RU133643U1 - SYSTEM OF PROTECTION AGAINST UNAUTHORIZED PERMISSION TO A PROTECTED PROTECT - Google Patents

Abstract

A system of protection against unauthorized entry into a protected object, the executive body of which contains an emitter of directional incoherent optical radiation of the visible range in the form of repetitive in time and constant in amplitude pulses with a fixed repetition rate corresponding to the α-rhythm of the human brain, and the duration corresponding to the time of inertia of the organs of vision person, characterized in that the executive body is equipped with a device for controlling the brightness level of the light-forming element from a directional incoherent optical radiation beam as part of the driving element and an electronic control generating unit connected to its output, the driving element being made as a background brightness meter in the area of the directional incoherent optical radiation emitter, and the electronic control driving generating unit is configured to provide the brightness level of the light-forming element of the emitter directional incoherent optical th emission determined by the relation B = (K + 1), where B and B luminance svetoformiruyuschego transducer element directed incoherent optical radiation and the background, respectively, and K - predetermined value of the luminance contrast.

Description

The utility model relates to devices for preventing unauthorized entry into a protected object.

All currently known devices for protection against unauthorized entry into a protected object contain a sensing organ, which is triggered when an attacker attempts to enter the territory of the protected object, and an executive body. Given the features of the functioning of the executive body, these devices can be divided into passive and active devices with a certain degree of conditionality. A fundamental feature of protection devices against unauthorized entry into a guarded object of active action is that the executive body that is part of them is made with the possibility of direct physical impact on the attacker (object of influence), leading to their loss of ability to perform the target task.

A known system of protection against unauthorized entry into a guarded object [1], capable of counteracting an attacker’s execution of a target using the visible range as pulsed incoherent optical radiation. The executive body of the specified system of protection against unauthorized entry into the protected object, selected as a prototype, is configured to generate incoherent optical radiation in the direction of the object (attacker), the structure of which takes into account the peculiarities of human perception of video information and is, accordingly, a sequence of time-repeated and constant in amplitude pulses of visible radiation, the repetition rate of which corresponds to α- the rhythm of the human brain, the duration of the pulses corresponds to the time of inertia of the human organs of vision, and the magnitude of the brightness level does not exceed the level of blinding brightness.

It should be noted that the human vision function is a multifactorial psychophysiological process of converting primary light excitation into visual sensation (the fact of awareness) and is carried out by the so-called visual analyzer [2]. The visual analyzer consists of three links: peripheral, connecting and central. The peripheral unit is the eye, which is a combination of optical and light-sensing systems, and the light-sensing system of the eye is its retina, filled with photosensitive cells, visual receptors. The central (coordinating and analyzing) link of the visual analyzer is located in the occipital lobe of the cortex of the cerebral hemispheres. The peripheral and central links of the visual analyzer are connected by the optic nerve (connecting link). Visible radiation (light) is perceived and converted by the peripheral link of the visual analyzer into primary electrical impulses, which through the connecting link enter the central link of the visual analyzer and are transformed by them into visual images. Essentially, the visual analyzer functions as a multi-level, self-adjusting system containing direct and feedback connections. In [3, 4, 5], it was pointed out that, firstly, visual images in the human mind do not arise instantly, but with some delay relative to the moment of occurrence or end of light stimulation of the peripheral link of the visual analyzer, and, secondly, electrical activity the central link of the visual analyzer, which is at rest (lack of external light exposure), is characterized by the so-called α-rhythm, which disappears when exposed to light stimuli. The inertia time of the human organs of vision is from 0.05 to 0.2 seconds, and the frequency of oscillations corresponding to the α-rhythm is different for individual human individuals and ranges from 8 to 13 Hz.

It is known [3, 4] that light stimulation of the visual analyzer by a pulsating light stream, the pulsation frequency of which corresponds to the α-rhythm of the human brain, and the duration corresponds to the time of inertia of the organs of vision, leads to a disturbance in the normal state between the processes of excitation and inhibition of the central link of the visual analyzer, which necessarily leads to a loss of orientation of the object of influence and its falling into a state of "aura", which passes into an epileptic seizure, i.e. to the physical impossibility of the object performing the impact of the target. It is quite obvious that the normal functioning of the visual analyzer is possible provided that the visual problem is consistently solved by all three links of the visual analyzer, and primarily by the peripheral link, the normal functioning of which is determined by the energy aspect of the perceived light signal. With visual perception of the light signal, the human eye (the peripheral link of the visual analyzer of the target object) reacts directly to the brightness of the light source forming the light signal in a rather wide range of brightnesses: from 2 × 10 ^-6 cd / m ² (lowest) to 2 × 10 ⁵ cd / m ² (highest or blinding brightness) [4]. The ability of the eye to adapt to different brightnesses of the perceived light signal is called luminance adaptation [4]. Brightness adaptation does not occur instantly, because when changing (increasing) the brightness level of the field of view of the object of influence, a number of mechanisms are automatically turned on, which provide adaptive restructuring of the peripheral link of the visual analyzer. The maximum duration of the process of brightness adaptation of the peripheral link of the visual analyzer with an increase in the level of brightness in the field of view of the target is usually 5-10 minutes. [6]. It should also be noted that the human eye recognizes the object of observation only if its brightness and the brightness of the background on which it is observed do not match. The level of mismatch of these brightnesses is determined by the luminance contrast (k), the value of which is determined by the ratio:

,

,

where B and B _f are the brightness of the object of observation and the background, respectively.

Thus, to ensure the normal functioning of the peripheral department of the visual analyzer for a given value of its contrast sensitivity, it is necessary to optimize the energy characteristics of the object affecting the visual analyzer to the brightness of the background on which it is observed. In some cases, a certain degree of confidence, it can be assumed that the background brightness is comparable to the brightness of the sky, the brightness level of which is [7] varies within wide limits: from 10 ^-5 cd / m ² (luminance night sky) to 1,5 × 10 ³ cd / m ² (clear sky brightness).

From the above it follows that one of the criteria for the effectiveness of the functioning of the device selected as a prototype [1] is the time to achieve the effect of damaging effects on the visual analyzer of the target object (attacker), and the functioning efficiency is higher, the shorter the time period of the brightness adaptation of the peripheral link visual analyzer.

The disadvantage of the system of protection against unauthorized entry into a protected object, selected as a prototype, is the practical impossibility of adjusting the brightness level of the light-forming element of the emitter, which is part of the executive body of the protection system, during its operation when the background brightness (external illumination) changes, which is kind cases inevitably leads to an increase in the time of the onset of the effect of the effect on the central link of the visual analyzer of the object of influence and, therefore, It has the functional effectiveness of a protection system.

The problem the utility model is aimed at resolving this drawback, i.e. in ensuring the maximum possible reduction in the time period of light adaptation of the peripheral link of the visual analyzer of the target object by adjusting the brightness of the light-forming element of the emitter, which is part of the executive body of the protection system, according to the results of continuous monitoring of the background brightness level at a given value of brightness contrast.

The technical result achieved by the implementation of the proposed solution consists, respectively, in increasing the efficiency of the system of protection against unauthorized entry into a protected object by minimizing the time interval before the start of perception of the damaging effect by the central link of the visual analyzer of the target object.

The inventive system of protection against unauthorized entry into a protected object, as well as a protection system selected as a prototype, contains an executive body, which includes an emitter of directional incoherent optical radiation of the visible range in the form of repetitive in time and constant in amplitude pulses with a fixed repetition rate, corresponding to the α-rhythm of the human brain, and the duration corresponding to the time of inertia of the human organs of vision.

The difference between the claimed system of protection against unauthorized entry into the protected object from the prototype is that the executive body is equipped with a device for controlling the brightness level of the network-forming element of the emitter of directional incoherent optical radiation as part of the master element and the electronic block for generating the control action connected to its output, the master element being made in the form of a background brightness meter in the surrounding area in the area of the emitter coherent optical radiation, and the electronic control action generating unit is configured to provide a brightness level of the light-forming element of the emitter of directional incoherent optical radiation, defined by the ratio B = (K + 1) V _f where B and B _f are the brightness of the light-forming element of the emitter and background, respectively, and K is the given value of their brightness contrast.

Figure 1 shows a block diagram of a specific embodiment of the inventive system of protection against unauthorized entry into a protected object. In this particular case, the protection system contains the master 1 and executive 2 bodies. The composition of the master body 1 includes a sensing element and a device for indicating intrusion into the territory of the protected object (not shown in FIG. 1). The design of devices of this type is well known and does not require special explanation. The actuator 2 contains a directional emitter 3 of time-constant and constant in amplitude pulses of incoherent optical radiation, which includes a light-forming element and a power and control unit (not shown in FIG. 1), and a brightness level control device 4 of the light-forming element of the emitter 3 The device 4 includes a driving element 5 and an electronic control action generating unit connected to its output 6. The structure and intensity of the optical radiation generated by the emitter 3 one given radiation inherent in the power and control unit (not shown in Figure 1) program. The principle of operation of the emitter 3 is based on the conversion of electrical energy into optical radiation of a certain structure with its subsequent redistribution into the surrounding space. Various options for the technical implementation of devices of this type are well known. In this particular case, the light-emitting element of the emitter 3 is made in the form of a combination of a pulsed gas discharge lamp, which provides generation of radiation in the visible range (400-760 km), and a light-converting optical system, and the power supply and control unit are made according to the usual scheme applicable for pulsed gas-discharge lamps, those. in the form of a modulation unit for the discharge current of a discharge lamp in frequency. The master element 5 is made in the form of a background brightness meter in the area where the emitter 3 is placed. As such a meter, Argus series radiometers or a TKA-04/3 type bright meter can be used, the operation of which is based on the principle of optoelectronic conversion [8]. The principle of operation of the electronic unit for the formation of control action 6 and the options for its technical implementation of the functional elements forming it are well known and, therefore, in this particular case, no detailed explanation is required.

The inventive system of protection against unauthorized entry into a protected object works as follows. When an intruder penetrates into the range of the sensing element of the master body 1, the device for indicating the intrusion of the body 1 generates a control signal that is fed to the input of the power supply and control unit of the emitter 3 of the executive body 2 and the input of the master element 5 of the brightness level control device 4. Master element 5 (meter brightness) produces an electrical signal proportional to the level of brightness of the background of the surrounding space in the area of the emitter 3. This signal is fed to the input of the electric of the control action generating unit 6, where the control action signal is generated, which, in accordance with the program incorporated in the electronic unit 6, sets the discharge current of the discharge lamp generated by the power supply and control unit of the emitter 3, providing a brightness level of the emitter 3 that exceeds the brightness level background in (K + 1) times, where K is a given level of brightness contrast. At the same time, under the influence of a control signal coming from the output of the master 1 to the input of the power supply and control unit of the emitter 3, a program is launched that is in the power supply and control unit, which determines the structure of optical radiation (pulse frequency and duration) generated by the light-emitting element of the emitter 3. The emitter 3 goes into combat mode and carries out in the direction of the penetrated into the territory of the protected object of the attacker the generation of optical radiation of visible pazona, brightness and structure which takes into account the characteristics of human vision and human perception of video information, which inevitably leads, as has been stated above, the object impacts a failed state. Ensuring maximum effectiveness of the damaging effect on the attacker consists essentially in minimizing the time interval of the luminance adaptation of the peripheral link of the visual analyzer of the target object based on the result of monitoring the background brightness level.

The proposed design allows you to quickly automatically control the level of brightness of optical radiation, which affects the visual analyzer of the target object, which significantly increases the efficiency of the protection system from unauthorized entry into the protected object.

The industrial applicability of the proposed solution is confirmed by the possibility of its multiple reproduction in the production process. The inventive device (protection system) is designed for serial production using standard equipment, modern technology and configuration.

Literature:

1. RF patent for ПМ №103955, G08B 13/18, 04/27/2011 Bull. No. 12.

2. Folb R.L. Fundamentals of visual flashing alarms, Moscow: Engineering, 1964

3. Hubel D. Eye, brain, vision, M.: Mir, 1990.

4. Gvozdeva N.P., Korkina K.I. The theory of optical systems and optical measurements, M .: Mir, 1990.

5. Luizov A.V. Inertia of Vision, Moscow: Oborongiz, 1961.

6. Meshkov VV, Matveev A.B. Fundamentals of Lighting Engineering, Moscow: Energoatomizdat, 1989.

7. Kuhling X. Handbook of Physics, Moscow: Mir, 1982.

8. Eisenberg Yu.B. Reference book on lighting engineering, M .: Znak, 2006.

Claims (1)

A system of protection against unauthorized entry into a protected object, the executive body of which contains an emitter of directional incoherent optical radiation of the visible range in the form of repetitive in time and constant in amplitude pulses with a fixed repetition rate corresponding to the α-rhythm of the human brain, and the duration corresponding to the time of inertia of the organs of vision person, characterized in that the executive body is equipped with a device for controlling the brightness level of the light-forming element from a directional incoherent optical radiation beam as part of the driving element and an electronic control generating unit connected to its output, the driving element being made as a background brightness meter in the area of the directional incoherent optical radiation emitter, and the electronic control driving generating unit is configured to provide the brightness level of the light-forming element of the emitter directional incoherent optical th emission determined by the relation B = (K + 1) _f, where B and _p - brightness svetoformiruyuschego transducer element directed incoherent optical radiation and the background, respectively, and K - predetermined value of the luminance contrast.

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