KR100556263B1 - Optical transmission and relay apparatus for watch cameras and remote monitoring system using of the apparatus - Google Patents

Abstract

The present invention relates to the field of remote monitoring technology using a surveillance camera, and more particularly to an optical transmission / relay device implemented in a rack type and a remote monitoring system using the optical transmission / relay devices, the optical transmission / relay device A board insertion unit including a plurality of slots and having a plurality of signal lines and power lines therebetween; At least one camera board portion inserted into the slot and connected to at least one surveillance camera through a coaxial cable; The video signal is inserted into the slot, the video signal transmitted from the at least one camera board through the signal line is switched and transmitted to another optical transmission / relay device or a remote monitoring server through an optical cable, and the other through the optical cable And a switching board unit which transmits a corresponding remote control signal to the surveillance camera by switching a signal received from any one of an optical transmission / relay device or a remote monitoring server.

Optical transmission / relay device, remote monitoring, surveillance camera

Description

Optical transmission and relay apparatus for watch cameras and remote monitoring system using of the apparatus

1 is an example of the configuration of a remote monitoring system according to the present invention.

2 is a schematic illustration of the internal structure of an optical transmission / relay device according to the present invention.

3 is an example of an internal configuration of a camera board unit according to the first embodiment of the present invention.

4 is an example of an internal configuration of a camera board unit according to the second embodiment of the present invention.

5 is an example of an internal configuration of an optical transmission board according to the present invention.

Figure 6 is an example of the internal configuration of the switching board portion according to the present invention.

7A, 7B, 7C, and 7D are examples of the internal structure of the optical transmission / relay device according to the present invention.

The present invention relates to the field of remote monitoring technology using an optical network, and more particularly, to an optical transmission / relay device between a surveillance camera and a remote monitoring server and a remote monitoring system using the optical transmission / relay devices.

Recently, many places such as apartment complexes, buildings, technotowns, etc. are gathering a lot of remote surveillance systems using surveillance cameras for security purposes. More and more surveillance cameras are being installed in high-rise buildings for security, and surveillance cameras are increasingly installed on roads and alleys.

The existing CCTV installation in an apartment or building is a method in which one or more surveillance cameras are installed in a building by directly connecting one-to-one using a coaxial cable between a surveillance camera and a remote surveillance server, for example, a surveillance monitor. More than 100 strands of wire are connected to the central control room. Therefore, the installation cost of cable is excessive, and it is very difficult to add surveillance camera and change its location. In addition, it is necessary to monitor the same surveillance camera at the same time in several security offices besides the central control room, but the cable installation is very complicated, and in most cases, simultaneous monitoring is not performed.

On the other hand, the remote monitoring method using the optical transmission method designed to enable long-distance transmission for the distance monitoring, Korean Patent No. 0382233 "Optical transmission / relay device between the web camera and the remote monitoring server and remote monitoring system using the optical transmission / relay devices (Hereinafter referred to as "first application"). The first application is for the method of transmitting a camera signal to a remote monitoring server through an optical transmission / relay device, in which a surveillance camera is applied to a web camera. The web camera can be usefully used where the web camera can be applied to the camera itself with a built-in camera. However, the web camera developed to date has very few kinds of products compared to the CCD camera. Performance is very difficult to choose. Also, the optical transmission / relay device according to the above-mentioned application is a product having N Ethernet ports and an optical transmission port for connecting web cameras, respectively, so that a suitable product can be selected and used as necessary. However, during the actual installation process, some surveillance cameras may need to be connected in some areas, and some cameras may need to be connected to many other camera relays or remote monitoring servers installed in various areas. Therefore, the conventional manufacturer is inconvenient to produce a variety of optical transmission / relay device to meet the above demands. In addition, there are disadvantages in that the manufacturing process is complicated, the product cost is expensive, and the size of the optical transmission / relay device is various. In addition, the optical transmission / relay device has a disadvantage in that it has considerably many functions not used.

The present invention is to solve the problems as described above, the object of the present invention is to provide a light transmission / relay device implemented in a rack structure that can be freely configured as necessary, the manufacturing process is simple, only necessary functions.

Another object of the present invention is to be connected to the optical transmission / relay devices via an optical cable to transmit the video signal from each surveillance camera to the remote surveillance server at high speed, and provides a remote surveillance system that is easy to expand and change. For that purpose.

Additionally, an object of the present invention is to provide a remote monitoring system capable of simultaneously monitoring a plurality of surveillance areas by transmitting an image signal captured by a surveillance camera through an optical network.

According to an aspect of the present invention for achieving the above object, an optical transmission / relay device includes a board insertion unit including a plurality of slots and a plurality of signal lines and power lines are wired between the slots; At least one camera board portion inserted into the slot and connected to at least one surveillance camera through a coaxial cable; The video signal is inserted into the slot, the video signal transmitted from the at least one camera board through the signal line is switched and transmitted to another optical transmission / relay device or a remote monitoring server through an optical cable, and the other through the optical cable At least one switching board unit for switching the signal received from any one of the optical transmission / relay device or a remote monitoring server to transmit the corresponding remote control signal to the surveillance camera.

According to this aspect, the manufacturer can simplify the manufacturing process and lower the production cost of the product by manufacturing the board insertion unit, the camera board unit and the switching board unit, respectively. On the other hand, the user only needs to purchase the necessary number of boards with the necessary functions to be mounted on the board insertion unit can reduce the equipment installation cost, it is possible to increase the efficiency of using the equipment.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily understand and reproduce the present invention.

1 schematically shows a remote monitoring system according to the present invention.

As shown, the remote monitoring system according to the present invention includes a plurality of surveillance cameras 401 to 412, optical transmission / relay devices 511 to 516, and remote monitoring servers 611 to 615. Preferably, each of the optical transmission / relay devices 511 to 516 installed in each monitoring area 311 to 316 is connected in a tree form through at least one or more optical cables to form a backbone network.

The surveillance cameras 401 to 412 may be implemented as a CCD camera or a web camera with a built-in web server function. The CCD camera or the web camera is well known in the past, and detailed description thereof will be omitted. The surveillance cameras 401 to 412 operate in accordance with camera remote control signals from the remote monitoring servers 611 to 615. The camera remote control signal may be a zoom, pan / tilt, focus control signal, or the like.

The optical transmission / relay device 511 to 516 switches signals input from the surveillance cameras 401 to 412 and the remote monitoring servers 611 to 615 to remote monitoring server 611 to 615 or another optical transmission / relay device. 511 to 516, and transmits a camera remote control signal of the remote monitoring servers 611 to 615 to the monitoring cameras 401 to 412. Hereinafter, a detailed description of the optical transmission / relay device 511 to 516 will be described later.

The remote monitoring server 611 to 615 multiplexes or selects and displays a plurality of camera images, and records the video information input from the monitoring cameras 401 to 412 through the optical transmission / relay devices 511 to 516 in real time. It has a function to play. In the present embodiment, the remote monitoring server 611 to 615 includes a main body including a monitor, a central processing unit (CPU), a hard disk drive (HDD), a ROM, a RAM, a graphics card, and a digital video recorder (DVR) software. It is implemented in a computer system having a.

Hereinafter, an implementation technique of the optical transmission / relay device will be described with reference to the drawings.

2 is a schematic illustration of the internal structure of an optical transmission / relay device according to the present invention.

As shown, the optical transmission / relay device includes a board inserting portion 10 and a plurality of board portions 21, 22, 23.

The board insertion unit 10 is equipped with a plurality of slots 11, 12, 13, and a plurality of signal lines and power lines are wired between the plurality of slots 11, 12, 13. The board inserter 10 receives an external commercial power supply, for example, AC 220V AC power through a plug (not shown) connected to the power line.

The board parts 21, 22, and 23 are inserted into any one of the slots 11, 12, and 13, and include a camera board part, an optical transmission board part, and a switching board part.

The camera board unit is connected to at least one surveillance camera (not shown) through a coaxial cable and transmits an image signal input from the surveillance camera to the switching board unit.

The optical transmission board unit is not only connected to at least one surveillance camera (not shown) through a coaxial cable, but also by another optical transmission / relay device (not shown) or a remote monitoring server (not shown) through an optical cable. It is implemented to connect with one.

The switching board unit switches the camera image signal transmitted from the camera board unit and the optical transmission board unit, and transmits it to another optical transmission / relay device (not shown) or a remote monitoring server (not shown) through an optical cable. And switching the signal received from any one of the other optical transmission / relay device (not shown) or the remote monitoring server (not shown) through the optical cable for the monitoring through the camera board unit and the optical transmission board unit. The remote control signal is transmitted to a camera (not shown).

Hereinafter, the implementation of the camera board unit, the optical transmission board unit and the switching board unit will be described in detail with reference to the drawings.

3 is an example of an internal configuration of a camera board unit according to the first embodiment of the present invention. The camera board unit according to the present embodiment is implemented to be connected to the CCD camera.

As shown, the camera board unit according to the present embodiment, the slot connector 41, the power supply 42, the Ethernet physical layer unit 43, the front connector 44, the video server unit 45 and the switching control unit ( 46).

The slot connector 41 is inserted into the slot and connected to a plurality of signal lines and power lines.

 The power supply unit 42 supplies power to the device by converting the external commercial power input from the slot connector unit 41 into a power level required by the device and outputting the power. That is, the power supply unit 42 supplies commercial AC220V power. It rectifies and smoothes it, converts it into a DC power supply, and converts this converted DC power supply into the predetermined DC voltage required by an apparatus, and outputs it. Preferably, the power supply unit 42 includes a separate switch 42a for opening and closing the power supply. Accordingly, the camera board unit operates independently regardless of the operation of other boards, and the camera board can be attached and detached even while the optical transmission / relay device is in operation.

The Ethernet physical layer unit 43 interfaces signals transmitted / received between the slot connector 41 and the switching control unit 46.

The front connector 44 is connected to a web camera (not shown) through an Ethernet cable. In this embodiment, the front connector 44 is connected to a CCD camera (not shown) through a coaxial cable and an RS-422 control signal cable. In the present embodiment, the front connector portions 44a to 44d are each implemented with a BNC connector and an RS-485 port.

The video server unit 45 digitally converts an analog image signal input from the front connector unit 44 and performs image signal processing and image compression including resolution / level adjustment. In the present embodiment, the video server unit 45 is implemented to process four surveillance camera signals, but the present invention is not limited thereto.

The switching control unit 46 switches the video signal input from the video server unit 45 to the optical transmission board through the slot connector 41, and transfers the slot connector 41 from the optical transmission board. The camera remote control signal is input through the front connector 44 to be transmitted to the surveillance camera (not shown).

4 is an example of an internal configuration of a camera board according to a second embodiment of the present invention. The camera board unit according to the present embodiment is implemented to be connected to the web camera.

The camera board unit according to the present embodiment includes a slot connector unit 51, a power supply unit 52, a first Ethernet physical layer unit 53, an Ethernet connector unit 54, a second Ethernet physical layer unit 55, and a switching control unit. And 56.

The slot connector 51 is inserted into a slot and connected to the plurality of signal lines and power lines.

The power supply unit 52 supplies power to the device by converting and outputting the external commercial power input from the slot connector unit 51 to the power level required by the device. That is, the power supply unit 52 rectifies and smoothes the commercial AC220V power source to convert the DC power source into DC power, and converts the converted DC power source into a predetermined DC voltage required by the device and outputs the converted DC power source. Preferably, the power supply unit 52 includes a separate switch 52a for opening and closing the power. Accordingly, the camera board unit operates independently regardless of the operation of other boards, and the camera board can be detached even while the optical transmission / relay device is in operation.

The first Ethernet physical layer unit 53 interfaces a signal transmitted / received between the slot connector 51 and the switching controller 56.

The Ethernet connector 54 is connected to a web camera (not shown) through an Ethernet cable. In the present embodiment, the Ethernet connector 54 is implemented with four Ethernet connectors 54a to 54d, but the present invention is not limited thereto. The Ethernet connectors 54a to 54d may be implemented as RJ-45 10 / 100Mbps connectors. The Ethernet cable may be implemented as an unshielded twisted pair wire (UTP).

The second Ethernet physical layer unit 55 interfaces a signal transmitted / received between the Ethernet connector unit 54 and the switching control unit 56. In the present embodiment, the second Ethernet physical layer unit 55 is implemented as four second Ethernet physical layer units 54a to 54d, but the present invention is not limited thereto.

The switching controller 56 switches an image signal input from the Ethernet connector 54 and transmits the image signal to another switching board through the slot connector 51, and the slot connector 51 from the other switching board. ) Transmits the camera remote control signal input through the Ethernet connector 54 to the web camera (not shown).

5 is an example of an internal configuration of an optical transmission board according to the present invention. Here, the same configuration as that in Fig. 4 uses the same reference numerals.

As shown, the optical transmission board unit slot connector 51, the power supply unit 52, the first Ethernet physical layer unit 53, the Ethernet connector unit 54, the optical connector unit 57 and the optical transceiver unit 58 ) And a photophysical layer unit 59 and a switching control unit 60.

The optical connector 57 is connected to any one of an optical transmission / relay device (not shown) and a remote monitoring server (not shown) through an optical cable. The optical connector 57 may be implemented as a one-core or two-core connector. In this case, the optical cable may be a single mode or multi-mode optical island, it may be implemented as an outdoor optical cable with a built-in stainless steel. Preferably, the optical connector 57 is implemented as a single-mode connector of a single mode type consisting of one strand of optical fiber when transmitting a long distance of 2Km or more.

The optical transceiver unit 58 converts an optical signal input from the optical connector unit 57 into an electric signal, converts an electric signal transmitted into an optical signal, and outputs the optical signal to the optical connector unit 57.

The optical physical layer unit 59 interfaces signals transmitted / received between the optical transceiver unit 58 and the switching control unit 60.

The switching controller 60 switches a signal received through the optical connector 57 to transmit a corresponding remote control signal to a monitoring camera connected to the camera board through a switching board, or transmits the received signal to another optical transmission board. It transmits to either the optical transmission / relay device (not shown) or the remote monitoring server (not shown) through the unit and the switching board.

6 is an example of an internal configuration of a switching board according to the present invention. Here, the same configuration as that in Fig. 5 uses the same reference numerals.

The switching board unit according to the present embodiment further includes an Ethernet connector unit 61, a first selection switch unit 62, a second Ethernet physical layer unit 63, and a second selection switch unit 64.

The Ethernet connector 61 is connected to a web camera (not shown) through an Ethernet cable.

The first selector switch 62 connects any one of the Ethernet connector 61 and the slot connector 51 to the first Ethernet physical layer 53 by user manipulation. In the present embodiment, the first selection switch unit 62 is implemented as four selection switches, but the present invention is not limited thereto. The selection switch is implemented as a dip switch.

The second Ethernet physical layer unit 63 interfaces signals transmitted / received between the slot connector unit 51 and the switching control unit 60.

The second selection switch unit 64 connects any one of the second Ethernet physical layer unit 63 and the optical physical layer unit 59 to the switching controller 60.

The switching board part configured as shown in FIG. 6 may be inserted into and used in all slots 11, 12, and 13 of the board insertion part (FIGS. 2 and 10), and the user may use the first and second selection switches 62 and 64. It is possible to perform the optical transmission board or camera board function as necessary by operating the switching board. Accordingly, the optical transmission / relay device can be implemented using only the switching board unit according to the present embodiment.

In one embodiment, when the user intends to use the switching board part as the camera board part shown in Fig. 4, i.e., a video signal input from a web camera (not shown) through the Ethernet connector part 61 is different. When transmitting to the switching board and the optical transmission board unit, the first selection switch unit 62 is set so that the Ethernet connector unit 61 and the first Ethernet physical layer unit 53 are connected, and the slot connector unit 61 is connected. ) And the second selection switch unit 64 to be connected to the switching control unit 61.

At this time, the camera video signal is connected to the Ethernet connector unit 61-> first selection switch unit 62--> first Ethernet physical layer unit 53-> switching control unit 60--> second selection switch unit 64- The second Ethernet physical layer unit 63 is transmitted to another optical transmission / relay device through the other switching board unit through the slot connector unit 51.

On the other hand, the camera remote control signal of the remote monitoring server is the slot connector unit 51-> first selection switch unit 62--> second Ethernet physical layer unit 63-> second selection switch unit 64-→ The switching controller 60 is transmitted to the monitoring camera through the first Ethernet physical layer unit 53, the first selection switch 62, and the Ethernet connector unit 61.

In another embodiment, in order to implement an optical transmission board using a switching board, the second selection switch 64 is switched so that the optical connector 57 and the switching control unit 60 are connected, and the Ethernet connector unit ( The first selection switch 62 is set to be connected to the switching control unit 60 and 61, and the first selection switch of 62d is set to be connected to the slot connector 51.

At this time, the camera video signal is connected to the Ethernet connector unit 61-> first selection switch unit 62--> first Ethernet physical layer unit 53-> switching control unit 60--> second selection switch unit 64- The optical physical layer unit 59 is transmitted to the other optical transmission / relay device or the remote monitoring server through the optical transceiver unit 58 and the optical connector unit 57.

On the other hand, the camera remote control signal from the remote monitoring server (not shown) is an optical connector 57-an optical transceiver unit 58-an optical physical layer unit 59-a second selection switch unit 61. )-→ switching control unit 61-→ second Ethernet physical layer unit 61-→ first selection switch unit 61-→ is transmitted to the camera through the camera board unit via the slot connector unit 61.

7A, 7B, 7C, and 7D are examples of the internal structure of the optical transmission / relay device according to the number of cameras mounted and how many other optical transmission / relay devices are connected.

Here, the board connection unit 10 is connected to the signal line and the power line, but this embodiment will be described in detail with respect to the signal line. In this embodiment, the board insertion portion 10 is shown so that the first to thirteenth slot is installed, but the present invention is not limited thereto. As shown in Figs. 7A, 7B, 7C, and 7D, in this embodiment, only a switching board may be inserted into slots 11 to 13, and the switching board inserted into the slot 13 is mounted in the slots 11 and 12. To switch the switching board. The signal lines wired to slots 1 to 4 are connected to slot 11, the signal lines wired to slots 5 to 8 are connected to slot 12, and the signal lines wired to slots 9 and 10 are connected to slot 13. In addition, slots 11 and 12 are connected to slots 13 and signal lines, respectively. Accordingly, when the user inserts the camera board unit into the slots 1 through 4 according to the configuration feature of the present embodiment, the user must insert the switching board unit into the slot 11. Likewise, when the camera board portion is inserted into the slots 5 to 8, the switching board portion is inserted into the slot 12, and the switching board portion must be inserted into the slot 13 when the camera board portion is inserted into the slots 9 and 10.

The optical transmission / relay device according to FIG. 7A shows the camera boards 21, 22, and 23 mounted in slots 1, 2, and 3 and the optical transmission board 31 in slot 11. The optical transmission / relay device according to the present embodiment is an example in which three (or 3 × 4; four video servers are built in one camera board) surveillance cameras are connected to one optical cable. 23 transmits the video signal from the other surveillance camera optical transmission / relay device or the remote surveillance server through one switching board unit. The remaining empty slots can be used for additional cameras or optical transmission ports, so that additional installation costs can be greatly reduced.

The surveillance camera optical transmission / relay device according to FIG. 7B is an example in which nine (or 9 × 4; four video servers are built into one camera board) surveillance cameras are connected to two optical cables. 4, 5, 6, 7, 9, and 10 show the camera boards 21 to 27, 29, and 30 installed in the slots 11, 12, and 13, and the switching boards 31, 32, and 33. The optical transmission / relay device according to the present embodiment is implemented to perform a role of relaying two different optical transmission / relay devices. Here, the optical transmission board part inserted into the slot 31 uses the switching board part shown in FIG. That is, the switching board unit switches the second selection switch unit 64 so that the second Ethernet physical layer unit (FIGS. 6 and 63) and the switching control unit (FIGS. 6 and 60) are connected, and the slot connector unit (FIGS. 6 and 61). ) And the first selection switch unit 62 to be connected to the switching control unit (Figs. 6 and 61).

The optical transmission / relay device according to FIG. 7C is an example in which 8 (or 8 × 4; four video servers are built in one camera board) surveillance cameras are connected to three optical cables, and slots 1, 2, 3, and 5 are provided. Camera boards 21, 22, 23, 25, 26, 27, 29, 30 in 6, 7, 9, 10, and switching boards 31, 32, 33 in slots 11, 12, and 13. It is shown. The surveillance camera optical transmission / relay device according to the present embodiment may be implemented to be connected to three different surveillance camera optical transmission / relay devices.

The optical transmission / relay device according to FIG. 7D is an example in which 7 (or 7 × 4; four video servers are built in one camera board) surveillance cameras are connected to four optical cables, and slots 1, 2, 3, and 5 are provided. Camera boards 21, 22, 23, 25, 26, 27, 29 in 6, 7, 9 and 9, optical transmission board 30 in slot 10 and switching boards 31, 32, 33 in slots 11, 12 and 13. ) Is shown. The surveillance camera optical transmission / relay device according to the present embodiment is implemented to be connected with four different surveillance camera optical transmission / relay devices.

As described above, according to the present invention, the manufacturing process is simple, there is a useful effect that can be configured in a rack structure freely configured only necessary functions as needed.

In addition, according to the present invention, there is an advantage that the video signal from each monitoring camera can be transmitted to the remote monitoring server at high speed by being connected to the optical transmission / relay devices through the optical cable.

In addition, according to the present invention, there is a useful effect that it is easy to expand and change the expansion of the camera and the optical transmission / relay device and the remote monitoring server.

In addition, according to the present invention, by transmitting the video signal photographed by the surveillance camera through the optical cable has a useful effect that can monitor the same surveillance camera in multiple at the same time in multiple places.

Although the present invention has been described with reference to the accompanying drawings, it will be apparent to those skilled in the art that many various obvious modifications are possible without departing from the scope of the invention from this description. Therefore, it should be interpreted by the claims described to include many such variations.

Claims (7)

delete A board insertion unit including a plurality of slots and having a plurality of signal lines and power lines therebetween; At least one camera board portion inserted into the slot and connected to at least one surveillance camera through a coaxial cable; Inserted into the slot, the video signal is transmitted from the at least one camera board through the signal line by switching to another optical transmission / relay device or a remote monitoring server via an optical cable, and another optical transmission through the optical cable / At least one switching board unit for switching the signal received from any one of the relay or the remote monitoring server to transmit the corresponding remote control signal to the surveillance camera; The camera board unit: A slot connector portion inserted into the slot and connected to a plurality of signal lines and power lines; A power supply unit for supplying power to the device by converting the external commercial power input from the slot connector unit into a power level required by the device and outputting the converted power level; An Ethernet physical layer unit that interfaces signals transmitted / received between the slot connector unit and the switching control unit; At least one front connector connected to the surveillance camera via a coaxial cable; A video server unit for digitally converting an analog image signal input from the front connector unit and performing image signal processing and image compression including resolution / level adjustment; The video signal input from the video server unit is switched to transmit the switching board through the slot connector, and the camera remote control signal from the switching board through the slot connector for monitoring through the Ethernet connector Switching control unit for transmitting to the camera; Optical transmission / relay device between the monitoring camera and the remote monitoring server, comprising a. A board insertion unit including a plurality of slots and having a plurality of signal lines and power lines therebetween; At least one camera board portion inserted into the slot and connected to at least one surveillance camera through a coaxial cable; Inserted into the slot, the video signal is transmitted from the at least one camera board through the signal line by switching to another optical transmission / relay device or a remote monitoring server via an optical cable, and another optical transmission through the optical cable / At least one switching board unit for switching the signal received from any one of the relay or the remote monitoring server to transmit the corresponding remote control signal to the surveillance camera; The camera board unit: A slot connector unit inserted into the slot and connected to the signal lines and the power lines; A power supply unit for supplying power to the device by converting the external commercial power input from the slot connector unit into a power level required by the device and outputting the converted power level; A first Ethernet physical layer unit for interfacing signals transmitted / received between the slot connector unit and the switching control unit; At least one Ethernet connector connected to the surveillance camera through an Ethernet cable; At least one second Ethernet physical layer unit for interfacing signals transmitted / received between the Ethernet connector unit and the switching control unit; Switching the video signal input from the at least one Ethernet connector unit and transmitting to the switching board unit through the slot connector unit, and monitors the camera remote control signal input from the switching board unit through the slot connector unit through the Ethernet connector unit Switching control unit for transmitting to the camera; Optical transmission / relay device between the monitoring camera and the remote monitoring server, comprising a. A board insertion unit including a plurality of slots and having a plurality of signal lines and power lines therebetween; At least one camera board portion inserted into the slot and connected to at least one surveillance camera through a coaxial cable; Inserted into the slot, the video signal is transmitted from the at least one camera board through the signal line by switching to another optical transmission / relay device or a remote monitoring server via an optical cable, and another optical transmission through the optical cable At least one switching board unit for switching a signal received from any one of a relay or a remote monitoring server to transmit a corresponding remote control signal to the surveillance camera; Including but not limited to: The switching board portion: A slot connector unit inserted into the slot and connected to the signal lines and the power lines; A power supply unit for supplying power to the device by converting and outputting the external commercial power inputted from the slot connector unit into a power level required by the device; A plurality of first Ethernet physical layer units for interfacing signals transmitted / received between the slot connector unit and the switching control unit; An optical connector unit connected to any one of an optical transmission / relay device and a remote monitoring server through an optical cable; An optical transceiver unit converting an optical signal input from the optical connector unit into an electrical signal, and converting the transmitted electrical signal into an optical signal and outputting the optical signal to the optical connector unit; An optical physical layer unit for interfacing signals transmitted / received between the optical transceiver unit and the switching control unit; And A switching control unit for switching a signal received through the optical connector unit to transmit the remote control signal to the surveillance camera through the slot connector unit or to transmit the received signal to another optical transmission / relay device or a remote monitoring server; Optical transmission / relay device between the monitoring camera and the remote monitoring server, comprising a. The method according to claim 4, wherein the switching board portion: At least one Ethernet connector connected to the surveillance camera through an Ethernet cable; At least one first selection switch unit connecting one of the Ethernet connector unit and the slot connector unit with the Ethernet physical layer unit by a user operation; A second Ethernet physical layer unit for interfacing a signal transmitted / received between the slot connector unit and the switching control unit; A second selection switch unit connecting one of the second Ethernet physical layer unit and the optical physical layer unit to the switching control unit; Optical transmission / relay device between the monitoring camera and the remote monitoring server, comprising a. The method according to any one of claims 2 to 5, wherein the camera board unit and the switching board unit is a power switch, and the ground is implemented independently, so that the detachable detachment of the camera board unit and the switching board unit even during the operation of the optical transmission / relay device. Optical transmission / relay device between the monitoring camera and the remote monitoring server, characterized in that possible. A remote monitoring system using the optical transmission / relay devices as claimed in claim 2, wherein the remote monitoring system comprises: A plurality of surveillance cameras installed in the surveillance area and connected through a camera board unit provided in each optical transmission / relay device and operating according to a camera remote control signal to capture an image; One optical transmission / relay device is connected to the optical connector part of the first switching board part provided in each optical transmission / relay device through an optical cable, and another optical transmission / relay device is connected to the optical connector part of the second switching board part provided through the optical cable. And a plurality of optical transmission / relay devices for forming a backbone network through the optical cables between the devices; It is connected through the corresponding optical cable, recorded by each surveillance camera, relayed by the optical transmission / relay device, and stores the video signal transmitted through the optical cable, and generates a remote monitoring control signal, which is then transmitted through the optical transmission / relay device. Remote monitoring server for transmitting to the surveillance camera; Remote monitoring system using the optical transmission / relay device, characterized in that comprises a.

Images