KR101992810B1 - Rotating Scan LED Display System and Device - Google Patents

Abstract

 The present invention provides a rotating scan LED display system and apparatus including a rotating display device, a core control panel and a video interface conversion board, wherein the video interface conversion board includes a universal video interface, and the core control panel is connected to each other with the rotating display device. And to send the video signal to the rotating display device, wherein the video interface conversion board is connected to the rotating display device, to secure the external video signal through the universal video interface, and to send the external video signal to the rotating display device. . The core control panel not only sends video signals to the rotating display facility, but also through the universal video interface of the video interface conversion board, video signals from external devices can be sent to the rotating display facility and display real-time images or animations. Can meet the display demand

Description

Rotating Scan LED Display System and Device

Cross Citation of Related Application

This application requires the priority of the Chinese patent application of the application number CN201810527944.2, titled "Rotational Scan LED Display System and Apparatus," filed with the Chinese Patent Office on May 25, 2018, all of which is hereby incorporated by reference. Combined.

TECHNICAL FIELD The present invention relates to the field of image display technology, and more particularly, to a rotating scan LED display system and apparatus.

With the recent development of the advertising display industry, there is an urgent need for novel and convenient display equipment in the market. The holographic display with the new display method has sufficient scientific sense and considerable potential due to its unique perspective display method. Rotating display is the mainstream holographic display solution, which uses one or several self-illuminated LED lightbars, controls, and motors to change the lighting of the facility as the rotational position changes during the high-speed rotation of the LED. The visual afterimage effect of the naked eye should be used to form such an image. In the process of observing with the human eye, only the image with high brightness exists and the equipment of the high-speed rotation itself is not visible, so it feels like the entire screen is floating in the air.

Existing rotational scan LED display fixtures cannot display real-time images or animations, and the appearing images or animations must be downloaded to the display fixtures in advance and cannot meet the various display needs.

In light of this, an object of the present invention is to provide a rotation scan LED display system and apparatus to improve a technical problem in which existing rotation scan LED display facilities cannot display real-time images or animations and cannot meet various display demands. .

Embodiments of the present invention in a first field provide a rotating scan LED display system comprising a rotating display facility, a core control panel and a video interface conversion board, wherein the video interface conversion board includes a universal video interface,

The core control panel is connected to the rotary display device and is configured to send an image signal to the rotary display device,

The video interface conversion board is connected to the rotary display facility and is configured to acquire an external video signal through the universal video interface and to send the external video signal to the rotary display facility.

Combining the first field, embodiments of the present invention provide a first class possible implementation of the first field, wherein the rotating display installations are in turn connected to each other by a motor drive board, a motor, a data processing board and an LED lamp panel. It includes, wherein the motor drive board is connected to each other and the data processing board.

Combining the first possible implementation manner of the first field, the present invention provides the second possible implementation manner of the first field, wherein the data processing board is a laser pair with the motor drive board. Wireless communication is carried out through transistors, mutually coupled inductors, mutually coupled antennas, infrared pair transistors or visible light pair transistors.

Combining the first possible implementation manner of the first field, the present invention provides a third possible implementation manner of the first field, wherein a first serial communication interface, a first high speed on the motor drive board is provided. Install serial interface, mirroring serial communication interface, and mirroring high speed serial interface,

The mirroring serial communication interface and the mirroring high speed serial interface are configured to proceed with the cascade connection of the facility.

Combining the first possible implementation manner of the first field, the embodiment of the present invention provides the fourth possible implementation manner of the first field, wherein the motor drive board includes a wireless power transmission circuit, and the data The processing board includes a wireless power receiver circuit, the rotary display facility adopts a wireless power supply scheme,

The wireless power transmission circuit includes a modulation module, the wireless power receiving circuit includes a demodulation module, and the rotary display device performs data communication through the modulation module and the demodulation module.

In combination with the first field, the embodiments of the present invention provide a fifth possible implementation manner in the first field, wherein the video interface conversion board includes a first parallel-serial data conversion module, a USB port and a USB serial port conversion. It also includes modules

The first parallel-serial data conversion module is configured to convert the universal video interface to a second high speed serial interface, the USB serial port conversion module is configured to convert the USB port to a second serial communication interface,

 The video interface conversion board is connected to the rotary display facility via the second serial communication interface or the second high speed serial interface.

Combining the first possible implementation manner of the first field, the embodiment of the present invention provides the sixth possible implementation manner of the first field, wherein the LED lamp panel is connected to each other in order, LED driving circuit, LED Includes an array and color correction module,

The LED driving circuit is configured to receive a control command of the data processing board, and drives the LED array to display colors according to the control command, and the color correction module stores color correction information.

Combining the third possible implementation manner of the first field, the embodiment of the present invention provides the seventh possible implementation manner of the first field, wherein the core control panel is a processor and a wireless communication each connected with the processor. A module, a third serial communication interface, and a third high speed serial interface,

The core control panel is connected to the rotary display device via the third serial communication interface or the third high speed serial interface;

The processor is connected to an external facility through the wireless communication module to receive image data or an operation command sent by the external facility.

Embodiment of the present invention in the second field also provides a rotation scan LED display device including the rotation scan LED display system, the core control panel and the video interface conversion board of the system is removable connection with the rotation display equipment, respectively.

Combining the second field, the embodiment of the present invention provides a first type of possible implementation of the second field, wherein the rotating display device includes a motor drive board installed at a lower end, and is arranged on the upper surface of the motor drive board. As the wireless power transmission coil, motor, wireless power receiving coil, data processing board and LED lamp panel are installed,

A wireless communication device is provided between the motor drive board and the data processing board.

An embodiment of the present invention has the following effects.

Embodiments of the present invention provide a rotating display device,

It provides a rotation scan LED display system and apparatus including a video interface conversion board with a core control panel and a universal video interface,

The core control panel is connected with the rotating display device and is configured to send a video signal to the rotating display device.

The video interface conversion board is connected to the rotational display facility and is configured to acquire an external signal through a universal video interface and to send an external video signal to the rotational display device.

The core control panel not only sends video signals to the rotating display facility, but also the general purpose video interface of the video interface conversion board can send video signals from external devices to the rotating display facility. To meet the display demand.

Other features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or will be understood by practice of the invention. The objects and other advantages of the present invention will be achieved and attained with the structure particularly pointed out in the written description, claims and drawings.

BRIEF DESCRIPTION OF DRAWINGS To describe the above objects, features, and advantages of the present invention more easily, the following detailed description will be made with reference to a comparatively superior embodiment and drawings.

BRIEF DESCRIPTION OF DRAWINGS To describe the embodiments of the present invention or the technical solutions in the prior art more clearly, the following briefly introduces the drawings used in the description of the specific embodiments or the prior art. In some implementations, a person skilled in the art may obtain other drawings according to these drawings without creative labor.
1 is a schematic diagram of a rotation scan LED display system provided by an embodiment of the invention.
Figure 2 is a schematic diagram of the core control panel connection provided by an embodiment of the present invention.
3 is a schematic diagram of a video interface conversion board connection provided by an embodiment of the present invention.
4 is a schematic view of a rotary display installation provided by an embodiment of the present invention.
5 is a structural diagram of a rotation scan LED display device provided by an embodiment of the present invention.
6 is a schematic diagram of a structure of a laser pair transistor of a rotation scan LED display device provided by an embodiment of the present invention.

BRIEF DESCRIPTION OF DRAWINGS To make the objectives, technical solutions, and advantages of the embodiments of the present invention clearer, the following clearly and completely describes the technical solutions of the present invention in conjunction with the accompanying drawings. Yes, but not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained under the premise of not having creative labor by those skilled in the art belong to the scope of the present invention.

Currently, existing rotating scan LED display fixtures cannot display real-time images or animations, and the images or animations to be displayed must be downloaded in advance to the display fixtures and cannot meet the various display needs. Based on this, a kind of rotation scan LED display system and apparatus provided by the embodiment of the present invention can not only send an image signal to the rotating display device through the core control panel but also transmit a video signal of an external device through the universal video interface of the video interface conversion board. It can also be sent to a rotating display facility and can display live images or animations to meet different display needs.

In order to understand this embodiment, first, the rotation scan LED display system disclosed in the embodiment of the present invention will be described in detail.

As shown in FIG. 1, the present embodiment provides a rotating scan LED display system including a rotating display device 10, a core control panel 20, and a video interface conversion board 30, wherein the video interface conversion board 30 is a general purpose. A video interface 31,

The core control panel 20 is connected to the rotary display device 10 and is configured to send an image signal to the rotary display device 10,

In detail, as shown in FIG. 2, the core control panel 20 includes a processor 21 and a wireless communication module 22, a third serial communication interface 23, and a third high speed serial interface, which are connected to the processor 21, respectively. And a memory 26, the memory 26 is configured to store image data. Among them, the processor 21 is connected with the third high speed serial interface 24 through the second parallel-serial data conversion module 25. The processor 21 may adopt an ARM chip, and the core control panel 20 is connected to the rotary display device 10 through the third serial communication interface 23 or the third high speed serial interface 24, and the processor 21 connects an external facility via the wireless communication module 22 to receive image data or an operation command sent by the external facility. The wireless communication module 22 may employ a WiFi / Bluetooth module or the like.

The core control panel 20 is the core of the overall system control, adopts a low power design, can be powered by the battery, managed through the battery management circuit 27, and may be connected to an external power source. The core of the core control panel 20 may adopt the ARM core processor 21, and the peripheral device may include a WiFi / Bluetooth module and may be connected to an external smart device, thereby receiving an image document and an operation command. The ARM processor 21 sends control commands to the rotating display facility 10 connected thereto via a third serial communication interface 23, converts video streaming into serial data via a parallel-to-serial data conversion module. The image data is then sent to the rotating display device 10 connected thereto via the third high speed serial interface 24.

The video interface conversion board 30 is configured to be connected to the rotational display device 10, to acquire an external video signal through the universal video interface 31, and to send the external video signal to the rotational display device 10.

In addition, as shown in FIG. 3, the video interface conversion board 30 includes a first parallel-serial data conversion module 33, and the first parallel-serial data conversion module 33 includes a universal video interface 31. Is converted to a second high speed serial interface 34, and the video interface conversion board 30 is connected to the rotary display facility 10 through a second high speed serial interface 34. And the video interface conversion board 30 also includes a USB serial port conversion module 35, the USB serial port conversion module 35 is configured to convert the USB port 32 to the second serial communication interface 36, The video interface conversion board 30 is connected to the rotary display device 10 via a second serial communication interface 36. The video interface conversion board 30 is connected to the rotating display device 10, and then converts the second serial communication interface 36 into the USB port 32 and converts the second high speed serial interface 34 into the universal video interface 31. It can be converted into, and the user can be connected to the rotary display facility 10 via a computer to directly control the display.

The rotating scan LED display system of the present embodiment allows the image to be connected to the rotating display facility 10 via a video interface directly from an external facility (eg, a PC) via the universal video interface 31 of the video interface conversion board 30. Without transmitting the image to the rotating display device 10 via WiFi or other media, the image can be transmitted and controlled in real time directly from an external facility. Compared with the traditional model, which downloads the image first and then sends it to the facility, the system is highly real-time, highly scalable, and combines external facilities to enable human-machine interaction and interaction in real time. At the same time, the universal video interface 31 applies a wired video input and can guarantee real-time compared to a technology for transmitting video streaming in real time wirelessly, such as RTSP (Real Time Streaming Protocol). There is no delay and the transmission is virtually uninterrupted and reliable.

Further, as shown in FIG. 4, the rotary display device 10 includes a motor drive board 11, a motor 12, a data processing board 13, and an LED lamp panel 14 that are connected to each other in order, Among them, the motor driving board 11 is connected to the data processing board 13. The motor 12 may employ a brushless motor.

Further, the laser transmission tube 17 is installed on the motor driving board 11, the laser receiving tube 18 is installed on the data processing board 13, the data processing board 13 and the motor driving board 11. Wireless communication is performed through the laser pair transistor. In addition, wireless communication may be performed between the data processing board and the motor driving board through a mutual coupling inductor, a mutually coupled antenna, an infrared pair transistor, or a visible light pair transistor.

Preferably, since the laser transmitting tube 17 and the laser receiving tube 18 adopt dual wavelength lasers, bidirectional high speed communication can be realized between the floor and the rotating end. In this way, transmission of the low speed control signal using the wireless power supply coil modulation signal can be avoided.

Adopt a mutually coupled inductor, transmit display data using magnetic field induction, specifically replace the correlated laser transmit / receive with an interconnected inductor, and simultaneously match the laser transmit / receive front end circuit with the coupled inductor It replaces the signal amplification / shaping circuit, adopts mutually coupled antennas, transmits the serial image signal directly to the rotating stage through electromagnetic radiation, and adopts general infrared or visible light to transmit laser (infrared pair transistor or visible light). Pair transistors, etc.), and a high-speed display data can also be transmitted by adopting a slip ring or current collector ring, usually an electric brush slip ring, a liquid metal slip ring, or an optical fiber slip ring.

In detail, the motor drive board 11 is a fixed part, the motor 12, the data processing board 13 and the LED lamp panel 14 are rotating parts, and the fixed part and the rotating part adopt a laser device to receive data. Since the data is transmitted in a serial manner, the bandwidth is very large, and the super large video streaming data input by the universal video interface 31 is transmitted in real time to the rotating display portion, so that the rotating display facility 10 transmits the general video interface ( 31) can be displayed in real time to input the image.

Further, on the motor drive board 11, a first serial communication interface, a first high speed serial interface, a mirroring serial communication interface and a mirroring high speed serial interface are installed, and the mirroring serial communication interface and the mirroring high speed serial interface are connected to the cascade of equipment. It is configured to proceed. And when a cascade of facilities is required, all the equipment receives is real-time, synchronized image data, allowing for convenient screen expansion.

Further, the rotary display device 10 adopts a wireless power supply scheme, the motor drive board 11 includes a wireless power transmission circuit, and the data processing board 13 includes a wireless power reception circuit. The wireless power transmission circuit includes a modulation module, the wireless power receiving circuit includes a demodulation module, and the rotary display device performs data communication through the modulation module and the demodulation module. Therefore, the transmission of the electrical energy wirelessly and at the same time add the modulation signal to implement the transmission of the partial low-speed control signal.

The motor driving board 11 implements the driving of the motor 12 and the control of the wireless power transmission coil 15. At the same time, since the motor 12, the data processing board 13, and the LED lamp panel 14 are always in a rotating state at the time of work, the user cannot operate them directly, but the motor drive board 11 is always in the stopped state. In addition, some basic function buttons may be installed on the motor driving board 11, and the communication serial port may be left as a spare and configured to receive a complex control signal. The motor drive board 11 also includes a high speed serial interface, which receives an image signal and adopts laser transmission between the data processing board 13 and the motor drive board 11 to implement wireless communication. The board also includes two mirroring interfaces and is configured to expand the cascade of equipment. The data processing board 13 secures the rotation state of the facility by using the rotational speed detection sensor, thereby determining the display angle of the screen. There is a receiving end of the laser communication tube on the data processing board 13, and recovers the image signals in parallel using a parallel-to-parallel data converter and receives them from a field-programmable gate array (FPGA) and also uses an LED lamp panel. 14 is configured to drive an image.

Specifically, the LED lamp panel includes an LED driving circuit, an LED array, and a color calibration module connected to each other in order, and the LED driving circuit is configured to display the color by driving the LED array, and the color calibration module stores the color calibration information. do. The LED lamp panel is a straight line of LEDs, which are connected to the data processing board, which drives the LED array through the LED driving circuit to display 24-bit RGB color, and the LED lamp panel also includes a memory module. Color correction information can be stored, and the data processing board can be provided to read the information and adjust the color difference accordingly.

The number of LEDs on the LED panel can vary depending on the equipment model and needs, and can be arranged within a certain range, enabling the display of different resolution screens, and at the same time, a memory chip is built in to store color calibration information. To correct for inconsistencies and improve display quality.

In detail, the motor drive board 11 may include a microcontroller, a motor 12 driver connected to the microcontroller, a first serial communication interface, a mirroring serial communication interface, a first high speed serial interface, a mirroring high speed serial interface, a button, and a wireless controller. A power transmission circuit, a power supply and a protection circuit, the power supply and protection circuit connects a power adapter, the motor 12 driver of the motor drive board 11 and the motor 12 are connected to each other, and the data processing board 13 ) Includes an FPGA, a rotation speed detection sensor, a serial-to-parallel data conversion interface, and a wireless power receiver circuit connected to each other, the rotation speed detection sensor detects the rotation speed of the motor 12, and specifically, a hall sensor. The wireless power receiver circuit and the wireless power transmission circuit of the motor driving board 11 may be wirelessly connected, and the LED lamp panel 14 may be connected to each other. A copper circuit and an LED array are included, and the LED driving circuit is connected to each other with the FPGA of the data processing board 13.

In detail, the data processing board 13 of the rotating display device 10 adopts an FPGA to implement image conversion between rectangular coordinates and rotational coordinates, and at the same time to control the LED driving chip and correct the LED luminance curve. . The image to be displayed is transmitted from the laser, then obtained through serial-to-parallel data conversion, and sent directly to the FPGA. Depending on the difference in demand, the FPGA caches bitmap data into the FPGA internal memory area or external RAM. The Hall sensor is employed to detect the current angle of the rotating part, and the FPGA looks up the sine table to further acquire the position in the cache of each LED corresponding pixel on the current position. Therefore, real-time transformation of the coordinate system is implemented by reading the color data (RGB value) of the pixel from the cache. To achieve high quality color display, pixel color information must be sent to the LED drive chip after Gamma calibration, center luminance calibration, and LED mismatch calibration. In this system, the calibration curve of the LED chip is implemented through a lookup table stored in the FPGA. For example, if the grayscale range of each pixel RGB value is 0-255, and the LED driving chip PWM digits are 13 digits, the PWM value corresponding to each gray level can be obtained by inquiring an inquiry table of size 13 * 256. .

Due to the nature of the rotating display itself, LEDs with a relatively small radius of rotation have a relatively short stroke during the course of one turn, so that the brightness seen is greater than that of a relatively large radius and the center of the image is brighter if not calibrated. The edges appear darker and are severely affected by the image display quality. The system uses an FPGA to correct the problem of particularly bright center luminance. A specific method is to multiply different luminance correction coefficients based on the difference in the LED position by the luminance information after Gamma correction. The centered LED bias correction factor is relatively small and the edge biased calibration factor is relatively large.

Since there is some inconsistency in the LED production process, there is some difference in the R / G / B luminance of each LED, and color difference occurs when displaying an image. The system has LED color calibration. A specific implementation is to add color correction during the production process: first set each LED to the same brightness, read the red / green / blue brightness of each LED on the LED lightbar, and find the LED with the lowest brightness among them. It also calculates the ratio of the other LEDs to the corresponding LED brightness, processes it, and stores it in the EEPROM on the lightbar. During normal operation of the facility, the FPGA reads the data from the EEPROM during initialization and obtains the red, green, and blue luminance gains of each LED and stores it in memory. This is called the calibration gain. After completing the Gamma calibration and image-centric luminance calibration in the FPGA, the output data is further multiplied by the calibration gain here, and the final data is then sent to the LED drive chip. Thus, a correction for LED inconsistency is implemented.

Further, since both center luminance calibration and LED inconsistency calibration are first-order multiplication calculations, to reduce FPGA hardware resource consumption, the center luminance calibration coefficients and LED calibration gains can be preprocessed and stored in the lightbar EEPROM. Two calibrations can be completed in one operation during installation.

Image data of the present system can be generated through two paths, corresponding to the two expansion boards, the core control panel 20 and the video interface conversion board 30, respectively. When using the core control panel 20, the transmission of the image is implemented by adopting the wifi module on the corresponding expansion board. Images and videos can be sent from the PC or mobile phone to the rotary display facility 10 via wifi, stored in the on-board flash or memory card and sent when needed. Real-time video streaming is also transmitted to the facility via wifi, and after decoding by the processor 21 can output the video streaming data to the rotating display facility 10 to implement a wireless real-time display.

When using the video interface conversion board 30, an external video source (e.g. PC) connects directly to the expansion board via the universal video interface 31 and uploads video streaming directly to the rotating display installation 10 in real time. It implements a screen display where the system can be used as a normal expansion screen.

As shown in FIG. 5, the present embodiment also provides a rotation scan LED display device including the rotation scan LED display system, wherein the core control panel 20 and the video interface conversion board of the system are respectively detachable from the rotation display device 10. This is possible.

Further, the rotary display device 10 includes a motor drive board 11 installed at a lower end portion, and the wireless power transmission coil 15, the motor 12, and the wireless power receiver coil in order on the motor drive board 11. 16, data processing board 13 and LED lamp panel 14 is installed,

A wireless communication device is installed between the motor drive board 11 and the data processing board 13.

Optionally, the core control panel 20 or the video interface conversion board is screwed with the rotating display device 10, and the motor drive board 11, the wireless power transmission coil 15, the wireless power receiving coil 16, the motor ( 12), the data processing board 13 and the LED lamp panel 14 can also be fixed by screws so that no professional fixing structure is required.

In order to realize the power supply of the rotary display device 10, the present embodiment adopts a wireless power supply method, specifically, a wireless power supply coil that couples with each other, and adopts an absorbing material or a ferrite material around the coil. Proceed with magnetic shielding, reduce interference with extraterrestrial, and improve wireless power supply efficiency. Simultaneous transmission of electrical energy from the coil adds a modulated signal to implement the transmission of some slow control signals.

Specifically, the wireless communication device realizes data transmission of real-time video streaming from the fixed floor to the rotating part, and the wireless communication device may adopt a laser pair transistor, in which the motor 12 employs a hollow bearing. And a laser transmission tube 17 and a laser receiver tube 18 are installed on the motor drive board 11 and the data processing board 13, respectively, and as shown in FIG. The laser transmitting tube 17 is installed at the bottom end of the bearing, and the laser receiving tube 18 is installed at the rotating end. By implementing the wireless transmission of video streaming data by using the characteristic of the bandwidth of the tube is large and contactless, it solves the problem of high-speed video streaming transmission, and also implements the display of the real-time screen.

Preferably, since the laser transmitting tube 17 and the laser receiving tube 18 adopt a dual wavelength laser, it is possible to realize high-speed communication in both directions between the floor and the rotating end. This avoids transmitting low speed control signals using wireless power coil modulated signals.

In addition to transmitting display data by employing a laser pair transistor, the following scheme may be adopted.

Adopting a mutual coupling inductor, transmitting display data using magnetic field induction, specifically replacing the correlated laser transmission / reception tube with a mutual coupling inductor, and simultaneously matching the laser transmission / reception shear circuit with the coupling inductor. It is replaced by signal amplification / shaping circuit, adopts mutually coupled antennas, transmits serial video signal directly to the rotating stage through electromagnetic radiation, adopts general infrared or visible light, and replaces laser transmission. It is also possible to transfer high-speed display data by adopting slip rings or current collecting rings such as electric brush slip rings, liquid metal slip rings or fiber optic slip rings.

The rotation scan LED display device provided by the embodiment of the present invention has the same technical features as the rotation scan LED display system provided by the embodiment, thus solving the same technical problem and achieving the same technical effect.

And in the description of the embodiments of the present invention, the terms "installation", "connected to each other", "connection" should be understood in a broad sense, except where explicitly defined or otherwise defined, for example, may be a fixed connection, It may be a dismantling connection or an integral connection, it may be a mechanical or electrical connection, it may be a direct connection, it may be indirectly connected to each other via an intermediate medium, or it may be a connection inside two parts. Those skilled in the art to which the present invention pertains may understand the specific meaning of the terms in the present invention in a specific situation.

In the description of the present invention, it should be explained that terms such as “centered”, “up”, “bottom”, “left”, “right”, “vertical”, “horizontal”, “my”, “external”, etc.) The bearing or positional relationship indicated is merely for describing and briefly describing the present invention based on the bearing or positional relationship indicated in the accompanying drawings, and indicates that the device or part to be pointed must have a specific bearing and structure and operation of a particular bearing. It is not intended to be understood as a limitation to the invention, as it does not indicate or imply that. In addition, the terms "first", "second", and "third" are for descriptive purposes only and are not to be understood as indicating or implying relative importance.

For those skilled in the art to which this invention pertains clearly, for the convenience and brevity of the description, the specific working procedures of the systems, devices and units of the above description may refer to the corresponding processes in the embodiments of the above-described method. It is understandable, so no further explanation is given here.

It should be understood that among the several embodiments provided in the present application, the disclosed system and apparatus may be implemented in other ways. The above-described device embodiments are only intended to be shown schematically, for example, the division of units is only a division for a logical function, and in actual implementation, there may be a separate division scheme, and for example, Units or components may be combined and may be integrated into another system, or some features may be neglected or not implemented. Further, the coupling or direct coupling or communication connection between each other to be shown or discussed may be an indirect coupling or communication connection through some communication interface, device or unit, and may be in electrical, mechanical or other form.

A unit described as a separate component may or may not be physically separated, and a component represented as a unit may or may not be a physical unit, that is, may be located in one place or distributed in several network units. Depending on the actual demand, some or all of them may be selected to achieve the purpose of the present embodiment scheme.

And each functional unit in each embodiment of the present invention may be integrated into one processing unit, each unit may exist physically alone, or two or more units may be integrated into one unit.

If the function is implemented in the form of a software functional unit and sold or used as an independent product, it can be stored in a nonvolatile computer readable storage medium that can be executed by one processor. Based on this understanding, part of the technical solution of the present invention, or part of the technical solution, which may contribute to the existing technology in essence, may be implemented in the form of a software product, and the computer software product may be a computer equipment (personal computer, Server, or a network facility, etc.) in a storage medium containing some instructions for performing all or some steps of each embodiment method of the present invention. The above-described storage medium includes a medium for storing various program codes such as a USB, an external hard drive, a read-only memory (ROM), a random access memory (RAM), a diskette or a CD. .

Finally, it should be explained that the above embodiments are merely specific implementation manners of the present invention, and are used to describe the technical solutions of the present invention, but are not limited thereto, and the scope of protection of the present invention is not limited thereto. Even if the present invention is described in detail with reference to the above-described embodiment, any person skilled in the art to which the present invention pertains should be skilled in the art within the technical scope disclosed by the present invention. It is still possible to make corrections or easy changes to the technical solutions described in the above-described embodiments, or to make equivalent replacements for some of the technical features, and such modifications, changes or replacements may result in the nature of the corresponding technical solutions. All protection scope of the present invention without departing from the spirit and scope of the technical solutions of the present invention It must be able to understand what should be included. Therefore, the protection scope of the present invention should be based on the protection scope of the claims.

10-rotating display unit 11-motor drive board
12-motor 13-data processing board
14-LED Lamp Panel 15-Wireless Power Transfer Coil
16-wireless power receiving coil 17-laser transmission tube
18-Laser Receiver 20-Core Control Panel
21-Processor 22-Wireless Communication Module
23-Third Serial Communication Interface 24-Third High Speed Serial Interface
25-2nd parallel-serial data conversion module 26-memory
27-battery management circuit 30-video interface conversion board
31-Universal Video Interface 32-USB Port
33-first bottle-serial data conversion module 34-second high-speed serial interface
35-USB Serial Port Conversion Module 36- Second Serial Communication Interface

Claims (10)

Includes a rotating display unit, key control panel and video interface conversion board,
The video interface conversion board includes a universal video interface,
The core control panel is connected to the rotary display device and is configured to send an image signal, which is video streaming data, to the rotary display device.
The video interface conversion board is connected to the rotational display facility and is configured to send an external video signal, which is an extra large video streaming data, to the rotational display device via the universal video interface.
The video interface conversion board also includes a first parallel-to-serial data conversion module, a USB port and a USB serial port conversion module,
The first parallel-serial data conversion module converts the universal video interface to a second high speed serial interface,
The USB serial port conversion module converts the USB port to a second serial communication interface,
The second serial communication interface and the second high speed serial interface are connected to the first serial communication interface and the first high speed serial interface of the motor drive board of the rotary display device;
The core control panel includes a processor and a wireless communication module, a third serial communication interface, and a third high speed serial interface connected to each other,
The core control panel is connected to the first serial communication interface and the first high speed serial interface of the motor drive board of the rotary display device through the third serial communication interface or the third high speed serial interface,
The processor receives image data or an operation command sent by the rotary display device through the wireless communication module,
The rotating display fixture
The motor driving board, the motor, the data processing board and the LED lamp panel;
The motor drive board is connected to each other and the data processing board, a laser transmission tube is installed, the data processing board is installed a laser receiver tube,
Wireless communication between the data processing board and the motor driving board through a laser pair transistor or wireless communication through a mutual coupling inductor, an mutual coupling antenna, an infrared pair transistor, or a visible light pair transistor,
The laser transmitting tube and the laser receiving tube adopt a dual wavelength laser to perform bidirectional high speed communication between the floor and the rotating end,
The data processing board includes an FPGA, a Hall sensor which is a rotation speed detection sensor connected to the FPGA, a serial-to-parallel data conversion interface, and a wireless power receiving circuit.
The rotational speed detection sensor detects the rotational speed of the motor, adopts an FPGA to implement image conversion between the rotational coordinates from the rectangular coordinates, control the LED driving chip and correct the LED luminance curve, and the hole Using sensors to detect the current angle of the rotating part,
The FPGA obtains a position in the cache of each LED corresponding pixel on the current position by querying a sine table, and corrects the center luminance of the LED by multiplying Gamma-corrected luminance information by different luminance correction coefficients according to the difference of the LED position. Sends the corrected LED center luminance multiplied by the calibration gain to the LED driving chip,
The LED lamp panel is connected with a data processing board, and includes an LED driving circuit, an LED array, and a color calibration module;
The LED driving circuit drives the LED array to display the color, the color correction module to correct the color,
The data processing board drives an array of LEDs through an LED driving circuit to display 24-bit RGB color,
The motor drive board and the data processing board is connected to each other,
A rotating scan LED display system further comprising a mirroring serial interface and a mirroring high speed serial interface for cascade connection with other equipment. delete delete delete The method of claim 1,
The motor driving board includes a wireless power transmission circuit, the data processing board includes a wireless power receiving circuit, the rotary display device is operated in a wireless power supply method,
The wireless power transmission circuit includes a modulation module, the wireless power receiving circuit includes a demodulation module, and the rotation display device performs data communication through the modulation module and the demodulation module. Display system. delete delete delete delete delete

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