KR20060072273A - Real time image display device using helmet and camera control device of unmanned aerial vehicle using it - Google Patents

Abstract

The present invention is to provide a device that can receive the image taken by the unmanned aerial vehicle in real time to display on the motorcycle helmet and the camera control device of the unmanned aerial vehicle that can automatically adjust the shooting direction according to the movement direction of the helmet. A display unit for displaying an image signal; A control unit which outputs an image signal transmitted from an unmanned aerial vehicle in real time to a display unit; And a radio frequency transceiver for converting the radio frequency signal transmitted from the unmanned aerial vehicle into a baseband signal and transmitting the radio frequency signal to the controller, wherein the display unit, the controller and the radio frequency transceiver are mounted on the helmet.

Helmet, camera, drone, image, adjustment, display, real time

Description

Apparatus for displaying real-time image using helmet and apparatus for controlling camera of remotely piloted vehicle using the same}

1 is a schematic diagram of a system for transmitting and receiving a composite video signal to which the present invention is applied.

2 is a block diagram of a real-time image display device using a helmet according to an embodiment of the present invention.

3 is a block diagram of an apparatus for adjusting a camera of an unmanned aerial vehicle according to another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100: helmet 110: display unit

120: speaker 130: direction sensor

140, 230: control unit 150, 240: radio frequency transceiver

160: video processing unit 170: audio processing unit

200: unmanned aerial vehicle 210: microphone

220: camera 250: drive unit

The present invention relates to a real-time image display device using a helmet and a camera control apparatus of an unmanned aerial vehicle using the same, and in particular, a device capable of receiving images captured by an unmanned aerial vehicle in real time and displaying them on a motorcycle helmet and the movement of the helmet. The present invention relates to a camera control apparatus of an unmanned aerial vehicle that can automatically adjust a shooting direction according to a direction.

In general, an aircraft includes a general aircraft in which flight is made by the pilot's coordination and an unmanned aerial vehicle that does not rely on the pilot's coordination. The unmanned aerial vehicle is typically classified into a model aircraft and an unmanned aerial vehicle in which flight is performed by adjusting a remote controller.

Since such unmanned aerial vehicles are widely used for military or weather observation, they are equipped with a special photographing apparatus for capturing a specific image.

However, the unmanned aerial vehicle as described above is used to photograph images of military use or weather, but does not photograph images for the general public. In other words, an unmanned aerial vehicle manufactured at astronomical cost is limited to a specific field and is not used for the general public.

The present invention has been made to solve the above problems, an object of the present invention is to provide a display device that can be shown to the person wearing a motorcycle helmet by receiving the image taken by the camera attached to the unmanned air in real time have.

Another object of the present invention is to provide a camera control apparatus for an unmanned aerial vehicle that can automatically adjust the shooting direction according to the movement direction of the helmet whenever the direction of the helmet is moved by a person wearing a motorcycle helmet.

Still another object of the present invention is to provide a display device capable of giving an effect such as boarding an aircraft to a person on the ground by showing an image taken by an unmanned aerial vehicle in real time to a person wearing a motorcycle helmet.

According to an aspect of the present invention, there is provided a display apparatus for wirelessly receiving and displaying an image photographed from an unmanned aerial vehicle, the display apparatus comprising: a display unit for displaying an image signal; A control unit which outputs an image signal transmitted from the unmanned aerial vehicle in real time to the display unit; And a radio frequency transceiver for converting a radio frequency signal transmitted from the unmanned aerial vehicle into a baseband signal and transmitting the radio frequency signal to the controller, wherein the display unit, the controller, and the radio frequency transceiver are mounted on a helmet.

According to an aspect of the present invention, there is provided an unmanned aerial vehicle that transmits a photographed video signal to an external device such as a helmet, the camera comprising: a camera for photographing a surrounding video; A controller for transmitting the image signal photographed by the camera to the external device in real time; And a radio frequency transceiver for converting an image signal transmitted from the controller into a radio frequency signal and transmitting the radio frequency signal to the external device.

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

1 is a schematic diagram of a system for transmitting and receiving a composite video signal to which the present invention is applied, and a helmet 100 for displaying a video signal used for a motorcycle occupant in real time and provided as a radio frequency signal, and an image of the ground through a mounted camera. It consists of an unmanned aerial vehicle 200 for transmitting the photographed image to the helmet 100 as a radio frequency signal.

The helmet 100 is generally used to prevent damage to the head of the motorcycle occupant when an accident occurs, in the present invention by providing a display function of the image signal and the output function of the sound signal to the helmet 100 of the unmanned aerial vehicle 200 Display the image taken in the air by the camera on the helmet 100 in real time, and also provides a sound signal, such as sound generated in the vicinity of the unmanned aerial vehicle 200 through the helmet 100, the helmet 100 ) Will make you feel like you're on an airplane on the ground.

The unmanned aerial vehicle 200 captures an image of the ground from the air through a mounted camera, receives a sound generated from the surroundings through a mounted microphone, and then outputs a composite video signal including the captured video signal and the input sound signal. Converts to a radio frequency signal and transmits to the helmet (100).

Here, the unmanned aerial vehicle 200 transmits a composite video signal to the helmet 100 by using a frequency of 2.4 GHz Industrial Scientific Medical (ISM) band that can be used without a separate legal permission. Transmit video signal by converting it into radio frequency signal.

Then, whenever the helmet 100 is moved by the wearer, when the direction of movement is detected, the direction signal detected and converted into a radio frequency signal is transmitted to the unmanned aerial vehicle 200 in real time, and the unmanned aerial vehicle 200 receives the helmet ( The shooting direction of the mounted camera is changed to the direction in which the helmet 100 is moved according to the direction signal transmitted from 100.

Looking at the present invention applied to the helmet 100 and the unmanned aerial vehicle 200 performing such a function as follows.

2 is a block diagram of a real-time image display apparatus using a helmet according to an embodiment of the present invention.

Referring to FIG. 2, the display apparatus of the present invention includes a display unit 110 for displaying an image signal, a speaker 120 for outputting a sound signal, and a direction for detecting a moving direction of the helmet 100. Outputs the video signal and the sound signal included in the detection sensor 130 and the composite video signal transmitted from the unmanned aerial vehicle 200 to the display 110 and the speaker 120, respectively, by the direction sensor 130 The controller 140 transmits the detected direction signal to the unmanned aerial vehicle 200, converts the radio frequency signal transmitted from the unmanned aerial vehicle 200 into a baseband signal, and transmits the converted baseband signal to the controller 140. Converts the direction signal into a radio frequency signal and transmits the radio frequency transceiver 150 for transmitting to the unmanned aerial vehicle 200, and converts an image signal transmitted by the controller 140 into a signal suitable for the display 110. To wealth (110) The video processor 160 outputs the audio signal, and the audio processor 170 converts the sound signal transmitted by the controller 140 into an electrical signal suitable for the speaker 120 and outputs it to the speaker 120.

The display device of the present invention having such a configuration is disposed on the helmet 100 and driven by a battery or a battery.

The display unit 110 receives and displays an image signal provided in real time from the unmanned aerial vehicle 200 by the controller 140, thereby giving an effect as if the wearer of the helmet 100 boards an airplane. Accordingly, when the wearer wears the helmet 100, the display unit 110 is implemented to be positioned in front of the wearer's eye, and in particular, the display unit (100) may be used as a safety tool when riding the motorcycle. 110 may be implemented to be able to move in the vertical direction. That is, when displaying an image signal provided from the unmanned aerial vehicle 200, the display unit 110 is positioned in front of the wearer's eyes, and when used as a safety tool for riding a motorcycle, the display unit 110 is the wearer's head. To be located in the part. In addition, the display 110 may be implemented as a liquid crystal display (LCD).

The speaker 120 receives and outputs a sound signal generated in the vicinity of the unmanned aerial vehicle 200 in real time, so that the wearer of the helmet 100 sees the video signal photographed by the unmanned aerial vehicle 200 and simultaneously generates the sound signal generated therein. It gives a higher sense of presence by being able to hear the sound signal. The speaker 120 is attached to the helmet 100, it will be preferable to be implemented in a pair to be located on both ears of the wearer when the wearer is wearing the helmet (100).

The direction sensor 130 detects the direction of the moved head when the wearer wearing the helmet 100 on the head moves the head and transmits the detected direction signal to the controller 140 to detect the direction signal. To be transmitted in real time. This is to allow the wearer of the helmet 100 to move his head to move the shooting position of the camera mounted on the unmanned aerial vehicle 200. Accordingly, the wearer moves his head to the image in the direction he wants to see. You can see it in real time.

When the composite video signal transmitted from the unmanned aerial vehicle 200 is received through the RF transmitter / receiver 150, the controller 140 outputs a video signal and a sound signal included in the received composite video signal to the video processor 160. Output to the audio processor 170. In this case, the video processor 160 converts an image signal transmitted by the controller 140 into a signal suitable for the display 110 and outputs the signal to the display 110, and the audio processor 170 controls the controller 140. The sound signal transmitted by converts into an electrical signal suitable for the speaker 120 and outputs to the speaker (120).

In addition, the controller 140 transmits the direction signal detected by the direction sensor 130 to the unmanned aerial vehicle 150 through the radio frequency transceiver 150 in real time.

The radio frequency transceiver 150 converts a radio frequency signal of the 2.4 GHz ISM band transmitted from the unmanned aerial vehicle 200 into a baseband signal and transmits the signal to the controller 140, and also transmits a direction signal transmitted from the controller 140. The 2.4GHz ISM band is converted into a radio frequency signal and transmitted to the unmanned aerial vehicle 200.

3 is a configuration diagram of a camera control apparatus of an unmanned aerial vehicle according to another embodiment of the present invention.

Referring to FIG. 3, the unmanned aerial vehicle 200 of the present invention includes a microphone 210 for receiving ambient sounds, a camera 220 for capturing surrounding images, and a sound input from the microphone 210. The composite video signal including the signal and the video signal taken by the camera 220 to the helmet 100, and controls the movement of the camera 220 in the shooting direction in accordance with the direction signal transmitted from the helmet 100 The control unit 230 and the helmet 100 converts the radio frequency signal transmitted to the baseband signal to the control unit 230 and converts the composite image signal transmitted from the control unit 230 into a radio frequency signal helmet (100) And a driving unit 250 for moving the position of the camera 220 under the control of the control unit 230.

The microphone 210 receives a sound generated in the vicinity of the unmanned aerial vehicle 200 and outputs an electric sound signal suitable for the controller 230 to the controller 230.

The camera 220 captures an image of the unmanned aerial vehicle 200 in flight according to a photographing instruction of the controller 230 and transmits the image to the controller 230 in real time, and the photographing direction is moved by the driver 250.

The controller 230 transmits a complex video signal including a sound signal input from the microphone 210 and a video signal captured by the camera 220 in real time to the helmet 100 through the radio frequency transceiver 240, and The movement of the photographing direction of the camera 220 is controlled according to the direction signal transmitted from the helmet 100.

The radio frequency transceiver 240 converts a radio frequency signal of the 2.4 GHz ISM band transmitted from the helmet 100 into a baseband signal and transmits the signal to the controller 230, and also transmits a composite video signal transmitted from the controller 230. The 2.4GHz ISM band is converted into a radio frequency signal and transmitted to the helmet 100.

The driving unit 250 moves the photographing direction of the camera 220 in the direction indicated by the controller 230.

Although the technical spirit of the present invention has been described in detail according to the above-described preferred embodiment, it should be noted that the above-described embodiment is for the purpose of description and not of limitation. In addition, those skilled in the art will understand that various embodiments are possible within the scope of the technical idea of the present invention.

As described above, the present invention automatically adjusts the shooting direction of the camera mounted on the unmanned aerial vehicle according to the moving direction of the helmet whenever the direction of the helmet is moved by a person wearing a motorcycle helmet and by this camera By showing the image taken in real time to the person wearing a motorcycle helmet, it is possible to give the person on the ground the same effect as boarding the aircraft, and also increase the usability of the motorcycle helmet and unmanned aerial vehicle.

Claims (7)

A display apparatus for wirelessly receiving and displaying an image photographed from an unmanned aerial vehicle, A display unit for displaying an image signal; A control unit which outputs an image signal transmitted from the unmanned aerial vehicle in real time to the display unit; And Is provided with a radio frequency transceiver for converting the radio frequency signal transmitted from the unmanned aerial vehicle to a baseband signal to pass to the control unit, The display unit, the control unit and the radio frequency transmitting and receiving unit, characterized in that mounted on the helmet. The method of claim 1, The display unit is attached to be located in the front of the wearer wearing the helmet, the display device, characterized in that to move in the vertical direction. The method of claim 1, The speaker is mounted on the helmet, and further provided with a speaker for outputting a sound signal transmitted by the control unit, And the control unit outputs the video signal and the sound signal included in the composite video signal transmitted from the unmanned aerial vehicle to the display unit and the speaker, respectively. The method according to any one of claims 1 to 3, Is mounted on the helmet, and further provided with a direction sensor for detecting the movement direction of the helmet, The control unit transmits the direction signal detected by the direction detection sensor to the unmanned aerial vehicle in real time through the radio frequency transmitter and receiver, And the radio frequency transmitting and receiving unit converts the direction signal transmitted from the controller into a radio frequency signal and transmits the direction signal to the unmanned aerial vehicle. In the camera control apparatus of the unmanned aerial vehicle for taking a picture of the surrounding images and transmitting the captured video signal to an external device such as a helmet, A camera for taking an image of a surrounding; A controller for transmitting the image signal photographed by the camera to the external device in real time; And A radio frequency transceiver for converting an image signal transmitted from the control unit into a radio frequency signal to transmit to the external device Camera control device of the drone comprising a. The method of claim 5, Further provided with a driving unit for moving the shooting direction of the camera under the control of the controller, Receiving a direction signal transmitted from the external device through the radio frequency transceiver and controls the drive unit to move the position of the camera according to the received direction signal, And the radio frequency transceiver converts a direction signal transmitted from the external device into a radio frequency signal to a baseband signal and transmits the direction signal to the controller. The method according to claim 5 or 6, Further provided with a microphone for receiving the ambient sound and transmitting the input sound signal to the control unit, The control unit transmits a complex video signal including a sound signal input from the microphone and a video signal photographed by the camera in real time to the external device through the radio frequency transceiver; The radio frequency transceiver unit is a camera control device for an unmanned aerial vehicle, characterized in that for converting the composite video signal transmitted from the control unit to a radio frequency signal to the external device.

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