KR101975234B1 - Operating method of Wireless integrated system transmitting power and video for aircraft - Google Patents

Abstract

The present invention relates to an electric power and image wireless integrated system for an aircraft and an operating method thereof, which are possible to be applied to transmission mechanisms with respect to electric power and an image in the aircraft. According to one embodiment of the present invention, the electric power and image wireless integrated system includes: a wireless integrated transmitter supplied with a power source in the aircraft to wirelessly transmit the electric power and the image; and a wireless integrated receiver wirelessly receiving the electric power and the image from the wireless integrated transmitter and providing the same to a user.

Description

Technical Field [0001] The present invention relates to an operating method of a wireless integrated system,

The present invention relates to a power and image wireless integration system for an aircraft and a method of operation thereof, and more particularly, to a power and image wireless integration system for an aircraft that can be applied to a power and image transmission system in an aircraft and an operation method thereof will be.

Recently, a wireless power transmission or wireless energy transfer, that is, a wireless energy transmission scheme can be roughly classified into a magnetic induction scheme, a magnetic resonance scheme, and an RF transmission scheme using a short wavelength radio frequency .

In the magnetic induction method, when two coils are adjacent to each other and current is supplied to one coil, a magnetic flux generated at this time causes an electromotive force to the other coils. As a technology, Commercialization is proceeding. The magnetic induction method has the disadvantage that it can transmit power of up to several hundred kilowatts (kW) and the efficiency is high, but the maximum transmission distance is relatively short, so that it is usually adjacent to the charger or the floor.

The magnetic resonance method can transmit electric power using the magnetic resonance phenomenon between the coils having the same resonance frequency. Since the magnetic resonance method is hardly influenced by the electromagnetic wave problem, it is advantageous in that it is safe for other electronic devices or human body. On the other hand, it can be used only at a limited distance and space, and has a disadvantage that energy transfer efficiency is somewhat lower than that of the magnetic induction method. Recently, the magnetic resonance method has been commercialized such as electric car charging and mobile phone charging.

The RF transmission method utilizes the principle of remote field emission that energy can be directly transmitted and received in the form of a radio wave. Recently, as the power transmission efficiency has been improved, commercialization has been actively researched.

However, despite the advancement of wireless power transmission technology, there has been no case in which wireless power transmission technology has been applied or applied to an aircraft.

The present invention provides a power and image wireless integrated system for aircraft capable of transmitting and receiving power and images wirelessly in an aircraft and an operation method thereof.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not restrictive of the invention, unless further departing from the spirit and scope of the invention as defined by the appended claims. It will be possible.

According to an aspect of the present invention, there is provided an integrated system for power and image wireless communication for an aircraft, including: a wireless integrated transmitter for receiving power and power from an aircraft; And a wireless integrated receiver that wirelessly receives power and images from the wireless integrated transmitter and provides the wireless integrated receiver to a user.

According to an embodiment, the wireless integrated transmitter and the wireless integrated receiver may be configured as independent boards.

According to an embodiment, the wireless integrated receiver may be a Multi-Function Display (MFD) or a Head Up Display (HUD).

According to another aspect of the present invention, there is provided an integrated system for power and image wireless communication for an aircraft, comprising: a wireless integrated transmitter for converting DC power into AC power and converting an image into a form that can be transmitted through an antenna; And a wireless integrated receiver that wirelessly receives power and images from the wireless integrated transmitter and provides the wireless integrated receiver to a user.

According to an embodiment, the wireless integrated transmitter and the wireless integrated receiver may be configured as independent boards.

According to an embodiment, the wireless integrated receiver may be a Multi-Function Display (MFD) or a Head Up Display (HUD).

In accordance with another embodiment of the present invention, there is provided a system for integrating power and image wireless for an aircraft, comprising: a DC / DC converter for converting DC power into DC power of a specific voltage by receiving DC power from the aircraft; A wireless integrated transmitter including a transmission control unit for generating AC power and an A / V processor for receiving the converted DC power and generating an image to be wirelessly transmitted; And a wireless integrated receiver that wirelessly receives power and images from the wireless integrated transmitter and provides the wireless integrated receiver to a user.

According to an embodiment, the wireless integrated transmitter and the wireless integrated receiver may be configured as independent boards.

According to an embodiment, the wireless integrated receiver may be a Multi-Function Display (MFD) or a Head Up Display (HUD).

A method of operating an integrated power and image wireless system for an aircraft according to an exemplary embodiment of the present invention includes: transmitting wireless power and images to a wireless integrated transmitter by receiving power from an aircraft; And wirelessly receiving the wirelessly power and video from the wireless integrated transmitter and providing the wirelessly integrated receiver to the user.

According to an embodiment, the wireless integrated transmitter and the wireless integrated receiver may be configured as independent boards.

According to an embodiment, the wireless integrated receiver may be a Multi-Function Display (MFD) or a Head Up Display (HUD).

According to another aspect of the present invention, there is provided a method of operating an integrated power and image wireless system for an aircraft, the method comprising: converting a direct current power into an alternating current power by a wireless integrated transmitter Converting the image into a form that can be transmitted through an antenna; And wirelessly receiving the wirelessly power and video from the wireless integrated transmitter and providing the wirelessly integrated receiver to the user.

According to an embodiment, the wireless integrated transmitter and the wireless integrated receiver may be configured as independent boards.

According to an embodiment, the wireless integrated receiver may be a Multi-Function Display (MFD) or a Head Up Display (HUD).

According to another aspect of the present invention, there is provided a method of operating an integrated power and image wireless system for an aircraft, the method comprising: converting a direct current power of an aircraft into a direct current power of a specific voltage; The wireless integrated transmitter generating alternating current power to be transmitted wirelessly using the converted direct current power; Generating an image to be wirelessly transmitted by the wireless integrated transmitter in response to the converted DC power; And wirelessly receiving the wirelessly power and video from the wireless integrated transmitter and providing the wirelessly integrated receiver to the user.

According to an embodiment, the wireless integrated transmitter and the wireless integrated receiver may be configured as independent boards.

According to an embodiment, the wireless integrated receiver may be a Multi-Function Display (MFD) or a Head Up Display (HUD).

According to an embodiment of the present invention, the power and image wireless integrated system for an aircraft and the operation method thereof can transmit power and a high resolution image of a display device wirelessly to a power cable and an image transmission cable mounted on an aircraft, It is possible to omit the entire weight, and it is possible to provide freedom in designing and manufacturing aircraft.

The effects obtained by the present invention are not limited to the above-mentioned effects, and other effects not mentioned can be clearly understood by those skilled in the art from the following description will be.

FIG. 1 is a diagram illustrating an integrated power and image wireless system for an aircraft according to an exemplary embodiment of the present invention. Referring to FIG.
2 is a more detailed block diagram of the wireless integrated transmitter shown in FIG.
3 is a more detailed block diagram of the wireless integrated receiver shown in FIG.
4 is a flowchart illustrating an operation method of the power and image wireless integration system for an aircraft shown in FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood, however, that the embodiments described below are only for explanation of the embodiments of the present invention so that those skilled in the art can easily carry out the invention, It does not mean anything. In describing various embodiments of the present invention, the same reference numerals are used for components having the same technical characteristics.

Throughout the specification, when a part is referred to as being "connected" to another part, it includes not only "directly connected" but also "electrically connected" with another part in between . Also, when an element is referred to as " comprising ", it means that it can include other elements as well, without departing from the other elements unless specifically stated otherwise.

The " terminal " referred to below can be implemented as a computer or a portable terminal that can access a server or other terminal through a network. Here, the computer includes, for example, a notebook computer, a desktop computer, a laptop computer, and the like, each of which is equipped with a web browser (WEB Browser), and the portable terminal may be a wireless communication device , International Mobile Telecommunication (IMT) -2000, Code Division Multiple Access (CDMA) -2000, W-CDMA (WCode Division Multiple Access), Wibro (Wireless Broadband Internet), LTE (Long Term Evolution) Tablet PCs, and the like. ≪ RTI ID = 0.0 > [0033] < / RTI > The term " network " may also be used in a wired network such as a local area network (LAN), a wide area network (WAN) or a value added network (VAN) And may be implemented in all kinds of wireless networks, such as communication networks.

FIG. 1 is a diagram illustrating an integrated power and image wireless system for an aircraft according to an exemplary embodiment of the present invention. Referring to FIG.

Referring to FIG. 1, an aircraft power and image wireless integration system 10 can be applied to a fixed wing or a flywheel aircraft, and is a system that wirelessly transmits and receives power and images integrated on one board.

The aircraft power and image wireless integrated system 10 may include a wireless integrated transmitter 100 and a wireless integrated receiver 200. [

The wireless integrated transmitter 100 may generate power and images for powering the aircraft (e.g., 28V) to be wirelessly delivered to the wireless integrated receiver 200.

The wireless integrated receiver (200) may receive power and images wirelessly from the wireless integrated transmitter (100) and provide it to a user. For example, the wireless integrated receiver 200 may be provided in a fixed aircraft display device such as a Multi-Function Display (MFD) or a Head Up Display (HUD) or a mobile display device.

Each of the wireless integrated transmitter 100 and the wireless integrated receiver 200 may be configured as independent boards. Accordingly, power and high-resolution images of the display device can be wirelessly transmitted, and the power cable and the image transmission cable mounted on the aircraft can be omitted, thereby reducing the overall weight and providing flexibility in designing and manufacturing aircraft.

2 is a more detailed block diagram of the wireless integrated transmitter shown in FIG.

2, the wireless integrated transmitter 100 includes a DC input 102, a DC / DC converter 104, a transmission control unit 110, a transmission coil 120, a noise detection coil 130, a matching circuit 140 ), An A / V processor 150, a network processor 160, an RF transceiver 170, and a beamforming antenna 180. The configuration of the wireless integrated transmitter 100 shown in FIG. 2 is exemplary and at least one configuration may be added, or at least one configuration may be omitted.

The DC input 102 may be a power port receiving an internal power source (e.g., 28V) in the aircraft.

The DC / DC converter 104 may convert DC (Direct Current) power supplied from the DC input 102 to DC power of a specific voltage. The converted DC power may be delivered to the internal configuration of the wireless integrated transmitter 100, including the transmission controller 110 and the A / V processor 150, to provide the necessary power.

The transmission control unit 110 can control the overall operation of the wireless integrated transmitter 100 and includes a micro control unit 112, a DC / DC booster 114, a power amplifier 116, and a phase-locked loop , 118). The transmission control unit 110 and the transmission coil 120 may be designed to conform to a wireless charging technology standard defined by a wireless power consortium (WPC) or a power matters Alliance (PMA), a wireless charging technology standard mechanism.

The MCU 112 may deliver the DC power converted by the DC / DC converter 104 to the DC / DC booster 114. In addition, the MCU 112 controls the PLL 118 to control the operating frequency of the AC power generated by the power amplifier 116.

The MCU 112 analyzes the noise detection signal from the matching circuit 140 to determine the current noise state and controls the PLL 118 according to the determination result to determine the operating frequency of the AC power generated by the power amplifier 116 as Can be controlled. In addition, before changing the operating frequency, the MCU 112 may transmit a frequency change signal indicating that the operating frequency is changed to the wireless integrated receiver 200 and receive a response signal from the wireless integrated receiver 200. At this time, the frequency change signal and the response signal are transmitted through the in-band communication through the power amplifier 116 and the transmission coil 120, or through the in-band communication through the RF transceiver 170 and the beam- Out-of-band communication, but the scope of the present invention is not limited thereto.

In addition, depending on the current noise condition, the MCU 112 may control the RF transceiver 170 to adjust the intensity of the output signal.

The DC / DC booster 114 may receive the converted DC power from the MCU 112, boost the DC power, and transmit the boosted DC power to the power amplifier 116.

The power amplifier 116 may convert the boosted DC power into AC power having an operating frequency that the PLL 118 generates. Here, the operating frequency may be a frequency in the range of several tens KHz to several MHz.

The transmitting coil 120 is a coil capable of transmitting the converted AC power to the wireless integrated receiver 200 by radio, and may be a spiral coil. However, the scope of the present invention is not limited thereto. The transmit coil 120 includes a plurality of coils for enhancing the efficiency of power transmission, and each coil can be controlled by the MCU 112.

The noise detection coil 130 can wirelessly receive AC power sent from the transmission coil 120. [ The noise detecting coil 130 may be a small coil having a similar size to the receiving coil 202 of the wireless integrated receiver 200, but a relatively small size. This is because the noise detecting coil 130 is not a coil for receiving the AC power sent from the transmitting coil 120 and supplying electric power to the inside of the coil 120 but a coil for estimating the degree of intervention of noise in the wireless power transmission / .

The matching circuit 140 controls the impedance so that the noise detecting coil 130 can perform impedance matching with the transmitting coil 120 and outputs the AC power having the operating frequency of the PLL 118 received by the noise detecting coil 130. [ To the MCU 112. The MCU 112 compares the intensity of the AC power corresponding to the operating frequency of the PLL 118 with the previously stored reference intensity to determine the current noise state and controls the PLL 118 according to the determination result The operating frequency of the AC power generated by the power amplifier 116 can be controlled.

Here, the pre-stored reference intensity may be a value that empirically determines the intensity of the AC power transmitted from the noise detecting coil 130 when the noise condition is good. The AC power transmitted by the matching circuit 140 may correspond to the noise detection signal described above.

The noise detection coil 130 and the matching circuit 140 may be defined as a noise detection circuit.

The A / V processor 150 receives the converted power from the DC / DC converter 104 and can generate an image to be displayed through the wireless integrated receiver 200. [ Here, the image may be an image that allows the user to visually check various status information, control information, control options, etc. of the aircraft. The image may be a frame-by-frame signal conforming to the resolution of the display.

The network processor 160 may convert the image generated by the A / V processor 150 into a signal of a format that can be transmitted through the RF transceiver 170 and the beamforming antenna. Depending on the embodiment, the network processor 160 may compress or encrypt the image in a particular format.

The RF transceiver 170 may generate or receive signals at a specific intensity to be transmitted through the beamforming antenna 180. Here, the RF transceiver 170 may increase or decrease the intensity of the signal under the control of the MCU 112.

The beamforming antenna 180 is a directional antenna in which the energy radiated from the antenna is radiated intensively along a specific direction and a specific direction can be fixed toward the beamforming antenna 240 of the wireless integrated receiver 200. [ According to another embodiment, the beamforming antenna 180 may be rotated under the control of the MCU 112 so that the wireless integrated transmitter 100 can deliver images to a plurality of wireless integrated receivers.

The signal generated by the RF transceiver 170 and transmitted through the beamforming antenna 270 can be a millimeter file based on a frequency band of 60 GHz so that an image of high resolution (for example, 720P, 1080P, etc.) can be transmitted without compression .

3 is a more detailed block diagram of the wireless integrated receiver shown in FIG.

3, the wireless integrated receiver 200 includes a receive coil 202, a matching circuit 204, a receive controller 210, a DC / DC converter 220, a system load 230, a beamforming antenna 240 A high pass filter 250, an RF transceiver 260, a network processor 270, an A / V processor 280 and a display controller 290. The configuration of the wireless integrated receiver 200 shown in FIG. 3 is exemplary and at least one configuration may be added, or at least one configuration may be omitted.

The receiving coil 202 may be a coil capable of wirelessly receiving AC power sent from the transmitting coil 120, and may be a spiral coil. However, the scope of the present invention is not limited thereto.

The matching circuit 204 controls the impedance so that the receiving coil 202 can achieve impedance matching with the transmitting coil 120 and receives AC power having the operating frequency of the PLL 118 received by the receiving coil 202 To the reception control unit 210. FIG. The matching circuit 204 can adjust the impedance according to the control of the MCU 210 of the reception control unit 210. [

The reception controller 210 can control the overall operation of the wireless integrated receiver 200 and includes a band-pass filter 211, a DC rectifier 212, an MCU 214, a charging circuit 216, And a battery 218. The reception control unit 210 and the reception coil 202 may be designed to conform to a wireless charging technology standard defined in WPC or PMA, a wireless charging technology standard framework.

The band pass filter 211 is a filter for removing a signal corresponding to a frequency except for a predetermined frequency band, and may have a pass band of a frequency in the range of several tens of KHz to several MHz. Therefore, the band-pass filter 211 can efficiently receive the power of the desired frequency band by removing the noise component excluding the pass band corresponding to the operating frequency of the AC power transmitted from the transmitting coil 120.

DC rectifier 212 can convert AC power that has passed through band-pass filter 211 to DC power. To this end, the DC rectifier 212 may include a bridge circuit, but the scope of the invention is not so limited.

The MCU 214 may control the operation of the DC rectifier 212 and the battery 218. For example, when the operation of the wireless integrated receiver 200 is deactivated or when the charging of the battery 218 is completed, the MCU 214 interrupts the output of the DC rectifier 212 or the input of the battery 218 Lt; / RTI >

The MCU 214 controls the A / V processor 280 to control an image output from the display controller 290. For example, if the power in the wireless power receiver 200 is not sufficient, the MCU 214 controls the A / V processor 280 to reduce the brightness of the image output by the display controller 290, The user can display a warning screen indicating that the user does not want to do so.

In addition, the MCU 214 may receive a frequency change signal from the wireless integrated transmitter 100 indicating that the operating frequency is changed and send a response signal to the wireless integrated transmitter 100. At this time, the frequency change signal and the response signal may be transmitted through an in-band communication through the matching circuit 204 and the receiving coil 202, or through an in-band communication through the RF transceiver 260 and the beam- Out-of-band communication, but the scope of the present invention is not limited thereto.

The MCU 214 may change the impedance of the matching circuit 204 to an impedance corresponding to the frequency change signal.

The charging circuit 216 may receive DC power from the DC rectifier 212 and convert it into a voltage for charging the battery 218 to supply DC power to the battery 218 and the DC / DC converter 220.

The battery 218 is supplied with DC power and can convert and store electric energy. For example, the battery 218 may be a lithium-ion battery, but the scope of the invention is not so limited. The battery 218 may block the input under the control of the MCU 214 when the charging is complete and may be powered off when the power to be supplied to the system load 230 is insufficient The DC power can be discharged to the DC / DC converter 220.

The DC / DC converter 220 may convert the DC power supplied from the charging circuit 216 or the battery 218 to a voltage suitable for the system load 230 and transmit it to the system load 230.

The system load 230 may be a power port coupled to other devices (e.g., LCD backlight, button illumination, etc.) that the wireless integrated receiver 200 can provide power to.

The beamforming antenna 270 is a directional antenna in which the energy radiated from the antenna is radiated intensively along a specific direction and a specific direction can be fixed toward the beamforming antenna 180 of the wireless integrated transmitter 100. [ The beamforming antenna 270 receives the signal transmitted from the beamforming antenna 180 of the wireless integrated transmitter 100 and transmits the signal to the high pass filter 250 or transmits the signal of the RF transceiver 260 to the beamforming antenna 180 ).

The high pass filter 240 is a filter for removing a signal below a predetermined cutoff frequency and may have a cutoff frequency lower than a predetermined frequency by 60 GHz. Therefore, the high pass filter 240 eliminates noise components below the frequency band corresponding to the signal transmitted by the beamforming antenna 180, so that the transmission distance between the wireless integrated transmitter 100 and the wireless integrated receiver 200 is The reception quality of the enhanced and received video can be improved.

The RF transceiver 260 may receive and receive the filtered signal through the beamforming antenna 240 and may generate and transmit signals to the beamforming antenna 240 at a specific intensity for communication with the wireless integrated transmitter 100 . The RF transceiver 260 may increase or decrease the intensity of the signal under the control of the MCU 214 which senses the frequency change signal.

The network processor 270 may convert the signal received from the RF transceiver 260 into an image of a format that can be interpreted by the A / V processor 150. According to an embodiment, the network processor 270 may decompress or decode an image in a specific format.

The A / V processor 280 may convert the image received from the network processor 270 into an image that can be reproduced through the display controller 290.

The display controller 290 may convert an image of the A / V processor 280 into an electric signal so as to be output to a screen through a display panel (not shown) and output the electric signal. Here, the display panel may be an LCD (Liquid Crystal Display), but the scope of the present invention is not limited thereto.

4 is a flowchart illustrating an operation method of the power and image wireless integration system for an aircraft shown in FIG.

4, the noise detection coil 130 and the matching circuit 140 of the wireless integrated transmitter 100 are connected to each other while electric power and images are normally wirelessly transmitted and received between the wireless integrated transmitter 100 and the wireless integrated receiver 200. [ The MCU 112 can confirm the noise detection amount (S10).

In particular, the matching circuit 140 may deliver the AC power received from the noise-sensing coil 130 to the MCU 112, which is impedance-matched to the transmitting coil 120. The MCU 112 detects the intensity of the AC power corresponding to the operating frequency of the PLL 118 among the AC power, and compares the intensity of the AC power with the stored reference intensity to check the current noise detection amount. Here, the pre-stored reference intensity may be a value that empirically determines the intensity of the AC power transmitted from the noise detecting coil 130 when the noise condition is good.

If the intensity of the AC power is equal to or lower than the previously stored reference intensity (NO in S20), the MCU 112 controls the PLL 118 so that the AC power generated by the power amplifier 116 The operating frequency can be maintained, the signal strength of the RF transceiver 170 can be maintained, and then step S10 can be continued.

If the intensity of the AC power exceeds the previously stored reference intensity (YES in S20), the MCU 112 may reduce the intensity of the signal output by the RF transceiver 170 because the current noise condition is in a poor state (S30). This is because a signal output by the beam forming antenna 180 due to interference between the beam forming antenna 180 and the transmission coil 120 may act as noise in power transmission between the transmission coil 120 and the reception coil 202, So as to temporarily reduce the output of the RF transceiver 170. Thereafter, when the change of the operating frequency is completed, the output of the RF transceiver 170 can be restored to its original strength.

The MCU 112 may transmit a frequency change signal to inform the wireless integrated receiver 200 that the operating frequency is changed and receive a response signal from the wireless integrated receiver 200 at step S40. At this time, the frequency change signal and the response signal may be transmitted through in-band communication through the power amplifier 116 and the transmitting coil 120, or by out-of-band communication through the RF transceiver 170 and the beam- However, the scope of the present invention is not limited thereto. The MCU 214 of the wireless integrated receiver 200 that has received the frequency change signal can change the impedance of the matching circuit 204 to an impedance corresponding to the frequency change signal. To this end, the frequency change signal may include information on an operation frequency to be changed.

The MCU 112 controls the PLL 118 to change the operating frequency of the AC power generated by the power amplifier 116 and transmit the wireless power at the changed operating frequency (S50). Accordingly, when it is detected that the amount of noise introduced into the receiving coil is increased, the power transmission efficiency can be increased by changing the operating frequency so that the maximum power can be transmitted.

The method described above can be implemented as computer-readable code on a computer-readable recording medium. The computer-readable recording medium includes all kinds of recording media storing data that can be decoded by a computer system. For example, it may be a ROM (Read Only Memory), a RAM (Random Access Memory), a magnetic tape, a magnetic disk, a flash memory, an optical data storage device, or the like. In addition, the computer-readable recording medium may be distributed and executed in a computer system connected to a computer network, and may be stored and executed as a code readable in a distributed manner.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be understood that various modifications and changes may be made.

Claims (9)

The wireless integrated transmitter receiving power from the aircraft and sending power and images wirelessly; And
The wireless integrated receiver wirelessly receiving power and video from the wireless integrated transmitter and providing the power and video to a user,
The wireless integrated receiver includes:
A multi-function display (MFD) or a head up display (HUD)
Wherein the wireless integrated transmitter and the wireless integrated receiver are configured as independent boards,
Wherein the wireless integrated transmitter transmits power and images wirelessly by receiving power from the aircraft,
DC input receives DC power of 28 [V] in the aircraft;
Converting a DC power of 28 [V] received from the DC input to a DC voltage of a predetermined other voltage;
The micro control unit (MCU) of the transmission control unit transmits the DC power converted from the DC / DC converter, receives and analyzes the noise detection signal from the matching circuit, determines the current noise state according to the analysis result, The DC booster receives DC power from the MCU, boosts the DC power, and the power amplifier of the transmission control unit amplifies the DC power boosted by the DC booster and converts the amplified DC power into AC power, and the PLL (phase-lock loop) Controlling the operating frequency of the AC power generated by the power amplifier according to the noise state determination result and the control of the MCU;
Wirelessly transmitting AC power converted from the power amplifier by the transmitting coil to the wireless integrated receiver;
The AC power of the AC power which is wirelessly received so that the MCU can estimate the degree of intervention of noise at the time of wireless power transmission / To the MCU;
The matching circuit controlling the impedance so that the noise detecting coil makes an impedance match with the transmitting coil;
Generating an image in which the A / V processor displays the converted DC / DC power from the DC / DC converter at the wireless integrated receiver;
Converting a video generated by the A / V processor into a video signal of a predetermined transmittable format;
Transforming the RF transceiver into millimeter waves in a frequency band of 60 GHz of a predetermined intensity capable of transmitting the converted video signal from the network processor;
Wherein the beamforming antenna is configured to emit the millimeter wave converted from the RF transceiver in a predetermined direction,
Wherein the wireless integrated receiver wirelessly receives power and video from the wireless integrated transmitter and provides the power and video to a user,
Wirelessly receiving AC power that the receiving coil radiates from the transmitting coil;
Controlling an impedance so that a matching circuit can achieve impedance matching with AC power wirelessly received at the receiving coil;
The band-pass filter of the reception control unit removes noise components other than the pass band of the operating frequency that the transmission coil radiates from the AC power wirelessly received in the reception coil, and the DC rectifier of the reception control unit removes noise from the band- The MCU of the reception control unit receives the frequency change signal of the operating frequency from the wireless integrated transmitter and changes the impedance of the matching circuit corresponding to the received frequency change signal The charging circuit of the reception control unit converts the DC power of the DC rectifier to a charging voltage, the battery of the receiving control unit is charged with the charging voltage converted in the charging circuit, If the power can not be received wirelessly, The step of discharging the pressure;
Converting the charging voltage converted from the charging circuit or the charging voltage discharged from the battery into a DC voltage different from the predetermined DC voltage;
Receiving a millimeter wave fixed from a beamforming antenna toward a beamforming antenna of the wireless integrated transmitter and emitted from a beamforming antenna of the wireless integrated transmitter;
Removing a noise component in a sub-millimeter band received by the beamforming antenna of the wireless integrated transmitter;
Transforming the millimeter wave from which the noise component has been removed from the high pass filter into a signal of a predetermined intensity for communication with the wireless integrated transmitter;
Converting a signal converted by the RF transceiver into a signal of a predetermined format capable of image analysis;
Converting an A / V processor converted signal from the network processor into a video signal;
And converting the video signal converted by the A / V processor to a display controller so that the video signal can be output through the display panel, and outputting the converted video signal.
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