KR102638279B1 - LED pixel calibration data transmission method for LED display apparatus - Google Patents

Abstract

The present invention provides high-quality image data through the LED display device by quickly correcting the deviation in luminance and color that occurs between each LED device during the driving (light emission) process of the LED device constituting the LED display device. This relates to a method for transmitting and correcting LED element pixel correction data of an LED display device.
The present invention utilizes a sending card and a receiving card installed in an LED display device, and can convert (split) data to a sending card installed in an LED display device. A controller is provided, the pixel correction data is converted into nine frames of pixel correction data through the controller, and then transmitted to a receiving card, and the transmitted nine frames of pixel correction data are used to determine the luminance and luminance generated between LED elements. It is designed to correct color deviation.
The present invention enables rapid transmission of pixel correction data by simulated division of pixel correction data into nine frames and transmission of the divided data through an existing display data transmission path. The present invention enables rapid transmission of pixel correction data using pixel correction data. This has the effect of providing high-quality image data through an IlEd display device by quickly correcting luminance and color deviations.

Description

LED pixel calibration data transmission and calibration method of an LED display device {LED pixel calibration data transmission method for LED display apparatus}

The present invention relates to a method for transmitting and correcting LED element pixel calibration data of an LED display device. More specifically, the present invention relates to a deviation in luminance and color that occurs between each LED element during the driving (light emission) process of the LED elements constituting the LED display device. This relates to a method of transmitting and correcting pixel correction data of an LED device, which enables the provision of high-quality image data through an LED display device by quickly correcting the pixel.

Since all LED elements used in the construction of an LED display device have differences in chemical composition or wavelength, deviations in luminance and emission color are bound to occur during the driving (light emission) process of the LED element, resulting in the screen of the LED display device. The resolution was lowered and noise occurring during the driving process was inevitable.

Therefore, in an LED display device, it is essential for the calibration process to eliminate differences in luminance and emission color between each LED device, and for calibration of LED devices, luminance and color data of all LED devices that make up the LED display device are collected. Therefore, it is necessary to obtain a correction coefficient suitable for each LED device.

The LED display device transmits pixel calibration data reflecting the calibration coefficient to a receiving card installed in each cabinet through a controller, and adjusts the deviation of each LED element through the pixel calibration data to adjust the luminance and color of each LED element. is maintained uniformly, so in order to adjust the deviation of the LED elements, a process of transmitting pixel correction data to the receiving card must be accompanied.

In a typical LED display device, the data transmission logic between the controller and the receiving card has two paths, one is the 'display data transmission path' and the other is the 'control file data transmission path.'

In the data transmission logic of an LED display device, the 'display data transmission path' is a path for transmitting the display screen and supports a rate of RGB24@60Hz per pixel, and the 'control file data transmission path' is a path for transmitting the firmware and configuration file data. This is a path for transmitting control files such as (configuration file data) and is connected to the CPU serial port provided on the receiving card, so the transmission speed is slow.

Since pixel correction data for adjusting the deviation of LED elements is included in the control file data area, it is transmitted using the 'control file data transmission path'.

Existing LED display devices transmit large amounts of pixel correction data for adjusting the deviation of LED elements through the control file data transmission path, so the transmission speed of the correction data is very slow, so not only does it take a lot of time to calibrate the display screen, but the larger the screen, the more time it takes to calibrate the display screen. The time required for calibration has increased, sometimes requiring tens of minutes to several hours depending on the screen size, and problems such as the inconvenience of having to transmit pixel calibration data separately for each receiving card have been pointed out.

The present invention was created to solve the problems caused by conventional LED device deviation adjustment as described above, and allows pixel correction data to be simulated by dividing the pixel correction data and transmitting the divided data through the existing display data transmission path. Transmitting and transmitting LED element pixel correction data of an LED display device, which was completed with a focus on the technical task of enabling rapid transmission and quickly correcting luminance and color deviations that occur between LED elements using the transmitted pixel correction data. We would like to provide a correction method.

The present invention to solve the above-described technical problem utilizes a sending card and a receiving card installed in an LED display device, and uses a controller provided in the sending card to pixel Converting the calibration data into nine frames of pixel calibration data and calculating and verifying a CRC; a display data transmission path (Ethernet; Transmitting to a receiving card via Gigaphy, storing the received nine frames of pixel correction data in RAM provided in the receiving card, display data provided in the sending card and receiving card Transmitting CRC verification data to a receiving card through a transmission path, determining whether nine frames of pixel correction data stored in a storage device (RAM) match the CRC verification data through data comparison means provided in the receiving card. Thus, when the nine frames of pixel correction data and the CRC verification data match, storing the pixel correction data recorded in the storage device (RAM) in a flash memory provided in a receiving card, the pixel correction data stored in the flash memory. It is a technical feature that includes a step of correcting differences in luminance and color that occur between LED elements by driving the LED elements.

The LED device pixel calibration data transmission and calibration method of the LED display device presented in the present invention simulates pixel calibration data into nine frames and allows the divided data to be transmitted through an existing display data transmission path, thereby speeding up pixel calibration data. By making transmission possible, it is possible to quickly correct differences in luminance and color that occur between LED elements using pixel correction data, which has the effect of providing high-quality image data through an ILED display device. This invention is a truly beneficial invention with its expected effects.

The present invention will be described in detail below. In describing the present invention, detailed descriptions of related known functions or configurations have been omitted in order to not obscure the gist of the technical idea to be enjoyed by the present invention.

The method of transmitting and correcting LED element pixel calibration data of an LED display device presented in the present invention utilizes a sending card and a receiving card installed in the LED display device.

A controller that can convert (split) data on a sending card installed in the LED display device is provided, and the pixel calibration data is converted into nine frames of pixel calibration data through the controller, and the CRC is calculated and verified. do.

At this time, the reason for converting the pixel calibration data into nine frames of pixel calibration data is that the display data structure consists of each pixel (Red, Green, Blue) and each data length is 8 bits, so it consists of a total of 24 bits of data per pixel ( On the other hand, in the pixel calibration data structure, each pixel has 9 data attributes: Rr, Rg, Rb, Gr, Gg, Gb, Br, Bg, Bb, and each data length is Since it is 16 bits, it consists of a total of 144 bits of data per pixel (see pixel calibration data structure table below), so it is possible to use a display transmission path (Ethernet) that supports a rate of RGB24@60Hz per pixel without frame division of the pixel calibration data. Because there is none.

The controller of the sanding card prepares nine frames of pixel correction data with a data size of 16 bits for each pixel by simulated division of the pixel correction data as shown in the frame scheme below.

As described above, the pixel correction data of the nine simulated segments is transmitted to the receiving card through a display data transmission path (Ethernet; Giga phy) linking the sending card and the receiving card.

The nine frames of pixel correction data are stored in RAM provided in the receiving card.

CRC verification data is transmitted to the receiving card through a display data transmission path provided in the sending card and receiving card.

Through the data comparison means provided in the reception card, it is determined whether the nine frames of pixel correction data stored in the storage device (RAM) match the received CRC verification data, and the nine frames of pixel correction data and the CRC verification data match. Once done, the pixel correction data recorded in the storage device (RAM) is stored in the flash memory provided in the receiving card.

The nine frames of pixel correction data are stored in a storage device (RAM) provided in the receiving card.

The present invention with the above configuration enables real-time correction of luminance and color deviation of LED elements using pixel correction data divided into nine frames. The FPGA installed in the sanding card analyzes the pixel correction data at the CPU interface. It is converted into a Gigabit Ethernet signal and transmitted to the receiving card, and transmitted to the MCU through FPGA decoding installed on the receiving card. The FPGA installed on the sending card transmits the video signal generated by the CPU or input from HDMI. (RGB24@60Hz) is received, the above video signal is converted into a Gigabit Ethernet signal and transmitted to the receiving card, and stored in the storage device (RAM) through decoding of the FPGA installed on the receiving card, and the LED module contents It is driven according to the needs of regeneration.

Through the data comparison means provided in the receiving card, it is determined whether the nine frames of pixel correction data stored in the storage device (RAM) match the received CRC verification data, and the nine frames of pixel correction data and the CRC verification data match. When this happens, the pixel correction data recorded in the storage device (RAM) is stored in the flash memory provided in the receiving card.

In practice, pixel calibration data is transmitted using a display data rate of 60 frames per second, and the pixel calibration data is transmitted in just nine frames, so the transmission speed is only 0.15 seconds.

The method of transmitting LED element pixel correction data of the LED display device proposed in the present invention is not limited to the above-described embodiments, and can be used in various forms within the scope of the technical idea to be enjoyed by the present invention. Substitutions, modifications and changes can be made, which will be obvious to those skilled in the art to which the present invention pertains.

Claims (2)

By utilizing the sending card and receiving card installed in the LED display device, each pixel is converted into Rr, Rg, Rb, Gr, Pixel calibration data consisting of a total of 144 bits of data with 9 data attributes of Gg, Gb, Br, Bg, and Bb are converted into pixel calibration data of 9 frames with a data size of 16 bits, and the CRC is calculated and verified, and the above The converted and verified nine frames of pixel correction data are transmitted to the receiving card through a display data transmission path linking the sending card and the receiving card, and the nine frames of pixel correction data are used to connect LED elements. In correcting deviations in luminance and color that occur,
Storing nine frames of pixel correction data transmitted to the receiving card in a storage device (RAM) provided in the receiving card,
Transmitting CRC verification data to a receiving card through a display data transmission path provided in the sending card and receiving card,
Through the data comparison means provided in the receiving card, it is determined whether the nine frames of pixel correction data and the CRC verification data stored in the storage device (RAM) match, and if the nine frames of pixel correction data and the CRC verification data match, they are stored. Saving the pixel correction data recorded in the device (RAM) in a flash memory provided in the receiving card,
Transmitting and correcting LED element pixel correction data of the LED display device, comprising the step of correcting deviations in luminance and color that occur between LED elements by driving the LED elements with the pixel correction data stored in the flash memory. method. delete