RU2451342C1 - Apparatus for remote monitoring of unauthorised access to secure facilities - Google Patents

Abstract

FIELD: information technology.

SUBSTANCE: apparatus is in form of four functional units - a monitoring unit with a flexible cable, an emitter unit with an optical output connected by the flexible cable to the monitoring unit, a photodetector unit with an optical input, a monitoring and identification signal generator with three light-emitting diodes and four output terminals which are outputs of the device. An alarm signal is generated at the first output terminal for switching on an audio signalling device, and a three-bit binary digital code for identifying the extent of unauthorised access to the secure facility is generated at the second, third and fourth output terminals. Light-emitting diodes provide visual identification of the extent of unauthorised access to the secure facility. The apparatus enables remote monitoring of unauthorised access to a secure facility.

EFFECT: broader functional capabilities of the device and improved operational characteristics.

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Description

The invention relates to the field of optoelectronic alarm systems and is intended for use as a device for remote control of unauthorized access to protected objects.

A device is known that includes a photodetector, first and second threshold elements, an OR gate, an electric oscillator (see RU No. 2051417, IPC ⁶ G08B 13/18, published December 27, 1995).

Such a device has narrowed functional capabilities, as it does not allow remote monitoring and identification of the amount of unauthorized access to such protected objects as, for example, safes with tangible assets, money, confidential documents and rooms without windows with tangible assets, containing for authorized access to There is only one front door.

The closest in technical essence to the proposed solution is a device containing a first photodetector and a first threshold element connected in series, a second photodetector and a second threshold element connected in series, as well as a third threshold element, an electric oscillation generator, a first and second voltage switch, an emitter unit including a series-connected generator of electrical oscillations and an optical emitter, the optical window of which forms the optical output of the emitter unit I, the first and second logical elements OR (see RU No. 2020590, IPC ⁵ G08B 13/18, published September 30, 1994).

However, this device does not allow remote control of unauthorized access (for example, to such protected objects as safes with material values, money, confidential documents and rooms without windows with material values that contain only one entrance door for authorized access) cases where between the protected object and the room in which the central control panel for the protected objects is located there is a hazardous production area or prolonged obstruction (for example, explosive atmosphere from powder dust or vapors of flammable liquids or capital communication facilities that interfere with the organization of the monitoring process of the protected object) through which it is impossible or forbidden from the point of view of safety to lay wires with electric current flowing into them. Those. the lack of the ability in such a device to remotely control unauthorized access to a guarded object significantly limits its functionality.

In addition, this device does not have three additional outputs through which it would be possible to transmit the current values of a three-digit binary digital code for identifying (recognizing) the amount of unauthorized access to protected objects, for example, to a central control panel for further automatic processing of identification results during monitoring simultaneously groups of protected objects using microprocessor control devices. This drawback does not allow to identify the amount of unauthorized access to the protected object, which limits its functionality, and to automate the process of controlling unauthorized access to the protected object, which impairs its performance. Thus, the above disadvantages significantly limit the functionality of the device and impair its performance.

The problem to be solved by the invention is the expansion of the functionality of the device and the improvement of its operational characteristics.

The problem is achieved in that in a device containing a first photodetector and a first threshold element connected in series, a second photodetector and a second threshold element connected in series, as well as a third threshold element, an electric oscillation generator, a first and second voltage switch, an emitter unit including serially connected generator of electrical oscillations and an optical emitter, the optical window of which is the optical output of the emitter unit, the first and second logical OR elements, an inductive sensitive element is introduced, made in the form of an inductor placed on the open end of the ferrite core with a central through hole in its annular groove, and included in the circuit of the oscillatory circuit of the electric oscillation generator, the output of which is connected to the input of the third threshold element, the output which is connected to the control input of the first voltage switch, a control element in the form of a metal plate fixed motionless on the door of the protected object with its side and is installed in the electromagnetic field at the open end of the ferrite core of the inductive sensor, the central through hole of which is installed coaxially with the optical window of the first photodetector located on the closed side of the ferrite core of the inductive sensor, which with the first photodetector based on pyroelectric sensitive element, forms a sensitive element of the device, and the surface of the open torus and the ferrite core of the inductive sensitive element and the surface of the optical window of the first photodetector, directed in the same direction and installed parallel to each other, form the sensitive surface of the device, a single-shot, the input of which is connected to the output of the first threshold element, the output to the control input of the second voltage switch, flexible cable connecting the first terminals of the first and second voltage switches, the second terminals of which are connected to a common "ground" circuit of the device, respectively, with the first and second the first inputs of the emitter unit, the first, second and third selective devices, the inputs of which are connected to the output of the second threshold element, the outputs, respectively, with the first, second and third inputs of the first logical element OR, initialization unit, display unit, first, second, the third inputs of which are connected to the outputs of the first, second, third selective devices, the fourth input - to the output of the installation unit in the initial state, the first and second outputs - respectively, to the first and second inputs of the second of the logical OR element, an inverter whose input is connected to the output of the first OR logical element, the output is to the third input of the second OR logical element, a detachable connection node, while the output of the second OR logical element is the first output of the device for connecting an audible alarm device, and the output the first selective device, the first and second outputs of the display unit, the logical signals of which form respectively the first, second and third bits of a three-digit binary digital code identically cations of the volume of unauthorized access to the protected object are the second, third and fourth outputs of the device, respectively, and the device is structurally made in the form of four functional units, the first of which includes the emitter unit, the second functional unit is the photodetector unit, which includes the second photodetector, the optical window of which is directed towards the optical output of the emitter unit and is the optical input of the photodetector unit, the second threshold element, the first, second, third se lective devices, the first logical OR element, a detachable connection node with their corresponding electrical connections, the third functional node is a driver of control and identification signals, which includes the initialization unit, display unit, the second OR logical element, an inverter with their corresponding electrical connections , the fourth functional unit, which is the control unit, is the rest of the device circuit, and a flexible cable that allows the installation of the control unit at any point inside of the stored object along the perimeter of its doorway and the orientation of the open end of the ferrite core of the inductive sensitive element towards the control element, ensures the installation of the emitter unit inside the space of the protected object in any direction during installation to achieve alignment of its optical output with the optical input of the photodetector unit and thereby ensure remote control and identification of the amount of unauthorized access to the protected object via an optical channel, images optical beam emanating from the optical output of the emitter unit and passing to the optical input of the photodetector unit through an opening made in the wall of the protected object, while the photodetector block and the driver of the control and identification signals are installed outside the protected object, and the control and driver of the signal and driver are installed on the central control panel of the guarded object, in which the photodetector unit and the shaper of control and identification signals are interconnected th through the detachable connection assembly.

Figure 1 presents the functional diagram of the device; figure 2 - diagram of the relative position and orientation of the inductive sensitive element, the first photodetector and the control element of the device; figure 3 is a diagram of a display unit of the device; figure 4 - voltage diagrams explaining the operation of the circuit device.

The device comprises (see FIG. 1) a first photodetector 1 connected in series, a first threshold element 2, a single vibrator 3, a second photodetector 4 connected in series, a second threshold element 5, as well as a third threshold element 6, an electric oscillation generator 7, the first and second keys 8, 9 voltage, the control inputs of which are connected to the outputs of the third threshold element 6 and one vibrator 3, respectively, the emitter unit 10, a flexible cable 11 connecting the first terminals of the first and second voltage keys 8, 9, the second terminals of which x connected to a common "ground" circuit of the device, respectively, with the first and second inputs of the emitter unit 10, an inductive sensing element 12, made in the form of an inductor 13 placed on the open end of the ferrite core 14 with a central through hole in its annular groove, and included in the circuit of the oscillatory circuit of the generator 7 of electrical oscillations, the output of which is connected to the input of the third threshold element 6, the control element 15 in the form of a metal plate, fixed stationary on the door 1 6 of the protected object from its inner side and installed in the zone of influence of the electromagnetic field 17 at the open end of the ferrite core 14 of the inductive sensing element 12, the central through hole of which is mounted coaxially with the optical window of the first photodetector 1, located on the closed end of the ferrite core 14 of the inductive sensitive element 12, which with the first photodetector 1, made on the basis of a pyroelectric sensor, forms a sensor element properties, and the surface of the open end of the ferrite core 14 and the surface of the optical window of the first photodetector 1, directed to one side and installed parallel to each other, form a sensitive surface of the device, the first logical element OR 18, the first, second and third selective devices 19, 20, 21 the inputs of which are connected to the output of the second threshold element 5, the outputs, respectively, with the first, second, and third inputs of the first logic element OR 18, the detachable connection unit 22, the initial setting unit 23 with condition, display unit 24, the first input of which is connected to the output of the first selective device 19, the second and third inputs - to the outputs of the second and third selective devices 20, 21, the fourth input - to the output of the initialization unit 23, the second logical element OR 25, the first and second inputs of which are connected respectively to the first and second outputs of the display unit 24, an inverter 26, the input of which is connected to the output of the first OR gate 18, the output to the third input of the second OR gate 25, the first the output terminal 27 connected to the output of the second logical element OR 25 and which is the first output of the device for connecting the sound alarm device (not shown in Fig. 1), the second output terminal 28 connected to the output of the first selective device 19 and which is the second output of the device, the third the output terminal 29 connected to the first output of the display unit 24 and being the third output of the device, the fourth output terminal 30 connected to the second output of the display unit 24 and which is the fourth output of the device Twa. In this case, the logical output signals of the first selective device 19, the first and second outputs of the display unit 24 form, respectively, the first, second, and third bits of a three-digit binary digital code for identifying the amount of unauthorized access to the protected object.

The device is structurally made in the form of four functional units. The first functional unit includes an emitter unit 10. The second functional unit is the photodetector unit 31, including the second photodetector 4, the optical window of which is its optical input, the second threshold element 5, the first, second, third selective devices 19, 20, 21, the first OR gate 18, the detachable connection unit 22 with their respective electrical connections. The third functional unit, which is the driver 32 of the control and identification signals, includes an initialization unit 23, an indication unit 24, a second OR 25 gate, an inverter 26, terminals 27-30 with their corresponding electrical connections. The fourth functional unit, which is the control unit 33, includes the rest of the device circuit. The flexible cable 11 allows the installation of the control unit 33 at any point inside the guarded object along the perimeter of its doorway and the orientation of the open end of the ferrite core 14 of the inductive sensing element 12 towards the control element 15. Moreover, the flexible cable 11 when mounting the emitter unit 10 provides its orientation inside the space of the protected object in any direction to achieve alignment of the optical input of the photodetector unit 31 with the optical output of the emitter unit 10, which is ensured by the ability to remotely control and identify the amount of unauthorized access to the guarded object through an optical channel that forms an optical beam (not shown in FIG. 1 to ensure compactness of the drawing) coming from the optical output of the emitter unit 16 and passing to the optical input of the photodetector unit 31 through the hole ( figure 1 is not shown), which is made in the wall of the protected object. At the same time, the photodetector unit 31 and the control and identification signal generator 32 are installed outside the protected object, and the control and identification signal generator 32 is mounted on the central control panel of the protected object, in which the photodetector unit 31 and the control and identification signal generator 32 are interconnected via node 22 detachable connection.

The inductive sensing element 12 includes an inductor 13, a ferrite core 14 made in the form of a cup having open and closed ends. On the side of the open end of the cup of the ferrite core 14, a winding of the inductor 13 is installed. At the open end of the cup of the ferrite core 14, when a high-frequency signal is applied to the inductor 13 from the generator 7, a high-frequency electromagnetic field 17 is formed in the airspace. The magnetic flux of this field is closed through the air space between an inner annular protrusion of the cup mounted inside the Central hole of the inductor 13, and an outer annular protrusion of the cup, covering its inner side surface, the outer side surface of the inductor 13 along its perimeter. In this case, a high-frequency electromagnetic field does not occur in front of the closed cup end in air space, since its magnetic flux is closed inside the ferrite core 14 through its continuous layer of ferrite forming the closed end of the cup, i.e. this layer is shielded by the electromagnetic field from the closed end of the ferrite core 14. Therefore, the photodetector 1 installed near the closed end of the cup of the ferrite core 14 does not interact with the electromagnetic field 17 with its metal structural elements and, therefore, does not introduce significant attenuation into the oscillatory circuit of the generator 7, by which is the inductor 13, and does not reduce its quality factor, which, in turn, does not lead to disruption of the oscillations of the generator 7 and nar sheniyu its functioning.

The installation of the photodetector 1 from the closed end face of the ferrite core 14 coaxially with its central hole ensures that the infrared radiation emitted by parts of the body of the unauthorized person through this opening passes through this hole to the protected object, to the optical window of the photodetector 1 only after opening the door 16 of the protected object and only at the moment the control element 15 leaves the electromagnetic field 17.

The photodetector 1 is made, for example, according to a circuit comprising a series-connected pyroelectric sensor in integral design, made on the basis of a pyroelectric sensitive element and a field effect transistor, and an amplifier made on an operational amplifier (see the magazine "Circuitry", No. 1, 2005, p. 47, Fig. 2; Cat No. S21E-3 catalog "Pyroelectric infrared sensor & sensor modules" of the Japanese company Murata, June 2001, p. 7: Murata website www.murata.com).

The generator 7 is made, for example, on the basis of a transistor according to a circuit of an oscillator of electrical oscillations with an inductive three-tone circuit, in which the inductive sensitive element 12 is connected to the circuits of its oscillatory circuit (see the book "PI Vilensky, L. A. Sribner. Contactless limit switches, - M: Energoatomizdat, 1985. - 80 p., Ill. - (Automation Library; Issue 654) ", p. 20, fig. 10, a; p. 38, fig. 25).

The one-shot 3 is made, for example, according to the scheme of a standby multivibrator based on a trigger and a timing RC circuit in the form of a series-connected resistor Rτ and a capacitor Cτ, the resistor Rτ of which is connected to a power source, and their connection point is connected to the trigger R input, at input Ā1 , which is the input of the one-shot, triggering pulses are fed, the inputs Ā2 and B are supplied with voltage levels of logic "1", and the direct output of the trigger is the output of the one-shot 3 (see the book "Shilo V. L. Popular digital circuits: Reference. -M .: Radio and communications, 1987. - 352 p.: Ill. - (Massive radio library. Issue 1111) ", p.188, fig. 1.136 a, b).

The control unit 33 is designed to control the opening of the entrance door of the guarded object and the intrusion of an unauthorized person into it, as well as to generate potential signals at the outputs of the threshold element 6 and one vibrator 3 for switching keys 8, 9, as well as for manipulating the frequency of the multivibrator 35.

The emitter unit 10 is made, for example, according to a circuit (see FIG. 1) containing a multivibrator 35, the first and second inputs of which are respectively the first and second inputs of the emitter unit 10, an LED emitter 36, the cathode terminal of which is connected to a common ground of the circuit of the emitter unit 10, and its optical window is the optical output of the emitter unit 10, a resistor 37, the first output of which is connected to the output of the multivibrator 35, the second output to the output of the anode of the LED emitter 36. The multivibrator 35 is made, for example, according to the scheme (see book " Chickens of digital electronics: In 4 volumes of T.1. Fundamentals of digital electronics on IP. Translated from Dutch. - M .: MIR, 1987. - 334 p., ill. ", 252 p., Fig. 4.84), containing an AND-NOT logic element, the output of which is the output of a multivibrator 35, a resistor connected between the first input and the output of an AND-NOT logic element, the second input of which is connected to a power source, the first capacitor, the first output of which is connected to the first input of the AND element NOT, the second conclusion is to the common "ground" of the multivibrator circuit, as well as the second and third capacitors 38, 39 (see 1), the first terminals of which are connected to the first input of the AND gate of the multivibrator 35, while the second terminal of the capacitor 38 and the second terminal of the capacitor 39 are respectively the first and second inputs of the multivibrator 35, which serve to manipulate the frequency of the pulses generated by it.

The emitter unit 10 is designed to generate voltage pulses U4 (see figure 4) with logical levels of "1" and different three frequencies F1 (see figure 4, time intervals t ₀ -t ₁ , t ₆ -t ₇ on the diagram U4 ), F2 (see Fig. 4, time intervals t ₁ -t ₂ , t ₃ -t ₄ , t ₅ -t ₆ in diagram U4) or F3 (see Fig. 4, time intervals t ₂ -t ₃ , t ₄ -t ₅ in the diagram U4), which are fed to the LED emitter 36 for modulating the optical radiation of the LED emitter 36, the output of which forms the multivibrator output pulses modulated optical beam 35 (1 H is shown for compactness of the drawing) defining an optical channel for transmission of the pulses of the multivibrator 35 to the optical input of the photodetector 31. Moreover, the spectral characteristic of the photodetector 4 and the spectral characteristic of the LED emitter 36 are consistent with each other according to the spectrum of the optical radiation of the LED emitter 36. The flexible cable 11 allows orientation in the space of the optical output of the emitter unit 10 in the direction of the optical input of the photodetector unit 31.

The keys 8 and 9 are designed to manipulate the frequency of the multivibrator 35 by closing the capacitors 38 and 39, respectively, to a common "ground" device.

Each key 8, 9 is made, for example, based on an npn type transistor. Their first conclusions are the conclusions of the transistor collectors, the second conclusions are the conclusions of their emitters, the control inputs are the conclusions of the transistor bases. When both keys 8, 9 are in the open state, the multivibrator 35 generates at its output a packet of voltage pulses U4 (see Fig. 4, time intervals t ₀ -t ₁ , t ₆ -t ₇ ), for example, with a frequency F1, which more frequencies F2, F3. With each closure of the key 8, the multivibrator 35 generates a packet of voltage pulses U4 at its output (see Fig. 4, time intervals t ₁ -t ₂ , t ₃ -t ₄ , t ₅ -t ₆ ), for example, with a frequency F2, which less than frequency F1, but more than frequency F3. With each simultaneous closure of the keys 8, 9, the multivibrator 35 generates at its output a packet of voltage pulses U4 with a frequency F3, which is less than the frequencies F1, F2 (see Fig. 4, time intervals t ₂ -t ₃ , t ₄ -t ₅ ).

The photodetector 4 is made, for example, according to a circuit consisting of a direct current amplifier based on an operational amplifier, a photodiode included in the photodiode mode at the input of the operational amplifier (see the book "M. Aksenenko et al. Microelectronic photodetectors / M.D. Aksenenko, M.L. Baranochnikov, O.V.Smolin. - M .: Energoatomizdat, 1984. - 208 p., Ill. ", P. 83, Fig. 4.11, B), and a transistor emitter follower with an open emitter output whose input is connected to the output of a DC amplifier, and its open emitter output is an output m photodetector. The photodetector 4 is designed to receive from the optical output of the optical emitter unit 10, modulated by voltage pulses U4 with the generation frequencies F1, F2, F3 of the multivibrator 35 of the emitter unit 10.

Each selective device 19, 20, 21 is made, for example, according to the scheme (see Interference-free photo relay, Journal of Radio, No. 11, 1984, p. 58), including a series-connected strip amplifier based on an operational amplifier, inverse the input of which is the input of the selective device, and in its feedback circuit between the output and the inverse input, a parallel oscillatory circuit from the capacitor and inductance coil is connected, a resistor is connected in parallel with the direct input of the operational amplifier connected to a common power supply bus, a detector made according to the scheme of a diode passive converter of amplitude values of alternating voltage to constant with a series-connected rectifier diode with an output load in the form of a parallel RC circuit connected between the rectifier diode anode and a common power supply bus, a threshold element made by a comparator circuit based on an operational amplifier, the output of which is the output of a selective device.

The photodetector unit 31 is intended for receiving, processing optical signals transmitted by the emitter unit 10, and generating voltage pulses U5 with frequencies F1, F2 or F3 (see FIG. 4), which is a “copy” of voltage U4, at the output of the second threshold element 5 the output of the multivibrator 35 of the block 10 of the emitter, as well as for the formation of the outputs of the selective devices 19, 20, 21, respectively, of the logical voltage signals U6, U7, U8 for the driver 32 of the control and identification signals. The installation of the photodetector unit 31 is made in such a way that its optical input is directed toward the optical output of the emitter unit 10.

The display unit 24 (see FIG. 3) is, for example, made according to a circuit including a first LED 40, the output of the cathode of which is connected to the common ground of the display unit 24, the first resistor 41, the first output of which is connected to the anode of the LED 40, and the second its output is the first input of the display unit, the second LED 42, the output of the cathode of which is connected to the common ground of the display unit 24, the second resistor 43, the first output of which is connected to the output of the anode of the LED 42, the OR gate 44, the first and second inputs of which are second and third respectively m inputs of the display unit 24, and its output is connected to the second output of the resistor 43 and is the first output of the display unit 24, the first capacitor 45, the first output of which is connected to the output of the logic element OR 44, trigger 46, the output of which is the second output of the display unit 24, and its R-input is connected to the second output of the capacitor 45 and is the fourth input of the display unit 24, the C-input of the trigger 46 is connected to the second input of the logic element 44, the third LED 47, the cathode output of which is connected to the common ground of the display unit 24, t the first resistor 48, the first output of which is connected to the output of the anode of the LED 47, the second output - with the output of the trigger 46, the second capacitor 49, the first output of which is connected to the connection point of the C-input of the trigger 46 and the second input of the OR gate 44, the second output to R-input of the trigger 46. Using the LEDs 40, 42, 47, the amount of unauthorized access to the protected object is visually identified when one protected object is to be protected using one device. In the case when a group of objects is protected, each of which is guarded by its own separate device, and all devices are connected to a centralized microprocessor control device or a personal computer, along with the visual mode, an automatic control mode is used using the first output of the device with an alarm and the second , the third and fourth outputs of the device with a three-digit binary digital code identifying the amount of unauthorized access to the protected object.

Shaper 32 is used to convert the output signals of selective devices 19, 20, 21 into visual information about monitoring and identification of the amount of unauthorized access to the protected object using the built-in LEDs 40, 42, 47, as well as to generate an alarm signal for output terminal 27 switching on the sound alarm device and generating logic signals at the second and third bits of the three-digit binary digital code for identifying the volume at the output terminals 29, 30 is unauthorized th access to the protected object. In addition, through the shaper 32 is transmitted from the output of the selective device 19 to its output terminal 23 of the logical signal of the first category of a three-digit binary digital code identifying the amount of unauthorized access to the protected object.

The device operates as follows.

When applied at time t ₀ (see Fig. 4) to the device, the supply voltage of the capacitor in block 23 begins to be charged through the base-emitter junction of its transistor, which then opens, and the output of block 23 generates a voltage pulse U1 with a logic level "0", which is supplied through the fourth input of block 24 to the R-input of its trigger 46. As a result, the trigger 46 and, therefore, block 24 is set to the initial state, in which the voltage U11 is set at the second output of block 24 and at terminal 30 of the device logical level sky "0". In this case, the LED 47 is in the quenched state. After the end of the charge of the capacitor of block 23, its transistor closes and does not affect the operation of the device circuit, since its base is connected through a resistor to the common ground of the device circuit. In this case, the generator 7 switches to the mode of disruption of electrical oscillations, since the control element 15, placed in the electromagnetic field 17 of the inductive sensing element 12, introduces a significant attenuation into the oscillatory circuit of the generator 7. As a result, the voltage U2 is set at the output of the threshold element 6 with a logic level of “0”, which is supplied to the control input of the key 8. After that, the key 8 is set to the open state. However, the photodetector 1 is set to a darkened state, and at the output of the threshold element 2 and the input of the one-shot 3, a voltage with a logic level of "1" is set. At the output of the one-shot 3, a voltage U3 is set with a logic level of "0", which is supplied to the control input of the key 9. As a result, the key 9 is set to open state. After the supply voltage is supplied to the device, the multivibrator 35 of block 10 goes into the mode of generating a packet of voltage pulses U4 with logical levels of “1” and frequency F1, which is supplied to the emitter 36. The packet of voltage pulses U4 is transmitted by the emitter 36 through the optical channel to the optical input of block 31. After the photodetector 4 receives this burst of pulses at the output of the threshold element 5, a burst of voltage pulses U5 is formed with a logic level of “1” and a frequency equal to the frequency of generation of the F1 pulses of voltage U4 of the multivibrator 35. Moreover, the packet of voltage pulses U5 with logic levels “1” formed at the output of the threshold element 5 is a “copy” of the packet of voltage pulses U4 with logic levels “1” formed at the output of the multivibrator 35 of block 10 (see Fig. 4, diagrams U4, U5 on the time interval t ₀ -t ₁ ). A pack of voltage pulses U5 with logic levels “1” from the output of the threshold element 5 is fed to the input of the selective device 19, in the strip amplifier of which it is selected, since its strip amplifier is tuned to the frequency F1 of the pulses of the multivibrator 35, while the selection of this a pulse train does not occur in the band amplifiers of the selective devices 20, 21, since they are tuned to the pulse generation frequencies F2 and F3 of the multivibrator 35, respectively, different from its pulse generation frequency F1. Therefore, starting from time t ₀ , at the outputs of the selective devices 20 and 21 during the time interval t ₀ -t ₁ , voltages U7 and U8 with levels of logic “0”, respectively, are supplied to the second and third inputs of logic element 18 and the second and third inputs of block 24. Next, a packet of voltage pulses U5 with logical levels of "1" in the selective device 19 is detected. Then, at the output of the selective device 19, the first input of the logic element 13, the first input of the block 24 and at the output terminal 28 of the device during the time interval t ₀ -t _{1 the} voltage U6 is set with the logic level "1". As a result, the LED 40 in the block 24 is illuminated. Since the voltages U6 and U7, U8 with levels of logical "1" and logical "0" are set at the first and second, third inputs of logic element 18, a voltage with a logic level of "1" is generated at its output, which is fed to the input of the inverter 26 . At the same time, at the output of the inverter 26 and the third input of the logic element 25, a voltage U9 is set with a logic level of "0". Since at the second and third inputs of block 24 and, therefore, at the first and second inputs of its logic element 44 (see Fig. 1, Fig. 3), the voltages U7 and U8 with logic levels of "0" are set respectively, at the first output of the block 24, the first input of the logic element 25 and the output terminal 29 is set to voltage U10 with a logic level of "0", and the LED 42 of the block 24 is in the quenched state. Moreover, the switching of the trigger 46 of the block 24 to another state does not occur, since a voltage U8 with a logic level “0” is applied to its C-input from the output of the selective device 21, confirming its initial state, in which the LED 47 of the block 24 is in the off state. Since the voltages U10, U11, U9 with the logic levels “0” are set at all three inputs of the logic element 25, the voltage U12 with the logic level “0” is set at its output and output terminal 27.

Thus, after supplying the supply voltage, the device is set to its initial state, in which the door 16 of the protected object is in the closed state, and the control element 15 is placed in the electromagnetic field 17 of the inductive sensing element 12, from the optical output of block 10 is transmitted through the optical channel to the optical input block 31 U4 voltage burst to logical levels "1" and the frequency F1 generation of pulses during the time interval t ₀ -t _1, the output terminal 27 is set to the level of voltage U12 log "0’, in which the audible alarm device (not shown in FIG. 1) is turned off, the voltage U6 and U10, U11 are set at the output terminals 23 and 29, 30, respectively, with levels of logical “1” and logical “0”, and in block 24, the LED 40 is in the lit state, the LEDs 42, 47 are in the canceled state. The initial state of the device is the standby mode of its operation, which corresponds to the value of 100 three-digit binary digital code for identifying access to the protected object, or in visual form: LED 40 is in the illuminated state, and LEDs 42, 47 are in the off state.

For example, at time t ₁ the door 16 of the protected object was opened by an outsider. As a result, the control element 15 in the direction of the arrow 34 leaves the zone of influence of the electromagnetic field 17, and the generator 7 switches to the mode of generating electric oscillations, at which the output of the threshold element 6 sets the voltage U2 with a logic level of “1”, which is supplied to the control input of the key 8 . When this key 8 is closed, the capacitor 38 is connected to a common "ground" device. As a result, from time t _{1, the} multivibrator 35 switches over the time interval t ₁ -t ₂ to the mode of generating a packet of voltage pulses U4 with logic levels “1” and frequency F2, which is supplied to the emitter 36. The packet of voltage pulses U4 is transmitted by the emitter 36 via the optical channel to the optical input of block 31. After receiving by the photodetector 4 of this packet of pulses at the output of the threshold element 5, a packet of voltage pulses U5 is formed with a logic level of “1” and a frequency equal to the frequency F2 of generating voltage pulses U4 m ultivibrator 35. Moreover, the packet of voltage pulses U5 with logical levels of “1” is a “copy” of the packet of voltage pulses U4 with logical levels of “1” formed at the output of the multivibrator 35 of block 10 (see Fig. 4, diagrams U4, U5 in the time interval t ₁ -t ₂ ). From the output of the threshold element 5, a packet of voltage pulses U5 with logical levels of “1” is fed to the input of the selective device 20, in the strip amplifier of which it is selected, since its strip amplifier is tuned to the frequency F2 of the generation of pulses of the multivibrator 35, while the selection of this A pulse train does not occur in the band amplifiers of the selective devices 19, 21, since they are tuned to the pulse generation frequencies of the multivibrator 35, respectively, different from its frequency F2. Therefore, at the outputs of the selective devices 19 and 21, starting from time t ₁ , during the time interval t ₁ -t ₂ , the voltages U6 and U8 are set, respectively, with logic levels “0”, which are supplied respectively to the first input of logic element 18, the first input block 24, the output terminal 28 and the third inputs of the logic element 18, block 24. As a result, the voltage U6 with the logic level “0” is set at the output terminal 28, and the LED 40 goes out. Next, a packet of voltage pulses U5 with logical levels of "1" in the selective device 20 is detected. Then, the output of the selective device 20 during the time interval t ₁ -t ₂ sets the voltage U7 with the logic level "1", which is supplied to the second input of the logic element 18 and to the second input of the block 24. Since the second and first, third inputs of logic element 18, voltages U7 and U6, U8 with logical levels of “1” and logical “0” are set, respectively, a voltage with a logic level of “1” is generated at its output, which is fed to the input of inverter 26. As a result, the output of inverter 26 and the third logic input 25 voltage U9 continues to be present with a logic level of "0". Since at the second and third inputs of block 24 and, therefore, at the first and second inputs of its logic element 44 (see FIG. 1, FIG. 3), the voltages U7 and U8 with logical levels of “1” and logical “0” are set respectively , at the first output of block 24, the first input of the logic element 25 and the output terminal 29, a voltage U10 with a logic level of “1” is set, and the LED 42 of the block 24 then switches to the illuminated state. Moreover, the switching of the trigger 46 of block 24 to another state does not occur, since a voltage U8 with a logic level “0” is applied to its C-input from the output of the selective device 21, confirming its initial state, in which the LED 47 of block 24 continues to be in the quenched state . Since the voltages U10 and U11, U9 with levels of logical “1” and logical “0” are set at the first and second, third inputs of logic element 25, voltage U12 with logic level “1” is set at its output and output terminal 27, t .e. an alarm is generated at the output terminal 27. After that, the sound alarm device connected to the output terminal 27 (not shown in FIG. 1) turns on, and an alarm sounds about unauthorized access of an unauthorized person to the protected object. The volume of access of an unauthorized person to the protected object is the opening of the door of the protected object by him without penetrating it into the protected object. This amount of unauthorized access corresponds to the value of a three-digit binary digital code 010 or in a visual form: the LED 42 is in the lit state, and the LEDs 40, 47 are in the canceled state.

Further, when the door of the guarded object is open at time 12, an intruder invades the guarded object by hand if the guarded object is a safe, or it entered inside it, if the guarded object is a storage facility or other room, exposure to infrared radiation occurs, respectively, coming from his hands or from his whole body, the optical window of the photodetector 1. As a result, the threshold element 2 switches to another state in which a voltage with a logic level is set at its output "0", under the action of which the one-shot 3 starts up and the voltage pulse U3 is formed at its output with the logic level "1" (see Fig. 4), which is supplied to the control input of key 9. In this case, key 9 closes, capacitor 39 connects to the common ground of the device. As a result, from time t _{2, the} multivibrator 35 switches over the time interval t ₂ -t ₃ to the mode of generating a packet of voltage pulses U4 with logical levels of “1” and frequency F3, which is supplied to the emitter 36. The packet of voltage pulses U4 is transmitted by the emitter 36 through the optical channel to the optical input of block 31. After the photodetector 4 receives this burst of pulses at the output of the threshold element 5, a burst of voltage pulses U5 is formed with a logic level of “1” and a frequency equal to the frequency F3 of generating voltage pulses U4 m ultivibrator 35. Moreover, the packet of voltage pulses U5 with logical levels of “1” is a “copy” of the packet of voltage pulses U4 with logical levels of “1” formed at the output of the multivibrator 35 of block 10 (see Fig. 4, diagrams U4, U5 in the time interval t ₂ -t ₃ ). A pack of voltage pulses U5 with logic levels “1” from the output of the threshold element 5 is fed to the input of the selective device 21, in the strip amplifier of which it is selected, since its strip amplifier is tuned to the frequency F3 of the generation of pulses of the multivibrator 35, while the selection of this A pulse train does not occur in the band amplifiers of the selective devices 19, 20, since they are tuned respectively to the pulse generation frequencies of the multivibrator 35, different from its frequency F3. Therefore, at the outputs of the selective devices 19 and 20, starting from time t ₂ , during the time interval t ₂ -t ₃ , the voltages U6 and U7 are set, respectively, with logic levels “0”, which are supplied respectively to the first input of logic element 18, the first input block 24, the output terminal 28 and the second inputs of the logic element 18, block 24. As a result, the voltage U6 with the logic level “0” continues to be present at the output terminal 28, and the LED 40 of the block 24 continues to be in the off state. Next, a packet of voltage pulses U5 with logical levels of "1" in the selective device 21 is detected. Then, at the output of the selective device 21, during the time interval t ₂ -t _{3 the} voltage U8 is set with the logic level "1", which is supplied to the third inputs of the logic element 18 and block 24. Since the first, second and third inputs of the logic element 18 voltages U6, U7, and U8, respectively, are set with logical levels of "0" and logical "1", a voltage with a level of logical "1" is generated at its output, which is fed to the input of inverter 26. As a result, the output of inverter 26 and the third input of the logic element 25 install Xia U9 the voltage to the level of logical "0". Since at the second and third inputs of block 24 and, therefore, at the first and second inputs of its logic element 44 (see FIG. 1, FIG. 3), the voltages U7 and U8 with logical levels of “0” and logical “1” are set respectively , at the first output of block 24, the first input of logic element 25 and output terminal 29, voltage U10 is set with logic level “1”, and LED 42 of block 24 remains in the illuminated state. Moreover, the trigger 46 of the block 24 is switched, since a voltage U8 with a logic level “1” is applied to its C-input from the output of the selective device 21, which switches it along the leading edge of the voltage U8 to another state in which the LED 47 of the block 24 is illuminated. Since the voltages U10, U11, and U9 are set at the first, second, and third inputs of logic element 25, respectively, with logic levels “1” and logic “0”, voltage U12 with logic level “1” continues to be present at its output and output terminal 27, those. Alarm terminal 27 continues to be present. After that, the sound alarm device (not shown in FIG. 1) connected to the output terminal 27 continues to be on, as a result, an alarm continues to sound about unauthorized access by an unauthorized person to the protected object. In this case, the volume of access of an unauthorized person to the protected object is the opening of its door 16 and the penetration of an unauthorized person inside the protected object to its contents. This volume of unauthorized access corresponds to the value of a three-digit binary digital code 011 or in visual form: LED 40 is in the canceled state, LEDs 42, 47 are in the illuminated state.

At time t _{3, the} intrusion of an unauthorized person into the guarded object is stopped, but his door 16 remains in the open state. After that, the photodetector 1 is darkened, the threshold element 2 is switched to its original state. As a result, the output of the one-shot 3 sets the voltage U3 with the logic level "0", the key 9 switches to the open state, and the key 8 continues to be in the closed state. In this case, the multivibrator 35 switches to the mode of generating a packet of voltage pulses U4 with a logic level of “1” and a frequency F2 during the time interval t ₃ -t ₄ , which is supplied to the emitter 36. This packet of pulses is transmitted by the emitter 36 through the optical channel to the optical input of the block 31. Reception, detection of this burst of pulses in block 31, generation in block 32 of a three-digit binary digital code for identifying the amount of access to the protected object is identical to that described above for the time interval t ₁ -t ₂ , which corresponds to the value of the specified code, equal to 010, in which the LED 42 of the block 24 is lit, and the LEDs 40, 47 are in the canceled state. Moreover, at time t ₃ according to the decay of the voltage pulse U8 generated at the output of the selective device 21, at the R-input of the trigger 46 of block 24 using the RC circuit, which is formed by the capacitor 49 of block 24 and the resistor of block 23, included in the collector circuit of its transistor , a short voltage pulse U1 is formed (see Fig. 4) with a logic level of "0", which sets the trigger 48 to its initial state, thereby preparing the trigger 46 and, therefore, the device for the next formation cycle during the time interval t ₃ -t ₄ three-digit binary nd digital code identifying the amount of unauthorized access to the protected object.

Next, at time t ₄ there is a repeated intrusion of an outsider into the protected object. In this case, the operation of the device circuit during the time interval t ₄ -t _{5 is} identical to its operation described above for the time interval t ₂ -t ₃ in which the first intrusion of an unauthorized person into the guarded object took place. The amount of unauthorized access to the guarded object is the opening of its door 16 and the penetration of an unauthorized person inside the guarded object and its contents, which corresponds to the value 011 of a three-digit binary digital code identifying the volume of unauthorized access to the guarded object, or in visual form: LED 40 is in the canceled state, and the LEDs 42, 47 are in the lit state.

Then, at time t _{5, the} repeated intrusion of an unauthorized person into the guarded object is terminated, but his door 16 remains open. In this case, the operation of the device circuit during the time interval t ₅ -t ₆ is identical to its operation described above for the time interval t ₁ -t _{2 to} which the amount of unauthorized access to the protected object corresponds to the opening of its door without intrusion of an outsider into the protected object and the value 010 a three-digit binary digital code identifying the amount of unauthorized access to the protected object or in a visual form: the LEDs 40, 47 are in the canceled state, and the LED 42 is in the lit state. Moreover, at time t _5, according to the decay of the voltage pulse U8 generated at the output of the selective device 21, at the R-input of the trigger 46 using the RC circuit, which is formed by the capacitor 49 of block 24 and the resistor of block 23, included in the collector circuit of its transistor, is formed a short voltage pulse U1 (see figure 4) with a logic level of "0", which sets the trigger 46 to its original state, thereby preparing the trigger 46 and, therefore, the device for the next formation cycle during the time interval t ₅ -t ₆ , three-digit binary qi rovogo identification code volume unauthorized access to the protected object.

Next, an outsider at time t ₆ closes the door 16 of the protected object. At this moment, on the decline of the voltage pulse U10 generated at the first output of block 24, at the trigger R input: 46 using a RC circuit, which is formed by the capacitor 45 of block 24 and the resistor of block 23, included in the collector circuit of its transistor, a short pulse is formed voltage U1 (see figure 4) with a logic level of "0", which sets the trigger 46 to its original state. As a result, the device passes during the time interval t ₆ -t ₇ to the initial state, which is described above after the supply voltage to the device. The initial state of the device is the standby mode of its operation, which corresponds to a value of 100 three-digit binary digital code identifying the amount of unauthorized access to the protected object or in a visual form during the time interval t ₆ -t ₇ : LED 40 is in the illuminated state, and LEDs 42, 47 - in a canceled state.

The above describes the operation algorithm of the device for remote control of unauthorized access to a guarded object, which can be, for example, stationary safes or rooms. But the proposed device also implements control of unauthorized access to the protected object, which may be, for example, a portable type safe. This is achieved as follows. Installation of the device in such a portable guarded object is carried out in the same way as in a stationary guarded object. For this, the standby mode of its operation implemented in the device is used. If during operation of the device in standby mode there was a short interruption of the optical channel of the device between the emitter unit 10 and the photodetector unit 31, in which for a short time at the same time:

- there was a transition of the LED 40 in block 24 from the illuminated to the canceled state and vice versa;

- there was a change in the value of 100 three-digit binary digital code to the value of 000 and vice versa;

- there was a short-term switching on and off of the audible alarm device (not shown in Fig. 1) connected to the output terminal 27, this means that during standby operation of the device there was unauthorized access to the control zone of the protected object of an unauthorized person, which when crossing the optical the beam of the emitter unit 10 blocked it for a short time.

If, during the operation of the device in standby mode, the optical channel of the device was interrupted for a long time, as a result of which it was simultaneously;

- there was a long time the transition of the LED 40 in the block 24 from the exposed to the canceled state;

- a change in the value of 100 three-digit binary digital code for a value of 000 occurred for a long time;

- an audible alarm device was turned on for a long time (not shown in Fig. 1) connected to the output terminal 27, this means that a portable protected object was stolen, as a result of which the alignment of the optical output of the emitter unit 10 and the optical input of the unit 31 photodetectors for an indefinitely long time. As a result, in the time interval after time t ₇ (see Fig. 4), the outputs U5, U6, U7 are set respectively at the outputs of the threshold element 5, selective devices 19, 20, 21, block 24 and the outputs of the inverter 26, logic element 25, U8, U10, U11 and U9, U12 with logical “0” and logical “1” levels, respectively. Those. the volume of unauthorized access to the protected object in the form of theft at the output terminals 28, 29, 30 of the device corresponds to the value of a three-digit binary digital code equal to 000, or in the visual form: the LEDs 40, 42, 47 of block 24 are in the canceled state, and at the same time an alarm sounds in the buzzer connected to output terminal 27.

From the description of the operation of the device it follows that the implementation in the device of remote control of unauthorized access to the protected object expands its functionality. The introduction of a three-digit binary digital code into the device expands the functionality and improves its operational characteristics, since the device provides automation of the process of identifying the amount of unauthorized access to protected objects during group control, as well as identifying the amount of unauthorized access to the protected object and its dynamics in two ways - with using a three-digit binary digital code and visually using the LED indicators installed in block 24 of the display.

Moreover, a visual method for identifying unauthorized access to a protected object is recommended when only one object is to be protected, in which a three-digit binary digital code is not used. The method using a three-digit binary digital code for identifying the amount of unauthorized access to the protected object is recommended to be applied in the case of protecting a group of objects when it is necessary to automate the group control process with unauthorized access to the protected objects by pairing the outputs of each group of devices with a microprocessor control device for this process as described above the algorithm.

Thus, the proposed device in comparison with analogues has significant advantages - enhanced functionality and improved performance.

At the same time, the implementation of the device circuit with the use of semiconductor and (or) hybrid technologies for the manufacture of microcircuits will significantly reduce its overall dimensions, material consumption, constructively perform in the form of four small-sized and economical units and further improve its operational characteristics, as well as ensure minimum cost performance.

Claims (1)

A device for remote control of unauthorized access to protected objects, comprising a first photodetector and a first threshold element connected in series, a second photodetector and a second threshold element connected in series, as well as a third threshold element, an electric oscillation generator, a first and second voltage switch, an emitter unit including serially connected generator of electrical oscillations and an optical emitter, the optical window of which is the optical output of the radiation unit atelier, first and second logical elements OR, characterized in that an inductive sensitive element is introduced into it, made in the form of an inductor placed on the open end of the ferrite core with a central through hole in its ring groove, and included in the oscillator circuit of the electric generator oscillations, the output of which is connected to the input of the third threshold element, the output of which is connected to the control input of the first voltage switch, the control element in the form of a metal plate ina, fixed motionlessly on the door of the protected object from its inner side and installed in the electromagnetic field at the open end of the ferrite core of the inductive sensitive element, the central through hole of which is mounted coaxially with the optical window of the first photodetector located on the closed end of the ferrite core of the inductive sensitive element which, with the first photodetector, made on the basis of a pyroelectric sensitive element, forms an identifying element of the device, and the surface of the open end of the ferrite core of the inductive sensitive element and the surface of the optical window of the first photodetector, directed to one side and installed parallel to each other, form a sensitive surface of the device, a one-shot, the input of which is connected to the output of the first threshold element, the output to the input control of the second voltage switch, a flexible cable connecting the first terminals of the first and second voltage switches, the second terminals of which are connected to the common ground of the device circuit, respectively, with the first and second inputs of the emitter unit, the first, second and third selective devices, the inputs of which are connected to the output of the second threshold element, the outputs, respectively, with the first, second and third inputs of the first logical element OR, block initialization, display unit, the first, second, third inputs of which are connected to the outputs of the first, second, third selective devices, the fourth input is to the output of the installation unit to the initial state, first the second outputs, respectively, to the first and second inputs of the second OR gate, an inverter whose input is connected to the output of the first OR gate, the output to the third input of the second OR gate, a detachable connection node, while the output of the second OR gate is the first output devices for connecting a sound alarm device, and the output of the first selective device, the first and second outputs of the display unit, the logical signals of which form respectively the first, second and t these bits of a three-digit binary digital code identifying the amount of unauthorized access to the protected object are the second, third and fourth outputs of the device, respectively, the device being structurally made in the form of four functional units, the first of which includes the emitter unit, the second functional unit is the photodetector unit, which includes a second photodetector, the optical window of which is directed towards the optical output of the emitter unit and is the optical input of the pho receiver, the second threshold element, the first, second, third selective devices, the first logical OR element, a detachable connection node with their corresponding electrical connections, the third functional node is a driver of control and identification signals, which includes the installation unit in the initial state, the display unit, the second OR gate, the inverter with their corresponding electrical connections, the fourth functional unit, which is the control unit, is the rest of the device circuit, and the flexible cable allows The installation of the control unit at any point inside the guarded object along the perimeter of its doorway and the orientation of the open end of the ferrite core of the inductive sensitive element towards the control element ensures the orientation of the emitter unit inside the guarded object in any direction during installation to achieve alignment of its optical output with optical input of the photodetector unit and thereby ensuring remote monitoring and identification of the volume of unauthorized about access to the protected object through the optical channel formed by the optical beam coming from the optical output of the emitter unit and passing to the optical input of the photodetector block through an opening made in the wall of the protected object, while the photodetector block and the driver of control and identification signals are installed outside the protected object moreover, the installation of the shaper of control and identification signals is performed on the central control panel of the protected object, in which the photodetector unit and Vatel control and identification signals are interconnected via a detachable connection node.

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