KR101367173B1 - Video transmission control device of camera equipped car antenna power supply method - Google Patents

Abstract

1. Technical field to which the invention described in the claims belongs
The present invention relates to a power supply method and an image transmission control apparatus for a vehicle antenna having a camera.
2. Technical problem to be solved by the invention
The power of the vehicle antenna having a camera is supplied to the power output from the image recording unit, and the rear image of the vehicle photographed by the camera is selectively transmitted to the image recording unit and the image display unit under the control of an image transmission control device. Provides a low loss transmission of the RF signal received from the power supply, and a video transmission control device for a vehicle antenna having an easy-to-install camera.
3. The point of the solution of the invention
An image signal amplifier included in the image transmission control device; An image signal distribution unit; An image signal controller; Forming an image switch, supplying power by biasing, and providing a power supply method and an image transmission control apparatus for a vehicle antenna having a camera composed of a coaxial cable and an image cable.
4. Important Uses of the Invention
Used in car black box video recorder and navigation.

Description

Power transmission method and a video transmission control device for a vehicle antenna equipped with a camera

The present invention relates to a power supply method and an image transmission control apparatus for a vehicle antenna having a camera, and more particularly, to provide an efficient power supply to an antenna having a camera installed to photograph a rear image of a vehicle. It is easy to prevent theft and installation by rugged installation of one antenna and provides stable and efficient signal to navigation and black box video recording device installed in front of the vehicle. The present invention relates to a power supply method and an image transmission control apparatus of a vehicle antenna including a camera which transmits and records a rear photographed image continuously to a black box image recording apparatus even when the vehicle is driven forward and rearward.

The vehicle antenna is provided with magnet parts at both sides to increase the binding force between the vehicle and the antenna, and is formed by forcibly binding with the vehicle body, the bolt and the nut by forming a coupling hole in the center thereof. Korean Utility Model Registration No. 20-0450556 relates to a vehicle DMB antenna which is mounted with a magnet or bolt outside the vehicle.

As such, in the case of a vehicle antenna 100 having a conventional camera, as shown in FIG. 1, a through hole is formed on one side of the rear surface of the vehicle roof using a machine such as a drill, and then the vehicle is formed by using a bolt / nut. Or a magnet attached to the bottom of the antenna and then fixed to the vehicle by magnetic force, or fixed using an adhesive.

However, in the case of installing the vehicle antenna 100 provided with a camera by such a conventional method, the coaxial cable and the image transmission cable 110 is fixed to one side of the vehicle roof and the cable from the upper center of the rear glass to the left and right There is an economic burden of increasing the installation cost due to the complexity of the installation to install the cable between the vehicle roof or the vehicle body and the vehicle rear glass boundary, that is, the rubber packing provided on the vehicle rear glass rim.

Recently, a large number of vehicle black box video recording devices have been installed for use as evidence for vehicle accidents as well as navigation. The black box image recording apparatus for a vehicle basically includes a camera for photographing the front of the vehicle, and in some cases, further includes a camera for photographing the rear or left and right sides of the vehicle.

In general, in a vehicle antenna having a camera, the power supplied to the antenna and the power supplied to the camera are separated. The power supplied to the antenna is a method of using DC12V voltage supplied from the vehicle by dropping the voltage to DC5V through the voltage regulator at the vehicle power supply terminal such as the fuse box or the cigar lighter of the vehicle and connecting the external GPS antenna of the navigation. The method of supplying DC3.3V to 5V from the connector is a common power supply method. In addition, the power supplied to the camera is a method of directly receiving the DC12V voltage supplied from the rear lamp of the vehicle without a voltage drop and using the voltage drop to DC5V through a voltage regulator.

In addition, the related patent No. 10-1168243 for selectively transmitting the rear image of the vehicle to the navigation and the black box image recording apparatus is connected to a receiver and the signal splitter wireless signal line for transmitting a radio signal and the first DC power; It is described as a camera video line connected between the receiver and the display terminal to transmit the captured image information and the second DC power, the second DC power is the reverse power provided by the reverse lamp, under the control of the reverse sensing unit. It is described that it comprises a reverse power selection switch for switching to supply the reverse power to the camera power line, the wireless DC power line is amplified and wireless to the DC power of 3.3 ~ 3.5V provided from the display terminal Supplying to the receiving module, the camera DC power line for supplying a DC power of 3.3 ~ 5V provided from the display terminal to the video signal processing unit and the camera module for a vehicle wiring apparatus having a rear surveillance camera It is starting.

However, under the control of the reverse sensing unit, the voltage transmitted to the camera module through the camera power line is DC12V, which is a reverse power source, and the DC power line for the camera supplies 3.3 to 5V DC power provided from the display terminal to the camera module. A phenomenon occurs, which is clearly technically incapable of operating the camera module, and assuming that the camera module operates at a voltage of 12 VDC by the operation of the reverse sensing unit and the reverse power selection switch, the camera when the vehicle is driving forward Since it is impossible to take a rear image of the vehicle and transmit a rear image of the vehicle to the image recording apparatus, an implementation method thereof has not been described in detail.

If DC12V, which is a vehicle power source, is directly applied to the camera's operating power, a small camera circuit generates a lot of heat in the process of voltage dropping the voltage of DC12V into and out of DC5V. In addition to the deterioration of the image quality, there is a problem in that video noise occurs due to oscillation.

As described above, a vehicle antenna having a conventional camera has disadvantages of complexity and theft in the power supply method and installation structure, and if the antenna and the camera power are separately provided, an economic burden due to an increase in installation cost is incurred. There is a problem in the technical method for selectively transmitting the rear image of the vehicle to the navigation and the black box image recording apparatus.

Utility Model Registration No. 20-0450556 Patent Registration No. 10-1168243

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The technical problem to be achieved by the present invention, the camera so that the power supply to the camera can be supplied from the antenna circuit, the power supply to the camera and the antenna is supplied from the black box video recording apparatus installed in a part of the vehicle It is to provide a power supply method and an image transmission control apparatus for a vehicle antenna having a.

Another object of the present invention is to provide a power supply method and an image transmission control apparatus for a vehicle antenna having a camera that can be installed easily and robustly without forming a through hole in a vehicle.

Another technical problem to be solved by the present invention is to smoothly transmit the RF signal received from the antenna and selectively transmit the rear image of the vehicle photographed by the camera to the navigation. It is an object of the present invention to provide a power supply method and an image transmission control apparatus of a vehicle antenna having a camera that can be recorded in a black box video recording device without interruption.

The present invention for solving the above technical problem, the power supply of the DC4.2V ~ 5V output from the rear camera video signal input connector of the black box video recording device; and an image transmission control device; And a first coaxial cable; to supply the input power to the antenna; and to supply the antenna input power to the input power of the camera.

The present invention for solving the technical problem, the RF signal received from the antenna is transmitted to the terrestrial DMB connector of the navigation through the first coaxial cable, the image transmission control device and the second coaxial cable, and the camera The rear image of the vehicle is transmitted to the black box image recording apparatus through a first image cable; and the image transmission control device and a power image cable, and the image transmission control device by the backward signal of the vehicle is captured by the camera. Optionally, the rear image of the second image cable; and transmits to the external input connector of the navigation.

The present invention for solving the above technical problem, a "⊂" shaped clamp formed on the lower end of the vehicle antenna provided with a camera, the clamp is inserted into the trunk upper panel of the vehicle and the bolt inside the trunk of the vehicle It is more preferable to install / fix using.

As described above, the present invention integrates the power supplied to the vehicle antenna and the camera so as to be supplied from the black box image recording device, thereby simplifying the installation of the power cable.

In addition, by using the "⊂" shaped clamp formed in the lower end of the vehicle antenna with a camera is installed while being fitted to the upper panel of the trunk of the vehicle, it is not necessary to form a through hole in the vehicle, the vehicle is not damaged. It is easy to install because there is no need to fix various cables connected to the antenna with a camera between the rubber packing of the rear glass of the vehicle.

In addition, since the rear image of the vehicle is seamlessly transmitted to the black box image recording apparatus by the image transmission control device, and the rear image of the vehicle is selectively transmitted to the external input of the navigation, two camera functions are performed by one camera. Efficiency and significant economic impact.

Hereinafter, the GND is not indicated in the drawings for the embodiments of the present invention to be described later. Since the transmission line and the GND are located close to the same line in an electromagnetic manner, a person having ordinary knowledge in the technical field to which the present invention belongs. For the sake of brevity, the description of GND is omitted for clarity.

1 is a view showing an installation example of a vehicle antenna with a conventional camera,
2 is a diagram illustrating an example in which a vehicle antenna having a camera according to the present invention is installed in a vehicle;
3 is a view showing an example of a detailed structure of an antenna having a camera according to the present invention,
4 is a view showing an example of a power supply method and an image transmission control apparatus for a vehicle antenna having a camera according to the present invention;
5 is a view showing an example of a detailed configuration of the bias circuit of the image transmission control apparatus according to the present invention;
6 is a view illustrating an example of detailed configuration of an image signal amplifier, an image signal distribution unit, and an image switch unit of an image transmission control apparatus according to the present invention;
7 is a view showing an example of a detailed configuration of the antenna substrate of a vehicle antenna with a camera according to the present invention, and
8 is a view showing another example of a power supply method and an image transmission control apparatus for a vehicle antenna having a camera according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a power supply method and an image transmission control apparatus for a vehicle antenna with a camera according to the present invention.

2 is a diagram illustrating an example in which a vehicle antenna having a camera according to the present invention is installed in a vehicle.

Referring to Figure 2, the vehicle antenna 200 with a camera according to the present invention is installed on one side of the trunk upper surface located between the trunk of the vehicle and the rear glass of the vehicle. The vehicle antenna 200 having a camera includes a clamp 340 having a '⊂' shape at the bottom as shown in FIG. 3, and clamps the clamp 340 to the trunk upper panel 210 to close the clamp 340. The bolt 350 provided at the bottom is turned to fasten and fixed.

3 is a diagram illustrating an example of a detailed structure of an antenna having a camera according to the present invention.

Referring to FIG. 3, the antenna 200 having a vehicle camera includes a case 300, an antenna substrate 310, an antenna element 320, a camera accommodating part 335, a clamp 340, and a bolt-shaped fixing part. And an opening 390 through which the coaxial cable 360 and the video cable 370 pass.

The appearance of the case 300 may be formed in various shapes as well as the conventional 'shark antenna' shape in consideration of design elements.

Since the shape and structure of the antenna element 320 is determined according to polarization of a band of a frequency to be received, the shape of the antenna element 320 may vary depending on an application example. As an example, the antenna element 320 may be a ceramic patch antenna element that receives a signal (right polarization) in the GPS frequency band, and a quarter wavelength for transmitting and receiving signals (vertical polarization) in WIFI or WCDMA and LTE frequency bands. It may be the following monopole antenna element. In addition, the outside of the antenna element 320 is covered with a plastic dielectric case 322.

The antenna substrate 310 processes a signal received from the antenna element 320. The detailed configuration of the antenna substrate 310 will be described with reference to FIG. 7.

The camera accommodating part 335 accommodates a camera 330 capable of capturing a rear image of the vehicle. The camera accommodating part 335 may be omitted according to an exemplary embodiment, and the camera 330 may be located at another place of the vehicle rather than inside the antenna 200 having the vehicle camera. The camera 330 accommodated in the camera accommodating part 335 simultaneously serves as a camera for recording the photographed image in the rear camera and the black box image recording apparatus of the conventional parking assist system. A detailed method and structure in which the camera 330 performs two roles at the same time will be described with reference to FIG. 4.

The clamp 340 is fixed in a shape that fits into the trunk upper panel 380 as a '⊂' shape.

In addition, an opening 390 through which the coaxial cable 360 connected to the camera 330 accommodated in the antenna substrate 310 and the camera accommodating part 335 and the image cable 370 may pass is provided at one side of the case 300. Is formed. In this embodiment, the coaxial cable 360 and the image cable 370 is shown to form an opening 390 in front of the clamp 340 of the lower surface of the case 300 so that it can go directly to the trunk of the vehicle, but must be The present invention is not limited thereto, and may be formed on the other side of the case 300 in consideration of the structure of the vehicle or the convenience of installation.

4 is a view showing an example of a power supply method and an image transmission control apparatus for a vehicle antenna having a camera according to the present invention.

Referring to FIG. 4, the image transmission control apparatus 400 receives power from the image recording unit 410, supplies power to the vehicle antenna 200 having a camera, and transmits the power from the vehicle antenna 200 having a camera. The received signal is transmitted to the image recording unit 410 or the image display unit 420. In detail, the image transmission control apparatus 400 includes a bias circuit 402, an image signal amplifier 403, an image signal distributor 404, an image signal controller 405, and an image switch unit 406. .

The image recording unit 410 is a device for storing the rear image of the vehicle taken by the camera 330 as an example, a black box, the image display unit 420 is a device for displaying the rear image of the vehicle taken by the camera 330 One example is navigation. Both the image recording unit 410 and the image display unit 420 operate by being supplied with a vehicle power supply (eg, DC12V). When the image display unit 420 is a navigation device, the image recording unit 410 and the image display unit 420 operate in a geographic information or terrestrial DMB viewing mode by a driver's operation. . The image recording unit 410 includes a port for dropping and outputting a voltage of the vehicle (for example, DC4.2 to 5V).

The power output from the port of the image recording unit 410 is connected in parallel to the bias power circuit 402 and the operating power of the image signal amplifier 403 and the image signal controller 405, respectively.

The bias circuit 402 transmits the input DC power to the vehicle antenna 200 having a camera and transmits an RF signal such as a terrestrial DMB signal or a GPS signal received from the vehicle antenna 200 having a camera. To 420. The image recording unit 410 is connected to the bias circuit 402 and the image signal distribution unit 404 by a cable including two cables for transmitting power and image signals to one cable.

The bias circuit 402 is a choke coil that cuts an AC signal to supply only DC to a vehicle antenna 200 having a camera, which is a circuit component that cuts an RF signal in a corresponding frequency band and passes only DC. It includes an inductor. The bias circuit 402 is connected to the vehicle antenna 200 having the camera and the image display unit 420 by a coaxial cable 360, respectively. The detailed structure of the bias circuit 402 will be described with reference to FIG. 5.

The antenna substrate 310 included in the vehicle antenna 200 having a camera supplies DC power received from the bias circuit 402 to the operating power of the camera 330, and the camera 330 is an antenna substrate ( The rear image of the vehicle is photographed using the power supplied from the 310, and the image signal is output to the image signal amplifier 403 through the image cable 370. That is, the camera 330 is not directly supplied with the vehicle power, but receives and uses the power output from the antenna substrate 310 that is output by the voltage drop from the image recording unit 410.

The video signal amplifier 403 amplifies the gain of the received video signal and outputs it to the video signal distributor 404.

The video signal distributor 404 distributes the received video signal into at least two output signals. The video signal distribution unit 404 distributes the gains of the distributed video signals so as to maintain the same gains. In the present embodiment, for convenience of description, it is assumed that the image signal distribution unit 404 distributes the signal to two ports of the first output port and the second output port. The first output port of the image signal distribution unit 404 is connected to the image recording unit 410, and the second output port is connected to the image switch unit 406. Specifically, the first output port is connected by an image cable included in a power image cable connecting the port of the image recording unit 410 and the bias circuit 402. The image recording unit 410 stores the image signal of the camera 330 received from the image signal distribution unit 404, that is, the rear image of the vehicle.

Next, looks at the configuration of the camera 330 is utilized as a rear camera of the parking assistance system.

When the driver manipulates the reverse gear of the vehicle, the reverse signal controller 430 supplies the vehicle reverse power (eg, 12V) to the reverse lamp 440 so that the reverse lamp 440 is turned on. The backward signal controller 430 also transmits a reverse signal, which is a reverse power source, to the image signal controller 405 through the reverse signal cable. The image signal controller 405 outputs a control signal to the image switch unit 406 when receiving the reverse signal, and the image switch unit 406 outputs the image signal of the camera received from the image signal distributor 404 to the image display unit ( 420). That is, the video signal controller 405 transmits the high signal to the video switch unit 406 when receiving the reverse signal, and the video receiving position unit 406 turns the contact of the switch on when the high signal is received. The video signal of the camera output from the distribution unit 404 is output to the image display unit 420. Here, the video signal distribution unit 404 distributes the video signal and outputs both to the video recording unit 410 and the video switch unit 406, so that the image behind the vehicle is displayed on the video display unit 420 and at the same time the video recording unit 410. Is also stored.

When the driver releases the vehicle reverse gear, the output of the reverse signal controller 430 is cut off and the reverse lamp 440 is also turned off. The image signal controller 405 outputs a low signal to the image switch unit 406 because there is no input from the backward signal controller 430, and the contact point of the image switch unit 406 is turned off again so that the image signal distribution unit 404 is provided. Blocks the output video signal from the output to the image display unit 420. In addition, the image display unit 420 returns to the previous step of the reverse of the vehicle and displays an image previously displayed.

Detailed configurations of the video signal amplifier 403, the video signal distributor 404, and the video switch 406 will be described with reference to FIG.

Cables between the image recording unit 410, the image display unit 420, the vehicle antenna 200 having a camera, and the image transmission control apparatus 400 may be implemented in various forms. The bias circuit 402 of the display unit 420 and the image transmission control device 400 are connected by a coaxial cable, and the image display unit 420 and the image switch 406 of the image transmission control device 400 are connected by an image cable. do. The antenna substrate 310 of the vehicle antenna 200 having a camera and the bias circuit 402 of the image transmission control device 400 are connected by a coaxial cable, and the camera 330 of the vehicle antenna 200 having a camera is connected. ) And the video signal amplifying unit 403 of the video transmission control device 400 is connected by a video cable. In addition, the backward signal controller 430 and the image signal controller 405 of the image transmission control device 400 are connected by a reverse signal cable. The port of the image recording unit 410 and the bias circuit 402 and the image signal distribution unit 404 of the image transmission control device 400 are connected through a power cable and an image cable included in the power image cable.

5 is a view showing an example of a detailed configuration of the bias circuit of the image transmission control apparatus according to the present invention.

Referring to FIG. 5, the bias circuit 402 is installed in the middle of a high frequency circuit or a coaxial cable to supply DC power required for the operation of an active element such as a transistor (TR) or a field effect transistor (FET).

The bias circuit 402 includes three T-shaped input / output ports, and the first port 500 at the bottom of the T-shape is a DC input port connected to the image recording unit 410 and supplied with power. The second port 510 on the right of the shape is an RF + DC input / output port connected to the vehicle antenna 200 having a camera, and the third port 520 on the left is an RF input / output port connected to the image display unit 420. .

The DC power input to the first port 500 is output to the second port 510 through the inductor (ie, the RF choke) and the microstrip transmission line 550. Power output to the second port 510 is transmitted through a coaxial cable and used as a DC power source for the operation of an active element formed on the antenna substrate 310 of the vehicle antenna 200 having a camera.

On the contrary, the RF signal received from the vehicle antenna 200 having the camera is amplified by the active element of the antenna substrate 310 and then input to the second port 510 through the coaxial cable. The RF signal input to the second port 510 is output to the third port 520 through a capacitor 542 formed between two microstrip transmission lines 540 and 550 and two microstrip transmission lines 540 and 550. . At this time, the capacitor 542 positioned between the two microstrip transmission lines 540 and 550 functions to block the DC power from being transmitted to the third port 520. The impedance of the microstrip transmission lines 540 and 550 is 50 Ω, and the width and length of the microstrip transmission lines 540 and 550 may vary depending on the frequency and the dielectric thickness of the substrate and the dielectric constant ε _r of the dielectric. have.

6 is a diagram illustrating an example of detailed configurations of an image signal amplifier, an image signal distributor, and an image switch of the image transmission control apparatus according to the present invention.

Referring to FIG. 6, the image signal amplifier 403 receives an image signal from the camera 330 through the image input port 600. The image signal amplifier 403 performs impedance matching to the input terminal of the amplifier circuit in order to transmit an image signal of clean image quality without distortion. For example, match the impedance of the input to 75Ω.

The video signal amplifier 403 amplifies the gain of the video signal by 2V _{P -P} in the amplifying circuit, and the amplified video signal is input to the video signal distributor 404. The video signal distributor 404 divides the gain of the input video signal into two identical video signals and outputs the same. In detail, the video signal distributor 404 compensates the gain of the divided video signal to stabilize the amplitude to 1V _PP and outputs the same to the first output port 620 and the second output port 630, respectively.

There is an image switch unit 406 in the second output port 630, the image switch unit 406 is a second in accordance with the high / low control signal of the image signal controller 405 input through the port 640 The video signal is transmitted or blocked to the output port 630.

7 is a view showing an example of a detailed configuration of the antenna substrate of a vehicle antenna with a camera according to the present invention.

Referring to FIG. 7, the antenna substrate 310 includes an amplifier 710, a filter 720, a microstrip transmission line 730, and first and second inductors 750 and 752.

The amplifier 710 amplifies the RF signal received by the antenna element 320. The filter unit 720 filters only a corresponding frequency band from the RF signal amplified by the amplifier 710. An example of the amplifier 710 is a low noise amplifier (LNA).

For example, when the antenna element 320 receives a terrestrial DMB signal, the filter unit 720 is a low pass filter that filters and outputs only a frequency of 240 MHz or less and a microstrip transmission line of only a frequency of 240 MHz or less. Output to the furnace (730). Alternatively, when the antenna element 320 receives the GPS signal, the filter unit 720 filters only the vicinity of the frequency of 1575.42 MHz (± 1 MHz to ± 10 MHz) as a band pass filter to filter the microstrip transmission line 730. )

As a driving power source of the amplifying unit 710 which is an active element, a power source provided from the bias circuit 402 of the salping image transmission control device 400 is used. Specifically, the antenna substrate 310 filters the DC power through the microstrip transmission line 730 and the inductor (for example, RF choke) 750 and 752 through the power inputted through the RF input / output port 740 to the amplifier 710. And a power input of the camera 330. The rear image signal of the vehicle captured by the camera 330 is output through the image signal output port 760 and is input to the image signal amplifying unit 403 of the image transmission control apparatus 400.

Inductors (eg, RF chokes) 750 and 752 function to block the RF signal received from the antenna element 320 from being lost or returned through the power input line.

8 is a view showing another example of a power supply method and an image transmission control apparatus for a vehicle antenna having a camera according to the present invention. FIG. 8 is an embodiment in which only a camera is included without an antenna, unlike FIG. 1.

Referring to FIG. 8, the image transmission control apparatus 800 includes an image signal amplifier 802, an image signal distributor 804, an image signal controller 806, and an image switch unit 808.

The image display unit 820 such as navigation operates by receiving a vehicle power (eg, DC12V), and performs geographic information or terrestrial DMB viewing mode by a driver's operation.

The image recording unit 810 such as a black box includes a port that receives a vehicle power and outputs a voltage drop power (for example, DC4.2-5V). The power output through the port of the image recording unit 810 is input in parallel to the operating power of the image signal amplifying unit 802 and the image signal control unit 806, respectively.

The image signal amplifier 802 transmits the supplied power to the camera 850 and amplifies the gain of the image signal by receiving a rear image of the vehicle photographed from the camera 850. The video signal distributor 804 distributes and outputs the amplified video signal received from the video signal amplifier 802, and the video switch unit 808 outputs the video signal under the control of the video signal controller 806. Send or block 820. The reverse signal controller 830 supplies power to the reverse lamp 840 according to whether the vehicle reverses, and transmits the reverse signal to the image signal controller 806. Since the configuration and functions of the image signal distribution unit 804, the image signal control unit 806, the image switch unit 808, the reverse signal control unit 830 and the like are the same as those described in FIG. .

The present invention can also be embodied as computer readable code on a computer readable recording medium. A computer-readable recording medium includes all kinds of recording apparatuses in which data that can be read by a computer system is stored. Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disks, optical data storage devices, and the like. The computer readable recording medium can also be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion.

The present invention has been described with reference to the preferred embodiments. 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, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof should be construed as being included in the present invention.

200: vehicle antenna with a camera
310: antenna substrate 330: camera
400: Video transmission control device

Claims (19)

The bias power supplying the power input from the image recording unit to the operating power of the active element for amplifying the RF signal received from the antenna through the coaxial cable, and outputs the RF signal received from the antenna through the coaxial cable to the image display unit Circuit;
An image signal distribution unit for distributing an image signal received from a camera photographing a rear image of the vehicle and transmitting the image signal to an image recording unit; And
After receiving one of the divided video signal, the image switch unit for transmitting or blocking to the image display unit according to whether or not the vehicle backward; power supply method and image transmission of a vehicle antenna with a camera comprising a Control unit. The method of claim 1,
The bias circuit,
Including three T-shaped ports,
A first port connected to the image recording unit and a second port connected to the antenna are connected to an RF choke and a microstrip transmission line;
The second port and the third port connected to the image display unit is a power supply method of a vehicle antenna with a camera, characterized in that connected via a capacitor located between the two microstrip transmission line and the two microstrip transmission line. And video transmission control device. The method of claim 1,
And a video signal amplifying unit configured to receive a rear image signal of the vehicle photographed by the camera through an image cable, amplify the received image signal, and output the amplified image signal to the image signal distribution unit. Power supply method of vehicle antenna and image transmission control device. The method of claim 3, wherein
The video signal amplifier,
Power supply method and image transmission control apparatus for a vehicle antenna with a camera, characterized in that to match the input impedance of the amplification circuit to 75Ω in order to transmit the image signal in a clear image without distortion. The method of claim 1,
The video signal distribution unit,
Power supply method and image transmission control apparatus for a vehicle antenna with a camera, characterized in that for distributing the video signal amplified by the video signal amplification unit to at least two signals. The method of claim 1,
And a video signal controller configured to read a signal of a reverse signal controller according to whether the vehicle is reversed to control the image switch unit. The method according to claim 6,
The video signal controller,
Transmitting a control signal indicating transmission of an image signal to the image switch unit when the vehicle is in reverse, and transmitting a control signal indicating blocking of the image signal to the image switch unit when the vehicle is released. Power supply method and image transmission control apparatus for a vehicle antenna having a camera characterized in that. case;
An antenna substrate having an antenna element and formed inside the case; And
And a '⊂' shaped clamp formed on the bottom of the case; and a power transmission method and an image transmission control apparatus for a vehicle antenna having a camera. The method of claim 8,
And a bolt-shaped fixing part penetrating through the lower end of the clamp. The method of claim 8,
And a camera accommodating unit having a predetermined size of space in which the camera can be accommodated on the rear side of the case. The method of claim 8,
The power supply method and the image transmission control apparatus for a vehicle antenna with a camera, characterized in that the case is provided with a camera for taking a rear image of the antenna and the vehicle inside the case. The method of claim 8,
The antenna element,
Power supply method and image transmission control apparatus for a vehicle antenna with a camera, characterized in that the monopole antenna for receiving the terrestrial DMB frequency band. 13. The method of claim 12,
The monopole antenna,
Power supply method and image transmission control apparatus for a vehicle antenna with a camera, characterized in that the helical antenna element implemented in a size of less than 1/4 wavelength from the antenna substrate. The method of claim 8,
The antenna element,
Power supply method and image transmission control apparatus for a vehicle antenna with a camera, characterized in that the ceramic patch antenna element for receiving a GPS frequency band. The method of claim 8,
The antenna element,
Power supply method and image transmission control device for a vehicle antenna with a camera, characterized in that the monopole antenna of the WIFI and WCDMA to LTE frequency band. 16. The method of claim 15,
The monopole antenna,
Power supply method and image transmission control device for a vehicle antenna with a camera, characterized in that the antenna element is implemented in a size of less than 1/4 wavelength from the antenna substrate. The method of claim 8,
The antenna substrate,
Power supply method and image transmission of a vehicle antenna with a camera, characterized in that the power supplied through the coaxial cable to filter the RF choke inductor to supply DC power to the operating power of the camera accommodated on the back of the case Control unit. The vehicle antenna with a camera,
Power supply method of a vehicle antenna with a camera, characterized in that the operating power of the camera and the antenna is not directly supplied with the vehicle DC12V, the DC4.2 ~ 5V power output from the image recording unit is supplied through the image transmission control device. And video transmission control device. An image signal amplifying unit which supplies power input from the image recording unit to a camera through an image transmission control device and amplifies the image signal received from the camera;
A video signal distributor which distributes the video signal amplified by the video signal amplifier and transmits the video signal to the video recording unit; And
An image switch unit configured to receive one of the divided image signals and transmit or block the image display unit according to whether the vehicle is driven backward; And
And a video signal controller configured to read a signal of a reverse signal controller according to whether the vehicle is reversed and control the image switch unit.

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