KR200334697Y1 - Light emitting diode driving control apparatus for displaying video signal - Google Patents

Abstract

Various control signals are input to the external input mode selector and the control data memory to set the operation method of the LED driving control device, and then the image data is input through the shift register and stored in the video data memory, and the stored data is LED The vertical line driving for the dot matrix panel is performed.

The shift register may selectively set the number of bits of the input data according to the control data stored in the control data memory, and the duty to be driven according to the input signal of the external input mode selector and the control data input to the control data memory. A read address corresponding to the ratio can be generated.

Therefore, the number of input terminals of the drive control device can be reduced, the size of input data can be varied, and the duty ratio of the display panel can be varied.

Description

LIGHT EMITTING DIODE DRIVING CONTROL APPARATUS FOR DISPLAYING VIDEO SIGNAL}

The present invention relates to a drive control device for driving a light emitting diode (LED) display panel used for an electric signboard and the like, and an LED display module including the drive control device. The present invention relates to a drive control device capable of displaying gray levels for displaying an image signal as well as on / off, and varying a duty ratio.

The electronic signboard system displays LEDs, small fluorescent tubes, etc. in a matrix, and displays information such as various characters and pictures, and is generally composed of red, green, and blue (R, G, B) LED elements. The combination of LED display modules displays multiple colors.

There are many ways to drive the LED display module of the electronic display system, but it can be classified into a dynamic method and a static method, and a dynamic method with a small number of driving elements and a low manufacturing cost is used on a large screen. Since it is effective, it is widely used for an electronic sign board system.

1 shows an example of a conventional dynamic drive control circuit for driving a 16x16 LED dot matrix panel.

In FIG. 1, input data (R_DATA, G_DATA, B_DATA) for turning on / off three LEDs of red, green, and blue (R, G, B) is input to each shift register 11, 12, 13, The output terminal may be connected to the next driving control circuit in a cascade form, and output data R_DATA_O, G_DATA_O, and B_DATA_O may be output to the input terminal of the next driving control circuit. In addition, the clock signal CLK is input to each of the shift registers 11, 12, and 13, and the data is sequentially stored in each of the shift registers 11, 12, and 13.

The input data stored in the shift registers 11, 12, 13 are latched to the latch element 14 by the latch signal LATCH_I, and the LED dot matrix panel 10 is passed through the output enable circuit 17. Drive. That is, vertical line data driving to the LED dot matrix panel 10 is performed. At the same time, the address signals AO to A3 are input to the address decoder 18 and decoded to drive the panel 10, thereby driving the horizontal line data driving of the LED dot matrix 10. Is executed. Subsequently, by performing vertical line data driving for the next data while sequentially changing the address input to the address decoder 18, the LED of the LED dot matrix 10 is turned on / off to display an image.

The output enable circuit 17 turns on the vertical line driving data by using the output enable signal OUT_EN at the time when the address is changed to solve the problem that an afterimage occurs due to the horizontal line driving. Control the time appropriately.

In addition, like the input data R_DATA, G_DATA, and B_DATA, the clock signal CLK, the latch signal LATCH_I, and the output enable signal OUT_EN are respectively a clock output signal CLOCK_O, a latch output signal LATCH_O, and an output. As the enable output signal OUT_EN_O, it is output to the drive control circuit of the next LED module connected in cascade form.

Since the conventional dynamic drive control circuit uses a separate shift register for each of the R, G, and B input signals, an input terminal [input pin of an ASIC (Application Specific Integrated Circuit) constituting the drive control circuit is used. pin)] has a large number of problems. In general, since the number of input terminals increases doubling as the duty ratio (display time ratio) in the image display increases, the design of the LED display module including the drive control circuit is complicated and the manufacturing cost increases.

In addition, in the conventional dynamic drive control circuit, when the size of input data varies. As a result, the driving control circuit must be redesigned and manufactured, thereby increasing the manufacturing cost of the LED display module.

On the other hand, in the LED display panel used for the electronic display system or the like, the duty ratio of the drive control circuit is set according to the use and installation environment of the system to be manufactured. However, the conventional drive control circuit can execute only one duty ratio, and there is a problem in that the drive control circuit must be newly designed and manufactured to change the duty ratio.

As described above, when the drive control circuit is changed as described above in the electronic sign system, the design of the system main controller to be interlocked with the driving control circuit must be changed, so that the design of the electronic sign system is complicated and the manufacturing cost increases.

The present invention is to solve the problems of the conventional drive control device of the LED panel, and to provide a drive control device that can reduce the number of input terminals and vary the size of the input data of the drive control device for that purpose. do.

In addition, an object of the present invention is to provide a drive control device capable of varying the duty ratio of the display panel.

It is also an object of the present invention to provide a drive control device capable of reducing the burden of controlling the drive control device in the main controller of a display system such as an electronic display system.

1 is a block diagram showing an example of a conventional LED driving control circuit.

2 is a block diagram showing a light emitting diode driving control apparatus according to an embodiment of the present invention.

Figure 3 is a partial block diagram of Figure 2 for explaining the duty ratio variable function of the present invention.

LED drive control device of the present invention for achieving the above object

An external input mode selector which receives a signal from an external device and determines an operation mode of the driving control device;

A control signal buffer for receiving and storing control signals for controlling the driving control device;

A shift register for receiving and storing input data for displaying and controlling an image on the dot matrix panel;

A memory write address generator for generating a write address for an internal memory of the drive control device according to a control signal of the control signal buffer;

A memory read address generator for generating a read address for the internal memory of the drive control device according to a control signal of the control signal buffer and an input signal of the external input mode selector;

A video data memory for receiving and storing image data to be displayed on the dot matrix panel from the shift register according to an address generated by the memory write address generator;

A control data memory for receiving and storing control data for determining an operation mode of the driving control device from the shift register according to a control signal stored in the control signal buffer;

And a display line address decoder for decoding the address of the memory write address generator.

The shift register may selectively set the number of bits of input data according to the control data stored in the control data memory.

In addition, the drive control apparatus according to the present invention, a PWM buffer for performing a pulse width modulation control on the data buffer for buffering the image data stored in the video data memory according to the driving method, and the image data of the video data memory It may further include.

The driving control apparatus according to the present invention may further include a gradation clock generator for generating a clock for driving the PWM counter according to a clock of the self-oscillator and an external clock input to the control signal buffer.

In addition, the drive control device according to the present invention,

A correction data memory for receiving and storing data for color correction for each dot of the dot matrix panel from the shift register according to an address generated by the memory write address generator;

A luminance and white balance memory for receiving and storing data for adjusting luminance and white balance of the light emitting diode of the dot matrix panel from the shift register according to a control signal stored in the control signal buffer;

A luminance controller which receives data stored in the luminance and the white balance memory, divides the clock of the PWM counter, and adjusts the luminance of the light emitting diode of the dot matrix panel;

A white balance controller which receives data stored in the luminance and white balance memory, divides the clock of the PWM counter, and adjusts the white balance of the light emitting diode of the dot matrix panel;

The apparatus may further include a dot correction controller configured to receive data stored in the correction data memory, divide the clock of the PWM counter, and correct the color of each dot of the dot matrix panel.

The memory read address generator may receive input data of the external input mode selector and control data input to the control data memory and generate a read address corresponding to a duty ratio to be driven.

In addition, the driving control apparatus according to the present invention can be easily mounted on a light emitting diode display module (LED display module) used in the display board.

Hereinafter, with reference to Figure 2 will be described a preferred embodiment of the present invention.

2 is a block diagram showing an LED driving control apparatus according to an embodiment of the present invention. In FIG. 2, the drive control apparatus which drives the 16x16 LED dot matrix 20 is shown as an example.

In the driving control apparatus of FIG. 2, first, setting signals for determining the overall operation of the driving control are input to the external input mode selector 23, and basic control signals and address signals A0 and A1 for controlling the operation of the driving control apparatus. , A3 and A3 are input to the control signal buffer 22.

The signals input to the external input mode selector 23 include PIN / REGISTER and PRE1 / TEST signals for determining the input method of control data, and LINEOUT_N / P for determining the method of applying data to the line driver. There are a COLOUT_N / P signal, a POSITION0 to POSITION3 signal for determining an address corresponding to the position of each drive control device according to the duty ratio, and a DRIVE_MTRX signal for selecting an output drive to the panel of the drive control device.

The control data is input and set through one of the external pin PIN, the external controller PRE1, and the internal register REGISTER according to the PIN / REGISTER and PRE1 / TEST signals. Here, the TEST signal is for testing the drive control device. Input through the external pin (PIN) is when some of the control data 30 bits are set by the external pin (PIN) and the rest is set in advance internally, input through the external controller (PRE1) is 30 bits control data All of them are stored in the internal memory through the shift register 21 to be described later, and an input through the internal register (REGISTER) represents a case where all 30 bits of control data are set in advance.

According to the LINEOUT_N / P signal, the driving element drives the output logic of the horizontal line to active low or active high, and likewise activates the output logic of the vertical line according to the COLOUT_N / P signal. Drive to active low or active high.

The DRIVE_MTRX signal determines whether the output drive is 1x16 drive or 2x8 drive.

The POSITION0 to POSITION3 signals are used to vary the duty ratio of the driving control device, which will be described later.

After the control signal for determining the overall operation of the drive control is input as described above, the input data R_DATA, G_DATA, B_DATA for turning on / off the LEDs of R, G, and B is 10 bits by the shift clock S_CRK. The input is input to the x3x16 shift register 21. Further, correction data, control data, etc. to be stored in the internal memory of the drive control device are also input through the shift register 21.

The shift register 21 may be set to shift registers of 1x3x16, 2x3x16, 4x3x16, 6x3x16, 8x3x16, and 10x3x16 bits in accordance with the control data. In addition, the input method can be converted in series and in parallel by the control data. In case of serial, all R, G, B data is input through R input terminal, and G, B input terminal is not used. Therefore, in this case, the number of input terminals (input pins) can be reduced.

In addition, the input data of the shift register 21 can be selected from 1 bit up to 10 bits. That is, data of 1, 2, 4, 6, 8, 10 bits can be selected according to the control data value stored in the control data memory 26. Therefore, by appropriately changing and inputting control data, only LED on / off driving is required to display only characters, and signals up to 10 bits (1024 gray scales) can be driven to display high quality video signals. Can be.

The data input through the shift register 21 is the video data memory 26, the correction data memory 50, and the control data, which are internal memories, according to control signals VD / CD, CRTL / BRT, and LATCH. Memory 27 and brightness and white balance memory 51, respectively.

The control signal VD / CD is a signal for selecting the video data memory 26 and the correction data memory 50, and the CTRL / BRT is a signal for selecting the control data memory 27 and the luminance and white balance memory 51. , LATCH is a signal to write data to memory.

The video data memory 26 is a memory in which 30x16x16 bits of data for displaying an image on an LED is stored, and the correction data memory 50 is 15x16x16 bits for color correction for each dot of the 16x16 dot matrix panel 20. The memory where data is stored. The video data memory 26 preferably uses dualport RAM in which data read / write is executed independently.

On the other hand, the control data memory 27 is a memory for storing 30-bit control data for determining an operation mode of the drive control apparatus, and the luminance and white balance memory 51 is provided with R, G, and R of the 16x16 bit dot matrix panel 20. It is a memory that stores 20-bit data for controlling the luminance and white balance of B colors.

The memory write address generator 24 generates data write addresses for the video data memory 26 and the correction data memory 50 according to the address signals A0 to A3, and controls them according to the generated addresses. The corresponding data is stored in the memory selected by the signals VD / CD and CRTL / BRT.

The data buffer 28 buffers the data stored in the video data memory 26 to be suitable for 1x16 driving or 2x8 driving.

The pulse width modulation (PWM) counter 29 performs pulse width modulation control on the data output from the data buffer 28 in accordance with the clock of the gradation clock generator 40 described later.

The gradation clock generator 40 is a circuit for generating a clock for driving the PWM counter 29 and includes a gradation clock generator 41, a gradation clock divider 42, and a gradation clock selector 43. The gray clock generator 40 selects an appropriate basic clock according to the clock of the self-oscillator and the external clock G_CLK input to the control signal buffer 22. The gradation clock generator 40 may increase or decrease the clock of the PWM counter 29 in multiples of 5 MHz to 80 MHz. Since the overall brightness of the LED panel 20 can be changed by such a clock change, the brightness of the LED panel can be easily adjusted by changing only the control data.

The luminance controller 52 receives 5-bit data stored in the luminance and white balance memory 51, divides the clock of the PWM counter 29, and adjusts the luminance of the LEDs of the panel 20. On the other hand, the white balance controller 53 receives the brightness and 15-bit data stored in the white balance memory 51, divides the clock of the PWM counter 29, and adjusts the white balance for the LED of the panel 20.

The dot correction controller 54 receives 5-bit data for each color stored in the correction data memory 50, divides the clock of the PWM counter 29, and corrects the color of each dot of the panel 20. FIG.

As described above, the PWM counter 29 is a video data memory by clock division by the gradation clock generator 40 and clock division by the luminance controller 52, the white balance controller 53, and the dot correction controller 54. PWM control is performed on the data in (26).

The output of the PWM counter 29 is applied to the LED dot matrix panel 20 through the output enable circuit 30 and the 16 dot x 3 color LED driving element 31, so that vertical line driving for the LED is executed.

At the same time, the memory read address generator 25 generates a memory read address in accordance with the 30-bit control data of the control memory. At this time, the memory read address is automatically generated in accordance with the control signal LOAD.

The memory read address is decoded by the display line address decoder 32 and applied to the LED dot matrix panel 20 through the 16-line driving element 33, so that the horizontal line driving for the LED is executed.

At this time, in order to solve the problem that an afterimage occurs due to the horizontal line driving, the output enable circuit 30 turns on the vertical line driving data by using the output enable signal OUT_EN at the time when the address is changed. control the turn on time appropriately. In addition, the watchdog timer 44 is for turning off the output of the driving device when the basic clock and other important signals for operating the PWM counter 29 are not input.

Next, the duty ratio variable function of the drive control device will be described.

The number of driving control devices is determined according to the duty ratio. When the duty ratio is 1/16 in a 16x16 dot matrix, one driving control device scans the horizontal line. When the duty ratio is 1/8, two driving is performed. The control device is applied, i.e., if the duty ratio is 1/8, one drive control device is responsible for displaying the upper 8 lines, and the other displays the lower 8 lines. Similarly, when the duty ratio is 1/4, four driving control devices are applied to display four lines each. When 16 drive control devices are applied and display one line each, the drive control device operates in the same manner as the static drive.

As shown in Fig. 3, the POSITION0 to POSITION3 signals and duty mask data (4 bits are used here) of the control data are input to the memory read address generator 25, and each drive control is performed in accordance with the LOAD signal. The read address for the device is determined. The determined address is input to the display line address decoder 32 and decoded to drive the corresponding line of the panel 20.

As described above, the read line corresponding to each driving control device is automatically determined by using the duty mask data of the POSITION0 to POSITION3 signals and the control data, thereby driving the horizontal line of the panel according to the duty ratio. Therefore, the duty ratio can be freely changed in one chip.

Next, the overall operation of the LED driving control apparatus according to the embodiment of the present invention described above.

First, signals for determining an operation method of the driving control apparatus are input to the external input mode selector 23, input data is stored in the shift register 21, and various control signals are input to the control signal buffer 22. Then, control data is input to the control data memory 27 to set the duty ratio of the drive control device and the like.

That is, by the signal input to the external input mode selector 23 and the control data input to the control data memory 27, various operations for driving are selected and set.

Next, the PWM clock is appropriately divided using the gradation clock, brightness, white balance, and dot correction data. This feature can be omitted as needed.

Next, image data is input so that luminance and white balance data, dot correction data, and image data are stored in each memory by a LATCH signal, and the stored data is driven vertical lines to the LED dot matrix panel 20 by a LOAD signal. Run At the same time, the horizontal line driving is also performed by the display line address decoder 32 to operate the LED of the panel 20 to display an image.

LED driving control device according to the present invention is preferably manufactured by ASIC. As described above, the LED driving control device of the present invention made of the ASIC can be easily mounted on the LED display module, which is a basic unit of the display board, and can provide a standardized control method to the LED display board for displaying an image.

LED driving control apparatus according to an embodiment of the present invention can select the transmission of R, G, B input data in series or in parallel. In the case of serial transmission, the number of input terminals of the drive control device can be reduced, thereby simplifying the design of the printed circuit board, thereby reducing the manufacturing cost. Such a reduction effect of the input terminal has a more significant effect when the duty ratio of the LED display panel is large.

In addition, since the LED drive control apparatus of the present invention can select a variable number of bits of the input data, it is possible to process the image data of up to 10 bits from the simple on / off of the LED.

In addition, the LED drive control apparatus of the present invention can be selected and driven to vary the duty ratio. In other words, even if the duty ratio is changed from 1/16 to 1/1 in the electronic board system, the control method is the same, so if you design a controller to control the 1/16 duty ratio, 1/2, 1/4, 1/8 The duty ratio of 1/16 can also be controlled. Therefore, it is possible to reduce the design and manufacturing cost of the signboard system.

In addition, the LED drive control apparatus of the present invention can select the clock for the internal PWM circuit by using the gray scale clock generator, and thus, the overall brightness of the LED panel can be easily adjusted by changing the clock.

Although the present invention has been described with reference to the above-described preferred embodiments and the accompanying drawings, different embodiments may be constructed within the spirit and scope of the present invention. Accordingly, the scope of the present invention is defined by the appended claims, and should be construed as not limited to the specific embodiments described herein.

Claims (5)

A light emitting diode driving control apparatus for displaying an image on a light emitting diode dot matrix panel, An external input mode selector which receives a signal from an external device and determines an operation mode of the driving control device; A control signal buffer for receiving and storing control signals for controlling an operation of the driving control device; A shift register for receiving and storing input data for displaying and controlling an image on the dot matrix panel and selectively setting the number of bits of the input data according to control data stored in a control data memory; A memory write address generator for generating a write address for an internal memory of the drive control device in accordance with a control signal of the control signal buffer; A memory read address generator for generating a read address for the internal memory of the drive control device according to a control signal of the control signal buffer and an input signal of the external input mode selector, A video data memory receiving and storing image data to be displayed on the dot matrix panel from the shift register according to an address generated by the memory write address generator; A control data memory for receiving and storing control data for determining an operation mode of the driving control device from the shift register according to a control signal stored in the control signal buffer; And a display line address decoder for decoding an address of the memory write address generator. The method of claim 1, A data buffer for buffering image data stored in the video data memory according to a driving scheme; And a PWM counter for performing pulse width modulation control on the image data of the video data memory. The method of claim 2, And a gradation clock generator for generating a clock for driving the PWM counter according to a clock of the self oscillator and an external clock input to the control signal buffer. The method according to claim 2 or 3, A correction data memory for receiving and storing data for color correction for each dot of the dot matrix panel from the shift register according to an address generated by the memory write address generator; A luminance and white balance memory for receiving and storing data for adjusting luminance and white balance of the light emitting diode of the dot matrix panel from the shift register according to a control signal stored in the control signal buffer; A luminance controller which receives data stored in the luminance and white balance memory, divides the clock of the PWM counter, and adjusts the luminance of the light emitting diode of the dot matrix panel; A white balance controller which receives data stored in the brightness and white balance memory, divides the clock of the PWM counter, and adjusts the white balance of the light emitting diode of the dot matrix panel; And a dot correction controller which receives data stored in the correction data memory, divides the clock of the PWM counter, and corrects the color of each dot of the dot matrix panel. The method according to any one of claims 1 to 3, The memory read address generator receives input data of the external input mode selector and control data input to the control data memory, and generates a read address corresponding to a duty ratio to be driven. .