KR101952274B1 - Apparatus for improving luminance of electric sign using photograph image - Google Patents

Abstract

The present invention relates to a brightness increasing device of a display device using photographed images. The brightness increasing device of the display device includes: a photographing unit generating photographing images by photographing the display device; a sensing unit which detects brightness data and individual pixels and brightness data and individual pixels adjacent to different individual pixels adjacent to the individual pixels and extracts a difference value of the brightness data between the individual pixels adjacent to the different individual pixels; and a control unit which updates a lookup table matched to location coordinates (x, y) corresponding to the different individual pixels in order to input the brightness data updated with the different individual pixels. According to the present invention, the brightness increasing device can detect the abnormal occurrences on the individual pixels by photographing the display device, input the brightness data updated with the individual pixels corresponding to the location coordinates (x, y) with the abnormal occurrences by indexing the lookup table, automatically correct the brightness of the individual pixels of the display device, and uniformly maintain the difference in the brightness of the pixels in the surroundings even when the individual pixels are replaced.

Description

TECHNICAL FIELD [0001] The present invention relates to a brightness enhancing device for a display device using a photographed image,

The present invention relates to an apparatus for improving luminance of a display apparatus using an image pickup, more specifically, to a system and method for detecting an abnormality of an individual pixel by photographing a display apparatus and detecting an abnormality by using a look- And a technique for automatically correcting the brightness of individual generated 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 includes a relationship coefficient (y) between the image brightness actually imaged and the image brightness output to 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 CRT 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 such a display device depend on the characteristics of the non-light emitting device or the light emitting device, for example, the color of the display screen and the linearity of the brightness are different depending on the type of the display device.

Depending on the display device, there are different characteristics between the input data and the output brightness, and the individual elements also exhibit different aging or deterioration speeds (so-called afterimage or burn-in).

If the difference is accumulated for a long period of time to make a visual difference, or if the display device is damaged or broken due to external physical influence, the quality of the display device is also deteriorated.

In addition, the brightness of the display element can be expressed differently from the normal due to the problem of the driving element driving the display element. In this case, the problem may be misjudged as a problem of the display element, and the same symptom may persist even after replacement of the display element.

Therefore, when replacing the individual display elements or a part of the display modules, the replaced display elements are replaced with the display elements located on the side of the display device.

In addition, a luminance meter, a colorimeter, and the like are used for measuring the brightness and chromaticity of a display device. Such a meter is not only expensive, but also has a complicated measuring procedure and difficulty in automatic measurement.

Therefore, although the problem can be solved by replacing the display element, replacing the module, replacing the driving element, and seriously replacing the entire display device, there is a problem that the replacement requires a lot of cost and human resources.

Korean Patent No. 10-1842904

SUMMARY OF THE INVENTION An object of the present invention is to provide an image processing apparatus and a method of processing an image by detecting an abnormality with respect to an individual pixel by photographing a display device and searching for a look- And the brightness of individual pixels provided in the display device is automatically corrected by inputting the updated brightness data.

According to an aspect of the present invention, there is provided an apparatus for improving luminance of a display device using an image pickup, the apparatus comprising: a photographing unit for photographing a display device to generate a photographed image; (Hereinafter referred to as " different individual pixels ") and luminance data that are different from predetermined brightness from the photographed image and individual pixels (hereinafter, referred to as " adjacent individual pixels ") and luminance data that are provided at positions adjacent to different individual pixels A sensing unit for extracting difference values of luminance data between different individual pixels and adjacent individual pixels; And a controller for updating the lookup table (LUT) matched with the position coordinates (x, y) corresponding to the different individual pixels to input the updated brightness data into the different individual pixels.

Preferably, the photographing section is provided at a position opposite to the display device, and photographs the chromaticity of each of R, G, and B mixed chromaticity of the individual pixels of the entire area of the display device to digitize the luminance data value.

Sensing unit, the position coordinate is different from the individual pixels from the photographed image (x, y), and adjacent pixels and coordinate individual positions (x _a, y _a) for detecting an abnormal pixel detection module; And a luminance measurement module for inputting image data so that different individual pixels and adjacent individual pixels have maximum brightness and extracting difference values of luminance data measured from different individual pixels and adjacent individual pixels.

The control unit indexes the lookup table (LUT) and updates the values of the brightness data matched with the different individual pixels so that the brightness data difference value is within a predetermined deviation. The brightness data is displayed by decrementing the image data by 1 for the different individual pixels A lookup table updating module for updating the brightness data of the screen so as to obtain the same brightness data as the adjacent pixels or all the pixels based on the difference value extracted from the sensing unit and performing this process until the image data becomes 0; And a defective pixel discrimination module for discriminating that different individual pixels are physically replaceable and generating defective pixel detection information when there is no change in the value of the luminance data even when the lookup table (LUT) is updated.

According to another aspect of the present invention, there is provided a method of improving brightness of a display device using an image pickup method, the method comprising: capturing a display device to generate a captured image; Detecting whether an individual pixel is abnormal from the sensing unit; And a step in which the control unit indexes the lookup table (LUT) and inputs updated brightness data to the individual pixels corresponding to the position coordinates (x, y) at which an abnormality has occurred.

Preferably, the step of detecting the abnormality of the individual pixels comprises the steps of: detecting the different individual pixels and the position coordinates (x, y) and the adjacent individual pixels and the position coordinates (x _a , y _a ) from the sensed image; Detecting the individual pixels having brightness different from the value of the image data from the photographed image by comparing the image brightness of the individual pixels with the actual brightness on the photographed image; Inputting luminance data such that the sensing unit has a maximum brightness and a different individual pixel and adjacent individual pixels; And extracting difference values of luminance data measured from different individual pixels and adjacent individual pixels by the sensing unit.

The step of inputting the brightness data updated to the individual pixels may include a step of displaying the screen in which the control unit subtracts the image data by 1 for the different individual pixels based on the difference value extracted from the sensing unit, Updating the brightness data so as to obtain the brightness data, and performing the process until the image data becomes 0; Determining whether the value of the luminance data changes according to the update of the lookup table (LUT); And generating a defective pixel detection information by judging that the control unit discriminates that different individual pixels are to be physically replaced if the value of the luminance data does not change in accordance with the update of the lookup table (LUT) as a result of the determination.

According to the present invention, when the display device is photographed and it is detected whether or not an error has occurred with respect to each of the individual pixels, the look-up table is indexed and the individual coordinates corresponding to the position coordinates (x, y) By inputting the updated brightness data into the pixels, the brightness of the individual pixels provided in the display device is automatically corrected, and even when the individual pixels are replaced, the brightness difference from the surrounding pixels is uniformly maintained.

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]
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a brightness enhancement apparatus, and more particularly,
4 is a block diagram of a sensing unit of a luminance improvement apparatus of a display apparatus using an image taken according to an exemplary embodiment of the present invention.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a brightness enhancement apparatus, and more particularly,
FIG. 6 is a flowchart illustrating a method of improving brightness of a display device using a photographed image according to an exemplary embodiment of the present invention. Referring to FIG.
FIG. 7 is a flowchart illustrating a detail process of step S200 of a method of improving brightness of a display device using an image taken according to an exemplary embodiment of the present invention. FIG.
FIG. 8 is a flowchart illustrating a detail process of step S300 of a brightness enhancement method of a display device using an image taken 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.

Hereinafter, a detailed description will be omitted. However, the display device of the brightness enhancing apparatus A using the photographed image according to an embodiment of the present invention may include a digitally processed CRT (Cathode Ray Tube), LED (Light Emitting Diodes) , OLED (Organic Light Emitting Diodes), or LCD (Liquid Crystal Display).

The lookup table LTU of the brightness enhancing device A of the display device using the photographed image according to an embodiment of the present invention is characterized by a characteristic that varies depending on the display method of the display device, The final data that has been calculated or transformed including the depth difference, the predefined chromaticity and luminance, and the conversion characteristic is set as the input data.

That is, since the input data included in the lookup table (LTU) has undergone various conversion procedures as described above, it is possible to derive a desired output with each individual pixel and one mapping.

Hereinafter, the brightness data according to an exemplary embodiment of the present invention will be referred to as data to be written into the lookup table (LTU), that is, conversion data.

The luminance data is data measured by photographing with a camera.

The image data is data to be displayed on the screen, data to be set when the image is created on the PC, or data to be inputted to the electric sign board or the display device.

Referring to FIG. 2, an apparatus A for improving luminance of a display using an image according to an exemplary embodiment of the present invention includes a photographing unit 100 for photographing a display device and generating a photographed image, And a controller 300 for indexing the lookup table (LUT) and inputting updated brightness data to individual pixels corresponding to the position coordinates (x, y) at which an error has occurred .

At this time, the luminance value included in the input data is stored in the look-up table (LUT) together with the address value of the memory 1, and the memory 1 is composed of either RAM or ROM.

Referring to FIG. 3, the photographing unit 100 is provided at a position opposite to the display device. The photographing unit 100 photographs the RGB chromaticity and RGB mixed chrominance of individual pixels of the entire area of the display device, .

The photographing unit 100 may photograph the individual pixels corresponding to the specific position coordinates (x, y) by performing a pan, tilt, rotation, or zoom function corresponding to the control signal of the controller 300.

At this time, the photographing unit 100 is configured to photograph the display device at a predetermined time, for example, at a dark time (nighttime) or at a time when no person is present. And can capture a TEST image output by the display device.

In addition, the sensing unit 200 and the controller 300 may be provided in a single hardware, and a program for performing the respective functions may be embedded therein, but the present invention is not limited thereto.

Referring to FIG. 4, the sensing unit 200 compares luminance data of each of the individual pixels from the photographed image received from the photographing unit 100, and compares the luminance data of the individual pixels (hereinafter referred to as 'different individual pixels' (Hereinafter referred to as " adjacent individual pixels ") and luminance data which are provided at positions (upper, lower, left, or right) adjacent to the different individual pixels and brightness data, And detects the difference value of the data, including the abnormal pixel detection module 202 and the luminance measurement module 204.

The ideal pixel detection module 202 detects different individual pixels and positional coordinates (x, y) and adjacent individual pixels and positional coordinates (x _a , y _a ) from the photographed image. Here, the factor _a is adjacent.

At this time, the abnormal pixel detection module 202 decreases the value of the image data of the individual pixels by '1' from the maximum value, and the image data of the individual pixels and the actual brightness (Luminance data) of the RGB image data, detects individual pixels having luminance data values different from those of the image data from the photographed image, and performs an ideal pixel detection in such a manner that RGB individual colors and mixed colors are combined.

The luminance measurement module 204 inputs image data so that different individual pixels and adjacent individual pixels have maximum brightness, and extracts difference values of luminance data measured from different individual pixels and adjacent individual pixels.

At this time, when there is no change in the difference value of the measured luminance data, the luminance measurement module 204 sets the different individual pixels as the replacement target, that is, the individual pixels that can not be corrected by updating the luminance data value.

5, the control unit 300 receives the positional coordinates (x, y), the adjacent individual pixels, the positional coordinates (x _a , y _a ), and the luminance data difference value from the sensing unit 200 And a lookup table (LUT) to update values of brightness data matched with different individual pixels so that the brightness data difference value is within a predetermined deviation, and detects defective pixels, wherein the lookup table updating module (302) And a determination module 304.

The lookup table update module 302 updates the lookup table (LUT) so that the value of the image data matched with the different individual pixels is decreased by '1', until the value of the image data becomes '0' ).

That is, the lookup table update module 302 obtains luminance data such as adjacent pixels or all pixels on the basis of the difference value extracted from the sensing section 100 by decreasing the image data by 1 for different individual pixels And the brightness data is updated until the image data becomes zero.

When the value of the luminance data does not change even when the lookup table (LUT) is updated, the defective pixel determination module 304 determines that the different individual pixels are physically replaced, and generates defective pixel detection information.

In addition, the brightness improving device A of the display device using the photographed image according to an exemplary embodiment of the present invention may include a device connected through an information communication network.

Device in accordance with one embodiment of the present invention, the photographing unit 100 is taken on a photographed image, the sensing unit 200 is detected, a different coordinate the individual pixel and the position (x, y), adjacent to coordinate the individual pixel and the position (x _a , y _a ) and the defective pixel detection information generated by the control unit 300, and can transmit a control signal for controlling the driving of the photographing unit 100.

Also, the driving state of each of the photographing unit 100, the sensing unit 200, and the control unit 300 can be monitored in real time, and the monitoring details can be shared with a manager for maintenance.

Hereinafter, the operation of the brightness enhancement apparatus A of the display apparatus using the photographed image according to an embodiment of the present invention will be described below.

1. Order to identify errors

(1) Input the maximum image data value that can be displayed by the display device as individual pixels.

(2) The photographing unit photographs the entire display device and checks whether the individual pixels are abnormal. At this time, the photographing unit records the difference between the position of the individual pixel showing the abnormal behavior and the neighboring pixel, and performs any one of the functions of panning, tilting, rotating or zooming as necessary.

(3) The sensing unit reduces the value of the image data by '1' to perform inspection on the individual pixels.

(4) The inspection of the individual pixels is repeated until the value of the image data becomes '0' to detect the individual element in which the error occurs.

(5) Individual individual pixels in which an error has occurred are detected by performing inspection on individual pixels of RGB individual colors and mixed colors by respective combinations.

2. Order to correct errors

(1) The control unit inputs image data so that any one of the normal individual pixels in the up, down, left, and right directions has the maximum brightness from the position coordinates (x, y) of the individual pixel in which the error occurs.

(2) Input the image data so as to have the maximum brightness for the individual elements in which the error occurs.

(3) The photographing unit displays the displayed brightness.

(4) By comparing the brightnesses of two individual pixels (individual pixels in which an error has occurred, and any one normal pixel in the upper, lower, right, and left), the position coordinates (x, y) (LTU).

(5) The above steps (1) to (4) are repeated so that the brightness difference of the two individual pixels is within a predetermined deviation.

At this time, if the brightness does not change even if the lookup table (LTU) corresponding to the individual pixel in which an error occurs, the individual pixel in which an error has occurred is recorded as being not a correctable element.

(6) The value of the image data is decreased by '1'.

(7) The above steps (2) to (6) are repeated until the value of the image data becomes '0'.

(8) RGB Individual colors and mixed colors are processed according to each combination (7).

In the case of individual pixels which are not automatically corrected by the above-described error correction, it is judged that they are defective pixels, and the judgment criteria of the defective pixels are as follows.

Example 1) When there is no change in brightness regardless of input pixel data

- In dark: Pixel defect

- When bright: Driver or controller defective

Example 2) When a nonlinear or staircase symptom occurs for input pixel data

- Deterioration of pixel parts, controller failure (comparison with change of peripheral pixels)

In addition, the A / S request according to the error correction result is as follows.

- Report to a terminal connected via network

At this time, the report details are improved, the degree of improvement (the performance deterioration is not improved or improved)

- Calibration completed: Calibration within specified deviation, change check at next inspection

- Corrected but close to the specified allowable deviation: Transmission of correction contents, judgment of A / S

- Not calibrated: send repair request immediately

Hereinafter, referring to FIG. 6, a method for improving brightness of a display device using a photographed image according to an exemplary embodiment of the present invention will be described.

First, the photographing unit 100 photographs a display device to generate a photographed image (S100).

Then, the sensing unit 200 detects whether an individual pixel is abnormal from the photographed image (S200).

Then, the controller 300 indexes the lookup table (LUT) and inputs updated brightness data to the individual pixels corresponding to the position coordinates (x, y) at which the anomaly occurred (S300).

Referring to FIG. 7, the detailed process of step S200 of the brightness enhancement method of the display device using the photographed image according to an exemplary embodiment of the present invention will be described below.

And after the step S100, the sensing unit 200 detects a coordinate position with a different individual pixels from the photographed image (x, y), and adjacent individual pixel coordinates for the location _(a x, _a y) (S202).

Then, the sensing unit 200 compares the image data of the individual pixels with the actual brightness (brightness data) on the captured image to detect individual pixels having brightness different from the image data from the captured image (S204).

Subsequently, the sensing unit 200 inputs image data so that different individual pixels and adjacent individual pixels have maximum brightness (S206).

Then, the sensing unit 200 extracts difference values of luminance data measured from different individual pixels and adjacent individual pixels (S208).

Referring to FIG. 8, the detailed process of step S300 of the brightness enhancement method of the display device using the photographed image according to an exemplary embodiment of the present invention will be described below.

After step S200, the control unit 300 updates the lookup table (LUT) so that the value of the image data matched with the different individual pixels is decreased by '1' (S302).

In operation S302, the control unit 300 may reduce the image data by one for each of the different individual pixels so that the same brightness data as adjacent pixels or all pixels may be obtained based on the difference value extracted from the sensing unit The brightness data is updated and this process is performed until the image data becomes zero.

Next, the control unit 300 determines whether the value of the luminance data is changed according to the update of the lookup table (LUT) (S304).

If it is determined in operation S304 that the value of the luminance data does not change according to the update of the lookup table (LUT), the controller 300 determines that the different individual pixels are physically replaced and generates defective pixel detection information (S306) .

As described above, according to an embodiment of the present invention, when the display device is photographed to detect whether or not an error has occurred with respect to an individual pixel, a look-up table is indexed to obtain position coordinates (x, y By inputting the updated brightness data to the corresponding individual pixels, it is possible to automatically correct the brightness of the individual pixels of the display device, and to keep the brightness difference from the surrounding pixels uniform even when the individual pixels are replaced.

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.

A: Display device pixel control system using lookup table
LUT: lookup table
1: Memory
100:
200:
202: abnormal pixel detection module
204: luminance measurement module
300:
302: Lookup Table Update Module
304: Bad pixel discrimination module

Claims (7)

A photographing unit photographing a display device and generating a photographed image;
(Hereinafter, referred to as 'different individual pixels') and luminance data, which are different from a preset luminance, and individual pixels (hereinafter referred to as 'adjacent individual pixels') and luminance data provided at positions adjacent to different individual pixels are detected A sensing unit for extracting a difference value of luminance data between different individual pixels and adjacent individual pixels; And
And a controller for updating the lookup table (LUT) matched with the positional coordinates (x, y) corresponding to the different individual pixels to input brightness data updated to the different individual pixels,
The sensing unit includes:
An ideal pixel detection module for detecting different individual pixels and positional coordinates (x, y) and adjacent individual pixels and positional coordinates (xa, ya) from the photographed image; And
And a luminance measurement module for inputting image data such that different individual pixels and adjacent individual pixels have maximum brightness and extracting difference values of luminance data measured from different individual pixels and adjacent individual pixels,
Wherein,
Updating the values of brightness data matched with different individual pixels so that the brightness data difference value is within a predetermined deviation by indexing the lookup table (LUT)
Up table (LUT) to update the lookup table (LUT) until the value of the image data becomes' 0 'by updating the lookup table (LUT) so that the value of the image data matched with the different individual pixels is decreased by'; And
And a defective pixel determination module that determines that the different individual pixels are physically replaced and generates defective pixel detection information when the value of the luminance data does not change even when the lookup table (LUT) is updated,
Wherein the abnormal pixel detection module comprises:
The value of the image data of the individual pixels is decreased by '1' from the maximum value, and the image data of the individual pixels is compared with the actual brightness (luminance data) on the captured image until the value of the image data becomes '0' And detecting an individual pixel having a luminance data value different from a value of the image data, and performing an ideal pixel detection in a form of combining RGB individual colors and mixed colors, respectively, . The method according to claim 1,
Wherein,
And the luminance data value is digitized by capturing the RGB chrominance and the RGB chrominance of each of the individual pixels of the entire display area of the display device, Device. delete delete delete delete delete

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