JP6698896B1 - Power supply and control signal superposition transmission system using video signal line in CCTV - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply and control signal superimposed transmission system using a video signal line in a CCTV. A system according to the present invention includes a PoC camera module, sends a video signal driven by the camera module to a PoC receiver, and receives a clock signal that enables the PoC receiver to sense the PoC transmitter. And a PoC transmitter for outputting to the unit, superimposing and transmitting power to the video signal line to the PoC transmitter, receiving and processing the video signal transmitted from the PoC transmitter, and controlling the camera module of the PoC transmitter. And a PoC receiver for transmitting a control signal to the PoC transmitter, wherein the PoC receiver applies power to the video signal line and superimposes the power on the PoC transmitter. A relatively low voltage is transmitted as a voltage supplied to operate only the circuit for detecting the signal, and a relatively high voltage is transmitted after the clock signal from the PoC transmitter is detected for a certain period of time. [Selection diagram]

Description

  The present invention relates to a power supply and control signal superposition transmission system using a video signal line in a CCTV, and more specifically, to a power supply and control using only a video signal line without providing a separate power supply line or control signal line. The present invention relates to a power supply and control signal superposition transmission system using a video signal line in CCTV, which can reduce the difficulty and cost associated with CCTV installation and camera setting by superimposing and transmitting a signal.

  PoC (Power over Coax) technology in Closed Circuit Television (CCTV) is a technology for transmitting power, video, and camera control signals to a remote camera and storage device via a single coaxial cable. ..

  In an environment that does not support PoC, a video line and a power line are separately required to operate a camera in a remote place. Also, depending on the environment in which the camera is installed, there are many difficulties in adding a power line, and in some cases, the already installed camera requires control such as setting change and position adjustment (PTZ). ..

  At the CCTV installation location, a general PoC-incompatible camera is installed or connected in an environment configured with PoC due to the carelessness or error of the user or the installer, or a general camera (PoC-incompatible) that is already installed is installed. (Camera) may be connected. In such a case, the PoC voltage may damage the camera or built-in components, and in severe cases, a fire may occur.

  In order to avoid the above risks, usually, when using a product that uses a PoC transmitter/receiver, be sure to install and use the transmitter/receiver set together, otherwise, PoC A method of detecting whether or not the image receiving unit (power superimposition applying unit) is connected to the PoC image transmitting unit (PoC power source separating unit) to determine whether to apply power to the image transmission line is used.

  On the other hand, Korean Patent Registration No. 10-0950741 (Patent Document 1) discloses a "power-supply superimposed video transmission system capable of stable power supply". The power superimposing video transmission system capable of stable power supply includes a coaxial cable that superimposes a power signal, a video signal and a control signal and transmits the superposed signal through one transmission line; and a camera operation via the coaxial cable. A power transmission unit for controlling remotely, receiving a captured video signal, and transmitting a power signal via a coaxial cable; receiving a power signal, providing it to the camera, and transmitting a video signal captured from the camera to the coaxial A signal transmitting unit for transmitting to the power transmitting unit via a cable; and the power transmitting unit periodically transmits the standby power to the signal transmitting unit, and Only when the ECHO signal is returned, the main power signal is transmitted to drive the camera, and the video signal of the driven camera is transmitted by being superimposed on the main power signal via the coaxial cable. When the standby power is input, the promised ECHO signal is returned to the power transmission unit via the coaxial cable.

  In the case of Patent Document 1, it is possible to detect the state of the line so as to effectively cope with various causes of a failure in the VP (power superimposition video transmission) system that may occur on the transmission line. May have advantages. However, since the countermeasures necessary for using the PoC compatible camera or the PoC non-compatible camera in the CCTV system are not presented, it is applicable when the PoC compatible camera or the PoC non-compatible camera is used in the CCTV system. There is a problem that it is difficult to do.

Korean Registered Patent Publication No. 10-0950741 (2010.4.05. Announcement)

  The present invention was created in view of the above circumstances, and an object thereof is to transmit a power supply and a control signal by superimposing only a video signal line without providing a separate power supply line or control signal line. By doing so, it is an object of the present invention to provide a power supply and control signal superposition transmission system using a video signal line in CCTV, which can reduce the difficulty and cost associated with CCTV installation and camera setting.

  Another object of the present invention is to prevent damage to the camera or built-in parts by maintaining operation in a low voltage mode when connecting a non-PoC compatible camera in a PoC environment. An object of the present invention is to provide a power supply and control signal superposition transmission system using a video signal line in a CCTV, which can prevent a fire from occurring.

In order to achieve the above object, a power supply and control signal superposition transmission system using a video signal line in a CCTV according to the present invention,
A PoC camera module is provided, the power supply signal is separated from the power supply superimposed signal transmitted from the PoC reception unit, a power supply for driving the camera is generated from the separated power supply signal, and the video signal driven by the camera module is sent to the PoC reception unit. A PoC transmitter that sends out and outputs a clock signal to the PoC receiver so that the PoC receiver can detect the PoC transmitter;
The power source supplied from the outside is processed, the power source is applied on the video signal line to be superposed and transmitted to the PoC transmission unit, and the video signal transmitted from the PoC transmission unit is received and processed, and the PoC transmission unit. A PoC receiver for transmitting a signal for controlling the camera module of the above to the PoC transmitter,
When the PoC receiver applies power to the video signal line and superimposes the power on the PoC transmitter, first, the PoC receiver relatively operates as a voltage supplied to operate only a circuit that detects the PoC transmitter. A primary voltage as a low voltage is transmitted, and a voltage supplied after detecting a clock signal from the PoC transmitter for a certain period of time is a voltage higher than the primary voltage (High Voltage). ) Is transmitted as a secondary voltage.

  Here, the PoC transmitting unit is a TR superimposing circuit unit that separates the power source signal from the power source superimposing signal by minimizing the distortion and damage of the video signal; and the power source for driving the camera from the separated power source signal (for example, A DC-DC conversion circuit unit that generates +12 VDC; an oscillation circuit unit that outputs a clock signal that enables the PoC reception unit to detect the PoC transmission unit to the PoC reception unit; and the oscillation circuit unit. And a selection circuit section for outputting an enable signal for outputting a clock signal to the oscillation circuit section.

  The PoC receiving unit includes a power output unit that superimposes a power source on a video signal line and transmits the power signal to the PoC transmitting unit; a video signal that is processed by a video signal received from the PoC transmitting unit and sent to a recording device (DVR) A signal processing unit; a video detection unit for detecting a state of a video signal on a video signal line; a power management unit for controlling and controlling the power supply output unit, the video signal processing unit and the video detection unit as a whole, And a control unit that receives the transmission signal, determines the type of the signal, and executes a corresponding control operation based on the type of the signal.

  The PoC receiving unit may output a relatively low voltage (Low Voltage) according to the control operation performed by the control unit; a low voltage output unit that outputs a relatively low voltage; And a high voltage output section that outputs a high voltage (High Voltage) may be further included.

  At this time, the relatively low voltage (Low Voltage) may be a voltage of 6 to 7V DC, and the relatively high voltage (High Voltage) may be a voltage of 36 to 48V DC.

  In addition, when the video detection unit determines a signal input from the PoC transmission unit to the PoC reception unit by the control unit, a signal that may contain actual video data that may confuse the determination. The portion may be cut out based on a preset voltage level, a high frequency signal may be filtered using a low pass filter (LPF), and then the signal may be transmitted to the control unit.

  In addition, the types of the signals that the control unit determines by receiving the transmission signal from the PoC transmission unit include a PoC transmission unit connection status signal, a camera direct connection status signal, a no-signal input or an abnormal status signal. You may stay.

  At this time, if the type of signal determined by the control unit upon receiving the transmission signal from the PoC transmission unit is a PoC transmission unit connection status signal, the control unit sets the power superimposition mode to a low voltage (Low). The high voltage may be supplied to the PoC transmission unit by switching from the high voltage (High Voltage) mode to the high voltage (High Voltage) mode.

  When the control unit receives the transmission signal from the PoC transmission unit and determines the type of the signal is a camera direct connection state signal, the control unit controls the low voltage mode that does not damage the camera device. May be configured to maintain operation.

  When the control unit receives the transmission signal from the PoC transmission unit and determines that the type of signal is no signal input or an abnormal state signal, the control unit maintains the low voltage mode. It may be configured to repeat the routine for input signal sensing.

  Further, in the high voltage mode in which the PoC transmission unit is supplying the camera power, the control unit continuously monitors the input signal to determine whether the video signal is continuous, When a video loss state occurs in which a signal disappears, it may be configured to switch to a low voltage mode and return to a routine for sensing an input signal to perform an operation.

  Further, when the PoC receiver determines that the PoC transmitter is directly connected to a general camera that is not a PoC-compatible camera, the PoC receiver may prevent damage to the camera due to overvoltage on the video signal line. The operation may be continued while the mode is maintained, and the presence or absence of the continuation of the video signal input to the control unit may be monitored in this state.

  At this time, if it is determined that the video signal is in a loss state while monitoring the continuity of the video signal, the control unit is configured to return to a routine for sensing an input signal and perform an operation. May be.

  In addition, when the PoC receiver uses UTC (Up The Coax) communication, the PoC receiver may directly transmit a video signal input from the PoC transmitter to the recording device (DVR) side through only passive elements. However, when the UTC communication is not used, a route in which an input video signal passes through an amplifier or a buffer and is transmitted to the recording device (DVR) side may be used.

  According to the present invention, a power supply and a control signal are superimposed and transmitted by using only a video signal line without providing a separate power supply line or control signal line, thereby accommodating CCTV installation and camera setting. There is an advantage that difficulty and cost can be reduced.

It is a figure which shows schematically the whole structure of the CCTV system to which the power supply and the control signal superposition transmission system using the video signal line in CCTV which concerns on this invention are applied. It is a figure which shows schematically the structure of the PoC transmission part of the power supply and control signal superposition transmission system using the video signal line in CCTV which concerns on embodiment of this invention. It is a figure which shows schematically the structure of the PoC receiving part of the power supply and control signal superposition transmission system using the video signal line in CCTV which concerns on embodiment of this invention. It is a figure which shows the mechanism which generates the signal for PoC camera detection in an oscillation circuit part diagrammatically. It is a figure which shows the high voltage operation mode of the PoC receiver in the power supply and control signal superposition transmission system using the video signal line in CCTV which concerns on this invention. It is a figure which shows the low voltage operation mode of the PoC receiving part in the power supply and control signal superposition transmission system using the video signal line in CCTV which concerns on this invention. FIG. 6 is a diagram showing a low-voltage operation mode of a PoC receiver when a PoC-incompatible camera is connected in a power supply and control signal superimposing transmission system using a video signal line in a CCTV according to the present invention. It is a figure which shows a UTC path|route and an amplifier path|route as a flow path of the video signal by the side of a PoC receiving part.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 is a diagram schematically showing an overall configuration of a CCTV system to which a power supply and control signal superposition transmission system using video signal lines in a CCTV according to the present invention is applied.

  Referring to FIG. 1, the CCTV system 100 may include a PoC transmission unit 110, a PoC reception unit 120, and a DVR (Digital Video Recorder) 130. As shown in FIG. 1, a video signal, a control signal, and a power source are transmitted and received between the PoC transmitter 110 and the PoC receiver 120 via one channel (video signal line), and the PoC receiver 120 and the DVR (recording device) are transmitted and received. A video signal and a control signal are transmitted to and received from the device 130 via one channel (video signal line). Here, the PoC transmission unit 110 and the PoC reception unit 120 will be described in detail later.

  INDUSTRIAL APPLICABILITY The present invention facilitates physical (hardware) installation and software setting of a CCTV camera, reduces physical and time costs for CCTV installation and setting, and improves convenience in use. This is a technical issue, and for that purpose, a power supply superimposing transmission technique using PoC and a control signal superimposing transmission technique using UTC (Up The Coax) are introduced. That is, the power supply is transmitted using only the video signal line (PoC) and the control signal is transmitted (UTC) without providing a separate power supply line or control signal line. It is intended to solve the problem of.

  Now, the present invention as described above will be described in detail below.

  FIG. 2 is a diagram schematically showing a configuration of a PoC transmitter of a power supply and control signal superposition transmission system using a video signal line in a CCTV according to an embodiment of the present invention, and FIG. 3 is an embodiment of the present invention. FIG. 3 is a diagram schematically showing a configuration of a PoC receiving unit of a power supply and control signal superimposed transmission system using a video signal line in the CCTV according to the present invention.

  Referring to FIGS. 2 and 3, the power supply and control signal superposition transmission system using the video signal line in the CCTV according to the present invention may include a PoC transmitter 110 and a PoC receiver 120.

  The PoC transmission unit 110 includes a PoC camera module 115, separates a power supply signal from a power supply superimposition signal transmitted from the PoC reception unit 120, and generates a power supply for driving the camera from the separated power supply signal. The driving image signal is transmitted to the PoC receiving unit 120, and the PoC receiving unit 120 outputs a clock signal to the PoC receiving unit 120 so that the PoC transmitting unit 110 can be detected.

  The PoC receiver 120 processes an externally supplied power (for example, AC 110 to 220 V), applies power to the video signal line, superimposes the power on the PoC transmitter 110, and transmits from the PoC transmitter 110. The received video signal is processed, and a signal for controlling the camera module 115 of the PoC transmitter 110 is transmitted to the PoC transmitter 110.

  The PoC receiving unit 120 in the power supply and control signal superimposing transmission system using the video signal line in the CCTV according to the present invention having the above-mentioned configuration applies the power supply to the video signal line to transmit the PoC transmitting unit. In superposing and transmitting to the 110, first, a primary voltage as a relatively low voltage (Low Voltage) is transmitted as a voltage supplied to operate only a circuit that detects the PoC transmitting unit 110, and the PoC transmission is performed. As a voltage supplied after detecting the clock signal from the unit 110 for a certain period of time (for example, about 3 seconds), a secondary voltage as a voltage (High Voltage) relatively higher than the primary voltage is transmitted. At this time, the relatively low voltage (Low Voltage) may be a voltage of 6 to 7V DC, and the relatively high voltage (High Voltage) may be a voltage of 36 to 48V DC.

  As shown in FIG. 2, the PoC transmission unit 110 includes a TR superimposition circuit unit 111 that separates a power supply signal from a power supply superimposition signal by minimizing distortion and damage of a video signal; and driving a camera from the separated power supply signal. A DC-DC conversion (for example, DC48V or 36V to DC12V) circuit section 112 for generating a power supply (for example, +12V DC); and a clock that enables the PoC reception section 120 to detect the PoC transmission section 110 ( an oscillating circuit section 114 for outputting a clock signal to the PoC receiving section 120; and a selecting circuit section 113 for outputting an enable signal for causing the oscillating circuit section 114 to output a clock signal to the oscillating circuit section 114. And; may be included. Here, the oscillator circuit unit 114 may include an oscillator (oscillator) that generates a 4 MHz clock and an output switch IC circuit. Here, the mechanism for generating the PoC camera sensing signal in the oscillator circuit 114 will be described.

  FIG. 4 is a diagram schematically showing a mechanism of generating a PoC camera sensing signal in the oscillation circuit unit.

  Referring to FIG. 4, the PoC transmitter 110 uses two voltages transmitted from the PoC receiver 120, which is a high voltage of DC 36V or 48V for a general camera that does not support PoC. Is applied to prevent the camera from being burnt out. When the power is turned on (ON), a low voltage of 6 to 7 VDC (hereinafter referred to as LV) is received from the PoC receiver 120, but this voltage does not operate the camera module and the I/F circuit, and the “PoC transmitter” part ( (See FIG. 2) is a voltage for operating only the circuit for sensing.

  The LV signal is converted into a “HIGH” signal through the “RESISTOR DIVIDE and TR circuit” (selection circuit unit) 113 (see FIG. 2), and the 4 MHz clock of the source of the oscillator circuit unit 114 is PoC reception. It is used as an enable signal output to the unit 120. The PoC receiver 120 senses this signal for about 3 seconds to determine that the PoC transmitter is present, and then the PoC transmitter 110 receives the HV. In the HV mode, the open circuit output is selected by the selection circuit unit 113 from the sources of the oscillation circuit unit 114, and the image signal is not affected and the system stands by. At the same time, the HV outputs the operating power supply (DC 12V) of the camera through the DC-DC conversion circuit unit 112, and the camera module 115 is operated thereby, so that the video signal is output to the PoC receiving unit 120. If the camera is a camera without a PoC transmitter, the 4 MHz clock cannot be transmitted to the PoC receiver 120, so the PoC receiver 120 does not output the HV. Therefore, the PoC transmitter 120 does not output the HV. You will be able to protect the none (None PoC camera).

  That is, only inexpensive and simple oscillation components and a selection circuit are added to the PoC transmitter 110 to minimize interference with the video signal and the control signal, and this signal is sensed by the PoC receiver (power transmitter and video receiver). By making the judgment, the PoC receiver 120 can determine an accurate operation mode and a voltage level corresponding to the operation mode, and as a result, prevent malfunction or damage that may occur during PoC use and installation. Will be able to.

  Referring again to FIG. 3, the PoC receiving unit 120 processes a video signal received from the PoC transmitting unit 110 and a power output unit 121 that superimposes a power source on the video signal line and transmits the power to the PoC transmitting unit 110. A video signal processing unit 122 for sending to a recording device (DVR); a video detection unit 123 for detecting the state of a video signal on a video signal line; and a power supply output unit 121, a video signal processing unit 122 and a video detection unit 123. A control unit 124 that manages and controls the entire system, receives a transmission signal from the PoC transmission unit 110, determines a signal type, and executes a corresponding control operation based on the signal type. May be done. Here, the control unit 124 may be configured by a programmable logic device (PLD), an FPGA (Field Programmable Gate Array), a central processing unit (CPU), or the like.

  Here, the PoC receiving unit 120 as described above includes a low voltage output unit 125 that outputs a relatively low voltage (Low Voltage) according to the control operation performed by the control unit 124; It may further include a high voltage output unit 126 that outputs a voltage (High Voltage) relatively higher than the output voltage.

  At this time, the relatively low voltage (Low Voltage) may be a voltage of 6 to 7V DC, and the relatively high voltage (High Voltage) may be a voltage of 36 to 48V DC.

  Also, when the video detection unit 123 determines the signal input from the PoC transmission unit 110 to the PoC reception unit 120 by the control unit 124, there may be actual video data that may confuse the determination. A signal portion having a certain characteristic is cut out based on a preset voltage level, a high frequency signal is filtered using a low pass filter (LPF, low pass filter), and then the signal is sent to the control unit 124. It may be configured to transmit. Here, the signal input to the control unit 124 through such a process is unchanged or unchanged from the determination signal of the transmission unit of 4 MHz, the video synchronization signal (for example, a signal having a frequency characteristic of 25 KHz to 35 KHz). It can be classified as a random signal.

  In addition, the types of signals that the control unit 124 receives and determines the transmission signal from the PoC transmission unit 110 include a PoC transmission unit connection status signal, a camera direct connection status signal, a no-signal input or an abnormal status signal. You can leave.

  At this time, if the control unit 124 receives the transmission signal from the PoC transmission unit 110 and determines that the type of the signal is a PoC transmission unit connection status signal (that is, a 4 MHz transmission unit determination signal), As shown in FIG. 5, the controller 124 switches the power supply superimposition mode from the low voltage (Low Voltage) mode to the high voltage (High Voltage) mode, and the transmitted power (high voltage) is supplied to the PoC transmitter 110. It may be configured such that the power is converted and supplied to the camera power supply (DC 12V) via the PoC transmitter.

  In addition, when the control unit 124 receives the transmission signal from the PoC transmission unit 110 and determines that the type of the signal is a camera direct connection state signal (that is, a video synchronization signal output from the camera), As shown in FIG. 6, the controller 124 may be configured to maintain operation in a low voltage mode that does not damage the camera device.

  When the control unit 124 receives the transmission signal from the PoC transmission unit 110 and determines that the type of the signal is no signal input or an abnormal state signal (that is, no change or random signal), Similar to the case of the camera direct connection status signal (video synchronization signal coming out of the camera), the control unit 124 is configured to repeatedly perform a routine for detecting an input signal while maintaining the low voltage mode. You may.

  In addition, in the high voltage mode (see FIG. 5) in which the PoC transmitter 110 is supplying the camera power, the controller 124 continuously monitors the input signal and the video signal continues. It is configured to determine whether or not there is a video signal, and to switch to the low voltage mode (see FIG. 6) when the video signal disappears (Video Loss) to return to the routine for input signal detection and perform the operation. Good.

  On the other hand, when the PoC receiver 120 determines that the PoC transmitter 110 is directly connected to a general camera (none PoC) that is not a PoC compatible camera (that is, when a video signal is detected in the low voltage mode). In order to prevent the camera from being damaged by the overvoltage on the video signal line, as shown in FIG. 7, the operation is continued in the state where the low voltage mode is maintained, and in this state, the same as in the high voltage mode. It may be configured to monitor whether or not the video signal input to the control unit 124 is continuous. At this time, if it is determined that the video signal is in the loss state while monitoring the continuity of the video signal, the controller 124 returns to the routine for sensing the input signal and operates. May be done.

  Further, as shown in FIG. 8, when the PoC receiver 120 uses the UTC (Up The Coax) communication, the video signal input from the PoC transmitter 110 is recorded only by the passive device. When the path directly transmitted to the DVR) side is used and the UTC communication is not used (normal case), the input video signal passes through the amplifier or buffer and is transmitted to the recording device (DVR) side. It may be configured to use the route (red route). A further description will now be given in connection with such route usage.

  When analog video signals are connected over a long distance, there is a problem that video distortion and deterioration occur due to the characteristics on the line. In such a case, a signal amplification circuit, a buffer and a filter circuit, etc. are usually connected to the video transmission side to improve the characteristics. However, due to the characteristics of the configuration of the analog buffer and the amplifier circuit, in such a case, only unidirectional signal transmission from the camera side to the video receiver is possible. Then, since the camera control signal (UTC signal) to be transmitted in the opposite direction (video receiver→camera) cannot be transmitted, the camera cannot be remotely controlled and operated from the video receiver side. That is, by selecting a method for improving the video signal, one important function (camera control signal transmission function) must be discarded.

  According to the present invention, in order to solve such a problem, the video flow path on the PoC receiver side is defined as “a path passing through an amplifier or a buffer” and “an input video signal is output through only a passive element (recording device (DVR )) is directly transmitted to ")", and a method that allows selective use when necessary is introduced.

  In other words, when using the camera-controlled UTC communication, try to use the "route in which the input video signal is directly transmitted to the output side through only the passive element", and if not, "pass through the amplifier or buffer". This is a method for promoting the use of the "route to do".

  Normally, the camera control (UTC communication) is temporarily used only at the time of camera installation and maintenance. Therefore, except for this case, by using the "route through the amplifier or buffer", A system that satisfies two needs (namely, reception of a video signal on the PoC receiver side and transmission of a camera control signal to the PoC transmitter) is adopted.

  At this time, as the route selection method as described above, a manual method in which the control unit 124 detects a physical switch operation of the user to select a route and a control method in which the control unit 124 communicates with the video receiving device are necessary. In such a case, there is an automatic method that automatically selects and switches the route.

  As described above, the power supply and control signal superimposing transmission system using the video signal line in the CCTV according to the present invention does not provide a separate power supply line or control signal line, and uses only the video signal line to control the power supply and control. By superimposing and transmitting the signal, there is an advantage that difficulty and cost associated with CCTV installation and camera setting can be reduced.

  Further, when a PoC-incompatible camera is connected in an environment configured with PoC, by continuing the operation while maintaining the low voltage mode, damage to the camera or built-in parts or fire can be prevented. There is an advantage that.

  Although the present invention has been described in detail above with reference to the preferred embodiments, the present invention is not limited to the embodiments, and various modifications and applications are possible without departing from the technical idea of the present invention. Is obvious to one of ordinary skill in the art. Therefore, the true protection scope of the present invention is determined only by the scope of the claims, and all technical ideas within the scope equivalent thereto are construed to be included in the scope of right of the present invention. Should be.

110 PoC transmission unit 111 TR superposition circuit unit 112 DC-DC conversion circuit unit 113 selection circuit unit 114 oscillation circuit unit 115 PoC camera module 120 PoC reception unit 121 power output unit 123 video detection unit 124 control unit 125 low voltage output unit 126 high Voltage output unit 130 DVR

Claims (12)

Comprising a PoC camera module, to separate the power signal from the transmitted power superposition signal from the PoC receiver generates a power supply for the camera drive from the separated power signal, the video signal by the driving of the camera module the PoC receiver a PoC transmitting unit transmits the PoC receiving unit for outputting a clock (clock) signals to be able to sense the PoC sending unit to the PoC receiver to;
The power supplied from the outside is processed, the power is applied on the video signal line to be superposed and transmitted to the PoC transmission unit, the video signal transmitted from the PoC transmission unit is received and processed, and the PoC transmission unit is processed. comprises; a PoC receiving section for transmitting a signal for controlling the camera module of the PoC transmission unit
The PoC receiver, when superimposed transmitted to the PoC sending unit by applying power to the video signal line, first, as the voltage supplied to operate the circuits for detecting the PoC sending unit, relatively A primary voltage as a low voltage is transmitted, and a voltage supplied after detecting a clock signal from the PoC transmitter for a certain period of time is a voltage higher than the primary voltage (High Voltage). ) As a secondary voltage ,
The PoC receiver is
A power supply output unit for superimposing a power supply on the video signal line and transmitting it to the PoC transmission unit;
A video signal processing unit that processes the video signal received from the PoC transmission unit and sends the processed video signal to a recording device (DVR);
A video detector for detecting the state of the video signal on the video signal line;
The power supply output unit, the video signal processing unit, and the video detection unit are managed and controlled as a whole, the transmission signal from the PoC transmission unit is received, the type of the signal is determined, and corresponding control is performed based on the type of the signal. A control unit for performing an operation;
When the control unit determines a signal input from the PoC transmission unit to the PoC reception unit, the video detection unit detects a signal portion that may contain actual video data that may confuse the determination. Characterized in that the high-frequency signal is cut out based on a preset voltage level and a high-frequency signal is filtered by using a low pass filter (LPF), and then the signal is transmitted to the control unit. A power supply and control signal superposition transmission system using video signal lines in CCTV. The PoC transmitter is
A TR superimposing circuit section that separates the power supply signal from the power supply superimposing signal while minimizing distortion and damage of the video signal;
A DC-DC conversion circuit unit for generating a power supply for driving the camera from the separated power supply signal;
An oscillation circuit section and the PoC receiving unit for outputting a clock (clock) signals to be able to sense the PoC sending unit to the PoC receiver;
The video signal line according to claim 1, further comprising: a selection circuit section that outputs an enable signal to the oscillation circuit section to cause the oscillation circuit section to output a clock signal. A power supply and control signal superposition transmission system using the. The PoC receiver is
A low-voltage output unit that outputs a relatively low voltage (Low Voltage) according to the execution of the control operation of the control unit;
A high voltage output section that outputs a low voltage output relatively higher than the voltage output from the unit voltage (High Voltage); characterized in that it further comprises a video signal line in the CCTV according to claim 1 A power supply and control signal superposition transmission system using the. The relatively low voltage (Low Voltage) is a voltage of DC6~7V, the relatively high voltage (High Voltage) is a voltage of DC36~48V, The claim 3 , characterized in that. Power supply and control signal superposition transmission system using video signal lines in CCTV. The type of the signal that the control unit receives and determines the transmission signal from the PoC transmission unit includes a PoC transmission unit connection state signal, a camera direct connection state signal, a no-signal input or an abnormal state signal. A power supply and control signal superposition transmission system using the video signal line in the CCTV according to claim 1 . When the control unit receives the transmission signal from the PoC transmission unit and determines the type of the signal is the PoC transmission unit connection status signal, the control unit sets the power supply superimposition mode to the low voltage (Low Voltage) mode. To a high voltage (High Voltage) mode, the high voltage is supplied to the PoC transmitter, the power source using the video signal line in the CCTV according to claim 5 , and Control signal superposition transmission system. When the control unit receives the transmission signal from the PoC transmission unit and determines the type of the signal is a camera direct connection state signal, the control unit maintains a low voltage mode that does not damage the camera device. The power supply and control signal superposition transmission system using a video signal line in a CCTV according to claim 5 , wherein the power supply and control signal superposition transmission system is configured to maintain the operation in the above state. When the control unit receives the transmission signal from the PoC transmission unit and determines that the type of the signal is a no-signal input or an abnormal state signal, the control unit keeps the input signal in the low voltage mode. The power supply and control signal superposition transmission system using a video signal line in a CCTV according to claim 5 , wherein the power transmission and control signal superposition transmission system is configured to repeatedly perform a sensing routine. In the high voltage mode in which the PoC transmission unit is supplying the camera power, the control unit continuously monitors the input signal to determine whether the video signal is continuous, When is disappearing image loss (video loss) state, is switched to the low voltage mode, characterized in that it is configured to perform the operations and returns to the routine for input signal sensing, according to claim 1 A power supply and control signal superposition transmission system using video signal lines in CCTV. When the PoC receiving unit determines that the PoC transmitting unit is directly connected to a general camera that is not a PoC compatible camera, the PoC receiving unit does not damage the camera due to an overvoltage on the video signal line, and thus the low voltage mode is set. The video signal line according to claim 1 , wherein the video signal line in the CCTV is configured to continue the operation in a state of maintaining A power supply and control signal superposition transmission system using the. When the it is determined that the loss state of the video signal during the monitoring duration existence of the video signal, the control unit is possible to return to the routine for input signal sensing is configured to perform the operations 11. A power supply and control signal superposition transmission system using a video signal line in a CCTV according to claim 10 . A PoC camera module is provided, the power supply signal is separated from the power supply superimposed signal transmitted from the PoC reception unit, a power supply for driving the camera is generated from the separated power supply signal, and the video signal driven by the camera module is sent to the PoC reception unit. A PoC transmitter that sends out and outputs a clock signal to the PoC receiver so that the PoC receiver can detect the PoC transmitter;
The power supplied from the outside is processed, the power is applied on the video signal line to be superposed and transmitted to the PoC transmission unit, the video signal transmitted from the PoC transmission unit is received and processed, and the PoC transmission unit is processed. A PoC receiver for transmitting a signal for controlling the camera module to the PoC transmitter;
When the PoC receiver applies power to the video signal line and superimposes the power on the PoC transmitter, first, the PoC receiver relatively operates as a voltage supplied to operate a circuit for detecting the PoC transmitter. A primary voltage as a low voltage is transmitted, and a voltage supplied after detecting a clock signal from the PoC transmitter for a certain period of time is a voltage higher than the primary voltage (High Voltage). ) As a secondary voltage,
When the PoC receiver uses UTC (Up The Coax) communication, the PoC receiver transmits a path through which the video signal input from the PoC transmitter is directly transmitted to the recording device (DVR) side through only passive elements. When it is used and the UTC communication is not used, it is configured to use a path through which an input video signal passes through an amplifier or a buffer and is transmitted to a recording device (DVR) side. , CC Power supply and control signal superimposed transmission system using video signal lines in CTV.