KR101028529B1 - Fault processing system for electric display pannel of parrel driving led - Google Patents

Abstract

PURPOSE: A fault eliminating system for an electric display panel on which LEDs are operated in parallel is provided to immediately cut off driving power supply of a defective LED, thereby preventing unnecessary power consumptlon. CONSTITUTION: An electric display panel(30) comprises a plurality of LEDs which is connected to a data line in parallel. A main controller(10) receives image data from a computer. A sub controller(20) rearranges the image data received from the main controller to correspond to the LEDs. A driver(40) receives the image data from the sub controller. A power supply device(60) supplies driving power to the LEDs and the driver.

Description

Fault processing system for electric display pannel of parrel driving LED}

According to the present invention, LED modules are connected to one data line in a parallel structure, and each LED module receives its own addressing area, so that even if a specific LED module is defective, it does not affect other LD modules of the same line. This is to minimize the error handling system of the LED parallel drive signboard, which is more specifically, to reduce the unnecessary power consumption by cutting off the driving power supply to the LED module in error, the LED module in the error is the image or guide letters, etc. Adjust the display area to be excluded from the display area so that images or guide letters are transmitted without error.The display data displayed by the LED module converts digital signals into analog signals and compares and analyzes the amount of data. Parallel LED for real-time error detection and status checking by quickly detecting module errors It relates to a fault handling system of a driving display board.

LED (Light Eeitting Diode) is a semiconductor device that emits light, and is widely used in various electronic products and electronic display panels such as instrument panels in various colors such as red, green, and blue.

Among them, the LED signboard arranges a plurality of LEDs or a plurality of LED modules in which a plurality of LEDs are modularized in a matrix form, and emits various colors according to the input signals of the LEDs arranged in the matrix form to display various images or texts. Express.

Such LED signboards are installed and used in various forms outside or inside the building for the delivery of advertisements and various information.

The LED display board can be divided into a series structure and a parallel structure according to the electrical connection structure of the LED modules arranged in a matrix form.

The serial structure is a structure in which the LED modules are connected in series. The first arranged LED module processes only the address data allocated to itself from the entire input data and outputs the remaining data to the second LED module. The module also processes only the address data allocated to itself from the input data transmitted by the first LED module and transmits the rest to the next LED module.

Such a serial structure has a simple structure, but when an error occurs in any one of the LED modules, data is not transmitted to the rear end thereof, thereby causing a problem in that an area where display defects or errors occur in the entire display board is expanded.

The parallel structure prevents the error of a specific LED module from affecting other LED modules. The LED modules are connected in parallel to one data line.

The entire input data is sent to the data line, and the LED modules connected in parallel to the data line select and receive data of their addressing area from the entire input data sent to the data line so that the defect of a specific LED module is the same. It is a parallel structure that does not affect other LED modules of the data line.

Like this, LED parallel drive LEDs connected in parallel with LED modules do not affect other LED modules even if a failure occurs in a specific LED module. Therefore, overall display defects such as images and characters displayed on the LED boards are minimized. Poor deterioration of the image quality of the signboard, the problem can be greater when in charge of important images or characters of the defective LED module.

Therefore, it is necessary to make a quick maintenance and repair by detecting a defective LED module in the LED display board.

As a prior art for detecting defective LED modules (or individual LEDs) on an electronic board, Korean Patent Nos. 0815587 and 0910593 detect the luminance of light emitted from an LED module and compare it with a reference luminance to determine whether there is a defect. This method has a problem in that a separate circuit configuration for detecting luminance is added, and the added circuit is complicated and expensive.

Another conventional technique for detecting bad LED modules (or individual LEDs) on an electronic board is to use a shift register transistor chipset with error detection. This method is simple in configuration but the chipset is mostly imported and expensive. In addition, there is a problem that it is difficult to detect high-speed error in real time when displaying images or text at high speed.

In addition, in the prior art, the failure detection of the LED module detects the failure by comparing and analyzing the digital signal as the output data of the LED module. The digital signal is composed of many low and high signals, which makes it difficult to perform high-speed comparison analysis in real time. have.

The digital signal compares the clock generation time of the low or high signal with the low or high duration, and many low or high signals are difficult to perform high-speed comparison analysis in real time.

In addition, the LED display board according to the prior art detects a defective LED module, and there is a problem in that a means for minimizing the problem by separately treating a failure of the LED display plate before maintenance and repair of the defective LED module is not provided.

The present invention has been made in order to solve the problem of detecting the failure of the LED module of the LED parallel drive display board according to the prior art, and the problem that the separate processing means is not provided before the maintenance according to the failure detection,

If a failure of the LED module is detected, immediately shut off the supply of driving power to the LED module where the failure is detected to prevent unnecessary power consumption.

By changing the display area of the electronic signboard to exclude the defective LED module from the display area, high quality images or guide letters are continuously provided.

It is possible to detect the defect of LED module without additional complicated and expensive additional configuration, and it has excellent economic efficiency.

As the output data of LED module, it converts digital signal into analog signal and compares and analyzes the data volume so that it can detect defects at high speed.

Consisting of a simple constitution, it is easy to maintain and check quickly, and to provide a failure handling system for LED parallel drive signboards that are protected from electrical shock and noise by transmitting and receiving data using optical cables.

In order to achieve the above object, the LED system for treating a parallel drive panel according to the present invention is

An electronic board including a plurality of LED modules connected in parallel to a data line;

A main controller for receiving the image data from an external display computer and controlling the image displayed on the electronic display board;

A sub-controller for rearranging and outputting the displayed image data received from the main controller according to the plurality of LED modules of the display board;

A driver module for receiving the display image data from the sub-controller and turning on / off LEDs of the corresponding LED modules, respectively;

It is made, including; a power supply for supplying driving power to the LED module and the driver module,

The LED module is provided with an output data return unit for transmitting the output data driving the display image data to the sub-controller,

The sub-controller compares and analyzes the output data transmitted by the return unit to determine whether the corresponding LED module is normal, and if it is determined to be error, transmits it to the main controller and controls the power supply to drive the LED module. It is characterized in that the power supply is cut off.

The may controller may control the sub-controller to change the image data display area on the display board to exclude the corresponding LED module in which an error occurs.

The return unit included in the LED module includes a D / A converter that converts a digital signal into an analog signal as output data obtained by driving display image data.

The sub-controller includes a D / A converter that converts the displayed image data into an analog signal as a digital signal sent to the LED module,

The sub-controller compares and analyzes the data amount of the analog signal for the display image data transmitted to the LED module and the analog signal for the output data transmitted from the return unit of the LED module to determine whether the LED module is normal at high speed. Characterized in that

The main controller and the sub-controller is connected to the optical cable to transmit and receive data,

The sub-controller and each LED module is characterized by transmitting and receiving data in the LVDS LEVEL method.

The fault handling system of the LED parallel driving signboard according to the present invention having such a configuration can quickly detect a bad LED module, immediately cut off the supply of driving power to a bad LED module, and prevent unnecessary power consumption, and a bad LED module. Except in the display area of the display board, high-quality images and texts are continuously provided to the display board.The output data output from the LED module converts the digital signal into an analog signal and compares and analyzes the data amount of the analog signal. It is a very useful invention for industrial development as a fault handling system of LED parallel drive signboard which is capable of real-time high-speed detection by using the optical cable and transmit / receive data by using optical cable to be protected from electric shock and noise.

1 is a block diagram of a failure treatment system of the LED parallel drive billboard according to the present invention.
Figure 2 is a block diagram of a driver module and an LED module.
3 is a data flow diagram for fault detection in a sub controller.

1 to 3 will be described in more detail with respect to the failure handling system of the LED parallel drive billboard according to the present invention.

As shown in the figure, the fault handling system of the LED parallel driving signboard according to the present invention includes a signboard 30 composed of a plurality of LED modules 30A, a main controller 10, a subcontroller 20, and a driver module 40. ), An output data return unit 50, and a power supply 60.

The electronic sign 30 is composed of a plurality of LED modules 30A, the LED module 30A may be composed of one single LED, may be composed of a plurality of LEDs.

In the present invention, a large display board installed in a highway toll gate, etc. mainly targets, and uses an LED module 30A composed of a plurality of LEDs for the convenience of production and maintenance of the display board.

The LED module 30A is composed of LEDs arranged in the form of 16 * 16 or 24 * 24 or 32 * 32.

In addition, the LED of the LED module 30A uses a combination of R, G, and B elements that emit red, green, and blue light, which are three primary colors of light, so as to realize full color.

The main controller 10 generally controls the failure processing system of the LED parallel drive billboard according to the present invention.

The main controller 10 is connected to the display computer 70 receives the data for the image or text to be displayed on the electronic display board 30 from the display computer 70, and temporarily stores the received data in the memory, The received data is transmitted to the corresponding subcontroller 20.

In addition, the main controller 10 receives information on the LED module 30A in which an error occurs from the sub-controller 20, and transmits information on an error of the received LED module 30A to a host (not shown). The maintenance of the LED module 30A can be performed, and the display area of the display board 30 is controlled so that the LED controller 30A having an error is excluded from the display area of the display board 30 by controlling the sub-controller 20. To change. That is, the display area of the electronic display board 30 is reduced or moved left and right or up and down so that an error-prone LED module 30A is not included in the display area so that information such as an image or a character to be delivered is missing to the viewer. Ensure accurate delivery without

The sub-controller 20 is connected to the main controller 10 to receive the display image data to be displayed on the display board 30 from the main controller 10, the received data through the data line DL LED module ( 30A).

The sub-controller 20 is connected to the main controller 10 and the optical cable (O.L) to transmit and receive data with each other.

Optical cable (O.L) prevents the inflow of noise in the process of transmitting and receiving data, and has a strong advantage against electric shock. By connecting the main controller 10 and the sub-controller 20 through an optical cable OL, clear images and texts are displayed on the electronic display board 30 by transmission and reception of noise-free data, and the system of the present invention is constructed from electric shock. The equipment is protected.

A plurality of data lines DL are connected to the subcontroller 20, and the subcontroller 20 rearranges and transmits the displayed image data transmitted from the main controller 10 to a corresponding data line DL. The LED modules 30A connected in parallel to each data line DL select and receive data of respective addressing regions from the displayed image data transmitted to the data line DL.

In addition, the sub-controller 20 includes a D / A converter (not shown) for converting the display image data, which is a digital signal transmitted to the LED module 30A through an data line DL, into an analog signal. The LED module 30A receives an analog signal as output data obtained by driving the displayed image data from the D / A converter (not shown) of the output data return unit 50 included in the module 30A.

The sub-controller 20 may convert an analog signal of the displayed image data converted by the D / A converter and an analog signal of the output data obtained by driving the displayed image data transmitted by the D / A converter of the return unit 50. The data amount is compared and analyzed to determine whether the corresponding LED module 30A is normal.

If it is determined that the error is normal, the sub-controller 20 transmits the notification to the main controller 10 and informs it, and simultaneously controls the power supply 60 to supply driving power to the LED module 30A in which the error occurs. To prevent power consumption and to receive the control signal of the main controller 10 to change the display area of the electronic sign 30 so that the LED module 30A having an error is not included in the display area.

In this case, the D / A converters are respectively provided in the sub-controller 20 and the return unit 50 connected to the LED module 30A to detect the normality of the LED module 30A, as described above. ) To quickly and accurately determine whether or not it is normal. That is, it takes a considerable time to directly cross-analyze the digital signal as the display image data transmitted through the data line DL and the digital signal as the output data driven by the LED module 30A. Since the real-time failure of the LED module 30A is not detected, the D / A converter is provided at the sub-controller 20 and the return unit 50 connected to the LED module 30A, respectively. After converting to, the data amount is compared and analyzed at high speed so that it can be determined in real time in real time.

In addition, the sub-controller 20 receives information on the humidity and temperature inside the display board from the humidity sensor 31 and the temperature sensor 33 provided in the display board 30, and sets the received humidity and temperature based on a predetermined reference humidity. And the reference temperature, and when the humidity and the temperature is out of the reference humidity and the reference temperature, respectively, by driving the fan 35 provided in the display board 30 to lower the humidity and temperature, the display board 30 It protects the LED, the driver module 40, the return unit 50 and the like of the provided LED module 30A.

In addition, although the main controller 10 and the sub-controller 20 may be connected in a one-to-one manner, a large number of LED modules 30A are used in the large display board 30 and may be connected in a one-to-many manner. That is, one sub-controller 20 may be connected to one main controller 10 in a one-to-many manner. One sub controller 20 is connected with as many data lines DL as the number of output ports.

The driver module 40 is embedded in each of the LED modules 30A, and has an addressing area allocated to itself in all displayed image data transmitted by the subcontroller 20 through a data line DL. Select and receive the displayed image data, and turn on / off the LEDs constituting the LED module 30A according to the received displayed image data.

When the LED is turned on, the LED is turned on by applying a current having a size and a wavelength according to the color to each of the R, G, and B elements constituting the LED so that the LED is turned on in accordance with the displayed image data.

  The driver module 40 is connected to a data line DL in parallel to receive a display image data transmitted by the sub-controller 20 and the display image data received by the receiving unit 41 itself. Extracts and selects only the display image data of the addressing area allocated to the selector 43, and reads the driving operation logic state of the display image data selected and received by the selector 43 to configure the LED module 30A. A shift register 45 for causing the LEDs to light up in their respective colors, and a transmitter 47 for transmitting analog signals of the output data of the LED module 30A transmitted by the return unit 50 to the sub-controller 20. It is made to include.

In addition, the driver module 40 and the return unit 50 and the sub-controller 20 connected to the LED module 30A are connected in parallel in an LVDS LEVEL method (low power high speed transmission method) to transmit and receive data.

The output data return unit 50 is connected to each of the LED modules 30A, and outputs data processed by the LED module 30A to drive display image data to the sub-controller 20 through a return line RL. send. At this time, the output data of the digital signal output from the LED module 30A is converted into an analog signal and transmitted to the sub-controller 20. The output data return unit 50 includes a D / A converter for converting a digital signal into an analog signal.
For reference, the return unit 50 directly outputs output data obtained by driving the displayed image data by the LED module, that is, output data outputted after the shift register is transmitted to the LED by the shift register and outputted by L emission. The part is not sent, but is sent back to the shift register.
The shift register transmits output data transmitted by all LEDs of the corresponding LED module to the return unit.
The return unit merges the output data of all the LEDs of the corresponding LED module transmitted by the sheet register into one and arranges the output image data inputted to the corresponding LED module in accordance with the arrangement order of the displayed image data.
When the LED module is in a normal state, output data of the same type as the inputted display image data is outputted, and when there is a failure, deformation occurs to output another type of output data. In other words, the input data and output data of the LED are digital signals, and when there is a failure, a distortion occurs in one or more bits of the clock signal.

The power supply 60 supplies the driving power to the equipment constituting the failure handling system of the LED parallel drive billboard according to the present invention. That is, the driving power is supplied to the main controller 10, the sub controller 20, the LED module 30A, the driver module 40, and the return unit 50.

Then, the driving power to the LED module 30A is supplied or cut off by the control of the sub-controller 20.

Hereinafter, a data flow process for determining whether the LED module 30A is defective will be described with reference to FIG. 3.

First, the sub-controller 20 prepares to determine whether the LED module (30A) is defective by initializing the individual ports (S10).

After initializing individual ports and preparing to determine whether the LED module 30A is defective, when the displayed image data and various control signals are received from the main controller 10 (S20), the subcontroller 20 Transmits the displayed image data to the LED module 30A through the data line DL and simultaneously converts the digital signal of the received image data into an analog signal to measure the power level and current of the displayed image data ( S30). The power level and current of the displayed image data to be measured are analog signals, and the data amount is temporarily stored (that is, collected) (S40).

The display image data transmitted to the LED module 30A through the data line DL is driven by the LED module 30A to display an image or a character on the display board 30, and output the driven display image data. Data is converted to an analog signal in the D / A converter of the output data return unit 50 (S50) and then transmitted to the sub-controller 20 to collect the data amount (S60).

When the output data of the LED module is collected and transmitted as an analog signal from the D / A converter of the output data return unit 50 (S60), the sub-controller 20 is input from the main controller 10 and converted. The analog signal data amount of the image data and the output data analog signal data amount of the output image data converted and output from the return unit 50 are compared and analyzed to determine whether the corresponding LED module 30A is normal (that is, whether or not it is defective). Determine (S70).

The sub-controller 20 transmits the determination result of the corresponding LED module 30A to the main controller 10 (S80), and when the determination result indicates that the corresponding LED module 30A is defective, the sub-supply 20 supplies the power supply 60. The control is cut off the power supply, and if determined to be normal, the power supply is continued (S90).

In the above description of the present invention with reference to the accompanying drawings has been described with respect to the failure handling system of the LED parallel drive billboard having a specific configuration, the present invention can be variously modified and changed by those skilled in the art, such modifications and changes are It should be interpreted as falling within the protection scope of the invention.

10: main controller 20: subcontroller
30: LED board 30A: LED module
40: driver module 50: output data return unit
60: power supply 70: display computer

Claims (4)

An electronic board including a plurality of LED modules connected in parallel to a data line;
A main controller for receiving the image data from an external display computer and controlling the image displayed on the electronic display board;
A sub-controller for rearranging and outputting the displayed image data received from the main controller according to the plurality of LED modules of the display board;
A driver module for receiving the display image data from the sub-controller and turning on / off LEDs of the corresponding LED modules, respectively;
It is made, including; a power supply for supplying driving power to the LED module and the driver module,

The LED module is provided with an output data return unit for transmitting the output data to the sub-controller for outputting the light output after driving the light according to the display image data input to the LED,
The sub-controller compares and analyzes the output data transmitted by the return unit to determine whether the corresponding LED module is normal, and if it is determined to be error, transmits it to the main controller and controls the power supply to drive the LED module. Characterized in that the power supply is cut off,

The return unit included in the LED module includes a D / A converter that converts a digital signal into an analog signal as output data obtained by driving display image data.
The sub-controller includes a D / A converter that converts the displayed image data into an analog signal as a digital signal sent to the LED module,
The sub-controller compares and analyzes the data amount of the analog signal for the display image data transmitted to the LED module and the analog signal for the output data transmitted from the return unit of the LED module to determine whether the LED module is normal at high speed. Disability treatment system for LED parallel drive billboard. The method of claim 1,
And the main controller controls the sub-controller to change the image data display area on the display board to exclude the corresponding LED module having an error. delete The method according to claim 1 or 2,
The main controller and the sub-controller is connected to the optical cable to transmit and receive data,
The sub-controller and each LED module transmits and receives data in an LVDS LEVEL manner.

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