RU2695410C1 - Security monitoring method using passive optoelectronic means of detecting infrared range - Google Patents

Abstract

FIELD: security systems.SUBSTANCE: invention relates to security monitoring methods and can be used in applications of one passive optoelectronic device for detection of infrared range (DD) for road signaling control. Proposed method consists in control of road section with one DD with double-beam detection zone (DZ), installed at distance not closer than 5 meters from road and oriented so that axis of double-ray detection zone crossed section of road at angle of not more than 25 degrees at distance of up to 30 meters from agents, section of road length of not less than 10 meters is located in two-beam detection zone, projection on road of second beam of double-ray detection zone would be shorter than at least twice projection to path of first beam of double-beam detection zone, followed by logical processing of pulse sequence of obtained useful signal during DD transition into alarm mode.EFFECT: enabling determination of the direction of movement along the road of the detected intruder using only one DD.1 cl, 7 dwg

Description

The invention relates to methods of security monitoring and can be used in cases of using one passive optical-electronic means for detecting the infrared range for signaling control of the road.

As a rule, the route of the intruder's movement on the ground goes along the existing network of paths and roads. Knowledge of the direction of movement of the intruder by the reaction forces is of great importance, since it allows you to narrow the direction of his search and thereby increase the likelihood of his detection and detention [1]. Therefore, considerable attention is paid to the signal cover of the network of paths and roads. For this task, passive optoelectronic infrared (CO) detection tools with a long detection zone (ZO) of the intruder up to 50 meters are widely used. As a rule, COs used as part of signaling systems (Radium-DBK, RSK “Radiobarrier-MF”) do not determine the direction of movement of the detected intruder [2, 3].

There is a method of security monitoring using CO, which consists in installing one CO at a distance of no closer than 5 meters from the road; transition of the detection means to alarm mode when the intruder crosses his two-beam AO; recording WITH a useful signal during the whole time it is in alarm mode; ensuring registration by the system for collecting and processing information (MTR) of an alarm signal from the CO when the SC crosses the intruder moving along the road (Fig. 1) [4].

There is another way of security monitoring, consisting in the installation of two CO at a distance of no closer than 5 meters from the road; transition of CO to the alarm mode when the intruder crosses its AO; recording WITH a useful signal during the entire time each person is in alarm mode; ensuring registration of SSOI of alarms from CO when crossing the AO by an intruder moving along the road, using an algorithm for determining the direction of movement of a detected intruder according to the order of receipt of alarm signals from CO (Fig. 2) [4].

The disadvantage of the first specified method of security monitoring is the inability to determine the direction of movement of the detected intruder.

The second specified method of security monitoring has the ability to determine the direction of movement of the intruder, however, for its implementation it is necessary to use two RMs.

The aim of the invention is to obtain the ability to determine the direction of movement along the road of the detected intruder using only one WITH.

To achieve this goal, a method of security monitoring using a passive optical-electronic infrared detection device has been developed, which consists in monitoring the road section with one CO with a two-beam AO installed at a distance of no closer than 5 meters from the road and oriented so that the axis of the two-beam detection zone intersects the site roads at an angle of no more than 25 degrees at a distance of up to 30 meters from the vehicle itself, a road section with a length of at least 10 meters was located in a two-beam detection zone, tions on the way the second beam two beam detection zone was shorter by at least twice the projection on the road first beam two beam detection zone; transition of CO to the alarm mode when the intruder crosses his two-beam AO; recording WITH a useful signal during the whole time it is in alarm mode; determining the CO of the direction of movement of the intruder along the road in relation to the duration of the pulse of the useful signal generated by the second to the duration of the pulse of the useful signal generated by the second: the intruder moved along the road from the CO if the pulse duration of the useful signal generated by the first is less than the duration of the pulse of the useful signal generated by the second, the intruder moved along the road to CO if the pulse duration of the useful signal generated by the first is longer than the pulse duration of the useful signal, sf rmirovannogo second; transmission of CO with a system for collecting and processing information (SSOI) together with an alarm signaling information about the direction of movement of the intruder along the road (Fig. 3).

It is known that the principle of operation of passive optoelectronic detection means is based on the registration of signals generated by the heat flux emitted by the intruder [5].

It is known that the sensitive element CO (pyrodetector) consists of two differentially included half-segments (first and second) forming a difference system [5]. These segments, in conjunction with the optical system, form a cone-shaped ZO WITH consisting of two rays (Fig. 4). The width of a two-beam ZO CO a few meters from CO (F) is tenths of a meter, closer to the middle of a two-beam ZO CO (F ') about 0.6 meters (Fig. 4). When the intruder enters the beam of the ZO, a positive potential is formed on the corresponding half-segment of the pyroelectric receiver. Due to the fact that the segments are connected differentially, the resulting useful signal from the pyroelectric receiver is determined:

where S (t) is the useful signal of the pyrodetector, μV;

S1 (t) is the signal formed on the first half segment of the CO pyrodetector, μV;

S2 (t) is the signal formed on the second half segment of the CO pyrodetector, μV.

The shape of the useful signal is two pulses with different polarity. In the known security monitoring methods, the projections of the AE rays onto the road are practically equal, since the axis of the two-beam AO intersects the road at an angle close to a straight line. Therefore, the pulse duration of the useful signal generated when the intruder moves through these projections will also be almost equal.

It is proposed to deploy the SO so that the length of the projection onto the road of the second beam of the DA (L _K ) is at least two times shorter than the length of the projection onto the road of the first ray of the DA (L _D ) (Fig. 3, 4).

where L _K is the length of the projection of the second beam of the two-beam DA on the road (short), m;

L _D - the length of the projection of the first beam of the two-beam DA on the road (long), m

For this, it is necessary to place the SO not closer than 5 meters from the road and orient the axis of its two-beam DA so that it crosses the road at a distance of 30 meters from the SO at an angle of no more than 25 degrees (Fig. 3).

Then, it is technically possible to determine with high reliability the direction of movement of the intruder along the road relative to the CO (from the CO or to the CO) according to the ratio of the pulse width of the useful signal generated by the first to the pulse duration of the useful signal generated by the second during the deployment of CO (Fig. 3):

- the duration of the pulse of the useful signal generated by the first is less than the duration of the pulse of the useful signal generated by the second, - the intruder first crossed the projection of the second beam of the DZ on the road L _K , then crossed the projection of the first beam of the DZ on the road L _D , respectively, moved along the road from CO (Fig. . 3, 5):

where t ₁ is the pulse duration of the useful signal generated first, s;

t ₂ - pulse duration of the useful signal generated by the second, s.

- the duration of the pulse of the useful signal generated by the first is greater than the duration of the pulse of the useful signal generated by the second, - the intruder first crossed the projection of the first beam of the CZ on the road L _D , then crossed the projection of the second beam of the CZ on the road L _D , respectively, moved along the road to CO (Fig. . 3, 6):

The alarm signal and information on the direction of movement of the intruder relative to the CO (from the CO or to the CO) are transmitted by the SSOI.

The security monitoring method using a passive optical-electronic infrared detection means includes two stages: preparatory and main.

Preparatory stage:

1. Deployment near the road according to the established JI scheme, which includes: an optical system 3, a pyroelectric receiver 4, an amplifier 5, an alarm driver 6, an alarm interface 7, a memory device 8, a decisive device 9 (Fig. 3, 7).

2. Writing to the device 9 the decisive algorithm for determining the direction of movement of the intruder relative to CO (Fig. 7, 7).

3. The beginning of the work of CO in standby mode.

The main stage begins when the intruder moves along the road and enters the two-beam AOR, it includes:

1. The formation of the useful signal by the pyroelectric receiver 4, the amplification of the signal by the amplifier 5 and the signal input to the shaper 6 of the alarm signals (Fig. 7).

2. The formation of the alarm by the driver 6 alarms and the recording device 8 of the memory pulses of the useful signal generated by the pyroelectric receiver.

3. Comparison by the device 9 of decisive pulse duration of the useful signal generated by the first with the pulse duration of the useful signal generated by the second, and determining the direction of movement of the intruder relative to the CO.

4. The transmission of CO through the interface 7 of the alarm signal and information about the direction of movement of the intruder relative to the CO system 10 for collecting and processing information (Fig. 7).

5. Reception by the system 10 of collecting and processing information from the interface 7 of signaling information and determining the direction of movement of the intruder along the road (Fig. 7).

6. Zeroing the device 6 memory (Fig. 7).

The invention is illustrated graphic materials, which are presented on:

- FIG. 1 is a deployment diagram of one passive optoelectronic detection means in a known method;

- FIG. 2 is a deployment diagram of two passive optoelectronic detection means in a known method;

- FIG. 3 is a deployment diagram of a passive optoelectronic detection means in the proposed method;

- FIG. 4 is a diagram of a detection zone of a passive optoelectronic detection means (top view);

- FIG. 5 is a form of the useful signal coming from the pyroelectric receiver when the intruder moves from the detection means;

- FIG. 6 is a form of the useful signal coming from the pyroelectric receiver when the intruder moves toward the detection means;

- FIG. 7 is a structural diagram of the relationship of the devices used when implementing the security monitoring method.

The technical result consists in obtaining the ability to determine the direction of movement of the detected intruder along the road using only one CO.

Information sources

1. Shumov, V.V. The use of mathematical methods and models to substantiate decisions on the protection of the state border: Scientific and practical manual. - Part 2. - M .: Education, 1996. - 196 p.

2. Quickly deployed complex "Radium - DBK". Operation manual USDP.425149.001RE - Penza: UMIRS, 2013. - 41 p.

3. RSK "Radio barrier-MF." Operation manual PMEK.424242.9000RE - M.: Polyus-ST, 2011. - 65 p.

4. Marshalov, T.A. Technical means of border protection: textbook / T.A. Marshalov, A.V. Gustov, I.M. Potapov. - Kaliningrad: KPI of the FSB of the Russian Federation, 2009 .-- 568 p.

5. Magauenov, R.G. Burglar alarm systems: the basics of theory and construction principles: study. allowance / R.G. Magauenov - M .: Hot - Telecom, 2004 .-- 367 p.

Claims (1)

A security monitoring method using a passive optical-electronic infrared detection device, which consists in installing one detection device at a distance of no closer than 5 meters from the road; transition of the detection means to the alarm mode when the intruder crosses his two-beam detection zone; recording means useful signal detection during the entire time it is in alarm mode; ensuring registration by the system of collecting and processing information of the alarm signal from the detection means at the intersection of the two-beam detection zone by an intruder moving along the road, characterized in that the detection means is oriented so that the axis of the two-beam detection zone intersects the road at an angle of no more than 25 degrees at a distance of up to 30 meters from the facility itself; a section of the road with a length of at least 10 meters was in the two-beam detection zone; the projection onto the road of the second beam of the two-beam detection zone was shorter than at least twice the projection onto the road of the first ray of the two-beam detection zone; the detection means determines the direction of movement of the intruder along the road in relation to the pulse width of the useful signal generated by the first to the pulse duration of the useful signal generated by the second; the pulse duration of the useful signal generated by the first is less than the pulse duration of the useful signal generated by the second — the intruder moved along the road from the detection means; the pulse duration of the useful signal generated by the first is greater than the pulse duration of the useful signal generated by the second — the intruder moved along the road to the detection means; the detection tool transmits information on the direction of movement of the intruder along the road to the information collection and processing system.

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