RU2679180C1 - Method of security monitoring of the location section by cutting reflectometric means of detection - Google Patents

Abstract

FIELD: physics.SUBSTANCE: invention relates to security monitoring methods of a terrain site by means of a discontinuous reflectometric detection means (DM) and can be used in cases of signaling cover of a site of terrain with discontinuous DM, determining the distance to the point of microwire breakage (MW). Method consists in ensuring the transmission of alarms (TA) from the DM to the system for collecting and processing information (SCPI) in the event of a break by the intruder MW; determining the waiting time for a second TA to arrive, depending on the distance between the outer lines and the minimum possible speed of the violator; transfer, together with two consecutive MWs from the DM to the SCPI, of the lengths of the parts of the MW that are connected to the DM; use of the algorithm for determining the movement direction (MD) of the offender.EFFECT: technical result of the invention is the ability to determine the direction of motion of the detected intruder using only one DM.1 cl, 6 dwg

Description

The invention relates to methods for security monitoring of a site with a breakaway reflectometric means of detection (CO) and can be used in cases of signaling cover of a site with a breakdown CO that determines the distance to the point of breakage of a microwire (MP) based on the scatterometry method.

The success of the detention of the offender on the ground depends on the knowledge of the response forces of the direction of its movement. Therefore, considerable attention is paid to the signaling cover of a site with the possibility of determining the direction of movement. As a rule, the protection of sites several hundred meters long or more is carried out by mobile quickly deployable COs with an extended linear part. For example, CO, which determines the distance to the place of MP breakage on the basis of the reflectometric method [1]. In the event of a MT breakdown, such a CO transmits an alarm signal to the information collection and processing system (SSOI), response forces upon arrival at the site take readings of the length of the remaining connected to the MP MP (the location of the MT breakage) from its indicator to clarify the location of the violation. That is, in the current practice of security monitoring using the considered JIs, the length of the remaining connected MP (the place where the MP is broken) indicated by them is used by the response forces only to determine the place of the break [2].

There is a method of security monitoring of a site with a break-off reflectometric RM, consisting in the deployment of a single RM in a straight line and connecting it to the RM; ensuring the transmission of an alarm signal from the SD to the SSOI in the event of an interruption by the intruder MP; determination of the length of the remaining part of the MP connected to it; the arrival of the response forces to the site and the reading of the length of the remaining part of the MP connected to the CO with its indicator to clarify the location of the violation (Fig. 1). [3, 4]

The disadvantage of this method is the inability to determine the direction of movement of the detected intruder.

There is a method of security monitoring of a site with a break-through reflectometric CO, which consists in deploying two COs in two directions on a terrain site in two directions and connecting the MP to the CO; ensuring the transmission of alarm signals from the SD to the SSOI in the event of an interruption by the intruder MP; the application of the algorithm for determining the side of the movement of the intruder according to the sequence of operation of the CO; the arrival of the response forces to the site and taking readings of the lengths of the indicators remaining connected to the CO MP with indicators to clarify the places of violation (Fig. 2). [3, 4]

The disadvantage of this method is the need to use two CO and low information about the movement of the intruder (only the direction of movement is indicated).

The cost of the considered JI with the ability to transmit information to the SSOI is quite high. So, for example, the retail cost of domestic CO - “KSM - OS” is more than 27 thousand rubles [5]. Therefore, reducing the number of CO used for security monitoring of the area is economically feasible.

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

To achieve this goal, a security monitoring method has been developed for a site of the terrain and a break-off reflectometric detection tool, which consists in deploying MP CO on the terrain at three lines so that the intruder crosses them sequentially when moving around the terrain; first connecting to the CO line located between two other lines; establishing a distance between the internal and external borders of at least two distances that the intruder can travel through the terrain at maximum speed during the transition of the CO from the alarm mode to the standby mode; ensuring the transmission of alarm signals from the CO to the system for collecting and processing information when the intruder breaks the MP; determining the waiting time for the receipt of the second alarm signal depending on the distance between the external boundaries and the minimum possible speed of movement of the intruder; transmitting along with two successive incoming alarms from the CO to the system for collecting and processing information of the values of the lengths of the parts of the MP remaining connected to the CO; the application of the algorithm for determining the direction of movement of the intruder, in which the direction of movement is defined as a vector connecting the ends of the MP remaining connected to the CO in the MP deployment diagram; the beginning of the vector is the first place of the MT break, the end of the vector is the second place of the cliff (Fig. 3, 4).

The beginning of the movement of the intruder is possible from one of the two sides of the signal line. If the MP is deployed only in two directions, then when the line lying closer to the CO is broken, an alarm signal from the second line will not be received, since the CO remains operational only with the remaining part of the MP connected to it [4]. In turn, in order to determine the direction of motion (to construct a vector), it is necessary to know two locations of the object, set within a certain time. Therefore, MP SO is deployed according to the proposed scheme in three directions. Then, regardless of the direction of movement of the intruder, the number of alarms received at the SSOI from the CO will be two. When one of the two external boundaries breaks along the length of the microwire remaining connected to the CO (S ₁ ), the first location of the object is determined. After the MP breaks off the internal boundary along the length of the microwire remaining connected to the CO (S ₂ ), the second location of the object is determined. The vector connecting the breakage points of the microwire will be the direction of movement of the intruder (Fig. 3, 4).

The cost of MP, which is an enamel wire with a diameter of 1-2 mm, is two orders of magnitude less than the cost of CO itself (300 rubles - 1 km) [6]. Therefore, an approach in which the number of CO is reduced by increasing the length of the MP is economically feasible.

Timely automatic transition of the CO into standby mode from the alarm mode after the first MT breakdown is ensured by the specified distance between the internal and external boundaries of the MP. This distance must be at least two distances that the intruder can travel through the terrain at maximum speed during the transition of the CO from the alarm mode to the standby mode.

where M is the distance between the internal and external boundaries of the MP, m

t - time of transition of the CO from the alarm mode to the standby mode, s.

V _MAX - maximum speed of the intruder on the road, m / s.

The maximum possible speed of the offender is taken on the basis of terrain conditions, this dependence is practically determined, known and confirmed on the basis of experimental studies (Fig. 5). [7, 8]

Also, to eliminate output errors, the maximum waiting time for the second alarm (T _MAX ) is set.

where T is the time between two alarms received from the CO

T _MAX - maximum waiting time for the second alarm, s.

The maximum waiting time for the second alarm is determined by the distance between the internal and external borders and the minimum movement speed of the intruder and is taken with a margin of 1.2. The calculation is made according to the formula:

where V _MIN is the minimum speed of the intruder on the road, m / s.

The minimum speed of the offender is taken on the basis of the terrain, this dependence is practically determined, known and confirmed on the basis of experimental studies (Fig. 5). [7, 8]

The method includes two stages: preparatory and main.

The preparatory phase includes:

1. The deployment of MP according to the established scheme and its connection to the means 1 of detection with a transmitter (Fig. 2, 6).

2. Deployment on the ground of a system for collecting and processing information, including a signal receiver 5, a timer control device 3, a timer 4, a decisive device 6 and a monitor 7 (Fig. 6).

3. Calculation of the maximum value of the time accumulation of alarms (T _MAX ) and loading it into the decisive device 6 (formula 3).

4. Writing to the device 6 the decisive algorithm for determining the direction of movement of the intruder (Fig. 4).

5. The start of the operation of the detection means 1 with the transmitter in standby mode (Fig. 4).

The main stage begins when the offender breaks one of the external borders of the MP, it includes:

1. The transition of the detection means 1 with the transmitter to the alarm mode and its transmission of the alarm signal and the length of the remaining part of the microwire connected to it to the SSOI (Fig. 6).

2. Registration by the receiver 5 of the alarm signal from the detection means 1 with the transmitter, the start of the timer 4 by the timer control device 3, the start of the countdown of the waiting time for the receipt of the second signal, alarm (T) (Fig. 6).

3. Recording the length of the remaining part of the microwire connected to the detection means 1 with the transmitter to the decisive device 6 (Fig. 6).

4. Automatically, the transition of the detection means 1 with the transmitter to standby mode (Fig. 6).

5. Interruption of the microwire breaker at the second (internal) boundary of the MP (Fig. 3).

6 Registration by the receiver 6 of the second alarm signal from the detection means 1 with the transmitter, stopping the timer 4 by the timer control device 3 (Fig. 6).

6. Recording the length of the remaining part of the MP connected to the detection means 1 with the transmitter in the decisive device 6 (Fig. 6).

7. The determination by the algorithm recorded in the decisive device 6 of the direction of movement of the intruder (Fig. 4).

8. Zeroing the timer 4 device 3 timer control. The output of the violation on the monitor 7 (Fig. 6).

The invention is illustrated by graphic materials, which represent:

- FIG. 1 deployment scheme MP in the known method of security monitoring of a site using a single CO

- FIG. 2 scheme of deployment of MP in the known method of security monitoring of a site using two RM

- FIG. 3 scheme of deployment of MP in the proposed method of security monitoring of a site;

- FIG. 4 algorithm for determining the direction of movement of the intruder (decision table);

- FIG. 5 table of the intervals of the speed of the intruder, depending on the terrain;

- FIG. 6 is a structural diagram of the relationship of the devices used in the implementation of the method.

The technical result of the invention is the ability to determine the direction of movement of the detected intruder using only one WITH.

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. Korshnyakov, V.G. Signaling means of protection of local areas: uc. allowance / V.G. Korshnyakov - Kaliningrad: KPI of the FSB of the Russian Federation, 2004 .-- 135 p.

3. 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.

4. Disruptive detection tool "KSM-OS". Passport BAZHK. 425112.002 Substation. - 21 p.

5. On the cost of [Electronic resource] / "Disruptive means of detection." Electron. Dan. - M. "KSM - OS", 2017 - Access mode: http: ///www.stroyportal.ru, free. - The title from the screen.

6. On the cost of [Electronic resource] / “Enameled wire (winding)”. - The electron. Dan. - M "CHIP AND DIP", 2017. - Access mode: http://www.chipdip.ru, free. - The title from the screen.

7. Psarev, A.A. Military Topography: Textbook. - M .: Military Publishing House, 1986 .-- 384 p.

8. Balenko, S.V. Survival School. - M., 1994 .-- 140 s.

Claims (1)

The method of security monitoring of a site with a breakaway reflectometric detection means, which consists in deploying a detection wire on a site of a microwire, which uses a reflectometric method for measuring the length of a microwire, ensuring the transmission of an alarm signal from a detection tool to an information collection and processing system when a microwire breaker breaks, characterized in that the microwire unfolds on the terrain in three directions so that the intruder crosses l frontiers sequentially; a line between two other lines (internal line) is connected to the detection means first; the distance between the internal and external boundaries is set at least two distances that the intruder can go through the terrain at maximum speed during the transition of the detection means from the alarm mode to the standby mode; together with two sequentially incoming alarms from the detection means, the values of the lengths of the parts of the microwire remaining connected to the detection means are transmitted to the information collection and processing system; the detection means after transmitting the alarm goes into standby mode automatically; an algorithm is used to determine the direction of movement of the intruder, in which the direction of movement is defined as a vector connecting the ends of the microwire remaining connected to the detection means in the microwire deployment scheme on the ground; the beginning of the vector is the first place of the breakdown of the microwire; the end of the vector is the second breakage point of the microwire; the maximum waiting time for the second alarm is determined by the distance between the external boundaries and the minimum possible speed of the intruder.

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