KR102768778B1 - Intelligent led display device - Google Patents

Abstract

The present invention discloses an intelligent LED display device characterized by comprising: a control unit that controls the overall operation so that display through LED is performed normally by embedding a flash memory (flash chip) storing RCFG data in an LEDD module and transmitting the RCFG data to a receiving card; a sending card that receives RGB image data transmitted from a PC or image equipment through a cable connected to the PC or image equipment, converts the RGB image data into a predetermined current value based on the RCFG data stored in the receiving card, and then transmits the RGB image data to the receiving card so that it is displayed through an LED; a receiving card that receives the RCFG data from the module under the control of the control unit, converts the RCFG data into a predetermined current value by applying it to the RGB image data transmitted from the sending card, and then transmits the converted RGB image data to the module so that it is displayed through the LED; and a cabinet that is composed of a plurality of modules having embedded flash memories storing the RCFG data and forms a display. The control unit performs a control operation comprising: a first step in which a sending card receives RGB image data transmitted from a PC or image equipment through a cable connected to the PC or image equipment; a second step in which a receiving card searches for RCFG data in a module so that the receiving card receives the RGB image data from the sending card and transmits it to a module as a converted current value based on the RCFG data; a third step in which, if the RCFG data is found in the module as a result of the search, the RCFG data is copied and transmitted to the receiving card; a fourth step in which the receiving card converts the RGB image data received from the sending card based on the RCFG data into current and transmits it to the module; and a fifth step in which the module receives the converted current value transmitted from the receiving card and displays the image data through an LED.

Description

INTELLIGENT LED DISPLAY DEVICE

The present invention relates to an intelligent LED display device.

The cabinet that makes up the LED display is made up of multiple LED modules arranged in a single unit and includes various configuration properties.

As illustrated in Fig. 1, RCFG data is the most basic unique setting data of a cabinet composed of multiple LED modules, and is based on basic information of the LED module, such as IC chip, size, and scan method.

Therefore, in order for a cabinet composed of multiple LED modules to achieve optimal performance, appropriate settings of parameters such as Refresh rate, Grayscale Level, Data Clock Frequency, and Duty Scale are required.

This RCFG data can display normal and uniform picture quality only when all cabinets that make up a single screen, i.e. the receiving card that transmits RGB data (image data) to the LED modules configured in the cabinet, have the same attribute values.

Conventionally, as illustrated in FIG. 2, image data received through a sending card (100), i.e., RGB data of each pixel, is converted into an appropriate current signal according to RCFG data stored in a receiving card (200) so that individual LED elements of an LED module configured in a cabinet (300) perform operations such as emitting light.

However, as shown in FIGS. 3 and 4, when the receiving card (250) is replaced with a new one in which RCFG data is not stored, or when an RCFG error occurs, the user loads the RCFG file being stored from the setting program and transmits and stores the RCFG data to the receiving card (250) via the sending card (100).

In other words, in order to display a normal image on the LED module, unique setting data, RCFG data, is required. However, since the new receiving card (250) does not have RCFG data, the above operation is performed to resolve this.

In addition, if you use the LED screen for a long period of time, there may be cases where problems occur due to internal conflicts, errors, or changes in settings of the receiving card, and you may need to initialize the receiving card. To resolve this, you must re-transmit the unique RCFG data through the setting program.

The above unique RCFG data must be stored in file form, but if used for several years, the file may be lost or compatibility issues may occur due to version upgrades of the setup program and operating system, which may affect the smooth operation of the LED module.

Korean Patent Registration No. 10-2534956 relates to an LED display update configuration method, a receiving card, an LED display module, and an LED display, characterized in that when a power-on status is detected from a receiving card, identity authentication data stored in the receiving card is read to verify whether the receiving card has been replaced, and if it is confirmed that the receiving card has been replaced, configuration parameters stored in a memory device are output to the receiving card to update the configuration parameters of the receiving card, and when a power-on status is detected from an LED display module, display identity authentication data of the LED display module is read to verify whether the LED display module has been replaced, and if it is confirmed that the LED display module has been replaced, correction data of the LED display module is output to the receiving card described above. By detecting the update status of the receiving card and/or the LED display module and automatically correcting the data, the display can be restored to normal video transmission within a short period of time after the receiving card and/or the LED display module is updated, thereby saving display video joint debugging time and cost.

Korean Patent Publication No. 10-2010-0126827 relates to methods and circuits for a self-calibrating controller, a circuit for controlling one or more LEDs or LED drivers, comprising: a programmable decentralized controller coupled to one or more detectors, wherein the one or more detectors are configured to detect one or more measurable parameters of the one or more LEDs or LED drivers, wherein the controller is configured to receive information from the one or more detectors associated with the one or more measurable parameters, the controller is configured to adjust one or more controllable parameters until the one or more detectors indicate that one or more measurable parameters in one of the LEDs or LED drivers satisfy a reference condition, and the controller is configured to set one or more of the controllable parameters to operate at a value relative to the value of the controllable parameters for which the reference condition is satisfied, wherein the controllable parameter can be set at any regular or adjustable interval, or can be set at an initial Controllable parameters can be set for certain events such as initial start up or when certain system parameters are changed.

Korean Patent Registration No. 10-2638279 discloses a method for correcting luminance and color deviations between LED elements by using a sending card and a receiving card installed in an LED display device, wherein, through a controller provided in the sending card, each pixel has nine data attributes of Rr, Rg, Rb, Gr, Gg, Gb, Br, Bg, and Bb, and pixel correction data consisting of a total of 144 bits of data is converted into pixel correction data of nine frames with a data size of 16 bits, and CRC is calculated and verified, and the converted and verified pixel correction data of nine frames is transmitted to the receiving card through a display data transmission path linking the sending card and the receiving card, and the step of storing the pixel correction data of nine frames transmitted to the receiving card in a storage device (RAM) provided in the receiving card in correcting luminance and color deviations occurring between LED elements by using the pixel correction data of nine frames, the sending card And the present invention relates to a method for transmitting and correcting pixel correction data of LED elements of an LED display device, comprising: a step of transmitting CRC verification data to a receiving card through a display data transmission path provided in the receiving card; a step of determining whether nine frames of pixel correction data stored in a storage device (RAM) match the CRC verification data through a data comparison means provided in the receiving card, and if the nine frames of pixel correction data and the CRC verification data match, a step of storing the pixel correction data recorded in the storage device (RAM) in a flash memory provided in the receiving card; and a step of driving the LED elements with the pixel correction data stored in the flash memory, thereby correcting the deviation in brightness and color that occurs between the LED elements. The present invention relates to a method for transmitting and correcting pixel correction data of LED elements of an LED display device, characterized in that the pixel correction data is simulated and the divided data can be transmitted through the existing display data transmission path, thereby enabling rapid transmission of the pixel correction data and rapidly correcting the deviation in brightness and color that occurs between the LED elements using the transmitted pixel correction data.

Republic of Korea Patent Registration No. 10-2534956 (Registered on May 17, 2023, Title: LED display update configuration method, receiving card, LED display module, and LED display) Korean Patent Publication No. 10-2010-0126827 (Published on December 2, 2010, Title: Methods and Circuits for Self-Calibrating Controller) Korean Patent Registration No. 10-2638279 (Registered on February 14, 2024, Title: LED element pixel correction data transmission and correction method of LED display device)

The purpose of the present invention is to provide an intelligent LED display device which stores RCFG data in a plurality of modules, embeds a flash memory (flash chip) in each module, automatically reads RCFG data from the module, processes RGB data, and then transmits it to the module, thereby enabling normal display through LED.

Another object of the present invention is to provide an intelligent LED display device that enables normal display through LED by storing RCFG data stored in a module in a receiving card at the time of initial execution, regardless of whether there is a receiving card defect, a program crash, a user setting error, or loss of an RCFG file, and converting RGB image data based on this into current and then transmitting it to the module.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below.

The intelligent LED display device of the present invention to achieve the above purpose

A control unit that controls the overall operation so that the display through the LED is performed normally;

A sending card that receives RGB image data transmitted from a PC or image equipment through a cable connected to the PC or image equipment, converts the RGB image data into a predetermined current value based on RCFG data stored in the receiving card, and then transmits the RGB image data to the module so that it can be displayed through an LED.

A receiving card that receives the RCFG data from the module under the control of the control unit, applies it to the RGB image data transmitted from the sending card, converts it into a predetermined current value, and then transmits it to the module so that it can be displayed through an LED; and

It is characterized by comprising a cabinet formed of a display, which is composed of a plurality of modules having built-in flash memory in which the above RCFG data is stored.

In the present invention, the control unit

Regardless of whether there is a malfunction in the receiving card, a program crash, a user setting error, or a loss of the RCFG file, the RCFG data stored in the module is stored in the receiving card at the time of initial execution, and RGB image data is converted to current based on this and then transmitted to the module.

In the present invention, the control unit

A first step in which a sending card receives RGB image data transmitted from a PC or image equipment through a cable connected to the PC or image equipment;

A second step in which the receiving card receives RGB image data from the sending card and searches for RCFG data in the module so that the module converts the data into a current value based on the RCFG data;

As a result of the above search, if RCFG data is found in the module, the third step is to copy the RCFG data and transmit it to the receiving card;

A fourth step in which the receiving card converts RGB image data received from the sending card into current and transmits it to the module based on the RCFG data; and

It is characterized by performing a control operation consisting of a fifth step of receiving the converted current value transmitted from the receiving card in the module and displaying image data through an LED.

In the present invention, RCFG data exploration in the second step

It is characterized in that if RCFG data is not searched for in any one LED module among multiple modules, an operation of searching for other LED modules is performed sequentially.

According to the intelligent LED display device of the present invention, a flash memory (flash chip) storing RCFG data is built into the module, and the RCFG data is automatically read from the module, processed as RGB data, and then transmitted to the module, so that display through the LED can be performed normally.

In addition, regardless of whether there is a malfunction in the receiving card, a program crash, a user setting error, or a loss of the RCFG file, the RCFG data stored in the module at the time of initial execution is stored in the receiving card, and RGB image data is converted to current based on this and then transmitted to the module, thereby enabling normal display through the LED.

In addition to the above-described contents, the specific effects of the present invention are described together with the specific matters for carrying out the invention below.

Figure 1 is an example screen for explaining RCFG data.
Figures 2 and 3 are configuration diagrams of image data transmission control of a conventional LED display.
Figure 4 is a flow chart of operations for resolving errors in receiving cards of conventional LED displays.
Figure 5 is a diagram showing a video data transmission control configuration of an intelligent LED display according to the present invention.
Figure 6 is a flow chart of the operation of the receiving card firmware of the intelligent LED display device according to the present invention.
FIG. 7 is an example of an LED display capable of expressing characters and videos through LEDs, as an embodiment to which the present invention is applied.
The drawings above illustrate clear embodiments of the present invention and are described in more detail in the following. These drawings are not intended to limit the scope of the invention in any way, but are intended to enable those skilled in the art to understand the concept of the present invention by referring to specific embodiments.

The present invention may have various modifications and forms, and specific embodiments thereof are illustrated in the drawings and described in detail in the text.

However, this is not intended to limit the present invention to a specific disclosure form, but should be understood to include all modifications, equivalents, or substitutes included in the spirit and technical scope of the present invention.

The terminology used in this application is only used to describe specific embodiments and is not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly indicates otherwise.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Terms defined in commonly used dictionaries should be interpreted as having a meaning consistent with their meaning in the context of the relevant art, and will not be interpreted in an idealized or overly formal sense unless expressly defined in this application.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings.

Fig. 5 is a diagram showing a configuration for controlling image data transmission of an intelligent LED display according to the present invention. Fig. 6 is a flow chart showing the operation of a receiving card firmware of an intelligent LED display device according to the present invention.

As illustrated in FIG. 5, the intelligent LED display device of the present invention may be composed of a control unit (not illustrated), a sending card (100), a receiving card (200), and a cabinet (300) comprising a plurality of LED modules.

The control unit controls the overall operation so that RGB image data transmitted from a PC or image equipment is converted to a predetermined current value based on RCFG data and then transmitted to the module, thereby ensuring that display through the LED is performed normally.

The control unit also controls the storage of RCFG data stored in the module at the time of initial execution to the receiving card (200) regardless of whether there is a receiving card defect, program crash, user setting error, or loss of the RCFG file, and then the RGB image data is converted to current based on this and then transmitted to the module.

The sending card (100) is connected to a PC or video equipment via a video cable such as an HDMI cable, and transmits RGB video data received via this cable to the receiving card (200), thereby converting the RGB video data into a predetermined current value based on the RCFG data stored in the receiving card (200), and then displaying it via an LED module.

The receiving card (200) receives RCFG data from the module under the control of the above control unit, applies the RCFG data transmitted in this manner to RGB image data transmitted from the sending card (100), converts it into a predetermined current value, and then transmits it to the module.

The above receiving card (200) may be a card in which the initial RCFG data is not stored.

The cabinet (300) is composed of a number of modules to form a display, and AC power and DC power can be shared by linking them between the cabinets.

Each of the above multiple modules has a built-in flash memory in which RCFG data is stored.

The firmware operation of the receiving card (200) according to the present invention is comprised of the following basic operations: a step of storing RCFG data in the flash memory of the module; a step of searching for RCFG data in the flash memory of the module during the firmware of the receiving card (200); a step of transmitting the searched RCFG data to the receiving card (200); and a step of receiving RGB image data corresponding to each LED element constituting the module from the sending card (100) and transmitting it to the module as a current value converted through the RCFG data and displaying it through the LED.

If we break down these actions into more detail, they result in a motion flow as shown in Figure 6.

First, the sending card (100) receives RGB image data transmitted from a PC or image equipment through a cable connected to the PC or image equipment (S10).

Next, the receiving card (200) receives RGB image data from the sending card (100) and searches for RCFG data in the module to transmit the converted current value based on the RCFG data to the module (S20).

Next, if RCFG data is found in the module as a result of the above search, the RCFG data is copied and transmitted to the receiving card (S30).

Next, the receiving card (200) converts the RGB image data received from the sending card (100) into current and transmits it to the module based on the RCFG data (S40).

Next, the converted current value transmitted from the receiving card (200) is received by the module and the image data is normally displayed through the LED (S50).

Meanwhile, in the RCFG data search in step S20, if RCFG data is not searched in any one LED module among multiple modules, an operation of searching other LED modules is sequentially performed.

Next, an example to which the present invention is applied will be described.

Figure 7 is an example of an LED display that can express characters and videos through LEDs.

A module (21) having a built-in flash memory storing RCFG data may be composed of, for example, 256 (16 X 16 = 256) cells (22) of 16 each in the width and height, and in this case, an LED may be installed in each of the 256 cells (22).

Each of the above cells (22) is equipped with a single or multiple LEDs to emit light of a single color or mixed color, thereby allowing still images or moving images to be displayed.

In order to implement a video through a display, first, a certain movement can be recorded in real time through a recording medium and the recorded video data can be stored in a storage device, such as a computer.

Meanwhile, the combination of LEDs installed in the cell consists of RED LED, GREEN LED (23) and BLUE LED (24), and the LEDs can express a combination of colors by turning them on/off.

Image data stored in the above computer can be transmitted to the sending card and then transmitted to the module via the receiving card, thereby being displayed via an LED.

That is, image data stored in a storage device such as the computer can be implemented as a video through an LED under the control of the control unit, and when the image data stored in the storage device such as the computer is transmitted to the sending card, it is then transmitted to the receiving card, and based on the RCFG data stored in the receiving card, the current is converted and the LED lights up to express the image.

This operation is made possible by the operation in which, as described above, the control unit searches for RCFG data in the flash memory of the LED module, transmits the searched RCFG data to the receiving card, and then converts RGB image data corresponding to each LED element transmitted from the sending card into a predetermined current value based on the RCFG data and transmits it to the module, thereby driving the LED.

The display shown in Fig. 7 can be applied to, for example, a construction guide board. A construction guide board displays construction progress status, etc. in various characters or images, and if the guide display installed at a construction site does not operate normally, it can cause serious danger.

Accordingly, by embedding flash memory storing RCFG data in a plurality of LED modules constituting a construction guide board, transmitting RGB image data for guidance from a sending card to a receiving card, and displaying an image through an LED with a current value converted based on the RCFG data stored in the receiving card, even if a problem related to the RCFG data as described above occurs while displaying the image normally, danger can be prevented.

As seen above, the detailed description of the present invention has described preferred embodiments of the present invention, but this has been described as an example of the best embodiment of the present invention and does not limit the present invention. In addition, it goes without saying that anyone with ordinary knowledge in the technical field to which the present invention belongs can make various modifications and imitations within the scope that does not depart from the technical idea of the present invention.

100: Sending card 200: Receiving card
300 : Cabinet

Claims (4)

In order to perform display through LED normally, regardless of the presence of a receiving card defect, program crash, user setting error, or loss of RCFG file, the RCFG data stored in the module at the time of initial execution is stored in the receiving card, and RGB image data is converted to current based on this and then transmitted to the module, thereby controlling the sending card to receive RGB image data transmitted from a PC or image equipment through a cable connected to the PC or image equipment; the second step of sequentially performing operations of searching for RCFG data in a module so that the receiving card receives RGB image data from the sending card and transmits it to the module as a converted current value based on the RCFG data, and if RCFG data is not searched in any one LED module among a plurality of modules, searching for another LED module; the third step of copying the RCFG data and transmitting it to the receiving card if RCFG data is found in the module as a result of the search; the fourth step of sequentially performing operations of converting RGB image data received from the sending card based on the RCFG data and transmitting it to the module; A control unit that performs a control operation, comprising: a fifth step of receiving the converted current value transmitted from the receiving card in a module and displaying image data through an LED;
A sending card that receives RGB image data transmitted from a PC or image equipment through a cable connected to the PC or image equipment, converts the RGB image data into a predetermined current value based on RCFG data stored in a receiving card, and then transmits the RGB image data to a module so that it can be displayed through an LED.
A receiving card that receives the RCFG data from the module under the control of the control unit, applies it to the RGB image data transmitted from the sending card, converts it into a predetermined current value, and then transmits it to the module so that it can be displayed through an LED; and
An intelligent LED display device characterized by comprising: a cabinet formed of a plurality of modules having built-in flash memory in which the above RCFG data is stored to form a display; delete delete delete

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