KR100715986B1 - Method and system for watching a security fence - Google Patents

Abstract

The present invention relates to a method and system for monitoring an optical cable security fence, and precisely detecting an intrusion point in an optical cable security fence, and adjusting a monitoring direction of a surveillance camera to a detected intrusion point to monitor and photograph an intrusion situation. There is an effect that can greatly reduce the equipment and auxiliary facilities of the.

Security fence, optical cable, optical transceiver, contrast table, intrusion point, detection, surveillance camera

Description

Optical cable security fence monitoring method and system {Method and System for Watching a Security Fence}

1 is an enlarged view of a part of an optical cable network

2 is a system diagram of a conventional optical cable network detection system

Figure 3a is a schematic diagram of an optical cable network detection system of the present invention

Figure 3b is another schematic diagram of the optical cable network detection system of the present invention

4 is intrusion detection system of the present invention

<Description of Signs for Main Parts of Drawings>

1: optical cable 2: clip 3: security fence

4: Segment Detection Controller 5. Surveillance Camera 6: Control System

7: optical transceiver 8: first wireless communication unit 9: second wireless communication unit

10: storage 11: monitor 12: input

13: alarm

The present invention relates to a method and system for monitoring an optical cable security fence, and more particularly, to accurately detect an intrusion point in an optical cable security fence and to adjust the monitoring direction of a surveillance camera to the detected intrusion point to monitor and photograph an intrusion situation. The present invention relates to a method and apparatus for greatly reducing equipment such as surveillance cameras and additional facilities.

Security fences are installed in special zones such as military facilities and airports at certain intervals and wire meshes are installed. Security guards and dogs are used to monitor the areas where security fences are installed. However, this traditional method is difficult to trust. This is because people or animals can be inadvertent or go away, and when they become bored, they will not be closely monitored.

To compensate for this problem, optical cables are used in security fences. As shown in FIG. 1, one optical cable 1 is fixed to a wire mesh of a security fence to form a zigzag pattern by using a plurality of clips 2, but an optical cable network is formed, but a space formed by the zigzag pattern can be passed by a person. Make it impossible to size. (The optical cable network is installed on the wire fence of the security fence, but the illustration of the wire mesh is omitted to avoid the complexity of the drawing. The same is also shown in the following drawings.) Due to such a configuration, the intruder cannot intrude without damaging the optical cable (1). As soon as an intruder damages the optical cable (1), it is immediately detected.

2 is a schematic diagram of a conventional optical fiber network sensing system. The security fence is classified into the first section, the second section, the third section, .., and the nth section according to the natural topography such as trees, rivers, rocks, and the like.

As shown in the drawing, the conventional optical cable network detection system installs a section detection controller 4 at each of the start and end points of each section of the security fence 3 and sets the start and end points of the optical cable 1 of the optical cable network of each section. It is connected to the section detection controller 4 installed at the start and end points of each section. In addition, the section detection controller is connected to the control system (6) and the monitoring camera (5).

This conventional optical cable network detection system operates as follows.

When one of the pair of section detection controllers 4 for each section enters an optical signal into the optical cable 1, the optical signal reaches the other section sensing controller 4 via the optical cable network of the section. After that, it is conveyed back to the first section detecting controller 4 via the optical cable network.

If there is no abnormality, the transmission and conveyance of the optical signal is normally performed. However, if an abnormality such as cutting or bending occurs in the optical cable 1 of the optical cable network, the optical signal is first detected at the point where all or part of the optical signal occurs. It is conveyed to the controller 4. The control system 6 detects this through the section detection controller 4 and the surveillance camera 5 photographs the scene. The surveillance camera 5 operates under the control of the section detection controller 4 or the control system 6.

Such a section detection technology has made great progress than the traditional surveillance by surveillance personnel, watch dogs, etc., but it is difficult to respond quickly because only the intrusion section is known and the intrusion point is not known.

In addition, the section detection controller (4) and the surveillance camera (5) and the power supply and lightning prevention facilities for each section of the security fence (3) must be installed, so the time and cost of the installation of such equipment and additional facilities This takes a great deal of time and the system becomes complicated.

If the total length of the security fence (3) is 10 km and the length of each section is 100 m, 200 section detection controller (4) and 100 surveillance cameras (5) should be installed. In addition, a power supply and lightning protection system for the section detection controller 4 and the surveillance camera 5 should be installed.

The present invention is to solve the above problems, by accurately detecting the point of intrusion to adjust the monitoring direction of the surveillance camera to the detected point to monitor and shoot the intrusion situation significantly reduced the equipment and auxiliary facilities such as surveillance cameras It is an object of the present invention to provide a method and apparatus that can be used.

In order to achieve the above object, the present invention calculates the length of the optical cable from the optical transmitting and receiving device to the intrusion point, and calculates the distance of the ground from the start point of the security fence to the intrusion point based on this, and accurately detects the intrusion point. . Then, the monitoring direction of the surveillance camera is adjusted to the detected intrusion point to monitor and photograph the intrusion situation.

First, a system for accurately detecting an invasion point in the present invention will be described. The detection system of the present invention is an optical cable installed in a security fence, a light transmission and reception device (Light Transmission and Reception Device) connected to one end of the optical cable, a control system connected to the optical transmission and reception device, the first security fence is provided on the side A wireless communication device, a second wireless communication device provided on the control system side, and a storage device connected to the control system and storing the length of the optical cable to various points of the security fence and the ground distance respectively corresponding thereto.
In the detection system of the present invention configured as described above, first, the length of the optical cable to each point is calculated from the time required for transmitting and conveying the optical signal, and the ground distance to each point is measured to measure the optical cable to each point. Remember to create a contrast table with the length and distance of the ground. After that, if the optical cable is damaged due to external intrusion, the length of the optical cable to the intrusion point where the optical cable is damaged is calculated and then the ground distance from the start point of the security fence to the intrusion point is calculated from the comparison table.

Hereinafter, a detection system of the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 4, the detection system of the present invention includes an optical cable 1 installed in a security fence 3, an optical transmission and reception device 7 connected to one end of the optical cable, and the optical transmission and reception device 7. A control system 6 connected to the control system, a first wireless communication unit 8 provided on the security fence side, a second wireless communication unit 9 provided on the control system side, and a control system 6 connected to and secured. It consists of a storage device 10 for storing the length of the optical cable to the various points of the fence and the distance of the ground corresponding thereto, respectively.

The control system 6 is connected to a monitor 11, an input device 12, an alarm 13, etc. in addition to the optical transmission and reception device 7 and the storage device 10. The first wireless communication unit 8 is provided inside the security fence, but may be replaced by a mobile device such as a mobile phone. In addition, the second radio communication unit 9 may be provided separate from the control system 6 or may be directly connected to the control system 6.
As shown in Figures 3 and 4 in the present invention, the optical cable 1 is successively installed over several sections from the start point to the end point of the security fence to form an optical cable network. Depending on the terrain, the length of each section of the security fence and the height of the optical cable network may be different, and because the arrangement or density of the optical cable network may be different, the length of the optical cable 1 for each section may be different.
As shown in FIG. 4, one end of the optical cable 1 of the optical cable network is connected to the optical transmission and reception device 7 connected to the control system 6. Here, the optical transmitter and receiver 7 refers to an optical time domain reflectometer (OTDR), a transceiver, or the like.
In the detection system of the present invention, when the optical transmitting and receiving device 7 enters the optical signal at the time of the optical cable 1, the optical signal is returned to the optical transmitting and receiving device 7 after reaching the end point of the optical cable 1. do. The time required for the transmission and conveyance of the optical signal depends on the length of the optical cable 1 to the point where the optical signal is conveyed, and the length of the optical cable 1 is determined from the time required for the transmission and conveyance of the optical signal as follows. Can be calculated
Length of optical cable = required time X speed of optical signal / 2
Where the speed of the optical signal is a known value.
In the normal case, the length of the optical cable thus calculated is the length of the total optical cable 1 from the optical transceiver 7 to the end of the security fence, and in case of intrusion, the length of the optical cable to the intrusion point is shorter than this.
The optical transmission / reception device 7 continuously monitors the time required for transmitting and returning such an optical signal, and judges that the optical cable 1 is in a normal state if the required time is in the standard requirement time category, and the required time is standard. If it is shorter than the time required, it is judged that there is an abnormality.

If the optical cable 1 is damaged due to cutting or bending, the transmission of the optical signal is disturbed and some or all of the optical cable 1 cannot reach the end point of the optical cable 1. Instead, it is conveyed to the optical transmitting and receiving device 7 at the cut or bent point. In this case, the time required for transmitting and returning the optical signal is shorter than the standard time required. In this case, it is determined that there is an error in the optical cable 1 and the control system 6 is notified so that a warning can be triggered.

Warnings are triggered at the moment of intrusion due to the high speed of light and electric circuit, but it is not easy to identify the intrusion point because the length of the security fence monitored by one optical transmitting and receiving device 7 is wide. However, it is important to know the point of intrusion precisely and easily because it is necessary to know the point of intrusion so that it can quickly cope with the intrusion such as photographing the intrusion situation, responding to the intruder, and repairing the optical cable 1.

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In the detection system of the present invention, first, the length of the optical cable to each point is calculated from the time required for transmitting and conveying the optical signal, and the length of the optical cable to each point is measured by measuring the distance of the ground to each point. Remember to create a contrast table with the distance. After that, when the optical cable is damaged due to external intrusion, the length of the optical cable from the time when the optical signal is transmitted and returned to the intrusion point where the optical cable is damaged is calculated, and based on this, from the start point of the security fence to the intrusion point from the comparison table. Calculate the distance of the ground.

Next, a method of preparing a contrast table between the length of the optical cable and the ground distance in the detection system of the present invention will be described. For convenience, the following abbreviation is used.
(A): Ground distance from the start of the security fence to the point of intrusion
(B): length of optical cable from optical transceiver to intrusion point
(C): length of optical cable from optical transceiver to start point of security fence

 First, the first wireless communication unit 8 provided on the security fence 3 side is carried, and the optical cable 1 is bent at some point while moving along the security fence 3, and the fact and the value (A) are controlled by the control system. (6) The second radio communication unit 9 on the side is notified. In addition, as the optical cable 1 is bent, the optical transmission / reception device 7 cooperates with the control system 6 so that the length (B value) of the optical cable from the optical transmission / reception device 7 to the point where the optical cable 1 is bent. Calculate The values (A) and (B) derived as described above are stored in the storage device 10 via the control system 6.

The value (A) may be derived by directly measuring the ground distance from the start point of the security fence to the intrusion point, or may be derived using this function by mounting a GPS (Global Positioning System) on the first wireless communication device (9). It may be. In addition, instead of the value (A), the distance from the specific point (for example, the start point of the third section) to the point where the optical cable 1 is bent may be reported.

In addition, the input of the value (A) to the control system 6 may be input to the control system 6 through the input device 12 after receiving the value (A) through the second wireless communication device 9, It is also possible to connect the second radio 9 directly to the control system 6 so that the received value (A) is automatically entered.
The measurement, transmission and reception of these (A) and (B) values are stable, and at least three times are repeated until there is no error to prepare a contrast table as in the following example.

Section number (A) (m) (B) (m) One 0 325 2 50 840 3 100 1370 4 135 1805 5 180 2290 . . . . . . n 000 0000
* In this case, the value (C) is 325 m.
* Each figure is a measure of the starting point of each section of the security fence.

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Next, a method of calculating the ground distance from the start point of the security fence to the intrusion point from the above contrast table will be described. When the above contrast table is drawn, the distance from the length of the optical cable to the ground, that is, the value (A) can be calculated from the value (B). A method of calculating the value (A) from the value (B) will be described taking as an example an intrusion at the point where the value (B) is 1100 m.

First, in the comparison table above, if the (B) value finds the section to which the 1100m point belongs, it is the second section. The distance between the second section is 50m (100m-50m) and the cable length is 530m (1370m-840m). The cable length from the start point of the second section to the intrusion point is 260m (1100m-840m).

In this case, the distance P from the start point of the second section to the intrusion point is

50: 530 = P: 260

P = (50 x 260) / 530 = 24.5 (m)

Therefore, it can be seen that an intrusion attempt was made at 24.5m from the start point of the second section and 74.5m (50m + 24.5m) from the start point of the security fence 3.

The control system 6, in cooperation with the optical transmission and reception device 7 and the memory device 10, calculates the value (B) as described above and calculates the value (A) from the value (B) to detect the exact intrusion point. As a result, you can quickly respond to intrusions.

Next, the monitoring system of the present invention will be described. Surveillance system of the present invention is configured by connecting a surveillance camera to the intrusion contact detection system as described above. The surveillance camera in the present invention is a surveillance camera whose surveillance direction is adjusted according to the control of the control system, and this surveillance camera 5 is connected to the control system 6. Since the head of the surveillance camera 5 is rotated according to the instruction of the control system 6 and the surveillance direction is adjusted, the area that can be monitored by one surveillance camera is greatly enlarged, and thus the number of surveillance cameras to be installed is greatly reduced. .

As shown in FIG. 2, in the conventional section monitoring system, a surveillance camera 5 should be installed for each section of the security fence 3. However, as shown in FIGS. 3A and 3B, the surveillance system of the present invention can accurately detect an intrusion point so that the control system 6 can adjust the surveillance camera 5 to face the intrusion point, so that the rotation diameter of the camera is changed. Install only one in the center.

When the optical transmission and reception device 7 recognizes an intrusion from the outside and informs the control system 6, the control system 6 issues a warning and detects an accurate intrusion point so that the surveillance camera 5 can face the intrusion point. The surveillance camera 5 monitors and photographs the intrusion site.

As described above, in the surveillance system of the present invention, since only one surveillance camera is provided at the rotation diameter thereof, the number of surveillance cameras can be greatly reduced as compared with the previous one. As described above, when the length of the entire security fence is 10 km and the length of each section is 100 m, 100 surveillance cameras should be installed in the conventional section monitoring system, but in the surveillance system of the present invention, only one per 1 km You only need to install 10 surveillance cameras. That is, the number of surveillance cameras can be reduced to 1/10 or less.
In the case of the conventional section monitoring system, a pair of section monitoring controllers 4 are required for each section of the security fence 3, but as shown in FIGS. 3A and 3B, the monitoring system of the present invention is completely free. Not required.
As such, in the surveillance system of the present invention, the section surveillance controller is not required at all, and the number of surveillance cameras is greatly reduced, and the installation position of the surveillance camera is also far from the security fence, so that power and lightning protection facilities need to be installed in the area of the security fence. There is no. As such, there is no need to provide power and lightning protection facilities in the area of the security fence, which greatly reduces time and cost, and has a great advantage of making the surveillance system compact.

Although the present invention has been described above based on the drawings, the present invention is not limited to the above description and various changes and modifications are possible.

The present invention has the effect that it is possible to detect the point of intrusion accurately and quickly and to quickly cope with the intrusion. In addition, according to the present invention can minimize the equipment and additional facilities, such as surveillance cameras, greatly reducing the time and cost, there is an effect that the surveillance system is compact.

Claims (7)

delete delete delete delete delete In the optical cable security fence monitoring system, A first step of continuously monitoring the time required for transmitting and returning the optical signal in the optical transmitting and receiving apparatus; A second step of calculating the length of the optical cable to the point where the optical cable is damaged in cooperation with the control system and the optical transmitting / receiving device when the time required for transmitting and conveying the optical signal is shorter than a standard time;  Based on the calculated length of the optical cable, the distance between the length of the optical cable to the various points of the security fence and the ground distance corresponding to each of the ground and the ground distance from the starting point of the security fence to the intrusion point is calculated A third step of detecting the intrusion point, and And a fourth step in which the control system adjusts the monitoring direction of the surveillance camera installed on the security fence side to the detected intrusion point, and the surveillance camera monitors and photographs the intrusion situation. In the optical cable security fence monitoring system, Optical cable installed in security fence, An optical transmission and reception device connected to one end of the optical cable, A control system connected to the optical transmitting and receiving device, A contrast table between the lengths of the optical cables up to various points of the security fence and the distances of the ground corresponding to the lengths of the optical fences, A memory device connected to said control system and storing said contrast table, and Optical cable security fence surveillance system is installed on the security fence side and connected to the control system consisting of a surveillance camera is adjusted to the monitoring direction according to the control of the control system

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