KR101948843B1 - System for controling picture element of display device using look-up table and method therefor - Google Patents

Abstract

The present invention relates to a display device pixel control system using a lookup table and a method thereof. The display device pixel control system using a lookup table comprises: a video signal input unit for receiving a video signal, converting the video signal into a digital video signal (RGB), and generating a horizontal synchronizing signal (H Sync), a vertical synchronizing signal (V Sync), and a clock; an LUT (RAM) for receiving an address generated by RGB, the H Sync, the V Sync, and the clock; a video output unit for receiving the RGB from the LUT (RAM) as data, receiving the H Sync, the V Sync, and the clock from the video signal input unit as data, and converting the data into output data of a display device; and a conversion data input unit for receiving mapping data calculated or converted from an I/O including a PC or a CPU and writing the mapping data into the LUT (RAM) by using an address signal to convert the video signal. According to the present invention, a final value obtained by various calculations and conversions for video data through a PC or a CPU is inputted and transmitted to the LUT to be outputted as one dot clock, thereby solving the problems such as delay and shortage of time in the output of the video data due to multiple calculations or conversions.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a pixel control system for a display device using a look-

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device pixel control system using a lookup table and, more particularly, to a display device pixel control system using a lookup table, And mapping the output data with respect to each pixel, thereby facilitating adjustment of the luminance and chrominance of each of the individual pixels.

The video display device is a device that displays brightness proportional to input brightness data. At this time, there is no exact proportional relationship between the input data and the brightness perceived by humans, because of the gamma characteristic.

The gamma characteristic refers to the nonlinearity inherent in the display or the like (mainly exponential relationship). The gamma characteristic is a relationship coefficient (y) between the image brightness actually captured and the image brightness output on the screen, And the signal value output to the output terminal is as shown in FIG.

As shown in FIG. 1, since the human visual response characteristic, the response gamma characteristic, and the linear gamma characteristic are different, gamma correction is performed when an image is displayed through a display device.

The characteristics of the display device differ depending on the characteristics of the non-light emitting device, the light emitting device, and the like. The characteristics of the display device differ depending on the type of the display device, such as the color of the display screen and the linearity of brightness.

That is, depending on the display device, the input data and the output brightness have different characteristics, and the human visual characteristics also have non-linear characteristics, and thus the input video signal can not be properly displayed.

Further, when the individual display elements or some of the display modules are replaced with each other, it is possible to exhibit brightness different from that of surrounding pixels due to aging or deterioration of the individual elements.

As a method for changing the brightness of a display element or a driving element, various mapping methods such as a method using a mathematical expression such as an arithmetic operation, a method using logic, and a method using a lookup table have been implemented.

However, in order to individually apply the conversion method using the formula to each of the individual pixels, in the case of the nonlinear or discontinuous conversion relation, the characteristic function for each of the individual pixels is required to be operated. Therefore, The problem of lengthening occurs.

In addition, the logic method also has a disadvantage in that if the computation is not performed within one frame period according to the performance of the CPU or the controller due to the multi-step computation, the screen is interrupted or chromaticity or brightness is abnormally generated.

A method of converting the brightness of a display device using some lookup tables has been disclosed. However, the brightness of all devices provided in the display device is collectively controlled, so that brightness can not be controlled for each device.

Korean Patent No. 10-1842904

SUMMARY OF THE INVENTION It is an object of the present invention to provide an image processing apparatus and an image processing method which are capable of: 1) converting image signals input from an image display apparatus to different output gamma characteristics, 3) the color depth including the gamma characteristic, the chromaticity, the luminance, the visibility or the color temperature is to be adjusted; and 4) in the case of the digital image signal, the bit depth of the input signal and the bit depth of the display device are different from each other 5) when the color gamut of the image input signal is to be converted, 6) when the brightness of the individual pixels is different from the surrounding pixels due to aging or deterioration, or 7) when the individual pixels or individual pixels A final value obtained by performing an arithmetic operation or a transformation on all input data with respect to the position coordinates of the individual pixels of the display device using the lookup table (LUT) is used as output data The mapping of the input data and the mapping of the data of each of the individual pixels facilitates the adjustment of the luminance and chrominance of each of the individual pixels and prevents the problems such as delay of the video data output and time shortage.

According to an aspect of the present invention, there is provided a display device pixel control system using a look-up table, which receives a video signal and converts the video signal into a digital video signal RGB, A video signal input unit for generating a signal (V Sync) and a clock; A LUT (RAM) for receiving a digital video signal (RGB), an address generated by a horizontal synchronizing signal (H Sync), a vertical synchronizing signal (V Sync), and a clock; And receives a digital video signal RGB from the LUT (RAM) as data, receives the horizontal synchronizing signal H Sync, the vertical synchronizing signal V Sync, and the Clock as data from the video signal input unit and converts it into output data of the display device A video output unit; And a conversion data input unit for receiving the mapping data calculated or converted from the I / O including the PC or the CPU and writing the mapping data into the LUT (RAM) using the address signal to convert the video signal .

Preferably, the video signal input unit inputs the digital video signal RGB to the data address of the LUT (RAM), inputs the dot clock to the counter to generate the horizontal position address of the LUT (RAM), and outputs the H Sync signal counter to generate a vertical position address of the LUT (RAM).

The horizontal position address is the x coordinate of the LUT (RAM), and the vertical position address is the y coordinate of the LUT (RAM).

The LUT (RAM) is characterized by a RAM having an access time shorter than 1 dot clock time.

The mapping data is output data to be finally displayed on a display device after completing calculations according to brightness, contrast, gamma characteristic, color temperature, visibility, color recall rate and bit depth difference between input devices by a PC or a CPU.

A display device pixel control method using a lookup table according to an embodiment of the present invention based on the system described above is characterized in that a video signal input unit receives a video signal and converts the video signal into a digital video signal, (A) generating a vertical synchronization signal (V Sync) and a clock; (B) receiving a digital image signal (RGB), a horizontal synchronizing signal (H Sync), a vertical synchronizing signal (V Sync) and an address generated by a Clock from a video signal input unit of a LUT (RAM); The video output unit receives the digital video signal RGB as data from the LUT and receives the horizontal synchronizing signal H Sync, the vertical synchronizing signal V Sync and the clock as data from the video signal input unit, (C) converting the data into data; And (d) inputting, as an address signal of the LUT (RAM), the mapping data received from the I / O conversion data input unit after the step (a) or before the step (c).

According to the present invention as described above, it is possible to (1) change a gamma characteristic between an input signal and an output device when displaying an image signal input from an image display device, (2) 3) to adjust the color gamut including gamma characteristics, chroma, luminance, visibility or color temperature; 4) to adjust the bit depth of the input signal and the bit depth of the display device in case of a digital image signal; 5) when the color gamut of the image input signal is to be converted, 6) when the brightness of the individual pixels is changed due to aging or deterioration, or 7) when the individual pixels or When replacing a module including individual pixels, a final value obtained by performing an arithmetic operation or a transformation on all input data with respect to the position coordinates of each of the individual pixels of the display device using a lookup table (LUT) It is easy to adjust the luminance and chrominance of each of the individual pixels through mapping to the data of each of the individual pixels instead of merely mapping the input data and it is possible to easily solve the problems such as delay of the video data output and lack of time .

FIG. 1 is a graph showing relationship coefficients according to human visual response characteristics, CRT response gamma characteristics, and linear gamma characteristics. FIG.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a display device,
3 is a block diagram illustrating a video signal input unit of a display device pixel control system using a look-up table according to an embodiment of the present invention.
4 is a block diagram illustrating a LUT of a display device pixel control system using a lookup table according to an embodiment of the present invention.
5 is a configuration diagram illustrating a video output unit of a display device pixel control system using a look-up table according to an embodiment of the present invention.
6 is a configuration diagram illustrating a conversion data input unit of a display device pixel control system using a lookup table according to an embodiment of the present invention.
FIG. 7 is a block diagram illustrating a display device pixel control method using a lookup table according to an embodiment of the present invention; FIG.
8 is a flowchart illustrating a detailed procedure of step S100 of a method of controlling a display device pixel using a lookup table according to an embodiment of the present invention.
FIG. 9 is a flowchart illustrating a process after step S100 or step S300 of a method of controlling a display device pixel using a lookup table according to an embodiment of the present invention. FIG.

Specific features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. Prior to this, terms and words used in the present specification and claims are to be interpreted in accordance with the technical idea of the present invention based on the principle that the inventor can properly define the concept of the term in order to explain his invention in the best way. It should be interpreted in terms of meaning and concept. It is to be noted that the detailed description of known functions and constructions related to the present invention is omitted when it is determined that the gist of the present invention may be unnecessarily blurred.

2, a display device pixel control system S using a lookup table according to an embodiment of the present invention includes a video signal input unit 100, a LUT (RAM), a video output unit 200, and a conversion data input unit 300).

Hereinafter, the pixel control system S using the look-up table according to the embodiment of the present invention receives 8-bit video signals of R, G, and B for detailed explanation, 256X256 will be described.

Therefore, the video signal according to an embodiment of the present invention is not limited to 8 bits but can receive a video signal of a bit conforming to the HDMI or DVI standard.

3, the video signal input unit 100 receives a video signal including an HDMI, DVI, or analog signal, converts the video signal into a digital video signal (8-bit RGB), and outputs a horizontal synchronizing signal H Sync, V Sync) and a clock and applies the generated clock to the LUT (RAM).

Specifically, the video signal input unit 100 inputs the digital video signal RGB to the addresses A0 to A7 of the LUT (RAM) and inputs the dot clock to the 8-bit counter to generate the addresses A8 to A15 of the LUT (RAM) .

Also, the video signal input unit 100 uses the H Sync signal as the clear signal of the counter, and inputs the H Sync signal to the 8-bit counter to generate addresses A16 to A23 of the LUT (RAM).

At this time, the addresses A8 to A15 generated by the 8-bit counter are the x coordinate of the LUT (RAM), and the addresses A16 to A23 are the y coordinates of the LUT (RAM).

That is, address signals A0 to A7 are generated as input data, and the video signal input unit 100 generates address signals A8 to A15 using a dot circuit as a dot clock signal, The address signals (A16 to A23) are generated by using a counter circuit corresponding to the vertical size of the image as the sync signal.

The address signals A0 to A7 may be interpreted as a data address, the address signals A8 to A15 may be interpreted as a horizontal position address, and the address signals A16 to A23 may be interpreted as a vertical position address according to an embodiment of the present invention.

4, the LUT (RAM) inputs the digital image signal RGB, the horizontal synchronizing signal H Sync, the vertical synchronizing signal V Sync, and the address generated from the clock A0 to A23 from the image signal input unit Receive.

In this case, the LUT (RAM) is composed of a RAM having an access time shorter than 1 dot clock time, and the RAM capacity is the bit depth of the screen resolution (256X256) X color (8 bits; 256) 3) The bit depth of the X output signal (ex 8bit) can be obtained.

According to the above-described configuration, the capacity of the RAM becomes 256 X 256 X 256 X 3 X 8 bits = 50,331,648 X 8 bits = 50,331,648 (bytes), that is, 50 megabytes.

5, the video output unit 200 receives a digital video signal RGB from the LUT and receives a horizontal synchronizing signal H Sync and a vertical synchronizing signal V from the video signal input unit 100. [ Sync) and Clock as data and converts it into output data of the display device. At this time, the display device may be configured either of HDMI or DVI.

Referring to FIG. 6, the conversion data input unit 300 is a module for writing data (mapping data) calculated or converted from an I / O including a PC or a CPU into a LUT (RAM) And inputs the data as an address signal of the LUT (RAM).

Here, the mapping data is output data to be finally displayed on the display device after completing calculations according to the brightness, contrast, gamma characteristic, color temperature, visibility, color recall rate, and bit depth difference between the input power devices by the PC or CPU.

For example, the conversion data input unit 300 converts the conversion data con0 corresponding to the input image data 0, the conversion data con1 corresponding to the image data 1, and the conversion data con255 corresponding to the image data 255 The same is written in the individual positions of the display pixels.

At this time, the conversion data input unit 300 sets the video data 0 to 255 to the addresses A0 to A7, designates the x position of the display pixel at the addresses A8 to A15, and designates the y position of the display pixel at the addresses A16 to A23.

Then, the conversion data input unit 300 inputs data corresponding to the position of the display pixel in the data D0 to D7.

The same data is stored in the storage locations of the LUT (RAM) designated by the addresses A0 to A7 for all positions of the individual display pixel x coordinate and y coordinate.

That is, con0 is stored at address 0 corresponding to the positional x-coordinate and y-coordinate of the individual display pixels, con1 to address 1, and con255 to address 255, and the same data is stored.

As described above, various operations or conversions of image data are input to the LUT through a PC or a CPU, and the final value is output to the LUT so as to be output as a single dot clock. As a result, It is possible to solve problems such as delay and time shortage.

Hereinafter, a display device pixel control method using a look-up table according to an embodiment of the present invention will be described with reference to FIG.

First, the video signal input unit 100 receives a video signal, converts the video signal into a digital video signal, and generates a horizontal synchronizing signal H Sync, a vertical synchronizing signal V Sync, and a clock (S100).

Subsequently, the LUT (RAM) receives the digital video signal RGB, the horizontal synchronizing signal H Sync, the vertical synchronizing signal V Sync, and the address generated from the video signal input unit 100 as A0 to A23 (S200).

The video output unit 200 receives the digital video signal RGB from the LUT and receives the horizontal synchronizing signal H Sync, the vertical synchronizing signal V Sync, and the clock And converts it into output data of the display device (S300).

Hereinafter, the detailed process of step S100 of the display device pixel control method using the lookup table according to an embodiment of the present invention will be described with reference to FIG.

First, the video signal input unit 100 receives a video signal and converts it into a digital video signal (S102).

Then, the video signal input unit 100 inputs the digital video signal RGB to the addresses A0 to A7 of the LUT (RAM) (S104).

Subsequently, the video signal input unit 100 inputs the dot clock to the 8-bit counter to generate addresses A8 to A15 of the LUT (RAM) (S106).

Then, the video signal input unit 100 inputs the H Sync signal to the 8-bit counter to generate addresses A16 to A23 of the LUT (RAM) (S108).

As described above, for the sake of convenience of description, the S104 to S108 described above are cases where the image signals of 8 bits each of RGB are input and the resolution is 256X256.

Hereinafter, the process of step S100 or step S300 of the display device pixel control method using the lookup table according to an embodiment of the present invention will be described below with reference to FIG.

The conversion data input unit 300 inputs the mapping data received from the I / O as an address signal of the LUT (RAM) after step S100 or step S300 (S400).

While the present invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It will be appreciated by those skilled in the art that numerous changes and modifications may be made without departing from the invention. And all such modifications and changes as fall within the scope of the present invention are therefore to be regarded as being within the scope of the present invention.

S: Display device pixel control system using lookup table
RAM: LUT (lookup table)
100: Video signal input unit
200: Video output unit
300: conversion data input unit

Claims (6)

A video signal input unit for receiving a video signal and converting the video signal into a digital video signal RGB and generating a horizontal synchronizing signal H Sync, a vertical synchronizing signal V Sync, and a clock;
A LUT (RAM) for receiving the digital video signal RGB, an address generated by a horizontal synchronizing signal H Sync, a vertical synchronizing signal V Sync, and a clock;
A digital video signal RGB from the LUT as data and receiving a horizontal synchronizing signal H Sync, a vertical synchronizing signal V Sync and Clock as data from the video signal input unit, To a video output unit; And
And a conversion data input unit that receives mapping data calculated or converted from an I / O including a PC or a CPU and writes the mapping data into the LUT (RAM) using an address signal to convert the video signal,
The video signal input unit includes:
A horizontal address of the LUT (RAM) is generated by inputting the digital video signal RGB into the data address of the LUT (RAM), inputting a dot clock to the counter through a counter circuit according to the horizontal size of the image, H Sync signal to the counter to generate a vertical position address of the LUT (RAM), uses the horizontal synchronizing signal H Sync as a clear signal of the counter,
The mapping data may include:
Wherein the display data is output data to be finally displayed on a display device after completing computation according to brightness, contrast, gamma characteristic, color temperature, visibility, color recall rate and bit depth difference between input devices by a PC or a CPU. Pixel control system. delete The method according to claim 1,
The horizontal position address is the x coordinate of the LUT (RAM)
Wherein the vertical position address is the y coordinate of the LUT (RAM). The method according to claim 1,
The LUT (RAM)
And the access time is shorter than the one dot clock time. delete (a) receiving a video signal input unit and converting the video signal into a digital video signal, generating a horizontal synchronizing signal (H Sync), a vertical synchronizing signal (V Sync), and a clock;
(b) receiving an address generated by a LUT (RAM) from the video signal input unit by a digital video signal (RGB), a horizontal synchronizing signal (H Sync), a vertical synchronizing signal (V Sync) and a clock;
(c) a video output unit receives the digital video signal RGB as data from the LUT and inputs the horizontal synchronizing signal H Sync, the vertical synchronizing signal V Sync, and Clock as data from the video signal input unit And converting it into output data of a display device; And
(d) inputting, as an address signal of the LUT (RAM), the mapping data input from the I / O conversion data input unit after the step (a) or before the step (c)
The step (a)
(a-1) receiving a video signal input unit and converting the video signal into a digital video signal;
(a-2) inputting a digital video signal RGB to an address input unit A0-A7 of a LUT (RAM);
(a-3) generating addresses A8 to A15 of the LUT (RAM) by inputting the dot clock to the 8-bit counter of the video signal input unit; And
(a-4) generating an address A16 to A23 of the LUT (RAM) by inputting the H Sync signal to the 8-bit counter of the video signal input unit,
After the step (a) or before the step (c)
(E) inputting the mapping data received from the I / O conversion data input unit as an address signal of the LUT (RAM)
And a display control unit for controlling the display unit based on the lookup table.

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