the“ Receive ”input of the device. Such a device provides input of information from sensors, data reliability control by introducing testing equipment that checks the operability of the main elements of the device.

 However, such a device does not provide the ability to automatically send special signals identifying applications for taking and disarming objects, and does not save short-term signals of violation of the normal state of security loops during their transmission to the central point. This reduces the information content of the device and the reliability of the issued information.

 The purpose of the invention is to increase the information content and reliability of the information of the tele-signaling device by introducing channel signal processing units characterizing the state of security loops and issued commands for taking and disarming objects and providing automatic transmission of installation commands for a new operating mode, monitoring and indicating the health of equipment that generates information signals and teams.

 Figure 1 presents a functional diagram of a tele-alarm device; in FIG. 2, 3, 4, 5, and 6, respectively, are diagrams of the program-time block, the first and second blocks of television signal sensors, a channel block of signal processing, and a parallel to serial code converter.

 The device includes a program-time block 1, a first block of 2 sensors of television signals characterizing the state of protected loops, a second block of 3 sensors of television signals corresponding to commands for arming and disarming, a channel block 4 of signal processing and a converter 5 of parallel code to serial .

 The program-time block 1 (Fig. 2) includes a master oscillator 6 of periodic oscillations, a generator of 7 periodic signals forming a group of address signals for the converter 5, and also a series of periodic signals for clocking and gating the operation of all elements and nodes of the device, a timer 8 generating periodic signals with a predetermined time delay relative to the setup signal of the initial state, arriving at the first input of the block, and a shaper 9 clock pulses, generating signals, in-phase relative But the synchronization signal supplied to the second input of the block. These clocks determine the data rate of the communication line.

 The first block 2 sensors of television signals (Fig.3) includes a node 10 security loops, the first 11, second 12, third 13, fourth 14 and fifth 15 switches, the first 16, second 17 and third 18 triggers, distributor 19, counter 20, block 21 OR elements, OR-NOT element 22, first 23 and second 24 EXCLUSIVE OR elements, first 25 and second 26 amplifiers, first 27 and second 28 indicators, element AND 29, delay element 30, first 31, second 32, third 33 and fourth 34 inverters, element OR 35.

 The second block of 3 sensors of television signals (Fig. 4) includes keys 36 and 37 connected in parallel, which respectively fix the arrival of security personnel and an unauthorized opening of the device at the guarded object, the first 38 and second 39-day switches-setters for codes for taking and disarming objects, an encryptor 40, generating arming and disarming signals in accordance with the codes defined for each protected object - the position of the switches 38 and 39. In addition, block 3 contains a block 41 of selection keys, as well as the first 42 and second 43 flip-flops forming the time interval for generating working signals from block 41.

 Channel signal processing unit 4 (figure 5) contains the first 44, second 45 and third 46 triggers, the first 47 and second 48 counters, the first 49, second 50, third 51, fourth 52, fifth 53 and sixth 54 elements AND, OR element -NOT 55, the first 56 and second 57 elements OR, the first 58 and second 59 amplifiers, the first 60 and second 61 indicators, the element EXCLUSIVE OR 62, the first 63 and second 64 inverters.

 The parallel-to-serial code converter 5 (FIG. 6) includes first 65, second 66 and third 67 triggers, first 68 and second 69 counters, multiplexer 70, first 71, second 72, third 73 and fourth 74 OR elements, first 75, second 76, third 77 and fourth 78 AND elements, pulse shaper 79, amplifier 80, indicator 81, fifth AND element 82.

 In the above example, the implementation of the device shows one channel block 4 signal processing, the actual used number of which can be arbitrary. In the example converter circuit 5, the multiplexer 70 is controlled by a group of three address signals from the counter 69, i.e. it can receive up to eight information signals from blocks 4. If necessary, without changing the essence of the device, the number of information signals can be changed.

 In the example implementation of the device, block 3 includes a block of 41 keys for selecting three protected objects, according to which block 2 shows the connection to the device of node 10 for three security loops and the use of a two-bit group of address signals generated by block 1. The number of protected objects can be changed.

 For example, the switching speed of the signals in the communication channel is selected equal to 1 kHz, for which the driver 9 generates signals with a period of 1 ms. The time delay for exiting the protected zone (room) after giving the command to arm the object is set to 1 min, the discreteness of the time delay from the moment of entering the protected zone to the command to disarm the object is taken to be 2 s, the frequency of issuing visual signals during a command was selected to be equal to 1 s, the time delay after a single command was issued until permission to submit a new command was taken to be 16 s. In accordance with this, in the example implementation of the device, the timer 8 generates the indicated periodic signals. If necessary, without changing the essence of the device, the numerical values of the time delays can be changed.

 The triggers used in the units of the device are controlled either asynchronously according to the signals supplied to the input S or R, or synchronously in accordance with the control signal at the input D installed by the time the signal was applied to the pulse input C. In various applications of the triggers in the device, some of the specified input signals not used.

 The counters are installed in the counting mode of the input signals arriving at its first input, in the presence of an enabling signal at the second input. When a signal is applied to the third input, the counter is transferred to its initial state. In different applications - with constant resolution of the account or when there is no need to force the initial state to be set, the second and (or) third counter inputs may not be displayed.

 The multiplexer 70 transmits one of the input signals to the output in accordance with the code signals supplied to the group of address inputs, if there is a signal at the input enable switching. Given that the multiplexer is a symmetrical element, i.e. able to transmit a signal from the input to one of the outputs, it can be used as a switch.

 The device operates as follows.

 The periodic signals of block 1 are used for program-time clocking and gating of the operation of all blocks. So, the signals generated at the sixth and eighth outputs of block 1 are sent to block 4, the signals generated at the first, second, fifth and sixth outputs and the tenth group of outputs are sent to block 2, the signals generated at the fourth and seventh outputs are block 3, the signals generated at the third, fifth, sixth, eighth and ninth outputs, to the Converter 5.

 The signals from blocks 2 and 3 are processed by block 4, which determines the serial code signals generated by the transducer 5 and fed to the "Transmit" output for transmission to the communication line with the receiver.

 The first block of 2 sensors of television signals includes a node 10 security loops, which is a concentrated or dispersed resistance, the value of which determines the state of the protected objects - an increase in resistance over a specified limit is interpreted as a break in the loop, a decrease as shorting it. Together with an additional capacitor C, each of these resistances forms an integrating circuit included in the direct signal transmission circuit from the output of trigger 16 through the switch 11 to the second input of setting the trigger to “0”. Since a similar integrating chain with fixed values of and C is included in element 30, connecting the second inverse output of the trigger with the first input of its setting to "1", a periodic signal generator is formed on the basis of trigger 16. The signals generated at the output of the trigger 16 are counted by the counter 20 in the interval when the logical signal "1" from the second output of the distributor 19 is not supplied to its third input to the initial state.

 Due to the fact that the group of address inputs of the switch 11 receives signals from the fifth input of the block, signals from the tenth group of outputs of the block 1, periodically (with a period of changing the combination of signals at the fifth inputs of the block), the output number of the switch 11 connected to its input changes, and therefore with the trigger output 16. Thus, the status of all security loops is sequentially and periodically interrogated.

 The frequency of the generator signals based on trigger 16 is chosen such that, with a limited scan time of one security loop (which determines the response time to violation of the loop), a sufficiently large number of pulses are received at counter 20. In this example, the implementation of the device, the scan time of one security loop is taken to be 2 ms, with half of this time (1 ms) allocated for counting pulses by a counter, the other half for reading and processing recorded data. The number of pulses at the nominal value of the loop resistance R should be approximately 100, i.e. the repetition period of these pulses should be 1/100 ms. The value of capacitance C for a given R is set based on the required pulse repetition period. It is obvious that the essence of the proposed device does not change when choosing parameters that differ from those given for example. So, during the first half-cycle of the signal supplied to the second input of the block, the distributor 19 is held in the “0” state and transmission of signals from the input to the output of the switch 11 is allowed. Counter 20 counts the pulses from trigger 16. In the second half-period of the indicated signal, clock signals are sent to the counter 20 do not arrive, at the same time, the distributor 19 is released and becomes sensitive to clock signals received at its first input from the first input of the block combined with the first output of block 1. It is obvious that the period of the indicated signal to be significantly smaller than the repetition period of the signal on the second input unit. In the given example of the implementation of the device, the repetition period of these signals is taken to be 16 μs, although the period can be any within the specified condition.

The first signal received at the input of the distributor 19 causes the formation of signal "1" at its first output, which allows the transmission of signals from the inputs of the switches 14 and 15 to their outputs. The number of the output to which the signal from the input of the switches 14 and 15 is transmitted is determined by the group of signals at their address inputs, which are equivalent to the signals at the address inputs of the switch 11. Thus, synchronous control of the security loop parameters is provided. If at the indicated moment the signal "1" is fixed at the third output of the counter 20, then the signal "1" is generated at the addressed output of the switch 15, i.e. the “Normal” signal is recorded, if the signal “0” is at the third output of the counter 20, then the “1” signal from the output of the inverter 32 is transmitted to the addressed output of the switch 14, and the “Violation” signal is recorded for the security loop controlled in this time interval. Taking into account the accepted conditions for the given example of the device’s implementation, the nominal number of pulses received at the counter 20 is approximately equal to one hundred, therefore it is most effective to fix the “Norma” signal with the actual number of pulses received at the counter, from 64 to 128, and the “Violation” signal - with the number of pulses (n) 64> n ≥ 128. Based on these considerations, the first, second, third and fourth outputs of the counter 20 correspond to its bits 2 ⁴ , 2 ⁵ , 2 ⁶ and 2 ⁷ .

 The number of combinations of address signals arriving at switches 11, 14, and 15 is chosen one more than the number of security loops. An excessive combination (zero in the given example of the device implementation) is used to check the operability of the block elements. Indeed, since when installing this combination, the real loop is not connected to the switch 11, the pulse frequency from the trigger 16 should be very different from the nominal one, and the signal “0” should be on the third output of the counter 20. When the signal "1" is detected at the zero output of the switch 15, the signal "Failure" is generated, coming from the fourth output of the block to the tenth input of the converter 5. In order to avoid a malfunction with a sharp increase in the frequency of signals from trigger 16 (shorting the security loop), when the signal is fixed " 1 "at the fourth output of the counter 20 from the inverter 31, the signal" 0 "is supplied to the second input of the counter 20 and blocks its sensitivity to the signals at the first input. In this case, the signal at the third output of the counter is "0" - violation of the loop is detected.

 Upon receipt of the second clock signal at the input of the distributor 19, the signal "1" is formed at its second output. With this signal, the counter 20 is set to its initial state, and the distributor 19 is blocked by the signal from the inverter 34 in the installed position until the front of the next signal at the second input of the block, which simultaneously changes the code combination at the address inputs of the switches 11, 14 and 15, i.e. before switching to monitoring the parameters of the next security loop.

 The assembly of elements 12, 17, 18, 22-28 provides the ability to visually control the real values of the security loop parameters. Signals from the eighth input of the block connected to the fifth group of outputs of block 3 are sent to the group of information inputs of the switch 12. Signals from the first, second, and third outputs of the first ten-day switch 38 are connected to these outputs in the example implementation of the device. the loop switch 38 is set to the position of the loop number. Moreover, in the period of time when the combination corresponding to the position set on the switch 38 is applied to the address inputs of the switch 12, the signal “1” arrives at the output of the switch 12, the front of which corresponds to the moment when the pulse counting by the counter 20 is stopped, but its initial state not yet occurred.

 If at the third output of counter 20 the signal is “1”, then at the output of the OR-NOT 22 element is the signal “0”, and the EXCLUSIVE OR 23 and 24 elements in this case are relaying signals from the counter 20. In this case, the triggers 17 and 18 are transferred the signals from the first and second outputs of the counter 20. Through the amplifiers 25 and 26, the signals are transmitted for display by the indicators 27 and 28. With the nominal value of the parameters of the loop being monitored, the indicator 27 should be off, and the indicator 28 should be on, since the counter fixes the nominal number impu Lls. If the loop resistance is below the nominal, then both indicators are off, if higher, both indicators are on.

 With an abnormal value of the parameter of the controlled loop at the third output of counter 20, the signal is “0”, and at the output of the OR-NOT 22 element, the alternation of signals “1” and “0” with a period corresponding to the signal at the third input of the block, which is connected to the fifth output of the block 1. In the given example of the device’s implementation, the signal period at the third input of block 2 is 1 s, therefore, in the considered mode, the signals “1” and “0” at the output of the OR-NOT 22 element follow with a period of 1 s. When the signal "1" is formed at the output of the OR-NOT 22 element, the EXCLUSIVE OR 23 and 24 elements are inverters, that is, they transmit inverse signals from the counter 20 to the triggers 17 and 18. Thus, they change with the period of the signals at the third input of the block to opposite signals at the outputs of triggers 17 and 18, i.e. indicators 27 and 28 are in flashing mode. As you can see, the status of the security loops is identified by the state of the indicators. It is important that the specified control of the security loop parameters can be carried out regardless of whether the object is armed or not.

 Using the node on the elements 13, 21, 29 and 30, dynamic control of the health of the elements of the channel block 4 signal processing is carried out. The request signal supplied to the sixth input of block 2 from the first output of the converter 5, corresponding to the moment of any change in the mode of protected objects, sends signals to the output of the switch 13 through the AND 29 element to the OR 35 element and to the information input of the switch 13, the number of which is determined by the combination of signals at its address inputs, which corresponds to the number of the security loop selected by block 41. The signals from the switch 13 together with the signals from the switch 14 are connected in pairs with the inputs of the block 21 of the OR elements. As a result, in the mode of operation under consideration, the corresponding output of the second group of signals of unit 2, irrespective of the actually fixed parameters of the security loop, receives periodic signals that test the ability of unit 4 to record violations of security loops. The signals from the OR 35 element, coming from the first output of block 2 to the eighth input of block 4, are also used to dynamically control the operability of the equipment, since at this output to the main periodic signal coming from the sixth output of block 1 (with a period of 2 s for considered example of implementation of the device), signals from the And element 29 are mixed in the control mode.

 Consider the operation of the second block 3 of the sensors of television signals (figure 4).

 Using two ten-day switches 38 and 39, up to one hundred combinations can be set, of which combinations corresponding to the “Arming” and “Disarming” signals for each of the objects are randomly allocated by the encoder 40, the signals are sent to the second and third groups of outputs of the block. The number of decade switches can be changed in accordance with the required number of possible code combinations. The signals from the outputs of the switch 38 are also used in the visual control mode of the security loop parameters.

 Block 41 includes individual buttons for each object with switching contacts, forming a sequential chain of the opening contact of one button and the middle output of the adjacent button. The output signals from the fourth group of outputs of the block to the fifth group of inputs of block 4 and the seventh group of inputs of block 2 are removed from the closing contacts of the buttons. The control signal to the input of the chain of these buttons comes from trigger 43. Using the triggers 42 and 43, the time interval from the moment the signal was sent to the third input of the block from the third output of the converter 5 (generated at the time of the command to change the mode of protected objects) until the signal was sent to the first input of the block from the fourth output of block 1. al time should be sufficient to provide the control parameters of any security loop, i.e. must be longer than the scan period of all security loops. In the example implementation of the device, the time interval is taken equal to 32 ms, since it is longer than the polling period of all (three in the given example) security loops.

 According to the signal from the first input of the block, trigger 42 returns to state "0", and trigger 43 is transferred to state "1", which stops the output of signal "1" at one of the outputs of block 41. Trigger 43 returns to state "0" by the signal from the second the input of the block, which is connected to the seventh output of block 1. This creates a time interval during which, after the formation of the command to arm or disarm the object once, the repeated issuance of the command is blocked. This prevents the attempt of unauthorized removal of objects from protection by quick search of code combinations on the switches 38 and 39. In the example implementation of the device, the specified time interval is taken to be 16 s.

 The composition of block 3 includes a key 36, which fixes the arrival of security personnel on the object (to monitor the object or check the status of the device), as well as a key 37, which records the opening of the device. The signal generated using these keys comes from the first output of the block to the seventh input of the converter 5 and leads to the transmission of a special code message to the communication line.

 Channel block 4 signal processing (figure 5) works as follows.

 When the security loop number is selected using block 41, the signal "1" is received from the fifth input of the corresponding block 4 to the input of the And 49 element. If the normal state of the selected security loop is fixed, then the signal "1" from the third group of outputs of block 2 is sent to the second input of the element And 49. In this case, a signal "1" is formed at the output of the element And 49, which goes to the elements And 50 and 51. In accordance with the combination of signals (with the correct set), set using switches 38 and 39, the encoder 40 produces a signal "Take" or “Disarm” the object, by blunt the third or fourth input block on the other inputs of AND gates 50 and 51. On command "Mark" flip-flop 44 is set to "1" when the command "remove" - in the state "0".

 When the state of the trigger 44 changes, a temporary mismatch is established between the states of the triggers 44 and 45, which leads to the formation of the signal "1" at the output of the EXCLUSIVE OR 62 element. This signal from the first output of the block (for generating the request signal) is supplied to the sixth group of inputs of the converter 5, as well as to the input of the OR-NOT 55 element. In this case, the signal for setting the initial state is taken from the counter 47, which in this case is sensitive to the signals received at the seventh input of the block from the second output of block 2. In the formation mode When the request signal is generated, periodic monitoring signals are sent to the seventh and eighth inputs, which lead to the installation (sequentially) of the outputs of counters 47 and 48 of signals “1”. This is a confirmation of the operability of counters 47 and 48 - shapers of the signal of violation of the normal state of protected objects. The further operation of the device is dependent on the results of checking the health of the elements. The signal "1" formed at the output of the counter 48 is set to trigger 45 in the position corresponding to the signal at the output of the trigger 44. In this case, the signal "1" at the output of the EXCLUSIVE OR 62 element disappears, the signal "1" is generated at the output of the OR-NOT 55 element, which counters 47 and 48 are initialized.

 Consider the operation of the unit and the device as a whole in the mode of giving the command to arm the object. After checking the operability of the elements, the triggers 44 and 45 are in the "1" state, the counters 47 and 48 are in the initial state, at the output of the And 52 element, the signal is "0", the release trigger 46, from the first output of the trigger 45, the signal is "1" through the second group outputs is fed to the ninth group of inputs of the Converter 5 for transmission to the communication line of the code sequence of the command. The signal "0", received through the ninth input of the block from the fourth output of the converter 5, blocks the And 54 element, at the same time to the element OR 57 from the tenth input of the block, a periodic signal is supplied through the third output of the converter 5 (in the given example of the device, the signal period is 2 s), which through the amplifier 59 acts on the indicator 61, thereby providing a flashing visual signaling the fixation of the given command and its development by the device.

 The specified mode is stored until the receiver receives confirmation of the receipt of the command, after which the signal "1" is supplied to the ninth input of the block, and the signal "0" to the tenth input. The flashing alarm with indicator 61 stops, because the signal “1” is at the output of the And 52 element, and the signal is also the “1” at the output of the And 54 element, the indicator 61 goes into steady light mode, identifying the setting of the system to arm the object, the object staff can leave it . To avoid the formation of a signal of violation of the normal state of the security loop when personnel leave the facility, trigger 46 is used, which releases the counters 47 and 48 only when a signal arrives at its second input from the second input of the unit connected to the eighth output of unit 1. In the example implementation of the device the time delay for personnel to leave the security facility is 1 min (including the relatively short time for sending a command and receiving confirmation of its acceptance).

 After setting the trigger 46 to state “1”, the counter 47 is sensitive to the signals from the corresponding output of the block of 21 OR elements arriving at the seventh input of the block from the second group of outputs of block 2. In this mode, these signals are equivalent to the output signals of the switch 14, fixing the real value of the parameters security loop. The capacity of the counter 47 can be changed arbitrarily, which allows you to record the violation of the loop when one, two, four or another number of signals from the switch. This number of pulses is set taking into account the required reaction time of the device to a violation and the possibility of short-term violations that do not require their transfer to the receiving point. After the appearance of the signal "1" at the output of the counter 47, the signal from the inverter 63 releases the counter 48, which determines the delay from the moment the violation was detected until the signal was transmitted through the second group of outputs to the ninth input of the converter 5 for transmission to the communication line. The delay value is regulated by the capacity of the counter 48 with a resolution determined by the period of signals arriving at the first input of the counter 48 through the eighth input of the block from the first output of block 2. In the example implementation of the device, the resolution of the delay time is taken to be 2 s.

 After setting the signal "1" at the output of the counter 48, the signal from the inverter 64 blocks the sensitivity of the counter 48 to the input clock signals - the unit is switched to the signal transmission mode of violation of the security loop.

 Consider the operation of unit 4 and the device as a whole in the mode of issuing a command to disarm an object. After checking the functionality of the elements, the trigger 45 is set to the state "0", however, the signal "1" will appear at the output of the And 52 element only if the personnel who issued the command to disarm the object returns the switches 38 and 39 to the "take the object to security. " This ensures secrecy for outsiders of the code combination of disarming the object. The staff identifies the need to return the switches 38 and 39 to the "take protection" position by the flashing alarm of indicator 61, which indicates the reception of the given command. If the personnel does not fulfill the specified requirement, the trigger 46 by the signal at the third input does not turn into the state “0”, the counters 47 and 48 are not blocked, and a security loop violation signal is transmitted to the communication line, since the trigger 46 returns to state “0” by the signal at the second input, it occurs with a delay (equal to 1 min in the given example of the device implementation), significantly longer than the time required for the transmission of the violation signal to the communication line.

 When the personnel fulfills the requirement to return the switches 38 and 39 to the “take protection” position with a signal from the And 52 element, the trigger 46 returns to the “0” state, and the counters 47 and 48 return to the initial state with the signal from the OR-NOT 55 element.

 The personnel must carry out all operations to disarm the object in a time shorter than the delay time set using counter 48. To prevent an unauthorized attempt to disarm the object by sorting through combinations of the position of switches 38 and 39, the signal at the fifth input of the unit is generated discretely with a sufficiently large a delay (equal to 16 s in the above example implementation of the device) after each attempt to issue a command. Upon completion of the command to disarm the object, the indicator 61 turns off, since the “1” signals at both inputs of the OR 57 element disappear. The node on the elements 53, 56, 58, 60 provides the ability to monitor the state of the object using the indicator 60, which can be taken out of the protected zone. If the security loop violation signal is not detected, then signal “1” is sent from the inverter 64 through the OR 56 element to the amplifier 58 and the indicator 60 lights up steadily. If a violation is detected at the output of the And 53 element, a periodic signal is generated, the frequency of which is set by the signal at the first input of the block connected to the sixth output of block 1, and the indicator 60 is put into flashing mode. The extinguished state of the indicator 60 should be interpreted as a malfunction of the device or removal of the supply voltage.

 Consider the operation of the Converter 5 parallel code to serial (Fig.6).

 When any new command is sent from the corresponding channel unit 4 to the sixth group of inputs of the converter, a signal "1" is supplied, which is perceived by the OR 71 element. The output signal of the OR 71 element is fed through the first output of the converter to the sixth input of the block 2 and is used to generate control signals for the health of the elements and through the OR element 72 to the second output of the converter connected to the first input of block 1 (to bring the timer 8 to its initial state) and to the third input of block 3 (to form a temporary and interrupted after a single command).

 The signal from the OR element 72 sets the trigger 67 to position "1", the inverse signal from which through the fourth output of the converter is supplied to the ninth input of block 4, and the direct signal to the inputs of the elements And 76 and 77. Through the elements And 76 and OR 74 in the communication line a periodic signal is transmitted corresponding to the signal from the third output of block 1 to the first input of the converter. This signal is interpreted as a "Warning" signal, fixing the issuance of a new command. The periodic signal generated by the And 77 element corresponds to the signal from the sixth output of block 1 to the third input of the converter; it is used for visual signaling by indicator 81 (through amplifier 80) of the established operating mode. Indicator 81 can be moved out of the protected area. In addition, the signal from the And 77 element through the third converter output goes to the tenth input of block 4 and provides a visual signaling of the set mode by indicator 61. In response to the information received from the receiver, a trigger signal is received through the communication line to the eighth input of the converter, after which the device disappears must transmit a serial code corresponding to the operating mode (taken or disarmed) and the status of the protected objects. The moment of the beginning of the information transfer is fixed by the And element 75, from which the signal goes to the trigger 66. When the trigger 66 is set to the state “1”, the signal from its inverse output through the fifth output goes to the second input of the block 1, by which the shaper 9 is in phase. The signals from the shaper 9 through the ninth output of block 1, they go to the fifth input of converter 5 connected to the first input of counter 69. Counter 69 is unlocked, since signal “1” is removed from its third input from trigger inverse output 66. The combination of output signals from the main output s (first, second, third) counter 69 is fed to the group of address signals of the multiplexer 70, the enable signal for which is generated by the And 82 element. Parallel output signals from the ninth group of inputs of the converter connected to the second group of outputs of all channel blocks 4 are fed to the information inputs of the multiplexer A serial information code is generated at the output of the multiplexer 70, which enters through the OR element 74 into the communication line via the "Transfer" bus. Upon completion of the code transmission, the signal "1" is generated at the additional (fourth) output of the counter 69, which returns to the state "0" trigger 66, which completes one information cycle of the device. To achieve high reliability of reception of each newly issued command, the “Attention” signal is held until the retransmission of information is completed, which is recorded by the appearance of signal “1” at the output of counter 68, which receives clock signals from the output of trigger 66. According to signal “1” from the counter 68 through the OR element 73, the trigger 67 returns to the state "0", completing the signal transmission mode "Attention". The signal from the trigger 67 returns to the state "0" and the counter 68.

 If the communication circuits of the transmitter and receiver are faulty or for another reason that makes it impossible to implement information cycles, trigger 67 returns to state “0” by a signal from timer 8, which arrives at OR element 73 from the ninth output of block 1 through the fourth input of the block.

 Special information cycles are generated by the device if the arrival of security personnel or the opening of the device is recorded. In any of these cases, from the second input of the converter, signal "1" is supplied to the second input of trigger 65, which at the same time is transferred to state "1" along the edge of the signal from the fifth output of block 1. When the trigger 65 is switched to state "1", the shaper 79 forms a pulse signal, which, passing through the element OR 72, leads to the transition of the device into the signal transmission mode "Attention". However, when a response signal is received from the receiver, an enable signal for multiplexer 70 by AND element 82 is not formed - information signals do not enter the communication line. At the same time, signals “1” from the triggers 65 and 66, as well as a signal from the first output of the counter 69 are supplied to the And 78 element. As a result, a periodic sequence of signals with a period half as much as the second is received through the And 78 and OR 74 elements into the communication line the signals at the counter input 69. The indicated sequence is impossible in the normal mode, equivalent to that which would be transmitted in information cycles in the case when all objects were disarmed, but a violation was detected for all security loops. Due to the fact that the signal, identified as a malfunction by an element of block 2, fixing the value of the security loop parameters, from the fourth output of block 2 through the tenth input of the converter goes to the first input (state setting "1") of trigger 65, in this case, to the communication line, as described above, a special sequence is also transmitted, easily decrypted at the reception point (not considered in the description).

 The structure of block 1 (FIG. 2) is completely determined by the structure and time ratios of clock and gate signals adopted for this example of the device implementation. So, given the fact that the minimum gradation of signals from the shaper 7 is (in the above example) 16 μs, the generator 6 provides the formation of periodic pulses with a period of 8 μs. Other periodic signals generated at the first, second, third and fourth outputs of the shaper 7 are created by a chain of counters-divisors into two pulses supplied to them, and the tenth group of output signals is connected to two (for this example implementation of the device) adjacent bits of counters dividers, the combination of signals at the outputs of which varies in accordance with the set monitoring time for each security loop in block 2.

 The timer 8 is made on a chain of counters-dividers into two, which are set to the initial state by a signal from the first input of the block when any command to change the device mode is given. In this example implementation of the device, the timer generates signals with a period of 1, 2, 16 s and 1 min. Shaper 9 is implemented on a chain of two divider counters and generates periodic signals whose frequency corresponds to the selected transmission speed (in the given example of the device implementation, the clock cycle period is 1 ms) of information on the communication line. The numerical values of the signals of block 1 are given only as an example and their variations do not change the essence and method of operation of the proposed device. Thanks to the described construction of the device, it is possible to receive and register information signals corresponding to the real conditions of the protected objects and the established mode of their operation, as well as signals recording the arrival of security personnel or opening the device. This is achieved by increasing the information content of the device. In addition, the device provides automatic control and visualization of the health of the equipment both continuously and in the mode of any new command, thereby increasing the reliability of the transmitted information.

Claims (6)

 1. A TELESIGNALIZATION DEVICE, comprising the first and second blocks of television signal sensors, a program-time block, a parallel-to-serial code converter, one output of which is the “Transfer” output of the device, and one input is the “Receive” input of the device, characterized in that, with In order to increase the information content and reliability, channel blocks of signal processing were introduced into it in the number of protected objects, in each channel block of signal processing and in the parallel code to ten serial converter c, the first block of television signal sensors has four outputs and eight inputs, in the program-time block nine outputs and a group of outputs; the outputs and outputs of the group of each of the channel signal processing units are connected to the corresponding sixth and ninth inputs of the parallel code converter into the serial, first, second, fifth and sixth outputs and outputs of the program-time block group are connected to the first and fourth inputs and fifth inputs of the first sensor block television signals, the sixth and eighth outputs - with the first and second inputs of channel signal processing units, the fourth and seventh outputs - with the first and second inputs of the second block of television signal sensors, third , fifth, sixth, eighth and ninth outputs, respectively, with the first - fifth inputs of the parallel code converter to serial, the first input - with the third input of the second block of television signal sensors and the second output of the parallel code converter to serial, the second input - with the fifth output of the parallel code converter in serial, the first output of which is connected to the sixth input of the first block of television signal sensors, the third and fourth outputs - with the tenth and ninth inputs of channel signal processing units, gray the seventh input - with the first output of the second block of signal sensors, the tenth input - with the fourth output of the first block of signal sensors, the first output of which is connected to the eighth input of the channel signal processing units, the second and third outputs - with the corresponding seventh and sixth inputs of the channel signal processing units, seventh inputs - with the corresponding fourth outputs of the second block of sensors of television signals and with the corresponding fifth inputs of channel blocks of signal processing, the second and third outputs of the second block of sensors the forest signals are connected to the corresponding third and fourth inputs of the channel signal processing units, the fifth outputs to the corresponding eighth inputs of the first block of television signal sensors.  2. The device according to claim 1, characterized in that the program-time block contains a master oscillator, a periodic shaper, a clock shaper and a timer, the first and fourth outputs of the periodic shaper group, the first and fourth timer outputs, the outputs of the clock shaper are accordingly, the first - fourth outputs, group outputs and fifth - ninth outputs of the program-time block, the input of the periodic signal generator is connected to the output of the master oscillator, the first the output is connected to the first input of the pulse shaper, the fourth output to the first input of the timer, the second input of which is the first input of the program-time pulse block, the second input of which is the second input of the pulse shaper.  3. The device according to claim 1, characterized in that the first block of television signal sensors includes a host of security loops made on resistors and a capacitor, five switches, three triggers, a counter, two amplifiers and indicators, a distributor, delay elements, OR, OR - NOT and two EXCLUSIVE OR elements, a block of OR elements, four inverters, the outputs of the first switch are connected to one terminal of the corresponding resistors of the security loop node, the other terminals of the resistors are combined and connected to the first input of the first trigger and from the condenser An inverted output of the first trigger is connected to the second input of the first trigger via the delay element through a delay element, the direct output of the first trigger is connected to the first input of the counter and the information input of the first switch, the address inputs of which group are combined with the address inputs of the group of the second, fourth and fifth switches and are the fifth inputs combined into a block group, the resolution inputs of the second switch, distributor and the input of the third inverter are combined and explicit are the second input of the unit, the output of the third inverter is connected to the enable input of the third switch, the information input of which is combined with the first input of the OR element and is connected to the output of the And element and the output of the OR element is the first output of the unit, the resolution inputs of the fourth and fifth switches are connected to the first output of the distributor , the outputs of the third and fourth switches of the same name are connected in pairs to the corresponding inputs of the block of OR elements, the outputs of which are the “Violation” signal bus and the second outputs, combined into a block group, the information outputs of the fifth switch are the “Norma” signal bus and third outputs combined into a block group, the “Fault” signal output of the fifth switch is the fourth block output, the address inputs of the third switch group are the seventh inputs combined into a block group, the information inputs of the group of the second switch are the inputs of the second and third triggers, the outputs of which, respectively, through the first and second amplifiers are connected to indicators, the second inputs are connected to by the moves of the first and second EXCLUSIVE OR elements, the first inputs of which are combined and connected to the output of the OR-NOT element, the second inputs are connected to the first and second outputs of the counter, the second input of which is connected through its first inverter to its third output, and the third input to the second output of the distributor and through the fourth inverter with its first input, the second input of the distributor is combined with the first input of the AND element and is the first input of the unit, the sixth input of which is the second input, and the first input of the OR element is NOT the third, the second input of the OR element - by the fourth inputs of the block, the fourth output of the counter is connected to the second input of the OR element - NOT, the information input of the fifth switch and through the second inverter is connected to the information input of the fourth switch.  4. The device according to claim 1, characterized in that the second block of television signal sensors contains a group of keys for setting the security loop number, the first and second decade switches, an encoder, the first and second keys, the first and second triggers, the first and second inputs of the first trigger are, respectively the third and first inputs of the block, the inverse output is connected to the first input of the second trigger, the second input of which is the second input of the block, the inverse output is the switching contacts of the first key to set the number of the security loop of the group, the first the movable contact of each of which is connected to the switching contact of the subsequent one, the second fixed contacts of which are combined and are the fourth outputs combined into a block group, the inputs of the decade switches and the first outputs of the first and second keys are combined with the power supply bus, the combined second outputs of the first and second keys are the first output of the block, the address outputs of the decade-long switches are connected to the corresponding inputs of the encoder, the first and second groups of outputs of the encoder are second and third they outputs combined in a block group, the address outputs of the first ten-day switch are fifth outputs combined in a block group.  5. The device according to claim 1, characterized in that each channel signal processing unit contains three triggers, two counters, six AND elements, two OR elements, two amplifiers and indicators, two inverters, an OR element - NOT, an EXCLUSIVE OR element, the fifth and sixth inputs of the block are the inputs of the first element And, the output of which is connected to the first inputs of the second and third elements And, the second input of the second and the first input of the fourth element And are combined and are the third input of the block, the second input of the third element And is the fourth input of the block , the outputs of the second and third elements AND are connected to the first and second inputs of the first trigger, the output of which is connected to the first inputs of the EXCLUSIVE OR element and the second trigger, the output of which is connected to the first input of the third trigger and the second input of the EXCLUSIVE OR element, the output of which is the first output of the block and connected together with the trigger output to the inputs of the OR - NOT element, the output of which is connected to the first input of the first counter, the second input of which and the first input of the second counter are combined and connected through the first inverter inen with the first input of the fifth element And and connected to the output of the first counter, the third input of which is the seventh input of the block, the inverse output of the second trigger is connected to the second input of the fourth element And, the output of which is connected to the first input of the sixth element And and the second input of the third trigger, the third the input of which is the second input of the block, the second input of the second counter is the eighth input of the block, the output is connected to the second input of the second trigger and through the second inverter with the first input of the first OR element and with its third the second input, the second inputs of the fifth and sixth AND elements and the first input of the second OR element are the first, ninth and tenth inputs of the block, respectively, the outputs of the fifth and sixth AND elements are connected to the second inputs of the first and second OR elements, whose outputs are respectively through the first and second amplifiers connected to the first and second indicators, the outputs of the second trigger and the second counter are the information bus of the block and the outputs of the group of the block.  6. The device according to claim 1, characterized in that the parallel-to-serial code converter contains three triggers, two counters, a multiplexer, four OR elements, five AND elements, a pulse shaper, an amplifier and an indicator, sixth inputs combined into a converter group are the inputs of the first OR element, the output of which is the first output of the converter and connected to the first input of the second OR element, the output of which is the second output of the converter and connected to the first input of the third trigger, the second the input of which is connected to the output of the third OR element, the first input of which is the fourth input of the converter, the output of the third trigger is to the first inputs of the second and third elements of And, the second inputs of which are the first and third inputs of the converter, the output of the second element And is connected to the first input of the fourth element OR, the output of the third one is the third output of the converter and is connected to the input of the amplifier connected by the output to the indicator, the inverse output of the third trigger is the fourth output of the converter For and is connected to the first input of the first counter, the output of which is connected to the second input of the third OR element and to the first input of the first trigger, the second, third and fourth inputs of which are the tenth, seventh and second inputs of the converter, the inverse output of the first trigger is connected to the first input the fifth element And, and the output with the first input of the fourth element And, through a pulse shaper with the second input of the second element OR, is the sixth output of the converter and is connected to the first input of the first element And, the inverting input of which is the eighth input of the converter, the output of the first element And is connected to the first input of the second trigger, the second input of which is connected to the fourth output of the second counter, the output is with the second inputs of the first counter, fifth and fourth elements AND, the inverse output is the fifth output the converter and is connected to the input of the second counter, the second input of which is the first and fifth inputs of the converter, the group outputs are with the group of address inputs of the multiplexer, the group of information inputs which th it is the ninth inputs combined in the transmitter group enable input - with the output of the fifth AND gate, the output - to the second input of the fourth OR gate, the third input of which is connected to the output of the fourth AND gate, the third input of which is connected to the first output group of the second counter outputs.

Images