CN110660352A - Point-to-point correction method, device and system for LED display screen and storage medium - Google Patents

Abstract

The invention relates to a point-by-point correction method, a device and a system for an LED display screen and a storage medium, wherein the point-by-point correction method for the LED display screen comprises the steps of acquiring a three-color tristimulus value matrix of the LED display screen as a correction data conversion target value; replacing the new LED display module, and reading back a three-color tristimulus value matrix of point-by-point chromaticity correction of the module; calculating a correction data change matrix T according to the three-color tristimulus value matrix of the LED display screen body and the three-color tristimulus value matrix of the replaced LED display module; calculating to obtain a changed correction data matrix of each pixel point according to the T and the correction data matrix of each pixel point on the updated LED display module; and performing point-by-point chromaticity correction on each pixel on the replaced LED module by using the obtained changed correction coefficient matrix, so that the brightness, chromaticity and uniformity of the LED display screen are greatly improved, and the system is faster and safer in operation speed.

Description

Point-to-point correction method, device and system for LED display screen and storage medium

Technical Field

The invention relates to the technical field of LED display correction, in particular to a point-by-point correction method, device and system for an LED display screen and a storage medium.

Background

In modern commercial environments, the LED display industry is rapidly evolving. The LED display screen is a flat panel display device composed of LED lattices, and compared with other traditional information media, the LED display screen has the advantages of adjustable brightness range, safety, reliability, electricity saving, environmental protection, accurate color embodiment, clear visual expression and the like. Along with the gradual improvement of the brightness of the LED display screen and the stronger optical density and adaptability, the display quality is rapidly improved.

In the existing point-by-point correction technology, the luminance and chromaticity data of each LED lamp point on the LED display screen are collected, the correction coefficient of each LED lamp point is obtained through calculation and then is sent to the control system, the control system applies the correction coefficient to realize point-to-point driving of each LED lamp point, and the pixel luminance, saturation and chromaticity uniformity of the LED display screen are improved. For a long time, the brightness, chromaticity and uniformity of the LED display screen are influenced by factors such as lamp beads, welding, structural design, heat dissipation and brightness of the LED display screen, and the development of the industry is seriously disturbed. When the point-by-point correction is performed, a correction target value needs to be selected, and the deviation of the value can cause chromatic aberration, so that the visual effect is obviously poor. At this time, the correction target value needs to be changed, and the correction coefficient needs to be recalculated, resulting in an increase in the number of calculations. Meanwhile, the number of LED pixels of the LED display screen is increased rapidly, which causes the calculation amount of the original brightness and chromaticity of the LED lamp to increase rapidly, and seriously affects the system operation speed and safety, and a more scientific point-by-point correction method, device, system and machine-readable storage medium for the LED display screen are needed.

Disclosure of Invention

In view of the above, in order to overcome the defects in the prior art, the invention provides a method, an apparatus, a system and a storage medium for correcting an LED display screen point by point.

An embodiment of the present invention provides a point-by-point correction method for an LED display screen, including:

acquiring a three-color tri-stimulus value matrix of the LED display screen as a correction data conversion target value;

replacing the new LED display module, and reading back a three-color tristimulus value matrix of point-by-point chromaticity correction of the module;

calculating a correction data change matrix according to the three-color tristimulus value matrix of the LED display screen body and the three-color tristimulus value matrix of the replaced LED display module;

calculating to obtain a correction data matrix after the change of each pixel point according to the correction data change matrix and the correction data matrix of each pixel point on the updated LED display module;

and performing point-by-point chromaticity correction on each pixel on the replaced LED module by using the obtained changed correction coefficient matrix.

Preferably, the method for acquiring a tristimulus value matrix of three colors of the LED display screen as the correction data conversion target value includes:

respectively measuring the brightness values and color coordinate values of the red, green, blue and white of the whole screen by using a cursor gun;

and performing fitting calculation by using the brightness values of red, green, blue and white and the color coordinate values.

Preferably, the fitting calculation is performed by using the brightness values and color coordinate values of red, green, blue and white colors to reduce the error of measuring the tristimulus values of red, green and blue colors, and the method comprises the following steps:

step 1: the brightness and color coordinate values obtained by measurement are respectively set as follows:

red is (Y)_r，x_r，y_r)；

Green is (Y)_g，x_g，y_g)；

Blue is (Y)_b，x_b，y_b)；

White is (Y)_w，x_w，y_w)；

Said Y is_rIs a red luminance value, said Y_gFor green brightness value of said Y_bIs a blue luminance value, said Y_wIs a white luminance value, said (x)_r，y_r) Is a red coordinate value, said (x)_g，y_g) Is a green coordinate value, (x)_b，y_b) Is a blue coordinate value, (x)_w，y_w) Is a white coordinate value; the values of x, Y are relatively accurate and the values of Y are relatively inaccurate. In the white color, the proportions of red, green and blue are r, g and b respectively, then step 2 is carried out

Step 2: the proportion of 3 colors of red, green and blue in white, namely the numerical values of r, g and b, is calculated by using relatively accurate color coordinate values, and the formula is as follows:

then, the brightness ratio r of red, green and blue 3 is calculated_y，g_y，b_yThe formula is:

and step 3: the luminance value Y 'of white color was fitted by the least square method'_wThe value, luminance value variance formula is:

(Y_r-r Y’_w)²+(Y_g-g Y’_w)²+(Y_b-bY’_w)²+(Y_w-Y’_w)²；

deriving the above formula and making the derivative be 0 to obtain Y 'with the minimum variance'_wThe formula is as follows:

and 4, step 4: with the fitted white luminance value Y'_wCalculating fitted three-color luminance values Y 'of red, green and blue'_r，Y’_g，Y’_bThe Y ' r, Y ' g and Y ' b are the red, green and blue three-color brightness values calculated by fitting, are more accurate than the direct measurement of the light gun, and are distinguished by adding a superscript, and the formula is as follows:

Y’_r＝rY’_w；

Y’_g＝gY’_w；

Y’_b＝bY’_w；

and 5: calculating the tristimulus values of the red, the green and the blue according to the fitted three-color brightness values of the red, the green and the blue and the measured coordinates of the red, the green and the blue, wherein the formula is as follows:

Y_c＝Y′_c

c, respectively taking r, g and b colors;

according to the three-color tristimulus values calculated by the formula, a whole-screen three-color tristimulus value matrix can be formed:

the M is_sAnd obtaining a three-color tristimulus value matrix of the LED display screen.

Preferably, the calculation formula for calculating the correction data change matrix according to the three-color tristimulus value matrix of the LED display screen body and the three-color tristimulus value matrix of the replaced LED display module is as follows:

according to the three-color tristimulus values calculated by the formula, a whole-screen three-color tristimulus value matrix can be formed:

in the above formula, the three-color tristimulus value matrix of the replaced LED display module is M_m；

Is M_mThe inverse matrix of (d); t is the correction data change matrix; the M is_sAnd obtaining a three-color tristimulus value matrix of the LED display screen.

Preferably, the method for obtaining the changed correction data matrix of each pixel point by calculation according to the correction data change matrix and the correction data matrix of each pixel point on the updated LED display module includes;

storing correction data of each pixel point in the module in a memory on the LED display module, wherein the correction data of each pixel point comprises 9 coefficients and can form 1 3x3 matrix, namely, each pixel point on the module corresponds to 1 matrix C_p：

In the above formula, the subscript P represents a pixel;

with C_grFor example, C_grGreen before correction is applied to red after correction, and the other coefficients are sequentially estimated;

the method for obtaining the corrected matrix through calculation according to the correction data change matrix T and the correction data matrix of each pixel point on the updated LED display module comprises the following steps of;

the correction data change matrix is T, and the T is applied to the correction data C of each pixel of the updating module_pAnd, such that:

C′_p＝C_pT

obtaining the correction data matrix C 'after the change of the pixel points'_p。

Then, after the correction data is changed, the calculation formula of the three-color tristimulus value matrix of the new module is replaced by:

preferably, the method for performing point-by-point chromaticity correction on each pixel on the replaced LED module by using the obtained post-change correction coefficient matrix is characterized by comprising:

for any input image color value (R, G, B), the calculation formula of XYZ tristimulus values output on the entire LED display screen is:

and the calculation formula of the XYZ tristimulus values output on the replaced LED module is as follows:

in the above formula M_pAnd C_pAnd correcting the front three-color tristimulus value matrix and the chromaticity correction data matrix point by point for any pixel point on the LED module. R, G, B represent image pixel color values.

Preferably, before the step of replacing the new LED display module and reading back the tristimulus value matrix of the three-color with point-by-point chromaticity correction, the method further includes:

and storing a target red, green and blue tristimulus value matrix set during point-by-point chromaticity correction in the LED display module during module production for providing the read-back module with the three tristimulus value matrix for point-by-point chromaticity correction.

The invention also provides a point-by-point correction device for the LED display screen, which comprises:

the acquisition module is used for acquiring the brightness value and the color coordinate value of the LED display screen, acquiring a three-color tristimulus value matrix of the LED display screen and taking the three-color tristimulus value matrix as a correction data conversion target value;

the processor is used for reading back a three-color tristimulus value matrix of the module point-by-point chromaticity correction; forming a point-by-point correction instruction of the LED display screen;

the matrix calculation module is used for calculating a correction data change matrix according to a three-color tristimulus value matrix of the LED display screen body and a three-color tristimulus value matrix of the replaced LED display module; the correction data matrix updating module is also used for calculating and obtaining the changed correction data matrix of each pixel point according to the correction data change matrix and the correction data matrix of each pixel point on the updated LED display module;

the correction processing module is used for performing point-by-point chromaticity correction on each pixel on the replaced LED module by using the obtained changed correction coefficient matrix;

preferably, the present invention provides a device for correcting an LED display screen point by point, further comprising:

the receiving and sending module is used for carrying out point-by-point chromaticity correction on the three-color tristimulus value matrix, the correction data change matrix and the correction data matrix of each pixel point on the updated LED display module, and carrying out data interaction among the storage module, the calculation module and/or the processor; uploading the data of point-by-point chromaticity correction of each pixel on the replaced LED module by the obtained changed correction coefficient matrix to the LED display screen so as to finish correction of the area to be corrected of the LED display screen;

the storage module is used for storing a target red, green and blue tristimulus value matrix set during point-by-point chromaticity correction in the production of the module in the LED display module; the tri-color tri-stimulus value matrix is used for providing point-by-point chromaticity correction for the read-back module.

The invention also provides a point-by-point correction system of the LED display screen, which comprises the following steps:

the acquisition module is used for acquiring the brightness value and the color coordinate value of the LED display screen, acquiring a three-color tristimulus value matrix of the LED display screen and taking the three-color tristimulus value matrix as a correction data conversion target value;

the processor is used for reading back a three-color tristimulus value matrix of the module point-by-point chromaticity correction; forming a point-by-point correction instruction of the LED display screen;

the matrix calculation module is used for calculating a correction data change matrix according to a three-color tristimulus value matrix of the LED display screen body and a three-color tristimulus value matrix of the replaced LED display module; the correction data matrix updating module is also used for calculating and obtaining the changed correction data matrix of each pixel point according to the correction data change matrix and the correction data matrix of each pixel point on the updated LED display module;

the correction processing module is used for performing point-by-point chromaticity correction on each pixel on the replaced LED module by using the obtained changed correction coefficient matrix;

the receiving and sending module is used for carrying out point-by-point chromaticity correction on the three-color tristimulus value matrix, the correction data change matrix and the correction data matrix of each pixel point on the updated LED display module, and carrying out data interaction among the storage module, the calculation module and/or the processor; uploading the data of point-by-point chromaticity correction of each pixel on the replaced LED module by the obtained changed correction coefficient matrix to the LED display screen so as to finish correction of the area to be corrected of the LED display screen;

the storage module is used for storing a target red, green and blue tristimulus value matrix set during point-by-point chromaticity correction in the production of the module in the LED display module; the tri-color tri-stimulus value matrix is used for providing point-by-point chromaticity correction for the read-back module.

The present invention also provides a storage medium storing machine-executable instructions that, when invoked and executed by a processor, cause the regional processor to: and realizing the point-by-point correction method of any one of the LED display screens.

The invention provides a point-by-point correction method for an LED display screen. When the module is replaced, the correction data change matrix T is calculated according to the brightness values and the color coordinate values of the red, green and blue pixel points and the white pixel points of the read-back module. And then, when the module color coordinate value correction data is read back, multiplying the correction matrix of each point by T to obtain an actual correction matrix and applying the actual correction matrix. The invention does not directly apply the correction data stored in the module, but applies the matrix method to transform the module correction data and apply the module correction data according to the difference of the color coordinate value parameters of the screen body and the module. When the module color coordinate parameters are different from the screen body color coordinate parameters, the module correction data can be used through calculation without re-correction. Therefore, the brightness, the chromaticity and the uniformity of the LED display screen are greatly improved, the chromatic aberration caused by directly selecting the stored correction target value during point-by-point correction is avoided, and the visual effect is obviously improved. Meanwhile, the increase of calculation times caused by repeatedly changing the correction target value is avoided, so that the system has higher running speed and is safer. Meanwhile, the method can be applied to large-scale LED display screens, and the rapid superposition and increase of the calculation amount of the original brightness and the chromaticity of the LED lamp points cannot be caused due to the rapid increase of the number of the LED pixel points. The invention can provide high-speed system operation and convenient and safe maintenance service for the large-scale LED display screen, and is a more scientific point-by-point correction method and device for the LED display screen and a machine readable storage medium.

Drawings

FIG. 1 is a flowchart illustrating a point-by-point calibration method for an LED display screen according to an embodiment of the present invention;

fig. 2 is a structural diagram of a point-by-point calibration apparatus for an LED display screen according to an embodiment of the present invention.

Detailed Description

So that the manner in which the above recited objects, features and advantages of the present invention can be understood in detail, a more particular description of the invention, briefly summarized above, may be had by reference to the embodiments thereof which are illustrated in the appended drawings. In addition, the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

As shown in fig. 1, a method for correcting an LED display screen point by point includes:

s100: three-color tristimulus value matrix M of LED display screen is obtained_sAs a correction data conversion target value;

three-color tristimulus value matrix M of LED display screen is obtained_sThe method of converting the target value as the correction data includes;

respectively measuring the brightness values and color coordinate values of the red, green, blue and white of the whole screen by using a cursor gun;

and performing fitting calculation by using the brightness values of red, green, blue and white and the color coordinate values.

Fitting and calculating three-color tristimulus values of red, green and blue by using four-color brightness values and color coordinate values of red, green, blue and white to reduce measurement errors of the tristimulus values for directly measuring the red, green and blue, wherein the method comprises the following steps:

step 1: measuring the brightness values and color coordinate values of red, green and blue to obtain:

red is (Y)_r，x_r，y_r)；

Green is (Y)_g，x_g，y_g)；

Blue is (Y)_b，x_b，y_b)；

White is (Y)_w，x_w，y_w)；

Said Y is_rIs a red luminance value, said Y_gFor green brightness value of said Y_bIs a blue luminance value, said Y_wIs a white luminance value, said (x)_r，y_r) Is a red coordinate value, said (x)_g，y_g) Is a green coordinate value, (x)_b，y_b) Is a blue coordinate value, (x)_w，y_w) Is a white coordinate value; the values of x, Y are relatively accurate and the values of Y are relatively inaccurate. Because the accuracy of the color coordinate values measured by the light gun is higher than the absolute values of the brightness, the tristimulus values and the like measured by the light gun. Therefore, measuring the color coordinates and brightness of red, green, blue and white

Step 2: and calculating the proportion of red, green and blue 3 colors in white by using the color coordinate values, namely the numerical values of r, g and b, wherein the formula is as follows:

then, the brightness ratio r of red, green and blue 3 is calculated_y，g_y，b_yThe formula is:

and step 3: the luminance value Y 'of white color was fitted by the least square method'_wA value;

for example, in the least squares method, the luminance value variance formula is:

(Y_r-r_yY’_w)²+(Y_g-g_yY’_w)²+(Y_b-b_yY’_w)²+(Y_w-Y’_w)²；

deriving the above formula and making the derivative be 0 to obtain Y 'with the minimum variance'_w，

And 4, step 4: with the fitted white luminance value Y'_wCalculating fitted three-color luminance values Y 'of red, green and blue'_r,Y’_g,Y’_bThe Y ' r, Y ' g and Y ' b are three-color brightness values of red, green and blue which are calculated by fitting, and are more accurate than the brightness values directly measured by an optical gun, so that the three-color brightness values are marked to be distinguished, and the formula is as follows:

Y’_r＝rY’_w；

Y’_g＝gY’_w；

Y’_b＝bY’_w；

and 5: calculating the tristimulus values of the red, the green and the blue according to the fitted three-color brightness values of the red, the green and the blue and the measured coordinates of the red, the green and the blue, wherein the formula is as follows:

Y_c＝Y′_c

c, respectively taking three colors of r, g and b, wherein the three colors of r, g and b correspondingly represent three colors of red, green and blue;

according to the three-color tristimulus values calculated by the formula, a whole-screen three-color tristimulus value matrix can be formed:

s102: replacing the new LED display module and reading back the three-color tristimulus value matrix M of point-by-point chromaticity correction of the module_m；

The new LED display module is replaced, and a three-color tristimulus value matrix M of point-by-point chromaticity correction of the module is read back_mBefore, still include:

storing a target red, green and blue tristimulus value matrix set during point-by-point chromaticity correction in the LED display module for providing the tristimulus value matrix M for point-by-point chromaticity correction of the read-back module_m。

And the new LED display module is replaced, and a three-color tristimulus value matrix of point-by-point chromaticity correction of the module is read back, specifically, a target red, green and blue tristimulus value matrix set when the point-by-point chromaticity correction is carried out during the production of the module is stored in a memory on the LED display module. The new LED display module is replaced, and the red, green and blue tristimulus value matrix M is read back from the memory in the replaced LED display module_m。

Storing the corrected three-color tristimulus values on the LED display module; red, green, blue, white brightness values and color coordinate values; the stored values include being stored in the form of luminance values and color coordinate values; the correction data change matrix T is stored in the form of a tristimulus value matrix.

S104: according to LED display screen bodyThree-color tristimulus value matrix M_sAnd three-color tristimulus value matrix M of replaced LED display module_mCalculating a correction data change matrix T; three-color tristimulus value matrix M according to LED display screen_sAnd three-color tristimulus value matrix M of replaced LED display module_mThe method for calculating the correction data change matrix T comprises the following calculation formula:

Y_c＝Y′_c

c, respectively taking r, g and b colors; the r, g and b three colors correspondingly represent red, green and blue colors;

according to the three-color tristimulus values calculated by the formula, a whole-screen three-color tristimulus value matrix can be formed:

in the above formula

Is M_mThe inverse matrix of (c). In the above formula, T is the correction data change matrix. The M is_sAnd obtaining a three-color tristimulus value matrix of the LED display screen.

S106: calculating to obtain a correction data matrix after the change of each pixel point according to the correction data change matrix T and the correction data matrix of each pixel point on the updated LED display module;

the correction data of each pixel point in the LED display module is stored in a memory on the module, and the correction data packet of each pixel pointContaining 9 coefficients, 1 matrix of 3 × 3 can be formed, that is, for each pixel on the module, 1 matrix C is corresponding_p：

In the above formula, the subscript P represents Pixel, and Chinese is a Pixel;

the chroma correction algorithm formula is as follows:

where (R, G, B) is the pixel RGB color value before the chroma correction and (R ', G ', B ') is the pixel RGB color value after the chroma correction. Thus with C_grFor example, C_grThe correction coefficient is a correction coefficient in which green color before correction acts on red color after correction, and other such values are sequentially estimated.

The method for obtaining the corrected matrix through calculation according to the correction data change matrix T and the correction data matrix of each pixel point on the updated LED display module comprises the following steps of;

applying T to correction data C for each pixel of the update module_pAnd, such that:

C′_p＝C_pT

obtaining the correction data matrix C 'after the change of the pixel points'_p。

Then, after the correction data is changed, the calculation formula of the three-color tristimulus value matrix of the new module is replaced by:

in the above formula M_pAnd C_pAnd correcting the front three-color tristimulus value matrix and the chromaticity correction data matrix point by point for any pixel point on the LED module.

Represents M_mThe inverse matrix of (c).

S108: and performing point-by-point chromaticity correction on each pixel on the replaced LED module by using the obtained changed correction coefficient matrix.

For any input image color value (R, G, B), the calculation formula of the X, Y, Z tristimulus values output on the whole LED display screen is as follows:

and the calculation formula of the XYZ tristimulus values output on the replaced LED module is as follows:

in the above formula M_pAnd C_pAnd correcting the front three-color tristimulus value matrix and the chromaticity correction data matrix point by point for any pixel point on the LED module. R, G, B represent image pixel color values.

Namely, for any same input image pixel color values (R, G, B), the X, Y and Z tristimulus values output on the whole LED display screen and the replaced LED module are the same.

Referring to fig. 2, an embodiment of the invention provides a point-by-point calibration apparatus 22 for an LED display screen, including:

the collecting module 12 is used for collecting the brightness value and the color coordinate value of the LED display screen to obtain a three-color tristimulus value matrix M of the LED display screen_sAs a correction data conversion target value;

a processor 14 for reading back a tristimulus value matrix M of the module point-by-point chromaticity correction_m(ii) a Forming a point-by-point correction instruction of the LED display screen;

a matrix calculation module 18 for calculating a tristimulus value matrix M of three colors of the LED display screen_sAnd three-color tristimulus value matrix M of replaced LED display module_mCalculating a correction data change matrix T; and calculating to obtain the changed correction data moment of each pixel point according to the correction data change matrix T and the correction data matrix of each pixel point on the updated LED display moduleArraying;

the correction processing module 16 is used for performing point-by-point chromaticity correction on each pixel on the replaced LED module by using the obtained changed correction coefficient matrix;

a transceiver module 10 for correcting the chromaticity of the module by point_mThe correction data change matrix T is used for exchanging the correction data matrix of each pixel point on the LED display module, and data interaction is carried out among the storage module, the calculation module and/or the processor; and uploading the data of point-by-point chromaticity correction of each pixel on the replaced LED module by the obtained changed correction coefficient matrix to the LED display screen so as to finish the correction of the area to be corrected of the LED display screen.

The storage module 20 is used for storing a target red, green and blue tristimulus value matrix set during point-by-point chromaticity correction in the LED display module during module production; three-color tristimulus value matrix M for providing point-by-point chromaticity correction of the read-back module_m。

Specifically, the acquisition module 12 acquires a tristimulus value matrix M of the three colors of the LED display screen_sAnd is sent to the processor 14 via the transceiver module 10; the new LED display module is replaced, and the processor 14 reads back the three-color tristimulus value matrix M of point-by-point chromaticity correction of the module_m(ii) a The matrix calculation module 18 calculates a tristimulus value matrix M of the LED display screen according to the three colors_sAnd three-color tristimulus value matrix M of replaced LED display module_mCalculating a correction data change matrix T; calculating to obtain a correction data matrix after the change of each pixel point according to the correction data change matrix T and the correction data matrix of each pixel point on the updated LED display module; to the processor 14 via the transceiver module 10; the processor 14 sends the correction processing module 16 to perform point-by-point chromaticity correction on each pixel on the replaced LED module by using the obtained changed correction coefficient matrix.

The embodiment of the invention also provides a point-by-point correction system for the LED display screen, which comprises the following steps:

the acquisition module is used for acquiring the brightness value and the color coordinate value of the LED display screen to acquire the LED displayThree-color tri-stimulus value matrix M of display screen_sAs a correction data conversion target value;

a processor for reading back a tri-color tri-stimulus value matrix M of point-by-point chromaticity correction of the module_m(ii) a Forming a point-by-point correction instruction of the LED display screen;

a matrix calculation module for calculating three-color tristimulus value matrix M of the LED display screen body_sAnd three-color tristimulus value matrix M of replaced LED display module_mCalculating a correction data change matrix T; the correction data change matrix T is used for changing the correction data matrix of each pixel point on the LED display module to obtain the changed correction data matrix of each pixel point;

the correction processing module is used for performing point-by-point chromaticity correction on each pixel on the replaced LED module by using the obtained changed correction coefficient matrix;

a transceiver module for correcting chromaticity of the module by point_mThe correction data change matrix T is used for exchanging the correction data matrix of each pixel point on the LED display module, and data interaction is carried out among the storage module, the calculation module and/or the processor; and uploading the data of point-by-point chromaticity correction of each pixel on the replaced LED module by the obtained changed correction coefficient matrix to the LED display screen so as to finish the correction of the area to be corrected of the LED display screen.

The storage module is used for storing a target red, green and blue tristimulus value matrix set during point-by-point chromaticity correction in the production of the module in the LED display module; three-color tristimulus value matrix M for providing point-by-point chromaticity correction of the read-back module_m。

An embodiment of the present invention further provides a machine-readable storage medium storing machine-executable instructions, which when invoked and executed by a processor, cause the processor to implement a method for correcting a LED display screen point by point as described in any of the above embodiments.

The system/computer device integrated components/modules/units, if implemented in the form of software functional units and sold or used as a stand-alone product, may be stored in a computer readable storage medium. Based on such understanding, all or part of the flow in the method according to the above embodiments may be implemented by a computer program, which may be stored in a computer-readable storage medium, and when the computer program is executed by a processor, the steps of the method embodiments may be implemented. Wherein the computer program comprises computer program code, which may be in the form of source code, object code, an executable file or some intermediate form, etc. The computer-readable storage medium may include: any entity or device capable of carrying the computer program code, recording medium, usb disk, removable hard disk, magnetic disk, optical disk, computer Memory, Read-only Memory (ROM), Random Access Memory (RAM), electrical carrier wave signals, telecommunications signals, software distribution medium, etc. It should be noted that the computer readable medium may contain content that is subject to appropriate increase or decrease as required by legislation and patent practice in jurisdictions, for example, in some jurisdictions, computer readable media does not include electrical carrier signals and telecommunications signals as is required by legislation and patent practice.

In the several embodiments provided in the present invention, it should be understood that the disclosed system and method may be implemented in other ways. For example, the system embodiments described above are merely illustrative, and for example, the division of the components is only one logical division, and other divisions may be realized in practice.

In addition, each functional module/component in each embodiment of the present invention may be integrated into the same processing module/component, or each module/component may exist alone physically, or two or more modules/components may be integrated into the same module/component. The integrated modules/components can be implemented in the form of hardware, or can be implemented in the form of hardware plus software functional modules/components.

It will be evident to those skilled in the art that the embodiments of the present invention are not limited to the details of the foregoing illustrative embodiments, and that the embodiments of the present invention are capable of being embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the embodiments being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned. Furthermore, it is obvious that the word "comprising" does not exclude other elements or steps, and the singular does not exclude the plural. Several units, modules or means recited in the system, apparatus or terminal claims may also be implemented by one and the same unit, module or means in software or hardware. The terms first, second, etc. are used to denote names, but not any particular order.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (11)

1. A point-by-point correction method for an LED display screen is characterized by comprising the following steps:

acquiring a three-color tri-stimulus value matrix of the LED display screen as a correction data conversion target value;

replacing the new LED display module, and reading back a three-color tristimulus value matrix of point-by-point chromaticity correction of the module;

calculating a correction data change matrix according to the three-color tristimulus value matrix of the LED display screen body and the three-color tristimulus value matrix of the replaced LED display module;

calculating to obtain a correction data matrix after the change of each pixel point according to the correction data change matrix and the correction data matrix of each pixel point on the updated LED display module;

and performing point-by-point chromaticity correction on each pixel on the replaced LED module by using the obtained changed correction coefficient matrix.

2. The method for correcting the LED display screen point by point according to claim 1, wherein the method for acquiring the tri-color tri-stimulus value matrix of the LED display screen as the correction data conversion target value comprises the following steps:

respectively measuring the brightness values and color coordinate values of the red, green, blue and white of the whole screen by using a cursor gun;

and performing fitting calculation by using the brightness values of red, green, blue and white and the color coordinate values.

3. The method for correcting the LED display screen point by point according to claim 2, wherein the fitting calculation is performed by using the brightness values and color coordinate values of red, green, blue and white colors to reduce the error of the tri-stimulus measurement of red, green and blue colors, and the method comprises:

step 1: the brightness and color coordinate values obtained by measurement are respectively set as follows:

red is (Y)_r，x_r，y_r)；

Green is (Y)_g，x_g，y_g)；

Blue is (Y)_b，x_b，y_b)；

White is (Y)_w，x_w，y_w)；

Said Y is_rIs a red luminance value, said Y_gFor green brightness value of said Y_bIs a blue luminance value, said Y_wIs a white luminance value, said (x)_r，y_r) Is a red coordinate value, said (x)_g，y_g) Is a green coordinate value, (x)_b，y_b) Is a blue coordinate value, (x)_w，y_w) Is a white coordinate value; of said x, yThe values are relatively accurate and the Y values are relatively inaccurate. In the white color, the proportions of red, green and blue are r, g and b respectively, and then the step 2 is carried out;

step 2: the proportion of 3 colors of red, green and blue in white, namely the numerical values of r, g and b, is calculated by using relatively accurate color coordinate values, and the formula is as follows:

then, the brightness ratio r of red, green and blue 3 is calculated_y，g_y，b_yThe formula is:

and step 3: the luminance value Y 'of white color was fitted by the least square method'_wThe value, luminance value variance formula is:

(Y_r-rY’_w)²+(Y_g-gY’_w)²+(Y_b-bY’_w)²+(Y_w-Y’_w)²；

deriving the above formula and making the derivative be 0 to obtain Y 'with the minimum variance'_wThe formula is as follows:

and 4, step 4: with the fitted white luminance value Y'_wCalculating fitted three-color luminance values Y 'of red, green and blue'_r，Y’_g，Y’_bY 'r, Y'g, Y' b is the red, green and blue three-color brightness value calculated by fitting, and is more accurate than the direct measurement of the light gun, so that the upper mark is added to indicate the distinction, and the formula is as follows:

Y’_r＝rY’_w；

Y’_g＝gY’_w；

Y’_b＝bY’_w；

and 5: calculating the tristimulus values of the red, the green and the blue according to the fitted three-color brightness values of the red, the green and the blue and the measured coordinates of the red, the green and the blue, wherein the formula is as follows:

Y_c＝Y′_c

c, respectively taking r, g and b colors;

according to the three-color tristimulus values calculated by the formula, a whole-screen three-color tristimulus value matrix can be formed:

the M is_sAnd obtaining a three-color tristimulus value matrix of the LED display screen.

4. The method for correcting the LED display screen dot by dot according to claim 3, wherein the calculation formula for calculating the correction data change matrix according to the tristimulus values matrix of the LED display screen body and the tristimulus values matrix of the replaced LED display module is as follows:

in the above formula, the replaced LEDThe three-color tristimulus value matrix of the display module is M_m；

Is M_mThe inverse matrix of (d); t is the correction data change matrix; the M is_sAnd obtaining a three-color tristimulus value matrix of the LED display screen.

5. The method for correcting the LED display screen point by point according to claim 1, wherein the method for calculating the corrected data matrix after the change of each pixel point according to the corrected data change matrix and the corrected data matrix of each pixel point on the updated LED display module comprises;

storing correction data of each pixel point in the module in a memory on the LED display module, wherein the correction data of each pixel point comprises 9 coefficients and can form 1 3x3 matrix, namely, each pixel point on the module corresponds to 1 matrix C_p：

In the above formula, the subscript P represents a pixel;

the method for obtaining the corrected matrix through calculation according to the correction data change matrix and the correction data matrix of each pixel point on the updated LED display module comprises the following steps of;

the correction data change matrix is T, and the T is applied to the correction data C of each pixel of the updating module_pAnd, such that:

C′_p＝C_pT

obtaining the correction data matrix C 'after the change of the pixel points'_p。

Then, after the correction data is changed, the calculation formula of the three-color tristimulus value matrix of the new module is replaced by:

in the above formula M_pAnd C_pAnd correcting the front three-color tristimulus value matrix and the chromaticity correction data matrix point by point for any pixel point on the LED module.

6. The method for correcting chromaticity of each pixel of the LED display screen in a point-by-point manner according to claim 1, wherein the obtaining of the changed correction coefficient matrix is used to perform a point-by-point chromaticity correction on each pixel of the replaced LED module, and the method comprises:

for any input image color value (R, G, B), the calculation formula of XYZ tristimulus values output on the entire LED display screen is:

and the calculation formula of the XYZ tristimulus values output on the replaced LED module is as follows:

in the above formula M_pAnd C_pAnd correcting the front three-color tristimulus value matrix and the chromaticity correction data matrix point by point for any pixel point on the LED module.

7. The method of claim 1, wherein the new LED display module is replaced and a tristimulus value matrix M of the three colors, which is a chromaticity correction of the module point by point, is read back_mBefore, still include:

and storing a target red, green and blue tristimulus value matrix set during point-by-point chromaticity correction in the LED display module during module production for providing the tristimulus value matrix for the point-by-point chromaticity correction of the read-back module.

8. A LED display screen point-by-point correction device is characterized by comprising:

the acquisition module is used for acquiring the brightness value and the color coordinate value of the LED display screen, acquiring a three-color tristimulus value matrix of the LED display screen and taking the three-color tristimulus value matrix as a correction data conversion target value;

the processor is used for reading back a three-color tristimulus value matrix of the module point-by-point chromaticity correction; forming a point-by-point correction instruction of the LED display screen;

the matrix calculation module is used for calculating a correction data change matrix according to a three-color tristimulus value matrix of the LED display screen body and a three-color tristimulus value matrix of the replaced LED display module; the correction data matrix updating module is also used for calculating and obtaining the changed correction data matrix of each pixel point according to the correction data change matrix and the correction data matrix of each pixel point on the updated LED display module;

and the correction processing module is used for performing point-by-point chromaticity correction on each pixel on the replaced LED module by using the obtained changed correction coefficient matrix.

9. The correction device of claim 8, further comprising:

the receiving and sending module is used for carrying out point-by-point chromaticity correction on the three-color tristimulus value matrix, the correction data change matrix and the correction data matrix of each pixel point on the updated LED display module, and carrying out data interaction among the storage module, the calculation module and/or the processor; uploading the data of point-by-point chromaticity correction of each pixel on the replaced LED module by the obtained changed correction coefficient matrix to the LED display screen so as to finish correction of the area to be corrected of the LED display screen;

the storage module is used for storing a target red, green and blue tristimulus value matrix set during point-by-point chromaticity correction in the production of the module in the LED display module; the tri-color tri-stimulus value matrix is used for providing point-by-point chromaticity correction for the read-back module.

10. A point-by-point correction system for an LED display screen is characterized by comprising the following components:

the acquisition module is used for acquiring the brightness value and the color coordinate value of the LED display screen, acquiring a three-color tristimulus value matrix of the LED display screen and taking the three-color tristimulus value matrix as a correction data conversion target value;

the processor is used for reading back a three-color tristimulus value matrix of the module point-by-point chromaticity correction; forming a point-by-point correction instruction of the LED display screen;

a matrix calculation module for calculating three-color tristimulus value matrix M of the LED display screen body_sAnd a three-color tri-stimulus value matrix of the replaced LED display module, and calculating a correction data change matrix; the correction data matrix updating module is also used for calculating and obtaining the changed correction data matrix of each pixel point according to the correction data change matrix and the correction data matrix of each pixel point on the updated LED display module;

the correction processing module is used for performing point-by-point chromaticity correction on each pixel on the replaced LED module by using the obtained changed correction coefficient matrix;

the receiving and sending module is used for carrying out point-by-point chromaticity correction on the three-color tristimulus value matrix, the correction data change matrix and the correction data matrix of each pixel point on the updated LED display module, and carrying out data interaction among the storage module, the calculation module and/or the processor; uploading the data of point-by-point chromaticity correction of each pixel on the replaced LED module by the obtained changed correction coefficient matrix to the LED display screen so as to finish correction of the area to be corrected of the LED display screen;

the storage module is used for storing a target red, green and blue tristimulus value matrix set during point-by-point chromaticity correction in the production of the module in the LED display module; the tri-color tri-stimulus value matrix is used for providing point-by-point chromaticity correction for the read-back module.

11. A storage medium having stored thereon machine executable instructions that, when invoked and executed by a processor, cause the regional processor to: carrying out the method steps of any one of claims 1 to 7.

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