KR101385858B1 - Video signal transmission system using transmission line - Google Patents

Abstract

The present invention relates to a video signal transmission system using a transmission line, the video signal transmission system using a transmission line according to an embodiment of the present invention, a video signal for transmitting a video signal obtained from the image pickup apparatus using the transmission line And a video signal receiver connected to the transmission line to receive the video signal, wherein the video signal transmitter supplies power to the video signal receiver using the transmission line, and the video signal receiver is the video signal. The current path of the power supplied from the signal transmitter through the transmission line is controlled to transmit an auxiliary signal for controlling the imaging device to the image signal transmitter using the transmission line.
Accordingly, by controlling the current path for the video signal and the video device control signal transmitted through one transmission line, it is possible to minimize and transmit the video signal and interference without modulating the control signal.

Description

Video signal transmission system using transmission line {VIDEO SIGNAL TRANSMISSION SYSTEM USING TRANSMISSION LINE}

The present invention relates to a video signal transmission system using a transmission line, and more particularly, a technology for transmitting a video signal and a video device control signal through one transmission line is disclosed.

Today, the use of surveillance cameras in crime prevention and industrial facility management is increasing. When the video signal acquired through the camera is transmitted to the manager by using the transmission line, the manager uses the video information to control the camera to control the camera such as the camera's angle, zoom in / zoom out, screen setting, and recording time setting. Will be sent. However, the conventional video signal transmission system has a problem of increasing installation cost and management by separately using a transmission line for transmitting a video signal of the camera and an auxiliary line for transmitting a control signal for controlling the camera.

In order to solve this problem, it is easy to install by transmitting the video signal and various control signals of the camera by using the power line communication method that can use the existing power line network as a video communication line, and the video transmission and reception based on economic power line communication The system was developed. However, the method using one power line also uses a method of modulating and transmitting the control signal in order to prevent interference between the control signal and the image signal. In this case, since the control signal transmitting means requires a power source, the control signal transmitting end must have a modulator, and the control signal receiving end must have a demodulator.

The background technology of the present invention is disclosed in Republic of Korea Patent Publication No. 10-1069368 (2011. 09. 26).

The technical problem to be solved by the present invention is to provide a video signal transmission system using a transmission line that can be transmitted by minimizing interference with each other by controlling the current path for the video signal and the video device control signal transmitted through one transmission line To provide.

An image signal transmission system using a transmission line according to an embodiment of the present invention includes a video signal transmission unit for transmitting an image signal, which is a serial digital interface (SDI) signal obtained from an imaging apparatus, using a transmission line, and the transmission line; A video signal receiver connected to receive the video signal, wherein the video signal transmitter supplies power to the video signal receiver using the transmission line, and the video signal receiver receives the transmission line from the video signal transmitter. The current path of the power supplied through the control unit is controlled to transmit an auxiliary signal for controlling the imaging device to the image signal transmitter using the transmission line.

In addition, the auxiliary signal may be an unmodulated signal.

In addition, the transmission line may be a coaxial cable.

The video signal transmitter may include a first high pass filter configured to pass the video signal input at one end, and to block the auxiliary signal input at the other end, and one end of the first high pass filter to the other end of the first high pass filter. A first low pass filter connected in parallel to pass the auxiliary signal, a power supply unit connected to the other end of the first low pass filter to supply power to the image signal receiver, and a first low pass filter of the first low pass filter It is connected to the other end, and may include an auxiliary signal receiving unit for receiving the auxiliary signal.

The video signal receiver may include a second low pass filter having one end connected in parallel with one end of the first low pass filter to pass the auxiliary signal, and one end having one end of the second low pass filter. And a second high pass filter connected in parallel to pass the video signal, and one end connected to the other end of the second low pass filter, and an auxiliary signal transmitter configured to receive the auxiliary signal at the other end. .

In addition, the first low pass filter and the second low pass filter has a cutoff frequency of 200 KHz or less and passes a frequency signal smaller than the cutoff frequency, and cutoff frequencies of the first high pass filter and the second high pass filter. Is less than 200 KHz, and can pass a frequency signal larger than the cutoff frequency.

In addition, according to the voltage level of the auxiliary signal input to the auxiliary signal transmitter, the contact point of the power supply and the auxiliary signal receiver and the voltage level of the auxiliary signal receiver may be changed in conjunction.

In addition, when the voltage of the auxiliary signal input to the auxiliary signal transmitter is high level, the voltage of the contact point of the power supply and the auxiliary signal receiver is low level, the voltage of the auxiliary signal receiver may be changed to high level. have.

In addition, when the voltage of the auxiliary signal is a high level, the current path of the power supply passes through the power supply unit, the first low pass filter, the transmission line, the second low pass filter and the auxiliary signal transmitter sequentially. It may be a path.

In addition, when the voltage of the auxiliary signal input to the auxiliary signal transmitter is low level, the voltage of the contact point of the power supply and the auxiliary signal receiver is a high level, the voltage of the auxiliary signal receiver may be changed to a low level. have.

In addition, when the voltage of the auxiliary signal is a low level, the current path of the power source may be a path passing through the power supply unit and the auxiliary signal receiver sequentially.

Accordingly, by controlling the current path for the video signal and the video device control signal transmitted through one transmission line, it is possible to minimize and transmit the video signal and interference without modulating the control signal. In addition, the control signal transmitter may transmit the control signal without a separate power source.

1 is a block diagram of a video signal transmission system using a transmission line according to an embodiment of the present invention;
FIG. 2 is a detailed circuit diagram of a video signal transmission system using a transmission line according to FIG. 1.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms used are terms selected in consideration of the functions in the embodiments, and the meaning of the terms may vary depending on the user, the intention or the precedent of the operator, and the like. Therefore, the meaning of the terms used in the following embodiments is defined according to the definition when specifically defined in this specification, and unless otherwise defined, it should be interpreted in a sense generally recognized by those skilled in the art.

1 is a block diagram of a video signal transmission system using a transmission line according to an embodiment of the present invention.

Referring to FIG. 1, an image signal transmission system 100 using a transmission line according to an embodiment of the present invention includes an image signal transmitter 110, a transmission line 120, and an image signal receiver 130.

The image signal transmitter 110 transmits the image signal obtained from the image pickup apparatus (not shown) to the image signal receiver 130 using the transmission line 120. In this case, the image capturing apparatus includes a camera or an imaging apparatus corresponding to the camera. In addition, the transmission line 120 is a line for transmitting a serial digital interface (SDI) transmission signal of 270Mb / sec or more, but may use a coaxial cable having a length of 100m or more, but is not limited thereto. In addition, the video signal is a serial digital interface signal, a DC signal having a voltage output of -1V to + 1V, a signal having a voltage output of -2.5V to + 2.5V at a frequency of 0Hz to 5KHz or less, and a frequency of 5KHz to 27MHz. At least one of a signal having a voltage output of -100mv to + 100mV, a signal having a voltage output of -40mv to + 40mV at a frequency of 27MHz or more.

In addition, the image signal transmitter 110 supplies power to the image signal receiver 130 using the transmission line 120, and controls the image signal receiver 130 to control the image pickup device through the transmission line 120. Receive an auxiliary signal which is a signal. In this case, the auxiliary signal may use an unmodulated unmodulated signal. More specifically, the video signal transmitter 110 includes a first high pass filter 111, a first low pass filter 113, a power supply 115, and an auxiliary signal receiver 117.

The first high pass filter 111 is connected in series with the transmission line 120 to pass an image signal input at one end and block an auxiliary signal input at the other end. For example, the video signal is a signal of the frequency band of 200KHz or more, the auxiliary signal is a signal of the frequency band of DC ~ less than 200KHz and is a signal of a low frequency band relative to the video signal. In this case, the first high pass filter 111 may be implemented as a passive filter to pass an image signal, which is a signal of a high frequency band, and to block an auxiliary signal, which is a signal of a low frequency band, by a user's setting. Therefore, the image signal obtained through the imaging device may be transmitted from the image signal transmitter 110 to the image signal receiver 130 through the transmission line 120.

One end of the first low pass filter 113 is connected to the other end of the first high pass filter 111 to pass an auxiliary signal input from the image signal receiver 130 through the transmission line 120. That is, the first low pass filter 113 branches from the transmission line 120 to pass only an auxiliary signal that is a signal of a low frequency band and blocks an image signal of a high frequency band. Accordingly, the auxiliary signal transmitted from the video signal receiver 130 overlaps the video signal in a portion of the transmission line 120, but the auxiliary signal is separated by the first low pass filter 113, thereby preventing interference with the video signal. It can be minimized.

The power supply unit 115 is connected to the other end of the first low pass filter 113 to supply power to the image signal receiver 130. For example, the power supply unit 115 supplies a current of 50 mA or less to the image signal receiver 130. In addition, in the present specification, for convenience of description, the power supply unit 115 supplies power to the image signal receiver 130, but only the auxiliary signal transmitter 135 of the image signal receiver 130 is supplied with power. Therefore, the power supply unit 115 exists only in the video signal transmitter 110 and supplies power to transmit the auxiliary signal from the video signal receiver 130. Therefore, the auxiliary signal transmitter 135 of the image signal receiver 130 does not require a separate power source. The power supply 115 may set a current path of the power source differently under the control of the auxiliary signal transmitter 135 of the image signal receiver 130. A detailed description thereof will be given later.

The auxiliary signal receiver 117 is connected to the other end of the first low pass filter 113 to receive an auxiliary signal transmitted from the image signal receiver 130. The auxiliary signal receiver 117 may output the received auxiliary signal to an external image pickup device (not shown). The auxiliary signal is set to a kind of voltage level, and may be configured, for example, when the voltage is high level and when it is low level.

Meanwhile, the video signal receiver 130 is connected to the transmission line 120 to receive the video signal transmitted from the video signal transmitter 110. In addition, the image signal receiver 130 controls the current path of the power supplied from the image signal transmitter 110 through the transmission line 120, and uses the transmission line 120 to provide an auxiliary signal for controlling the imaging device. The video signal is transmitted to the transmitter 110. That is, the video signal receiver 130 receives a video signal and transmits an auxiliary signal. In this case, as described above, the image signal receiver 130 may not include a separate power source. More specifically, the image signal receiver 130 includes a second low pass filter 131, a second high pass filter 133, and an auxiliary signal transmitter 135.

One end of the second low pass filter 131 is connected to one end of the first low pass filter 113 to pass the auxiliary signal. That is, the second low pass filter 131 is branched from the transmission line 120 to block the video signal and to pass the auxiliary signal. The second low pass filter 131 is a passive filter for classifying an auxiliary signal and an image signal in a configuration corresponding to the first low pass filter 113 of the video signal transmitter 110.

One end of the second high pass filter 133 is connected to one end of the second low pass filter 131 to pass an image signal. That is, the second high pass filter 133 is connected in series with the transmission line 120 to pass the image signal transmitted from the image signal transmitter 110 through the transmission line 120, and blocks the auxiliary signal. The second high pass filter 133 is a passive filter for classifying the video signal and the auxiliary signal in a configuration corresponding to the first high pass filter 111 of the video signal transmitter 110. Therefore, the transmission path ① of the video signal passes through the first high pass filter 111, the transmission line 120, and the second high pass filter 133 sequentially.

For example, the cutoff frequencies of the first high pass filter 111 and the second high pass filter 133 are 10 KHz or more and 200 KHz or less, and pass a video signal having a frequency signal greater than the cutoff frequency, and then pass the first low pass filter. 113 and the second low pass filter 131 may pass an auxiliary signal having a cutoff frequency of 10 KHz or more and 200 KHz or less and having a frequency signal smaller than the cutoff frequency.

The auxiliary signal transmitter 135 has one end connected to the other end of the second low pass filter 131, and the auxiliary signal is input to the other end. The auxiliary signal transmitter 135 may transmit the auxiliary signal to the auxiliary signal receiver 117 by controlling the current paths ③-1 and ③-2 of the power transmitted from the power supply 115. That is, according to the voltage level of the auxiliary signal input to the auxiliary signal transmitter 135, the voltage level of the contact point P and the auxiliary signal receiver 117 of the power supply 115 and the auxiliary signal receiver 117 is changed in conjunction with each other. do. Therefore, the transmission path of the auxiliary signal ② passes through the auxiliary signal transmitter 135, the second low pass filter 131, the transmission line 120, the first low pass filter 113, and the auxiliary signal receiver 117. Done.

For example, when the voltage of the auxiliary signal input to the auxiliary signal transmitter 135 is high level, the voltage of the contact point P of the power supply 115 and the auxiliary signal receiver 117 is low level, and the auxiliary signal receiver The voltage at 117 is changed to the high level. In this case, the current path ③-1 of the power supplied from the power supply unit 115 is the power supply unit 115, the first low pass filter 113, the transmission line 120, and the second low pass filter 131. And a path sequentially passing through the auxiliary signal transmitter 135.

On the other hand, when the voltage of the auxiliary signal input to the auxiliary signal transmitter 135 is low level, the voltage of the contact point P of the power supply 115 and the auxiliary signal receiver 117 is high level, the auxiliary signal receiver 117 ) Is changed to the low level. In this case, the current path ③-2 of the power supplied from the power supply unit 115 is set as a path passing sequentially through the power supply unit 115 and the auxiliary signal receiving unit 117.

FIG. 2 is a detailed circuit diagram of a video signal transmission system using a transmission line according to FIG. 1. The circuit diagram of FIG. 2 is one example for implementing the video signal transmission system of the present invention, but is not necessarily limited thereto, and a specific element configuration may be differently set by a user.

Referring to FIG. 2, the video signal transmission system 200 using the transmission line includes a video signal transmitter 210, a transmission line 220, and a video signal receiver 230. In this case, the video signal transmitter 210 includes a first high pass filter 211, a first low pass filter 213, a power supply unit 215, and an auxiliary signal receiver 217. In addition, the image signal receiver 230 includes a second low pass filter 231, a second high pass filter 233, and an auxiliary signal transmitter 235.

No. 1 high-pass filter 211 LC passive filter including a plurality of capacitors (C _1, C ₂₎ and the inductor (L _1), is passed through the video signal input (V _i) obtained from an external imaging device .

The first low pass filter 213 is an LC passive filter including a plurality of capacitors C ₃ , C ₄ , a plurality of inductors L ₂ , L ₃ , and a resistor R ₁ , and passes a signal in a low frequency band. Let's do it.

The power supply unit 215 includes a constant power supply V ₁ and a resistor R ₂ , and supplies power to the image signal receiver 130. In this case, the constant power V ₁ refers to a main power supply for supplying power to the image signal receiver 130.

The auxiliary signal receiver 217 includes a constant power supply V ₂ , a plurality of resistors R ₃ and R ₄ , and a transistor TR ₂ , and receives the received auxiliary signal output V ′ _O from an external image pickup device. Output In this case, the constant power supply V ₂ means a driving power supply for driving a transistor.

The second low pass filter 231 is an LC passive filter including a plurality of capacitors (C ₅ , C ₆ ), a plurality of inductors (L ₄ , L ₅ ), and a resistor (R ₅ ), and passes a signal in a low frequency band. Let's do it. In addition, the second low pass filter 231 may be configured to correspond to the first low pass filter 113.

The second high pass filter 233 is an LC passive filter including a plurality of capacitors C ₇ and C ₈ and an inductor L _6. The second high pass filter 233 outputs an image signal transmitted through the transmission line 220. _O )

The auxiliary signal transmitter 235 includes a resistor R ₆ and a transistor TR ₁ , and controls the current path of the power supplied from the power supply unit 215 according to the auxiliary signal input V ′ _i . In this case, the auxiliary signal transmitter 235 does not include a separate power source.

Hereinafter, a method of controlling the current path of the power supply according to the auxiliary signal input will be described.

The on / off of the transistor TR ₁ of the auxiliary signal transmitter 235 is determined according to the voltage level of the auxiliary signal input, and correspondingly, the voltage level of the contact point P of the power supply unit 215 and the auxiliary signal receiver 217 is determined. Then, the on and off of the transistor TR ₂ of the auxiliary signal receiver 217 is determined, and finally the voltage level of the auxiliary signal output is determined.

This can be summarized in Table 1 below.

Voltage level of auxiliary signal input Operation state of transistor TR ₁ Voltage level of contact P Operation state of transistor TR ₂ Voltage level of auxiliary signal output High
On Low Off High Low
Off High On Low

Referring to Table 1, when the voltage of the auxiliary signal input is high level, the transistor TR ₁ of the auxiliary signal transmitter 235 is in a state where a gate voltage is applied. In addition, the current of the power delivered from the power supply unit 215 is the first low pass filter 213, the transmission line 220, the second low pass filter 231 and the transistor (TR ₁ ) of the auxiliary signal transmitter 135. It has a first current path ③-1 flowing to the source of, and the voltage of the contact point P of the power supply unit 215 and the auxiliary signal receiver 217 is at a low level. Further, the transistor (TR ₂₎ the secondary signal receiver 217 has, and the state, so the power is not supplied from the power supply 215 turned off, the normal power (V ₂₎ of the auxiliary signal receiving unit 217, the output of the auxiliary signal Therefore, the voltage of the auxiliary signal output becomes high level.

On the other hand, when the voltage of the auxiliary signal input is low level, the transistor TR ₁ of the auxiliary signal transmitter 235 is turned off because the gate voltage is not applied. In addition, since the current of the power supplied from the power supply 215 does not flow to the transistor TR ₁ , the voltage of the contact point P of the power supply 215 and the auxiliary signal receiver 217 becomes high level. In addition, the transistor TR ₂ of the auxiliary signal receiver 217 is turned on because power is supplied from the power supply unit 215 through the second current path ③-2, and the constant power of the auxiliary signal receiver 217 is maintained. Since V ₂ flows to the source of the transistor TR ₂ , the voltage of the auxiliary signal output becomes low level.

Therefore, the current path of the power supplied from the power supply unit 215 is changed according to the level of the input power of the auxiliary signal transmitter 235 to transmit the auxiliary signal to the auxiliary signal receiver 217 without modulating the auxiliary signal.

As such, according to an embodiment of the present invention, by controlling the current path for the video signal and the video device control signal transmitted through one transmission line, it is possible to minimize and transmit the video signal and interference without modulating the control signal. . In addition, the control signal transmitter may transmit the control signal without a separate power source.

As such, according to an embodiment of the present invention, by controlling the current path for the video signal and the video device control signal transmitted through one transmission line, it is possible to minimize and transmit the video signal and interference without modulating the control signal. . In addition, the control signal transmitter may transmit the control signal without a separate power source.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, Therefore, the present invention should be construed as a description of the claims which are intended to cover obvious variations that can be derived from the described embodiments.

100, 200: Video signal transmission system
110, 210: video signal transmitter
111, 211: first high pass filter
113,213: 1st low pass filter
115, 215: power supply
117, 217: auxiliary signal receiver
120, 220: transmission line
130, 230: video signal receiver
131, 231: second low pass filter
133 and 233: second high pass filter
135, 235: auxiliary signal transmitter

Claims (11)

A video signal transmitter for transmitting a video signal, which is a serial digital interface (SDI) signal obtained from an image pickup apparatus, using a transmission line; And
A video signal receiver connected to the transmission line to receive the video signal;
The video signal transmitter,
Supplying power to the video signal receiver by using the transmission line;
The video signal receiver,
Controlling an electric current path of power supplied from the video signal transmitter through the transmission line, and transmitting an auxiliary signal for controlling the imaging device to the video signal transmitter using the transmission line,
The video signal transmitter,
A first high pass filter for passing the video signal input at one end and blocking the auxiliary signal input at the other end;
A first low pass filter having one end connected in parallel with the other end of the first high pass filter to pass the auxiliary signal;
A power supply unit connected to the other end of the first low pass filter to supply power to the image signal receiving unit; And
An auxiliary signal receiver connected to the other end of the first low pass filter to receive the auxiliary signal;
The video signal receiver,
A second low pass filter having one end connected in parallel with one end of the first low pass filter to pass the auxiliary signal;
A second high pass filter having one end connected in parallel with one end of the second low pass filter to pass the video signal; And
One end is connected to the other end of the second low pass filter, and includes an auxiliary signal transmitter for inputting the auxiliary signal to the other end,
When the voltage of the auxiliary signal is high level,
Forming a current path sequentially passing through the power supply unit, the first low pass filter, the transmission line, the second low pass filter, and the auxiliary signal transmitter;
When the voltage of the auxiliary signal is low level,
And a transmission line forming a current path sequentially passing through the power supply unit and the auxiliary signal receiver. The method of claim 1,
The auxiliary signal is a video signal transmission system using a transmission line that is an unmodulated signal. The method of claim 1,
The transmission line is a video signal transmission system using a transmission line which is a coaxial cable. delete delete The method of claim 1,
The first low pass filter and the second low pass filter have a cutoff frequency of 200 KHz or less and pass a frequency signal smaller than the cutoff frequency,
And a transmission line through which a frequency signal having a cutoff frequency of the first high pass filter and the second high pass filter is 200 KHz or less and greater than the cutoff frequency. The method of claim 1,
And a contact line of the power supply unit, the auxiliary signal receiver, and the voltage level of the auxiliary signal receiver in accordance with the voltage level of the auxiliary signal input to the auxiliary signal transmitter. 8. The method of claim 7,
When the voltage of the auxiliary signal input to the auxiliary signal transmitter is high level, the voltages of the contacts of the power supply unit and the auxiliary signal receiver are low level, and the voltage of the auxiliary signal receiver is changed to a high level. Image signal transmission system using. delete 8. The method of claim 7,
When the voltage of the auxiliary signal input to the auxiliary signal transmitter is low level, the voltages of the contacts of the power supply and the auxiliary signal receiver are high level, and the voltage of the auxiliary signal receiver is changed to low level. Image signal transmission system using. delete

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