KR101347571B1 - Camera signal transfer system and monitoring method of coaxcial cable - Google Patents

Abstract

The present invention relates to a camera signal transmission system and a coaxial cable monitoring method, particularly, to a camera signal transmission system of the present invention comprising: a first transmission device which generates a power overlap signal in which an analog signal for controlling a predetermined camera overlaps power for driving the camera, transmits the generated power overlap signal through a coaxial cable and blocks the generation of the power overlap signal if an error occurs in the coaxial cable, by monitoring current flowing through the coaxial cable; and a second transmission device which receives the power overlap signal transmitted through the coaxial cable from the first transmission device, divides the power overlap signal into the power and the analog signal for controlling the camera, and transmits the analog signal and the power to the camera. Consequently, it is possible to reduce costs and installation time by using an existing coaxial cable as reducing transmission distance limits and prevent system damage by determining whether an error occurs in the coaxial cable. [Reference numerals] (100) DVR device; (200) First transmission device; (300) Second transmission device; (500) IP camera; (AA,CC) UTP cable; (BB) Coaxial cable

Description

Camera signal transfer system and monitoring method of coaxcial cable

The present invention relates to a camera signal transmission system and a method for monitoring a coaxial cable, and more particularly, converts an Ethernet signal that can be transmitted through an Unshielded Twisted Pair (UTP) cable into a signal that can be transmitted through a coaxial cable, and overlaps the power supply. The present invention relates to a camera signal transmission system and a method of monitoring a coaxial cable that can be superimposed on an analog signal and transmitted through a coaxial cable.

In recent years, surveillance cameras have been installed for security and surveillance in crowded places such as apartment complexes, alleys and buildings. Conventional surveillance cameras take images and generate them as SD-level analog video signals, but SD-level video signals have poor image quality and lack of pixels.

In order to solve this problem, IP cameras are being introduced to generate HD digital signals. As shown in FIG. 1, the video signal generated by the IP camera 50 is transmitted to the DVR (Digital Video Recorder) device 10 through a UTP cable. Here, when multiple IP cameras 50 are connected, the video signals generated by the respective IP cameras 50 are transmitted to the DVR device 10 through the hub 30.

Video signals captured by HD IP cameras cannot be transmitted through coaxial cables installed to transmit existing SD video signals. As shown in FIG. 1, the video signal generated by the IP camera 50 is transmitted to the DVR device 10 through the UTP cable. Therefore, in order to install an HD class IP camera, a problem arises in that an optical cable or a UTP cable needs to be removed and a coaxial cable installed for transmitting a video signal of an existing SD class camera is reinstalled.

Low-cost UTP cable, which is generally used, cannot transmit more than 90m in transmitting the video signal generated from IP camera, so additional repeater should be installed. In addition, inexpensive UTP cable is weak and the shielding is impossible, so it is vulnerable to external physical shock or heat.

If an expensive optical cable is installed in place of the UTP cable, an additional optical transmission device needs to be installed and a power cable for driving the IP camera needs to be separately installed.

1. Republic of Korea Patent Publication No. 10-0490948 (13 May 2005) 2. Republic of Korea Patent Publication No. 10-1195703 (October 23, 2012) 3. Republic of Korea Patent Publication No. 10-1172389 (August 02, 2012)

The present invention is to solve the above conventional problems, while using the coaxial cable installed for the video signal transmission of the conventional SD class, while minimizing the limitation of the transmission distance, install a separate power supply for driving the camera It is an object of the present invention to provide a camera signal transmission system and a coaxial cable monitoring method for converting an Ethernet signal into a signal that can be transmitted through a coaxial cable so as not to be necessary, and transmitting the superimposed on a power source capable of driving an IP camera.

Camera signal transmission system of the present invention generates a power superimposition signal superimposed an analog signal for controlling the camera to a power source for driving a predetermined camera and transmits it through a coaxial cable, by monitoring the current flowing through the coaxial cable A first transmission device that blocks generation of the power overlapping signal when an abnormality is detected in the coaxial cable; And a second transmission device receiving the power superimposition signal transmitted through the coaxial cable from the first transmission device, separating the signal into an analog signal and power for controlling the camera, and transmitting the power signal to the camera. .

The first transmission device may include: a signal overlapping unit configured to generate a power overlap signal combined with the analog signal to a power source for driving the camera; A power supply unit supplying power to drive the camera to the signal overlapping unit; A coaxial terminal unit to which a coaxial cable for transmitting the power overlapping signal generated by the signal overlapping unit to the camera is connected; And monitoring the coaxial cable connected to the coaxial terminal unit through the signal overlapping unit, and when the occurrence of an abnormality in the coaxial cable is detected, cut off the power output from the power supply unit to control the signal overlapping unit so that the power overlapping signal is not generated. The control unit; characterized in that it comprises a.

The signal overlapping unit may include: a signal separation / combining unit for combining the analog signal with the power provided by the power supply unit to generate the power superimposition signal; A CLC unit checking whether the second transmission device is connected when the power is turned on; A monitoring unit configured to monitor current flowing through the coaxial cable and determine short, open, and overcurrent of the coaxial cable; And a power switching unit which is turned on and off so that power is supplied to and disconnected from the power supply unit to the signal separation / coupling unit. The control unit controls the CLC unit to transmit a standby signal to the coaxial cable. When the normal signal is received in the CLC unit, it is determined that the second transmission device is normally connected, and the power switching unit is controlled to be turned on, and when the monitoring unit detects short, open, and overcurrent of the coaxial cable, The power switch is characterized in that the control to turn off.

In addition, the first transmission device, the UTP terminal is connected to the UTP terminal unit for transmitting and receiving Ethernet data in the form of a balanced signal; A signal conversion unit converting the Ethernet data in the form of a balanced signal received through the UTP terminal unit into the Ethernet data in the form of an unbalanced signal; And a modem unit for modulating the non-balanced Ethernet data output from the signal converter into an analog signal.

On the other hand, a coaxial cable monitoring method of a camera signal transmission system including a transmission device for transmitting and receiving an analog signal through a coaxial cable between a predetermined camera and the DVR device for controlling the camera when the power of the transmission devices, the coaxial cable Transmitting a standby signal to the network; When a normal signal is received through the coaxial cable in response to the standby signal, supplying power for driving the camera; Generating and transmitting a power superimposition signal superimposing an analog signal for controlling the camera on a power supply for driving the camera; Monitoring current flowing through the coaxial cable to determine whether a short, open, and overcurrent of the coaxial cable has occurred; And if it is determined that short, open, and overcurrent of the coaxial cable have occurred, controlling the power overlap signal not to be generated.

The generating and transmitting the power overlapping signal may include converting the Ethernet control data in the form of a balanced signal transmitted from the DVR apparatus into the Ethernet control data in the form of a non-balanced signal, and then modulating the control signal into an analog control signal to drive the camera. And generating and transmitting the power overlapping signal superimposed on the power supply.

As described above, the camera signal transmission system of the present invention has the following effects.

By using the coaxial cable installed to transmit the video signal of the existing SD camera, the video taken from the IP camera can be transferred to the DVR device, thereby reducing the construction cost and the construction period.

In addition, by using a coaxial cable than when using a UTP cable, it is possible to reduce the limitation of the transmission distance, and there is no need to install a separate power supply for driving the camera, thereby reducing costs.

In addition, by monitoring the state of the coaxial cable, if an error occurs in the coaxial cable, the power is cut off to prevent the system from being damaged and to prevent the occurrence of a fire or the like.

In addition, it can transmit IP camera signal separately while using the coaxial cable installed for existing SD camera video signal transmission, and can be replaced with IP cameras sequentially.

1 is a view showing a conventional camera transmission system,
2 is a diagram illustrating a camera signal transmission system according to a first embodiment of the present invention;
3 is a diagram illustrating a camera signal transmission system according to a second embodiment of the present invention;
4 is a diagram showing a camera signal transmission system according to a third embodiment of the present invention;
5 is a block diagram showing a schematic configuration of a transmission apparatus included in a camera signal transmission system according to the first to third embodiments of the present invention;
6 is a block diagram showing a schematic configuration of a signal overlapping part included in the transmission device shown in FIG.
7 is a flowchart illustrating a coaxial cable monitoring method of a camera signal transmission system according to the first to third embodiments of the present invention.

Hereinafter, with reference to the accompanying drawings, a description will be given of an IP camera signal transmission apparatus having a coaxial cable monitoring function and a method thereof according to the present invention.

2 is a diagram illustrating a camera signal transmission system according to a first embodiment of the present invention.

Referring to FIG. 2, the camera signal transmission system of the present invention includes a DVR device 100, a first transmission device 200, a second transmission device 300, and an IP camera 500.

The DVR device 100 stores an image captured by the IP camera 500 or controls the IP camera 500, and is connected to the first transmission device 200 through the UTP cable. Control data in the form of a balanced signal for controlling the IP camera 500 is transmitted to the first transmission device 200 through the UTP cable. In addition, the image data captured by the IP camera 500 through the first transmission device 200 is received and stored in the DVR device 100.

The first transmission device 200 converts the control data of the balanced signal form transmitted from the DVR device 100 into a non-balanced signal form, and modulates the analog control signal. The modulated analog control signal is superimposed on a power source for driving the IP camera 500 to generate a power superimposition signal, and then transmitted to the second transmission device 300 through a coaxial cable. In addition, the first transmission device 200 receives an analog video signal transmitted from the second transmission device 300, demodulates the Ethernet video data in the form of an unbalanced signal, and converts the Ethernet video data in the form of a balanced signal. It transmits to the DVR device 100.

In addition, the first transmission device 200 monitors the current flowing through the coaxial cable, and when an abnormality is detected in the coaxial cable, the first transmission device 200 blocks the generation of a power superposition signal. In addition, when the power is turned on, the first transmission device 200 transmits a standby signal to check the connection state of the second transmission device 300. That is, when the standby signal is transmitted from the first transmission device 200 to the coaxial cable connected to the second transmission device 300 and a normal signal corresponding to the standby signal is received, the second transmission device 300 is normally connected. To judge.

The second transmission device 300 receives the power superimposition signal transmitted from the first transmission device 200, separates the signal into an analog control signal and a power source, and transmits the signal to the IP camera 500, respectively. That is, the separated power is supplied to the driving power of the IP camera 500, and the separated analog control signal is demodulated into Ethernet control data in the unbalanced signal form, and then converted to the Ethernet control data in the balanced signal form to convert the IP camera ( 500). In addition, the second transmission device 300 converts the Ethernet image data in the form of a balanced signal photographed and output by the IP camera 500 into the Ethernet image data in the form of an unbalanced signal, and then modulates the image into an analog image signal to transmit the first transmission signal. Send to device 200.

The IP camera 500 operates by receiving power provided from the second transmission device 300. In addition, the Ethernet control data of the balanced signal type transmitted from the second transmission device 300 is received and performs a corresponding operation, and the captured image is transmitted to the second transmission device 300 as the Ethernet image data of the balanced signal type. do.

3 is a diagram illustrating a camera signal transmission system according to a second embodiment of the present invention.

Referring to Figure 3, the camera signal transmission system of the present invention is the first to N-th DVR device (100-1,100-2, ..., 100-n), the 1-1 to 1-N transmission device 200 -1,200-2, ..., 200-n), 2-1st to 2nd-N transmission apparatuses 300-1,300-2, ..., 300-n, hub 400, and 1st to N-th IP camera 500-1,500-2, ..., 500-n.

The first to Nth DVR apparatuses 100-1, 100-2,..., 100-n display images captured by the first to N-th IP cameras 500-1, 500-2,. Store or control each IP camera 500-1,500-2, ..., 500-n. For example, when the first DVR device 100-1 controls the second IP camera 500-2, the address of the second IP camera 500-2 to be controlled by the first DVR device 100-1 is included. Ethernet control data is transmitted to the hub 400. In addition, the first DVR device 100-1 receives and stores image data received through the hub 400.

The hub 400 refers to the address included in the control data received from the first to Nth DVR apparatuses 100-1, 100-2, ..., 100-n, and transmits the control data to the first-first to first-first. It transmits to N transmitters 200-1, 200-2, ..., 200-n. In addition, the first to the N-th DVR device (100-100) for requesting the corresponding video data from the video data transmitted through the 1-1 to 1-N transmission apparatuses 200-1, 200-2, ..., 200-n. 1,100-2, ..., 100-n).

The first through N-th transmission apparatuses 200-1,200-2,..., 200-n transmit the first through N-th DVR apparatuses 100-1, 100-2, ... through the hub 400. And control data in the form of a balanced signal transmitted from (100-n) into a non-balanced signal form and then modulate it into an analog control signal. Then, the modulated analog control signal is superimposed on a power source for driving the first to Nth IP cameras 500-1, 500-2,. It transmits to 2-1 th-2nd N th transmission apparatus 300-1,300-2, ..., 300-n. Further, the first-first to first-N transmission apparatuses 200-1,200-2, ..., 200-n are the second-first to second-N transmission apparatuses 300-1,300-2, ... 300-n) receives the analog video signal transmitted from the signal, demodulates the Ethernet video data in the form of an unbalanced signal, converts the Ethernet video data in the form of a balanced signal, and transmits the same to the hub 400.

The first to first transmission apparatuses 200-1, 200-2, ..., 200-n monitor the current flowing through the coaxial cable to generate a power overlap signal when an abnormality is detected in the coaxial cable. To block. In addition, when the power is turned on, the 1-1st to 1st-N transmitters 200-1, 200-2, ..., 200-n transmit standby signals to transmit the 2-1st to 2nd-N transmitters ( Check the connection status of 300-1,300-2, ..., 300-n). That is, in the 1-1 to 1-N transmission apparatuses 200-1,200-2, ..., 200-n, the 2-1 to 2-N transmission apparatuses 300-1, 300-2, ... When the standby signal is transmitted through the coaxial cable connected to the 300-n, respectively, and the normal signal corresponding to the standby signal is received, the corresponding 2-1 to 2-N transmitters 300-1,300-2, ... 300-n) is determined to be normally connected.

The first through second transmission apparatuses 300-1,300-2, ..., 300-n, and the second through second transmission apparatuses 200-1, 200-2, ..., 200 -n) and receives the power superposition signal transmitted from the analog control signal and the power source, and transmits to the first to N-th IP camera (500-1,500-2, ..., 500-n), respectively. Further, the second through second N-th transmission apparatuses 300-1,300-2, ..., 300-n are the first through N-th IP cameras 500-1,500-2, ..., 500-n. Ethernet image data in the form of a balanced signal photographed and output from the converted into Ethernet image data in the form of a non-balanced signal, and then modulated into an analog image signal to transmit the 1-1 to 1-N transmission apparatuses 200-1,200-2. , ..., 200-n).

The first through N-th IP cameras 500-1,500-2, ..., 500-n are transmitted by the second through second transmission apparatuses 300-1, 300-2, ..., 300-n. It operates by receiving power. In addition, the Ethernet control data in the form of a balanced signal transmitted from the 2-1 to 2-N transmitters 300-1, 300-2, ..., 300-n is received to perform a corresponding operation, and photographed. The image is generated as Ethernet image data in the form of a balanced signal and transmitted to the second through second transmission apparatuses 300-1, 300-2, ..., 300-n.

4 is a diagram illustrating a camera signal transmission system according to a third embodiment of the present invention.

4, the camera signal transmission system of the present invention is a DVR device 100, the first transmission device 200, the 2-1 to the 2-N transmission device (300-1, 300-2, ..., 300-n), and first to N-th IP cameras 500-1,500-2, ..., 500-n.

The DVR apparatus 100 may store an image taken by the first to Nth IP cameras 500-1,500-2,..., 500-n or the first to Nth IP cameras 500-1,500-2. .., 500-n) is controlled, and is connected to the first transmission device 200 through the UTP cable. Control data in the form of a balanced signal for controlling the first to Nth IP cameras 500-1, 500-2,..., 500-n is transmitted to the first transmission device 200 through the UTP cable. Here, the control data in the form of a balanced signal generated by the DVR device 100 includes addresses of the first to Nth IP cameras 500-1,500-2,..., 500-n to be controlled. In addition, image data photographed by the first to Nth IP cameras 500-1, 500-2,..., 500-n through the first transmission device 200 is received and stored in the DVR device 100.

The first transmission device 200 converts the control data of the balanced signal form transmitted from the DVR device 100 into a non-balanced signal form, and modulates the analog control signal. Then, a power superimposition signal is generated by superimposing the modulated analog control signal on a power source for driving the IP cameras 500-1,500-2, ..., 500-n to control the modulated analog control signal. The first to second N-th transmission apparatuses 300-1, 300-2, ..., 300-n are transmitted. In addition, the first transmission device 200 receives an analog video signal transmitted from the 2-1 to 2-N transmission devices (300-1, 300-2, ..., 300-n) of the non-balanced signal form After demodulating the Ethernet video data, the Ethernet video data is converted into Ethernet video data in the form of a balanced signal and transmitted to the DVR apparatus 100.

In addition, the first transmission device 200 monitors the current flowing through the coaxial cable, and when an abnormal occurrence is detected in the coaxial cable, the first transmission device 200 blocks the generation of a power overlap signal. In addition, when the power is turned on, the first transmission device 200 transmits a standby signal to check the connection state of the 2-1 to 2-N transmission devices 300-1, 300-2, ..., 300-n. do. That is, the standby signal is transmitted from the first transmission device 200 to each of the coaxial cables connected to the 2-1 to 2-N transmission devices 300-1, 300-2, ..., 300-n. When the normal signal corresponding to the signal is received, it is determined that the 2-1 th to 2nd-N transmission apparatuses 300-1, 300-2, ..., 300-n are normally connected through the coaxial cable.

The 2-1 to 2-N transmitters 300-1, 300-2, ..., 300-n receive a power superimposition signal transmitted from the first transmitter 200 and separate the analog control signal into a power supply. After that, transmit to the IP camera (500-1,500-2, ..., 500-n) to control, respectively. That is, the separated power is supplied to the driving power of the IP cameras 500-1,500-2, ..., 500-n to be controlled, and the separated analog control signals are converted into Ethernet control data in the form of non-balanced signals. Then, it is converted into the Ethernet control data in the form of a balanced signal and transmitted to the IP cameras 500-1,500-2, ..., 500-n to be controlled. Further, the second through second N-th transmission apparatuses 300-1,300-2, ..., 300-n are the first through N-th IP cameras 500-1,500-2, ..., 500-n. After converting the Ethernet image data in the form of a balanced signal photographed and output to the Ethernet image data in the form of an unbalanced signal, it is modulated into an analog image signal and transmitted to the first transmission device (200).

The first through N-th IP cameras 500-1,500-2, ..., 500-n are transmitted by the second through second transmission apparatuses 300-1, 300-2, ..., 300-n. It operates by receiving power. In addition, each of the Ethernet control data in the form of a balanced signal transmitted from the 2-1 to 2-N transmitters 300-1, 300-2, ..., 300-n is received to perform a corresponding operation, and photographing. The transmitted image is transmitted to the second through second transmission apparatuses 300-1, 300-2, ..., 300-n in the form of a balanced signal Ethernet image data, respectively.

5 is a block diagram showing a schematic configuration of a transmission apparatus included in a camera signal transmission system according to the first to third embodiments of the present invention. 5 to 7, an example of the first transmission device 200 and the second transmission device 300 disclosed in the first embodiment will be described. First and First to First to Nth Transmission Devices 200,200-1,200-2,200-n and Second to First to Nth Transmission Devices 300-1,300-2 disclosed in the second and third embodiments ... 300-n) is also the same as the configuration and operation of the first transmission device 200 and the second transmission device 300 disclosed in the first embodiment.

Referring to FIG. 5, a transmission device 200, 200-1, 200-2,..., 200-n, 300, 300-1, 300-2,..., 300 included in the camera signal transmission system according to the first to third embodiments. -n) includes a UTP terminal unit 110, a signal conversion unit 120, a modem unit 130, a signal overlapping unit 140, a coaxial terminal unit 150, a control unit 160, and a power supply unit 170.

The UTP terminal unit 110 is connected to the UTP cable transmits and receives the Ethernet data in the form of a balanced signal. That is, the UTP terminal unit 110 included in the first transmission device 200 is connected to the DVR device 100 through the UTP cable, and receives the Ethernet control data in the form of a balanced signal transmitted from the DVR device 100, Equilibrium Ethernet data output from the signal converter 120 is transmitted to the DVR device 100.

The UTP terminal unit 110 included in the second transmission device 300 receives the Ethernet image data in the form of a balanced signal transmitted from the IP camera 500 or the Ethernet control data in the form of a balanced signal output from the signal converter 120. It transmits to the IP camera 500.

The signal converter 120 converts Ethernet data in the form of a balanced signal into Ethernet data in the form of a non-balanced signal, or converts Ethernet data in the form of a balanced signal into Ethernet data in the form of a balanced signal. That is, the signal conversion unit 120 included in the first transmission device 200 converts the Ethernet control data of the balanced signal type received through the UTP terminal unit 110 into the control data of the non-balanced signal type, or the modem unit ( Ethernet image data in the form of an unbalanced signal output from 130 is converted into Ethernet image data in the form of a balanced signal.

The signal conversion unit 120 included in the second transmission device 300 converts the Ethernet control data in the unbalanced signal form output from the modem unit 130 into the Ethernet control data in the balanced signal form, or the UTP terminal unit 110. Ethernet image data in the form of a balanced signal received through converts into image data in the form of a non-balanced signal.

The modem unit 130 modulates the data in the non-balanced signal form into an analog signal, or demodulates the analog signal into the data in the non-balanced signal form. That is, the modem unit 130 included in the first transmission device 200 modulates the non-balanced Ethernet control data output from the signal converter 120 into an analog control signal or outputs the signal from the signal overlapping unit 140. The analog video signal is demodulated into Ethernet video data in the form of an unbalanced signal.

The modem unit 130 included in the second transmission device 300 demodulates the analog control signal output from the signal overlapping unit 140 into Ethernet control data in the form of an unbalanced signal or criticizes the signal output from the signal converter 120. Ethernet video data in the form of a signal is modulated into an analog video signal.

The signal overlapping unit 140 overlaps the analog signal and the power supply to generate the power overlap signal, or separates the power overlap signal into the analog signal and the power source. In addition, the coaxial cable is monitored to detect whether an abnormality has occurred in the coaxial cable.

That is, the signal overlapping unit 140 included in the first transmission device 200 generates a power superposition signal combining the analog control signal output from the modem unit 130 to a power source for driving the IP camera 500 or coaxially. The analog video signal received through the terminal unit 150 is transmitted to the modem unit 130.

The signal overlapping unit 140 included in the second transmission device 300 transmits the analog video signal output from the modem unit 130 to the coaxial terminal unit 150, and transmits a power superimposition signal received through the coaxial terminal unit 150. Separate into power and analog control signals.

Coaxial cable is connected to the coaxial terminal unit 150 to transmit and receive analog signals. That is, a coaxial cable for transmitting the power overlap signal generated by the signal overlapping unit 140 to the second transmission device 300 connected to the IP camera 500 is included in the coaxial terminal unit 150 included in the first transmission device 200. Connected. The power superposition signal is transmitted to the second transmission device 300 through the coaxial terminal unit 150 or an analog video signal is received from the second transmission device 300.

The analog video signal output from the signal overlapping unit 140 is transmitted to the first transmission device 200 through the coaxial terminal unit 150 included in the second transmission device 300, or the power is overlapped from the first transmission device 200. The signal is received.

The power supply unit 170 supplies power required by each part of the transmitters 200 and 300. The power supply unit 170 included in the first transmission device 200 provides power to the signal overlapping unit 140 to drive the IP camera 500. In addition, in the case of the power supply unit 170 included in the second transmission device 300, the power is supplied to the IP camera 500 to receive and control the power separated from the signal overlapping unit 140.

The control unit 160 controls the signal overlapping unit 140 of the transmission apparatuses 200 and 300, and monitors the coaxial cable connected to the coaxial terminal unit 150 through the signal overlapping unit 140, and when an abnormality is detected in the coaxial cable, the power supply unit By cutting off the power output from the 170, the signal overlapping unit 140 is controlled so that the power overlap signal is not transmitted through the coaxial terminal unit 150. The operation of the controller 160 will be described in detail later with reference to FIG. 6.

FIG. 6 is a block diagram illustrating a schematic configuration of a signal overlapping part included in the transmission apparatus shown in FIG. 5.

Referring to FIG. 6, the signal overlapping unit 140 includes a signal protection unit 142, a signal separation / coupling unit 141, an LPF unit 143, a CLC unit 146, a power switching unit 144, and a monitoring unit. 145.

The signal separating / combining unit 141 combines the analog signal and the power source to generate a power overlap signal, or separates the power overlap signal into an analog signal and a power source.

The signal separation / combining unit 141 included in the first transmission device 200 combines the analog control signal output from the modem unit 130 and the power output from the power supply unit 170 to generate a power overlap signal. When the analog video signal received through the coaxial terminal unit 150 is received, the signal overlapping unit 140 is transmitted to the modem unit 130 as it is.

The signal separation / combining unit 141 included in the second transmission device 300 separates the power superposition signal received through the coaxial terminal unit 150 into an analog control signal and a power source. The analog video signal output from the modem unit 130 is transmitted from the signal overlapping unit 140 to the first transmission device 200 through the coaxial terminal unit 150 as it is.

The signal protection unit 142 prevents the power separated from the signal separation / combining unit 141 from being output to the modem unit 130.

The LPF unit 143 prevents the analog control signal separated from the signal separating / combining unit 141 from flowing into the power switching unit 144.

The CLC unit 146 checks whether the coaxial cable is connected when the power of the first transmission device 200 is turned on. That is, the controller 160 controls the CLC unit 146 to transmit the standby signal through the coaxial cable, and when the normal signal is received, determines that the second transmission device 300 is normally connected to the power switch unit 144. Is controlled to be ON, and the signal separation / combining unit 141 controls to generate a power overlap signal.

As described above, when it is determined that the second transmission device 300 is connected under the control of the controller 160, the power switching unit 144 supplies power to the signal separation / combining unit 141 from the power supply unit 170. ON as possible.

The monitoring unit 145 monitors the current flowing through the coaxial cable to determine the short, open and overcurrent of the coaxial cable. That is, the controller 160 controls the power switching unit 144 to be turned off when the short, open, and overcurrent of the coaxial cable is detected as a result of the monitoring of the monitoring unit 145.

7 is a flowchart illustrating a coaxial cable monitoring method of a camera signal transmission system according to the first to third embodiments of the present invention.

When the power of the first transmitter 200 is turned on (S600-Y), the controller 160 controls the CLC unit 146 to transmit a standby signal to the coaxial cable (S610). If it is determined that the second transmission device 300 is normally connected (S620-Y), the controller 160 turns on the power switching unit 144 (S630). That is, when the normal signal is received through the coaxial cable in response to the standby signal, the power for driving the IP camera 500 to be controlled by turning on the power switching unit from the power supply unit 170 to the signal separation / combination unit 141. To be supplied.

In addition, an analog control signal for controlling the IP camera 500 and a power are overlapped to generate and transmit a power overlap signal (S640). That is, the signal separation / combining unit 141 combines the power supplied from the power supply unit 170 and the analog control signal output from the modem unit 130 to output a power superimposition signal, and the power superimposition signal is the coaxial terminal unit 150. It is transmitted to the second transmission device 300 through.

At this time, by monitoring the current flowing through the coaxial cable (S650), it detects whether the coaxial cable is in a short state (S660). That is, the monitoring unit 145 monitors the current flowing through the coaxial cable to determine whether a short of the coaxial cable occurs. If the coaxial cable is not short (S660-N), the open / overcurrent state of the coaxial cable is sensed (S670), and if the coaxial cable is not in the open / overcurrent state (S670-N), step S640 is performed.

If it is detected that the coaxial cable is in an open / overcurrent state (S670-Y), the current of the coaxial cable is monitored for a set number of times (S675). If the open / overcurrent state of the coaxial cable is not maintained continuously (S380-N), step S340 is performed.

If the open / overcurrent state of the coaxial cable is maintained continuously (S680-Y), the power switching unit 144 is turned off (S690). That is, when it is determined that short, open, and overcurrent of the coaxial cable are generated, the controller 160 turns off the power switching unit 144 to prevent the power superposition signal from being generated and transmitted to the coaxial cable.

By the above process, it is possible to transmit and receive the superimposed power signal overlapping the analog signal and the power supply through the coaxial cable, it is possible to detect the abnormality by monitoring the coaxial cable.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Therefore, one embodiment described above is intended to be illustrative in all respects and not to be considered as limiting, the scope of the present invention is indicated by the claims that follow rather than the foregoing description, and the scope of the claims All changes or modifications derived from the meaning and scope and equivalent concept thereof should be construed as being included in the scope of the present invention.

10, 100: DVR device 30,400: Hub
100-1, 100-2, ..., 100-n: First to Nth DVR Devices
200: first transmission device 300: second transmission device
200-1, 200-2, ..., 200-n: 1-1 to 1-N transmission apparatus
300-1, 300-2, ..., 300-n: 2-1 to 2-N transmission apparatus
50,500: IP Camera
500-1, 500-2, ..., 500-n: First to Nth IP Cameras
110: UTP terminal unit 120: signal conversion unit
130: modem portion 140: signal overlapping portion
150: coaxial terminal unit 160: control unit
170: power supply unit 141: signal separation / coupling unit
142: signal protection unit 143: LPF unit
144: power switching unit 145: monitoring unit
146 CLC section

Claims (6)

Generates a power superimposition signal superimposing an analog signal for controlling the camera on a power source for driving a predetermined camera, transmits it through a coaxial cable, and monitors a current flowing through the coaxial cable to detect an abnormality in the coaxial cable. A first transmission device that blocks the generation of the power overlapping signal when the signal is overlapped; And
And a second transmission device for receiving the power superimposition signal transmitted through the coaxial cable from the first transmission device, separating the signal into an analog signal and power for controlling the camera, and transmitting the power signal to the camera.
The first transmission device,
A signal overlapping unit generating a power superimposition signal combining the analog signal with a power source for driving the camera;
A power supply unit supplying power to drive the camera to the signal overlapping unit;
A coaxial terminal unit to which a coaxial cable for transmitting the power overlapping signal generated by the signal overlapping unit to the camera is connected; And
By monitoring the coaxial cable connected to the coaxial terminal unit through the signal overlapping unit, if an abnormal occurrence is detected in the coaxial cable by cutting off the power output from the power supply unit to control the signal overlapping unit so that the power overlap signal is not generated Camera signal transmission system comprising a. delete The method of claim 1,
The signal overlapping part,
A signal separation / combining unit for combining the analog signal with the power provided by the power supply unit to generate the power overlap signal;
A CLC unit checking whether the second transmission device is connected when the power is turned on;
A monitoring unit configured to monitor current flowing through the coaxial cable and determine short, open, and overcurrent of the coaxial cable; And
And a power switching unit which is turned on and off so that power is supplied to and disconnected from the power supply unit to the signal separation / combination unit.
The control unit,
After the CLC unit controls the standby signal to be transmitted to the coaxial cable, when the normal signal is received in the CLC unit, it is determined that the second transmission device is normally connected, and the power switching unit is controlled to be turned on, and the monitoring is performed. When the short, open, and overcurrent of the coaxial cable is detected as a result of the negative monitoring, the camera signal transmission system, characterized in that for controlling to turn off the power switch. The method of claim 1,
The first transmission device,
UTP terminal unit for transmitting and receiving the Ethernet data in the form of a balanced signal connected to the UTP cable;
A signal conversion unit converting the Ethernet data in the form of a balanced signal received through the UTP terminal unit into the Ethernet data in the form of an unbalanced signal; And
And a modem unit for modulating the non-balanced Ethernet data output from the signal conversion unit into an analog signal. In the coaxial cable monitoring method of a camera signal transmission system comprising a transmission device for transmitting and receiving an analog signal through a coaxial cable between a predetermined camera and the DVR device for controlling the camera,
Transmitting a standby signal through the coaxial cable when the power of the transmitters is turned on;
When a normal signal is received through the coaxial cable in response to the standby signal, supplying power for driving the camera;
Generating and transmitting a power superimposition signal superimposing an analog signal for controlling the camera on a power supply for driving the camera;
Monitoring current flowing through the coaxial cable to determine whether a short, open, and overcurrent of the coaxial cable has occurred; And
If it is determined that the short, open, and overcurrent of the coaxial cable has occurred, controlling the power superimposition signal not to be generated;
Generating and transmitting the power overlap signal,
After converting the Ethernet control data in the form of a balanced signal transmitted from the DVR device into the Ethernet control data in the form of an unbalanced signal, modulate the signal into an analog control signal to generate the power overlap signal superimposed on a power source for driving the camera. Coaxial cable monitoring method of the camera signal transmission system, characterized in that the step of transmitting. delete

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