CN112634819A - Correction method and related device for LED display screen - Google Patents

Abstract

The embodiment of the application provides a correction method of an LED display screen and a related device. The method comprises the following steps: calculating to obtain a point-by-point thermal compensation correction coefficient according to the thermal compensation correction coefficient and the point-by-point correction coefficient of the LED display screen box body; and correcting the LED display screen box body according to the point-by-point thermal compensation correction coefficient. According to the method and the device, the thermal compensation correction coefficient and the point-by-point correction coefficient are stored separately, the point-by-point thermal compensation correction coefficient is calculated according to the thermal compensation correction coefficient and the point-by-point correction coefficient and then is corrected once, the problem that the thermal compensation correction cannot achieve the expected effect due to the fact that the position of the LED display screen module is changed is solved, the separated thermal compensation correction coefficient only needs to be collected once for the LED display screen box body with the same structure and the same PCB layout, and the correction efficiency is greatly improved.

Description

Correction method and related device for LED display screen

Technical Field

The present disclosure relates to the field of display technologies, and in particular, to a method for correcting a Light Emitting Diode (LED) display screen and a related device.

Background

With the rapid development of modern industrial technology, LED display screens are gradually becoming widely used in people's life and industrial production processes. The LED display screen is simple to manufacture, can keep normal work in different environments, and has the characteristics of high resolution, wide visual range, long visual distance, large area and the like. The LED display screen is generally applied to the fields of outdoor advertising, commercial display, stage rental, data visualization and the like. In an LED display screen control system, an LED display screen is a flat panel display formed by splicing small LED modules or LED boxes and is used for displaying various information such as characters, images, videos and the like. And each LED box body comprises a receiving card and a plurality of LED lamp panels electrically connected to the receiving card, and the receiving card is used for driving the LED lamp panels to display. Some LED display screen's LED box still can dispose the switching card (Hub card) to be connected a plurality of LED lamp plates to the receiving card, the switching card here plays interface extension, signal switching's effect. Because the LED display screen can be widely applied to various scenes such as traffic signal lights, literature shows, news releases, and the like, the demand of people on the display quality of the LED display screen is also increasing. The luminance and chromaticity of the LED display screen are two important indicators of display quality. The luminous brightness of the LED display screen can be reduced along with the temperature rise, and the LEDs with different luminous chromaticities are affected differently by the temperature. Therefore, the display brightness and chromaticity uniformity are deteriorated due to the uneven distribution of heat in the LED display screen, which is a problem in the art.

At present, people usually adopt a point-by-point thermal compensation correction method to solve the problem of poor consistency of display brightness and chromaticity, wherein the point-by-point thermal compensation correction is to perform thermal compensation correction on an LED display screen firstly, and then perform point-by-point correction on the LED display screen after the LED display screen reaches a thermal equilibrium state. However, the above method of point-by-point thermal compensation calibration is too long, the calibration efficiency is low, and the thermal compensation calibration cannot achieve the expected effect under the condition of changing the position of the LED display screen module.

Disclosure of Invention

The embodiment of the application discloses a correction method and a related device of an LED display screen, wherein a thermal compensation correction coefficient and a point-by-point correction coefficient are stored separately, and are calculated according to the thermal compensation correction coefficient and the point-by-point correction coefficient to obtain the point-by-point thermal compensation correction coefficient and then are corrected at one time, so that the problem that the thermal compensation correction cannot achieve the expected effect due to the change of the position of an LED display screen module is solved, the separately stored thermal compensation correction coefficient only needs to be collected once for an LED display screen box body with the same structure and Printed Circuit Board (PCB) layout, and the correction efficiency is greatly improved.

In a first aspect, an embodiment of the present application discloses a method for correcting an LED display screen, including:

calculating to obtain a point-by-point thermal compensation correction coefficient according to the thermal compensation correction coefficient and the point-by-point correction coefficient of the LED display screen box body; the thermal compensation correction coefficient is correlated with the mechanical structure of the LED display screen box body, the point-by-point correction coefficient is correlated with the module position of the LED display screen box body, and the point-by-point thermal compensation correction coefficient is correlated with the mechanical structure of the LED display screen box body;

and correcting the LED display screen box body according to the point-by-point thermal compensation correction coefficient.

In the embodiment of the application, because the thermal compensation correction coefficient used by the original correction method is included in the point-by-point correction coefficient, and the point-by-point correction coefficient has a correlation with the module position of the LED display screen box body, the thermal compensation correction coefficient also has a correlation with the module position of the LED display screen box body, that is, under the condition that the module position of the LED display screen box body is changed, the thermal compensation correction coefficient is affected by the change of the module position, so that the thermal compensation correction cannot achieve the expected effect; according to the embodiment of the application, the thermal compensation correction coefficients originally contained in the point-by-point correction coefficients are separated, the thermal compensation correction coefficients and the point-by-point correction coefficients are stored respectively, and the point-by-point thermal compensation correction coefficients are calculated according to the thermal compensation correction coefficients and the point-by-point correction coefficients and then are corrected once, so that the problem that the thermal compensation correction cannot achieve the expected effect due to the change of the module position of the LED display screen box body after the thermal compensation correction is solved, the separately stored thermal compensation correction coefficients only need to be collected once for the LED display screen box body with the same structure and PCB layout, and the correction efficiency is greatly improved.

In a possible implementation manner of the first aspect, the calculating the point-by-point thermal compensation correction coefficient according to the thermal compensation correction coefficient and the point-by-point correction coefficient of the LED display screen box includes:

and multiplying the thermal compensation correction coefficient and the point-by-point correction coefficient to obtain the point-by-point thermal compensation correction coefficient.

In the embodiment of the application, the thermal compensation correction coefficient and the point-by-point correction coefficient are respectively stored, and then the product of the thermal compensation correction coefficient and the point-by-point correction coefficient is calculated, so that the obtained point-by-point thermal compensation correction coefficient has relevance only with the mechanical structure of the LED display screen box body and is irrelevant with the module position of the LED display screen box body, and the thermal compensation correction is still effective even under the condition that the module position of the LED display screen box body is changed.

In a possible implementation manner of the first aspect, the correcting the LED display screen box according to the point-by-point thermal compensation correction coefficient includes:

and under the condition that the position of the module of the LED display screen box body is changed, correcting the LED display screen box body according to the point-by-point thermal compensation correction coefficient.

In the embodiment of the present application, since the calculated point-by-point thermal compensation correction coefficient has a correlation only with the mechanical structure of the LED display screen box body, and is not related to the module position of the LED display screen box body, the thermal compensation correction is still effective even when the module position of the LED display screen box body is changed.

In a possible implementation manner of the first aspect, the correcting the LED display screen box according to the point-by-point thermal compensation correction coefficient includes:

if the temperature of the LED display screen box body is smaller than a first threshold value, correcting the LED display screen box body by utilizing a first point-by-point thermal compensation correction coefficient;

if the temperature of the LED display screen box body is larger than a second threshold value, correcting the LED display screen box body by utilizing a second point-by-point thermal compensation correction coefficient;

if the temperature of the LED display screen box body is not less than the first threshold value and not more than the second threshold value, correcting the LED display screen box body by utilizing a third point-by-point thermal compensation correction coefficient;

the first point-by-point thermal compensation correction coefficient, the second point-by-point thermal compensation correction coefficient and the third point-by-point thermal compensation correction coefficient are point-by-point thermal compensation correction coefficients with different values.

In the embodiment of the application, different point-by-point thermal compensation correction coefficients are adopted to correct the LED display screen box body according to different temperatures of the LED display screen box body. Because the thermal compensation correction coefficients of the LED display screen box body at different temperatures are different, and the product results of different thermal compensation correction coefficients and point-by-point correction coefficients also correspond to a plurality of different point-by-point thermal compensation correction coefficients, the temperature monitoring and point-by-point thermal compensation correction coefficients of the LED display screen box body can be associated, namely, a plurality of temperature thresholds, such as a first threshold, a second threshold and the like, are set, and when the temperature of the LED display screen box body is monitored to be lower than the first threshold, the LED display screen box body is corrected by using the first point-by-point thermal compensation correction coefficient; when the temperature of the LED display screen box body is monitored to be larger than a second threshold value, correcting the LED display screen box body by utilizing a second point-by-point thermal compensation correction coefficient; and when the temperature of the LED display screen box body is not less than the first threshold value and not more than the second threshold value, correcting the LED display screen box body by utilizing a third point-by-point thermal compensation correction coefficient. Therefore, the automatic point-by-point thermal compensation correction function of the LED display screen box body can be realized through the correction method.

In a possible implementation manner of the first aspect, before the calculating the point-by-point thermal compensation correction coefficient, the method further includes:

performing cold screen correction on the LED display screen box body to obtain a sample box, wherein the sample box is the LED display screen box body subjected to cold screen correction;

carrying out white light aging treatment on the sample box until the sample box reaches a thermal equilibrium state, wherein the thermal equilibrium state is that the thermal distribution and the highest temperature of the sample box are not changed any more;

collecting a red brightness value matrix of a sample box in a thermal equilibrium state;

and calculating to obtain a thermal compensation correction coefficient matrix of the LED display screen box body according to the red brightness value matrix, wherein the thermal compensation correction coefficient matrix comprises thermal compensation correction coefficients.

In the embodiment of the application, a method for obtaining a thermal compensation correction coefficient is provided, the cold screen correction is performed on the LED display screen box body, then the white light aging treatment is performed until the thermal distribution and the highest temperature of the LED display screen box body do not change any more, then a red brightness value matrix of the LED display screen box body is collected, and the thermal compensation correction coefficient is obtained through calculation according to the collected red brightness value matrix. The thermal compensation correction coefficient obtained by the method has relevance with the mechanical structure of the LED display screen box body and is irrelevant with the module position of the LED display screen box body.

In a possible implementation manner of the first aspect, the calculating a thermal compensation correction coefficient matrix of the LED display screen box according to the red luminance value matrix includes:

and dividing the maximum value in the red brightness value matrix by the red brightness value matrix to obtain a thermal compensation correction coefficient matrix of the LED display screen box body.

In the embodiment of the application, a method for calculating a thermal compensation correction coefficient matrix is provided, in which a maximum value in a collected red brightness value matrix of a sample box is divided by the red brightness value matrix to obtain the thermal compensation correction coefficient matrix, and the thermal compensation correction coefficient matrix includes thermal compensation correction coefficients of an LED display screen box body at different temperatures.

In a possible implementation manner of the first aspect, before the calculating the point-by-point thermal compensation correction coefficient, the method further includes:

collecting a first red brightness value matrix and a second red brightness value matrix of the LED display screen box body, wherein the first red brightness value matrix comprises a red brightness value of the LED display screen box body in a cold screen state, the second red brightness value matrix comprises a red brightness value of the LED display screen box body in a heat balance state, and the heat balance state is that the heat distribution and the highest temperature of the LED display screen box body are not changed any more;

and calculating to obtain a thermal compensation correction coefficient matrix of the LED display screen box body according to the first red brightness value matrix and the second red brightness value matrix, wherein the thermal compensation correction coefficient matrix comprises thermal compensation correction coefficients.

In the embodiment of the application, the camera can be placed right in front of the LED display screen box body, so that the camera lens is right opposite to the central position of the display surface of the LED display screen box body, and the focal length and the aperture of the camera lens are adjusted to enable the LED display screen box body to be located at the central position of the camera viewfinder. Adjusting the camera to enable the imaging of each pixel in the camera to be clearly visible, enabling the LED display screen box body to display red through the LED controller, and controlling the camera to acquire cold screen red brightness distribution data (namely the first red brightness value matrix) of each pixel by the upper computer control software. The LED display screen box body is subjected to cold screen correction, then white light aging treatment is carried out to enable the LED display screen box body to reach a thermal equilibrium state, the LED display screen box body displays red through the LED controller, and the upper computer control software controls the camera to collect and finish hot screen red brightness distribution data (namely the second red brightness value matrix) of each pixel within a specified time. And then according to the collected first red brightness value matrix and the second red brightness value matrix, calculating to obtain a thermal compensation correction coefficient matrix of the LED display screen box body, wherein the thermal compensation correction coefficient matrix comprises thermal compensation correction coefficients. The thermal compensation correction coefficient obtained by the method has relevance with the mechanical structure of the LED display screen box body and is irrelevant with the module position of the LED display screen box body, and the product of the same LED display screen box body only needs to be collected once, so that the time for each LED display screen box body to be corrected to reach a thermal balance state is greatly reduced, the operation is simple, and the efficiency is higher.

In a possible implementation manner of the first aspect, calculating a thermal compensation correction coefficient matrix of the LED display screen box according to the first red luminance value matrix and the second red luminance value matrix includes:

and respectively dividing the difference value between the red brightness value in the first red brightness value matrix and the red brightness value in the second red brightness value matrix by the maximum value of the difference value to obtain a thermal compensation correction coefficient matrix of the LED display screen box body.

In the embodiment of the present application, a method for calculating a thermal compensation correction coefficient matrix is provided, where differences between red luminance values in a first red luminance value matrix and red luminance values in a second red luminance value matrix are calculated, and the obtained differences are respectively divided by a maximum value of the differences to obtain a thermal compensation correction coefficient matrix of an LED display screen box, where the thermal compensation correction coefficient matrix includes thermal compensation correction coefficients of the LED display screen box at different temperatures.

In a possible implementation manner of the first aspect, before the calculating the point-by-point thermal compensation correction coefficient, the method further includes:

collecting brightness and chrominance data of the LED display screen box body;

and calculating to obtain a point-by-point correction coefficient matrix of the LED display screen box body according to the brightness and chrominance data of the LED display screen box body, wherein the point-by-point correction coefficient matrix comprises point-by-point correction coefficients.

In the embodiment of the application, a method for obtaining a point-by-point correction coefficient is provided, wherein luminance and chrominance data of an LED display screen box body are collected, a point-by-point correction coefficient matrix is obtained through calculation according to the luminance and chrominance data, the point-by-point correction coefficient matrix comprises point-by-point correction coefficients, and the point-by-point correction coefficients are associated with the position of a module of the LED display screen box body.

In one possible implementation of the first aspect, the point-by-point correction coefficients and the thermal compensation correction coefficients are stored in different locations.

In the embodiment of the application, the point-by-point correction coefficient and the thermal compensation correction coefficient are stored separately, the point-by-point thermal compensation correction coefficient is calculated according to the thermal compensation correction coefficient and the point-by-point correction coefficient and then is corrected at one time, the problem that the thermal compensation correction cannot achieve the expected effect due to the change of the position of the module of the LED display screen box body after the thermal compensation correction can be solved, the separately stored thermal compensation correction coefficient only needs to be collected once for the LED display screen box body with the same structure and the same PCB layout, and the correction efficiency is greatly improved.

In a second aspect, an embodiment of the present application discloses a correction device for an LED display screen, including:

the calculation unit is used for calculating a point-by-point thermal compensation correction coefficient according to the thermal compensation correction coefficient and the point-by-point correction coefficient of the LED display screen box body; the thermal compensation correction coefficient is correlated with the mechanical structure of the LED display screen box body, the point-by-point correction coefficient is correlated with the module position of the LED display screen box body, and the point-by-point thermal compensation correction coefficient is correlated with the mechanical structure of the LED display screen box body;

and the correction unit is used for correcting the LED display screen box body according to the point-by-point thermal compensation correction coefficient.

In the embodiment of the application, because the thermal compensation correction coefficient used by the original correction method is included in the point-by-point correction coefficient, and the point-by-point correction coefficient has a correlation with the module position of the LED display screen box body, the thermal compensation correction coefficient also has a correlation with the module position of the LED display screen box body, that is, under the condition that the module position of the LED display screen box body is changed, the thermal compensation correction coefficient is affected by the change of the module position, so that the thermal compensation correction cannot achieve the expected effect; according to the embodiment of the application, the thermal compensation correction coefficients originally contained in the point-by-point correction coefficients are separated, the thermal compensation correction coefficients and the point-by-point correction coefficients are stored respectively, and the point-by-point thermal compensation correction coefficients are calculated according to the thermal compensation correction coefficients and the point-by-point correction coefficients and then are corrected once, so that the problem that the thermal compensation correction cannot achieve the expected effect due to the change of the module position of the LED display screen box body after the thermal compensation correction is solved, the separately stored thermal compensation correction coefficients only need to be collected once for the LED display screen box body with the same structure and PCB layout, and the correction efficiency is greatly improved.

In a possible embodiment of the second aspect, the calculation unit is specifically configured to multiply the thermal compensation correction coefficient and the point-by-point correction coefficient to obtain a point-by-point thermal compensation correction coefficient.

In the embodiment of the application, the thermal compensation correction coefficient and the point-by-point correction coefficient are respectively stored, and then the product of the thermal compensation correction coefficient and the point-by-point correction coefficient is calculated, so that the obtained point-by-point thermal compensation correction coefficient has relevance only with the mechanical structure of the LED display screen box body and is irrelevant with the module position of the LED display screen box body, and the thermal compensation correction is still effective even under the condition that the module position of the LED display screen box body is changed.

In a possible embodiment of the second aspect, the correction unit is specifically configured to correct the LED display screen box according to the point-by-point thermal compensation correction coefficient when the module position of the LED display screen box changes.

In the embodiment of the present application, since the calculated point-by-point thermal compensation correction coefficient has a correlation only with the mechanical structure of the LED display screen box body, and is not related to the module position of the LED display screen box body, the thermal compensation correction is still effective even when the module position of the LED display screen box body is changed.

In a possible implementation manner of the second aspect, the correction unit is specifically further configured to correct the LED display screen box by using a first point-by-point thermal compensation correction coefficient if the temperature of the LED display screen box is less than a first threshold; if the temperature of the LED display screen box body is larger than a second threshold value, correcting the LED display screen box body by utilizing a second point-by-point thermal compensation correction coefficient; if the temperature of the LED display screen box body is not less than the first threshold value and not more than the second threshold value, correcting the LED display screen box body by utilizing a third point-by-point thermal compensation correction coefficient; the first point-by-point thermal compensation correction coefficient, the second point-by-point thermal compensation correction coefficient and the third point-by-point thermal compensation correction coefficient are point-by-point thermal compensation correction coefficients with different values.

In the embodiment of the application, different point-by-point thermal compensation correction coefficients are adopted to correct the LED display screen box body according to different temperatures of the LED display screen box body. Because the thermal compensation correction coefficients of the LED display screen box body at different temperatures are different, and the product results of different thermal compensation correction coefficients and point-by-point correction coefficients also correspond to a plurality of different point-by-point thermal compensation correction coefficients, the temperature monitoring and point-by-point thermal compensation correction coefficients of the LED display screen box body can be associated, namely, a plurality of temperature thresholds, such as a first threshold, a second threshold and the like, are set, and when the temperature of the LED display screen box body is monitored to be lower than the first threshold, the LED display screen box body is corrected by using the first point-by-point thermal compensation correction coefficient; when the temperature of the LED display screen box body is monitored to be larger than a second threshold value, correcting the LED display screen box body by utilizing a second point-by-point thermal compensation correction coefficient; and when the temperature of the LED display screen box body is not less than the first threshold value and not more than the second threshold value, correcting the LED display screen box body by utilizing a third point-by-point thermal compensation correction coefficient. Therefore, the automatic point-by-point thermal compensation correction function of the LED display screen box body can be realized through the correction method.

In a possible implementation manner of the second aspect, the correction unit is further configured to perform cold screen correction on the LED display screen box body to obtain a sample box, where the sample box is the LED display screen box body after the cold screen correction; the device still includes:

the aging unit is used for carrying out white light aging treatment on the sample box until the sample box reaches a thermal equilibrium state, wherein the thermal equilibrium state is that the thermal distribution and the highest temperature of the sample box are not changed any more;

the acquisition unit is used for acquiring a red brightness value matrix of the sample box in a thermal equilibrium state;

and the calculation unit is also used for calculating a thermal compensation correction coefficient matrix of the LED display screen box body according to the red brightness value matrix, wherein the thermal compensation correction coefficient matrix comprises thermal compensation correction coefficients.

In the embodiment of the application, a method for obtaining a thermal compensation correction coefficient is provided, the cold screen correction is performed on the LED display screen box body, then the white light aging treatment is performed until the thermal distribution and the highest temperature of the LED display screen box body do not change any more, then a red brightness value matrix of the LED display screen box body is collected, and the thermal compensation correction coefficient is obtained through calculation according to the collected red brightness value matrix. The thermal compensation correction coefficient obtained by the method has relevance with the mechanical structure of the LED display screen box body and is irrelevant with the module position of the LED display screen box body.

In a possible implementation manner of the second aspect, the calculating unit is further configured to divide the maximum value in the red luminance value matrix by the red luminance value matrix to obtain a thermal compensation correction coefficient matrix of the LED display screen box.

In the embodiment of the application, a method for calculating a thermal compensation correction coefficient matrix is provided, in which a maximum value in a collected red brightness value matrix of a sample box is divided by the red brightness value matrix to obtain the thermal compensation correction coefficient matrix, and the thermal compensation correction coefficient matrix includes thermal compensation correction coefficients of an LED display screen box body at different temperatures.

In a possible implementation manner of the second aspect, the collecting unit is further configured to collect a first red luminance value matrix and a second red luminance value matrix of the LED display screen box, where the first red luminance value matrix includes a red luminance value of the LED display screen box in a cold screen state, and the second red luminance value matrix includes a red luminance value of the LED display screen box in a thermal equilibrium state, where the thermal equilibrium state is that a thermal distribution and a maximum temperature of the LED display screen box do not change any more;

and the calculation unit is further used for calculating a thermal compensation correction coefficient matrix of the LED display screen box body according to the first red brightness value matrix and the second red brightness value matrix, wherein the thermal compensation correction coefficient matrix comprises thermal compensation correction coefficients.

In the embodiment of the application, the camera can be placed right in front of the LED display screen box body, so that the camera lens is right opposite to the central position of the display surface of the LED display screen box body, and the focal length and the aperture of the camera lens are adjusted to enable the LED display screen box body to be located at the central position of the camera viewfinder. Adjusting the camera to enable the imaging of each pixel in the camera to be clearly visible, enabling the LED display screen box body to display red through the LED controller, and controlling the camera to acquire cold screen red brightness distribution data (namely the first red brightness value matrix) of each pixel by the upper computer control software. The LED display screen box body is subjected to cold screen correction, then white light aging treatment is carried out to enable the LED display screen box body to reach a thermal equilibrium state, the LED display screen box body displays red through the LED controller, and the upper computer control software controls the camera to collect and finish hot screen red brightness distribution data (namely the second red brightness value matrix) of each pixel within a specified time. And then according to the collected first red brightness value matrix and the second red brightness value matrix, calculating to obtain a thermal compensation correction coefficient matrix of the LED display screen box body, wherein the thermal compensation correction coefficient matrix comprises thermal compensation correction coefficients. The thermal compensation correction coefficient obtained by the method has relevance with the mechanical structure of the LED display screen box body and is irrelevant with the module position of the LED display screen box body, and the product of the same LED display screen box body only needs to be collected once, so that the time for each LED display screen box body to be corrected to reach a thermal balance state is greatly reduced, the operation is simple, and the efficiency is higher.

In a possible implementation manner of the second aspect, the calculating unit is further configured to divide a difference between the red luminance value in the first red luminance value matrix and the red luminance value in the second red luminance value matrix by a maximum value of the difference, so as to obtain a thermal compensation correction coefficient matrix of the LED display panel box.

In the embodiment of the present application, a method for calculating a thermal compensation correction coefficient matrix is provided, where differences between red luminance values in a first red luminance value matrix and red luminance values in a second red luminance value matrix are calculated, and the obtained differences are respectively divided by a maximum value of the differences to obtain a thermal compensation correction coefficient matrix of an LED display screen box, where the thermal compensation correction coefficient matrix includes thermal compensation correction coefficients of the LED display screen box at different temperatures.

In a possible implementation manner of the second aspect, the collecting unit is further configured to collect luminance and chrominance data of the LED display screen box;

and the calculation unit is also used for calculating a point-by-point correction coefficient matrix of the LED display screen box body according to the brightness data of the LED display screen box body, wherein the point-by-point correction coefficient matrix comprises point-by-point correction coefficients.

In the embodiment of the application, a method for obtaining a point-by-point correction coefficient is provided, wherein luminance and chrominance data of an LED display screen box body are collected, a point-by-point correction coefficient matrix is obtained through calculation according to the luminance and chrominance data, the point-by-point correction coefficient matrix comprises point-by-point correction coefficients, and the point-by-point correction coefficients are associated with the position of a module of the LED display screen box body.

In one possible embodiment of the second aspect, the point-by-point correction coefficients and the thermal compensation correction coefficients are stored in different locations.

In the embodiment of the application, the point-by-point correction coefficient and the thermal compensation correction coefficient are stored separately, the point-by-point thermal compensation correction coefficient is calculated according to the thermal compensation correction coefficient and the point-by-point correction coefficient and then is corrected at one time, the problem that the thermal compensation correction cannot achieve the expected effect due to the change of the position of the module of the LED display screen box body after the thermal compensation correction can be solved, the separately stored thermal compensation correction coefficient only needs to be collected once for the LED display screen box body with the same structure and the same PCB layout, and the correction efficiency is greatly improved.

In a third aspect, an embodiment of the present application discloses an electronic device for LED display screen correction, where the electronic device includes a memory and a processor, where the memory stores program instructions, and when the program instructions are executed by the processor, the processor is caused to execute the method according to the first aspect or any one of the possible implementations of the first aspect.

In a fourth aspect, this application discloses a computer-readable storage medium, in which a computer program is stored, which, when running on one or more processors, performs the method as in the first aspect or any one of the possible implementations of the first aspect.

According to the embodiment of the application, the thermal compensation correction coefficient required by the thermal compensation correction has relevance with the mechanical structure and the module position of the LED display screen box body, and the point-by-point correction coefficient required by the point-by-point correction has relevance with the module position of the LED display screen box body, so that under the condition that the module position of the LED display screen box body is changed, the thermal compensation correction coefficient is influenced, and the thermal compensation correction cannot achieve the expected effect; however, in the embodiment of the application, the thermal compensation correction coefficient originally contained in the point-by-point correction coefficient is separated, the thermal compensation correction coefficient and the point-by-point correction coefficient are respectively stored, the point-by-point thermal compensation correction coefficient is calculated according to the thermal compensation correction coefficient and the point-by-point correction coefficient and then is corrected once, the problem that the thermal compensation correction cannot achieve the expected effect due to the change of the module position of the LED display screen box body after the thermal compensation correction can be solved, the separately stored thermal compensation correction coefficient only needs to be collected once for the LED display screen box body with the same structure and PCB layout, and the correction efficiency is greatly improved.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments or the background art of the present application, the drawings used in the embodiments or the background art of the present application will be briefly described below.

Fig. 1 is a schematic diagram of a framework for correcting an LED display screen box according to an embodiment of the present disclosure;

fig. 2 is a schematic flowchart of a method for correcting an LED display screen according to an embodiment of the present disclosure;

FIG. 3 is a schematic flowchart of another LED display screen calibration method according to an embodiment of the present disclosure;

fig. 4 is a schematic flowchart of another LED display screen calibration method according to an embodiment of the present disclosure;

fig. 5 is a schematic structural diagram of an LED display screen calibration apparatus according to an embodiment of the present disclosure;

fig. 6 is a schematic structural diagram of an LED display screen correction device according to an embodiment of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more clear, the present application will be further described with reference to the accompanying drawings.

The terms "first" and "second," and the like in the description, claims, and drawings of the present application are used solely to distinguish between different objects and not to describe a particular order. Furthermore, the terms "comprising" and "having," as well as any variations thereof, are intended to cover non-exclusive inclusions. Such as a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those steps or elements listed, but may alternatively include other steps or elements not listed, or inherent to such process, method, article, or apparatus.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the application. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. Those skilled in the art will explicitly and implicitly appreciate that the embodiments described herein may be combined with other embodiments.

In this application, "at least one" means one or more, "a plurality" means two or more, "at least two" means two or three and three or more, "and/or" for describing an association relationship of associated objects, which means that there may be three relationships, for example, "a and/or B" may mean: only A, only B and both A and B are present, wherein A and B may be singular or plural. The character "/" generally indicates that the former and latter associated objects are in an "or" relationship. "at least one item(s) below" or similar expressions refer to any combination of these items. For example, at least one (one) of a, b, or c, may represent: a, b, c, "a and b," a and c, "" b and c, "or" a and b and c.

In order to describe the scheme of the present application more clearly, some knowledge related to the calibration of the LED display screen box is introduced below.

LED display screen box: the LED display screen box is simply a screen body formed by a plurality of display units (unit display panels or LED display modules) which can be combined and spliced. In order to meet different environments, a set of appropriate controllers (a main control board or a control system) is added, so that display boards (or unit boxes) with various specifications can be matched with controllers with different control technologies to form a plurality of LED display screens, and different display requirements are met.

LED display screen module: the LED display screen module is one of main components forming a finished LED display screen, and mainly comprises an LED lamp, a PCB (printed Circuit Board), a driving IC (integrated Circuit), a resistor, a capacitor and a plastic sleeve.

Correcting point by point: the point-by-point correction is a technology for improving the brightness uniformity and the color fidelity of the LED display screen, namely, the brightness (and the chromaticity) data of each pixel (or each primary color sub-pixel) area on the LED display screen are collected, the correction coefficient of each primary color sub-pixel or the correction coefficient matrix of each pixel is given and fed back to a control system of the display screen, the control system applies the correction coefficient to realize the differential drive of each pixel (or each primary color sub-pixel), the picture of the LED display screen is fine and smooth, and the color is really restored.

The embodiments of the present application will be described below with reference to the drawings.

Referring to fig. 1, fig. 1 is a schematic diagram illustrating a calibration structure of an LED display screen box according to an embodiment of the present disclosure. As shown in FIG. 1, the architecture diagram includes an LED display screen housing, an LED controller, a control computer, and a camera. The LED display screen box body is used for displaying the brightness and the chromaticity of the LED display screen box body, the camera is used for collecting the brightness and the chromaticity data of the LED box body and transmitting the collected brightness and the chromaticity data to the control computer, the control computer is used for calculating to obtain a point-by-point correction coefficient, the control computer is connected with the LED controller through a network, and the LED controller is indicated to carry out point-by-point brightness and chromaticity correction on the LED display screen box body through the calculated point-by-point correction coefficient. The point-by-point brightness chromaticity correction is to solve the problem of chromaticity deviation by changing the color coordinates of RGB three colors according to the RGB color matching principle. When point-by-point brightness chromaticity correction is carried out, color coordinates of corrected RGB three colors are reasonably selected, and color distortion is avoided. The point-by-point brightness and chromaticity correction is to adjust the brightness and color uniformity of each LED lamp. The corrected architecture diagram is suitable for correcting factory standardization and standardization management, the box bodies can be freely spliced, the edges of the box bodies are automatically corrected, the correction angle is consistent and minimum, the correction efficiency is high, and the correction cost is low.

Referring to fig. 2, fig. 2 is a schematic flow chart of a method for calibrating an LED display screen according to an embodiment of the present application, where the method includes, but is not limited to, the following steps:

step 201: and calculating to obtain the point-by-point thermal compensation correction coefficient according to the thermal compensation correction coefficient and the point-by-point correction coefficient of the LED display screen box body.

Calculating to obtain a point-by-point thermal compensation correction coefficient according to the thermal compensation correction coefficient and the point-by-point correction coefficient of the LED display screen box body; the thermal compensation correction coefficient has relevance with the mechanical structure of the LED display screen box body and is irrelevant with the module position of the LED display screen box body, namely when the mechanical structure of the LED display screen box body is changed, the thermal compensation correction coefficient of the LED display screen box body is changed along with the change of the module position, and the thermal compensation correction coefficient of the LED display screen box body is not changed along with the change of the module position; the point-by-point correction coefficient has relevance with the module position of the LED display screen box body, namely when the module position of the LED display screen box body is changed, the point-by-point correction coefficient of the LED display screen box body is changed; the point-by-point thermal compensation correction coefficient has relevance with the mechanical structure of the LED display screen box body and is irrelevant with the module position of the LED display screen box body, namely when the mechanical structure of the LED display screen box body is changed, the point-by-point thermal compensation correction coefficient of the LED display screen box body can be changed along with the change of the module position of the LED display screen box body, but cannot be changed along with the change of the module position of the LED display screen box body. Therefore, in the embodiment, the point-by-point thermal compensation correction coefficient is used for correcting the LED display screen box body, so that the expected effect of the point-by-point thermal compensation correction can be still achieved under the condition that the position of the module of the LED display screen box body is changed. According to the embodiment of the application, the thermal compensation correction coefficients originally contained in the point-by-point correction coefficients are separated, the thermal compensation correction coefficients and the point-by-point correction coefficients are respectively stored, the point-by-point thermal compensation correction coefficients are calculated according to the thermal compensation correction coefficients and the point-by-point correction coefficients and then are corrected at one time, and the separately stored thermal compensation correction coefficients only need to be collected once for the LED display screen box bodies with the same structure and the same PCB layout, so that the correction efficiency is greatly improved.

Specifically, there are many possible calculation methods for obtaining the point-by-point thermal compensation correction coefficient, and this embodiment provides one possible implementation method. And multiplying the thermal compensation correction coefficient of the LED display screen box body by the point-by-point correction coefficient, and taking the product result of the two as the point-by-point thermal compensation correction coefficient. The point-by-point correction coefficient can be obtained by collecting brightness data of the LED display screen box body and calculating according to the collected brightness data to obtain a point-by-point correction coefficient matrix, the point-by-point correction coefficient matrix comprises a plurality of different point-by-point correction coefficients, and the point-by-point correction coefficients are related to the module position of the LED display screen box body. The thermal compensation correction coefficient may be obtained by:

firstly, performing lighting chromaticity-by-lighting cold screen correction on an LED display screen box body, specifically, completing lighting chromaticity-by-lighting chromaticity correction within one minute after the LED display screen box body is lighted at room temperature, wherein the room temperature refers to about 25 ℃; optionally, the point-by-point correction coefficient can also be used for acquiring the brightness and chrominance data of the sample box at the moment, and calculating to obtain a point-by-point correction coefficient matrix; displaying the LED sample box with 100% brightness, and aging the LED sample box for about 30 minutes to enable the LED sample box to reach a thermal equilibrium state, wherein the thermal equilibrium state refers to the state that the thermal distribution of the LED sample box does not change and the highest temperature does not change, namely the LED sample box is regarded as reaching the thermal equilibrium state; and then collecting a red brightness value matrix of the sample box which is corrected by the cold screen and reaches a thermal equilibrium state, wherein a result obtained by dividing the maximum value in the collected red brightness value matrix by the red brightness value matrix is used as a thermal compensation correction coefficient matrix, the thermal compensation correction coefficient matrix comprises a plurality of thermal compensation correction coefficients, and the thermal compensation correction coefficients are only related to the mechanical structure of the LED display screen box body and do not change along with the change of the position of the module of the LED display screen box body. The obtained point-by-point correction coefficient and the thermal compensation correction coefficient are respectively stored in different positions, so that the effect of coefficient separation is achieved. Further, the control computer connected with the LED controller network sends the thermal compensation correction coefficient matrix to a receiving card of the LED controller through upper computer software of the LED controller, and the point-to-point coefficients of the thermal compensation correction coefficient matrix and the point-to-point correction coefficient matrix are multiplied to obtain a plurality of point-to-point thermal compensation correction coefficients, so that the point-to-point thermal compensation correction function is realized through the point-to-point thermal compensation correction coefficients.

In addition, a camera can be placed right in front of the LED display screen box body, so that the camera lens is right opposite to the central position of the display surface of the LED display screen box body, and the focal length and the aperture of the camera lens are adjusted to enable the LED display screen box body to be located at the central position of the camera viewfinder. And adjusting the camera to enable the imaging of each pixel in the camera to be clearly visible, enabling the LED display screen box body to display red through the LED controller, and controlling the camera to acquire cold screen red brightness distribution data of each pixel as a first red brightness value matrix by the upper computer control software. Displaying the LED display screen box body with 100% brightness, and aging the LED display screen box body for about 30 minutes in a white state to enable the LED display screen box body to reach a thermal equilibrium state, wherein the thermal equilibrium state refers to the state that the thermal distribution of the LED display screen box body does not change any more and the highest temperature does not change any more, namely the LED display screen box body reaches the thermal equilibrium state; and then the LED display screen box body displays red through the LED controller, and the upper computer control software controls the camera to collect the hot screen red brightness distribution data of each pixel within a specified time to serve as a second red brightness value matrix. And finally, calculating the difference value between the red brightness value in the first red brightness value matrix and the red brightness value in the second red brightness value matrix, and dividing the obtained difference value by the maximum value in the difference values to obtain a thermal compensation correction coefficient matrix of the LED display screen box body, wherein the thermal compensation correction coefficient matrix comprises a plurality of thermal compensation correction coefficients, the thermal compensation correction coefficients are only related to the mechanical structure of the LED display screen box body and do not change along with the change of the module position of the LED display screen box body, and the thermal compensation correction coefficients only need to be collected once for the product of the same LED display screen box body, so that the time for each LED display screen box body to be corrected to reach a thermal balance state is greatly reduced, the operation is simple, and the efficiency is higher. The obtained point-by-point correction coefficient and the thermal compensation correction coefficient are respectively stored in different positions, so that the effect of coefficient separation is achieved.

Step 202: and correcting the LED display screen box body according to the calculated point-by-point thermal compensation correction coefficient.

As can be seen from the step 201, the calculated point-by-point thermal compensation correction coefficient is independent of the module position of the LED display screen box, i.e. does not change with the change of the module position, so that under the condition that the module position of the LED display screen box changes, the LED display screen box can be corrected according to the calculated point-by-point thermal compensation correction coefficient, thereby implementing the point-by-point thermal compensation correction function. And the thermal compensation correction coefficient originally contained in the point-by-point correction coefficient is separated, the thermal compensation correction coefficient and the point-by-point correction coefficient are respectively stored, the point-by-point thermal compensation correction coefficient is calculated according to the thermal compensation correction coefficient and the point-by-point correction coefficient and then is corrected at one time, and the separately stored thermal compensation correction coefficient is only required to be collected once for the LED display screen box body with the same structure and PCB layout, so that the correction efficiency is greatly improved.

Specifically, the LED display screen box body correction equipment can adopt different point-by-point thermal compensation correction coefficients to correct the LED display screen box body according to different temperatures of the LED display screen box body. Because the thermal compensation correction coefficients of the LED display screen box body at different temperatures are different, and the product results of different thermal compensation correction coefficients and point-by-point correction coefficients also correspond to a plurality of different point-by-point thermal compensation correction coefficients, the temperature monitoring and point-by-point thermal compensation correction coefficients of the LED display screen box body can be associated, namely, a plurality of temperature thresholds, such as a first threshold, a second threshold and the like, are set, and when the temperature of the LED display screen box body is monitored to be lower than the first threshold, the LED display screen box body is corrected by using the first point-by-point thermal compensation correction coefficient; when the temperature of the LED display screen box body is monitored to be larger than a second threshold value, correcting the LED display screen box body by utilizing a second point-by-point thermal compensation correction coefficient; and when the temperature of the LED display screen box body is not less than the first threshold value and not more than the second threshold value, correcting the LED display screen box body by utilizing a third point-by-point thermal compensation correction coefficient. The first threshold and the second threshold are not fixed values, and may be set differently according to different application scenarios, for example, the first threshold may be set to be 50 ℃ and the second threshold may be set to be 70 ℃. Therefore, the temperature monitoring of the LED display screen box body and the command under the point-by-point thermal compensation correction coefficient can be associated through the correction method, and the automatic point-by-point thermal compensation correction function of the LED display screen box body is realized.

Referring to fig. 3, fig. 3 is a schematic flow chart of another LED display screen calibration method according to an embodiment of the present application, where the method includes, but is not limited to, the following steps:

step 301: and calculating to obtain the point-by-point correction coefficient of the LED display screen box body according to the brightness and chrominance data of the LED display screen box body.

The correction device of the LED display screen box body such as an LED control computer can acquire the brightness and chroma data of the LED display screen box body through an external device such as a camera and the like, and calculate to obtain a point-by-point correction coefficient matrix according to the brightness and chroma data, wherein the point-by-point correction coefficient matrix comprises point-by-point correction coefficients, and the point-by-point correction coefficients are associated with the module position of the LED display screen box body. Optionally, the LED controller connected to the LED display screen box of the LED control computer via a network may perform point-by-point correction on the LED display screen box according to the calculated point-by-point correction coefficient of the LED display screen box, where the point-by-point correction is a technique for improving the brightness uniformity and color fidelity of the LED display screen, that is, by collecting brightness (and chromaticity) data of each pixel (or each primary color sub-pixel) region on the LED display screen, a correction coefficient of each primary color sub-pixel or a correction coefficient matrix of each pixel is given and fed back to the control system of the display screen, and the control system applies the correction coefficient to implement differential driving of each pixel (or each primary color sub-pixel), so that the picture of the LED display screen is pure and fine, and the color is really restored.

Step 302: and collecting a red brightness value matrix of the LED display screen box body which is corrected by the cold screen and reaches a thermal equilibrium state.

Performing cold screen correction on the LED display screen box body, wherein the cold screen correction is to finish point-by-point lighting chromaticity correction within one minute after the LED display screen box body is lighted at room temperature, wherein the room temperature refers to about 25 ℃; optionally, the point-by-point correction coefficient can also be used for acquiring the brightness and chrominance data of the sample box at the moment, and calculating to obtain a point-by-point correction coefficient matrix; displaying the LED sample box with 100% brightness, and carrying out a white light aging step for about 30 minutes to enable the LED sample box to reach a thermal equilibrium state, wherein the thermal equilibrium state refers to the state that the thermal distribution of the LED sample box does not change and the highest temperature does not change, namely the LED sample box is regarded as reaching the thermal equilibrium state; and then collecting a red brightness value matrix of the sample box which is corrected by the cold shield and reaches a thermal equilibrium state, wherein the collected red brightness value matrix can be used for calculating to obtain a thermal compensation correction coefficient of the LED sample box.

Step 303: and calculating according to the collected red brightness value matrix to obtain a thermal compensation correction coefficient of the LED display screen box body.

The red luminance value matrix of the LED display screen box body can be acquired in the above step 302, and the red luminance value matrix can be used for calculating the thermal compensation correction coefficient of the LED sample box. Specifically, a result obtained by dividing the maximum value in the collected red luminance value matrix by the red luminance value matrix is used as a thermal compensation correction coefficient matrix, the thermal compensation correction coefficient matrix comprises a plurality of thermal compensation correction coefficients, and the thermal compensation correction coefficients obtained by the method have relevance to the mechanical structure of the LED display screen box body and are irrelevant to the module position of the LED display screen box body. It should be noted that the obtained point-by-point correction coefficient and the obtained thermal compensation correction coefficient are respectively stored at different positions, the thermal compensation correction coefficient can be enabled not to be influenced by the change of the module position by separately storing the point-by-point correction coefficient and the thermal compensation correction coefficient, so that the thermal compensation correction is still effective, the point-by-point thermal compensation correction coefficient is calculated according to the thermal compensation correction coefficient and the point-by-point correction coefficient and then is corrected at one time, the problem that the thermal compensation correction cannot achieve the expected effect due to the change of the module position of the LED display screen box body after the thermal compensation correction can be solved, and the correction efficiency is greatly improved.

Step 304: and calculating the point-by-point thermal compensation correction coefficient of the LED display screen box body according to the calculated point-by-point correction coefficient and the calculated thermal compensation correction coefficient.

The point-by-point correction coefficient and the thermal compensation correction coefficient of the LED display screen box body can be calculated in the steps 301 to 303 and are respectively stored in different positions, so that the effect of coefficient separation is achieved. Further, a control computer connected with the LED controller through a network sends the thermal compensation correction coefficient matrix to a receiving card of the LED controller through upper computer software of the LED controller, so that point-to-point coefficients of the thermal compensation correction coefficient matrix and the point-to-point correction coefficient matrix are multiplied to obtain a plurality of point-to-point thermal compensation correction coefficients, and therefore the point-to-point thermal compensation correction function is achieved through the point-to-point thermal compensation correction coefficients. The calculated point-by-point thermal compensation correction coefficient is irrelevant to the position of the module of the LED display screen box body, namely, the point-by-point thermal compensation correction coefficient is not changed along with the change of the position of the module, so that under the condition that the position of the module of the LED display screen box body is changed, the LED display screen box body can be corrected according to the calculated point-by-point thermal compensation correction coefficient, and the point-by-point thermal compensation correction function is realized. In the embodiment of the application, the thermal compensation correction coefficients originally contained in the point-by-point correction coefficients are separated, the thermal compensation correction coefficients and the point-by-point correction coefficients are respectively stored, the point-by-point thermal compensation correction coefficients are calculated according to the thermal compensation correction coefficients and the point-by-point correction coefficients and then are corrected at one time, the separately stored thermal compensation correction coefficients only need to be collected once for the LED display screen box bodies with the same structure and the same PCB layout, and the correction efficiency is greatly improved.

Step 305: and correcting the LED display screen box body according to the calculated point-by-point thermal compensation correction coefficient.

In accordance with step 202 described above.

Referring to fig. 4, fig. 4 is a schematic flow chart of another LED display screen calibration method according to an embodiment of the present application, where the method includes, but is not limited to, the following steps:

step 401: and calculating to obtain the point-by-point correction coefficient of the LED display screen box body according to the brightness and chrominance data of the LED display screen box body.

In accordance with step 301 described above.

Step 402: and collecting a first red brightness value matrix and a second red brightness value matrix of the LED display screen box body.

In the step, the camera is placed right in front of the LED display screen box body, so that the camera lens is right opposite to the central position of the display surface of the LED display screen box body, the focal length and the aperture of the camera lens are adjusted, and the LED display screen box body is positioned at the central position of the camera viewfinder. And adjusting the camera to enable the imaging of each pixel in the camera to be clearly visible, enabling the LED display screen box body to display red through the LED controller, and controlling the camera to acquire cold screen red brightness distribution data of each pixel as a first red brightness value matrix by the upper computer control software. Displaying the LED display screen box body with 100% brightness, and aging the LED display screen box body for about 30 minutes in a white state to enable the LED display screen box body to reach a thermal equilibrium state, wherein the thermal equilibrium state refers to the state that the thermal distribution of the LED display screen box body does not change any more and the highest temperature does not change any more, namely the LED display screen box body reaches the thermal equilibrium state; and then the LED display screen box body displays red through the LED controller, and the upper computer control software controls the camera to collect the hot screen red brightness distribution data of each pixel within a specified time to serve as a second red brightness value matrix. The collected first red brightness value matrix and the second red brightness value matrix can be used for calculating to obtain a thermal compensation correction coefficient of the LED sample box.

Step 403: and calculating according to the collected first red brightness value matrix and the second red brightness value matrix to obtain a thermal compensation correction coefficient of the LED display screen box body.

The first red brightness value matrix and the second red brightness value matrix of the LED display screen box body can be acquired in the above step 402, and the first red brightness value matrix and the second red brightness value matrix can be used for calculating to obtain a thermal compensation correction coefficient of the LED sample box. Specifically, the difference value between the red brightness value in the first red brightness value matrix and the red brightness value in the second red brightness value matrix can be calculated, and then the obtained difference value is divided by the maximum value of the difference values respectively to obtain the thermal compensation correction coefficient matrix of the LED display screen box body, wherein the thermal compensation correction coefficient matrix comprises a plurality of thermal compensation correction coefficients, the thermal compensation correction coefficients are only related to the mechanical structure of the LED display screen box body and do not change along with the change of the module position of the LED display screen box body, and only one collection is needed for a product of the same LED display screen box body, so that the time for each LED display screen box body to be corrected to reach a thermal balance state is greatly reduced, the operation is simple, and the efficiency is higher. The obtained point-by-point correction coefficient and the thermal compensation correction coefficient are respectively stored in different positions, so that the effect of coefficient separation is achieved.

Step 404: and calculating the point-by-point thermal compensation correction coefficient of the LED display screen box body according to the calculated point-by-point correction coefficient and the calculated thermal compensation correction coefficient.

In accordance with step 304 described above.

Step 405: and correcting the LED display screen box body according to the calculated point-by-point thermal compensation correction coefficient.

In accordance with step 305 described above.

The method of the embodiments of the present application is explained in detail above, and the apparatus of the embodiments of the present application is provided below.

Referring to fig. 5, fig. 5 is a schematic structural diagram of an LED display screen calibration apparatus 50 according to an embodiment of the present disclosure. The LED display screen correction device can comprise a calculation unit 501, a correction unit 502, an aging unit 503 and an acquisition unit 504, wherein the description of each unit is as follows:

the calculating unit 501 is configured to calculate a point-by-point thermal compensation correction coefficient according to the thermal compensation correction coefficient and the point-by-point correction coefficient of the LED display screen box; the thermal compensation correction coefficient is correlated with the mechanical structure of the LED display screen box body, the point-by-point correction coefficient is correlated with the module position of the LED display screen box body, and the point-by-point thermal compensation correction coefficient is correlated with the mechanical structure of the LED display screen box body;

and the correction unit 502 is used for correcting the LED display screen box body according to the point-by-point thermal compensation correction coefficient.

In the embodiment of the application, because the thermal compensation correction coefficient used by the original correction method is contained in the point-by-point correction coefficient, and the point-by-point correction coefficient is associated with the module position of the LED display screen box body, the thermal compensation correction coefficient is also associated with the module position of the LED display screen box body, namely, under the condition that the module position of the LED display screen box body is changed, the thermal compensation correction coefficient is influenced by the change of the module position, so that the thermal compensation correction can not achieve the expected effect, the embodiment of the application separates the thermal compensation correction coefficient originally contained in the point-by-point correction coefficient, respectively stores the thermal compensation correction coefficient and the point-by-point correction coefficient, calculates the point-by-point thermal compensation correction coefficient according to the thermal compensation correction coefficient and the point-by-point correction coefficient and then carries out one-time correction, thereby solving the problem that the thermal compensation correction can not achieve the expected effect due to the change of the module position of the LED display screen box body after the thermal compensation correction, and the separately stored thermal compensation correction coefficients only need to be acquired once for the LED display screen box body with the same structure and PCB layout, so that the correction efficiency is greatly improved.

In a possible implementation, the calculating unit 501 is specifically configured to multiply the thermal compensation correction coefficient and the point-by-point correction coefficient to obtain a point-by-point thermal compensation correction coefficient.

In the embodiment of the application, the thermal compensation correction coefficient and the point-by-point correction coefficient are respectively stored, and then the product of the thermal compensation correction coefficient and the point-by-point correction coefficient is calculated, so that the obtained point-by-point thermal compensation correction coefficient has relevance only with the mechanical structure of the LED display screen box body and is irrelevant with the module position of the LED display screen box body, and the thermal compensation correction is still effective even under the condition that the module position of the LED display screen box body is changed.

In yet another possible embodiment, the correction unit 502 is specifically configured to correct the LED display screen box according to the point-by-point thermal compensation correction coefficient when the module position of the LED display screen box changes.

In the embodiment of the present application, since the calculated point-by-point thermal compensation correction coefficient has a correlation only with the mechanical structure of the LED display screen box body, and is not related to the module position of the LED display screen box body, the thermal compensation correction is still effective even when the module position of the LED display screen box body is changed.

In another possible embodiment, the correcting unit 502 is further specifically configured to correct the LED display screen box by using a first point-by-point thermal compensation correction coefficient if the temperature of the LED display screen box is less than a first threshold; if the temperature of the LED display screen box body is larger than a second threshold value, correcting the LED display screen box body by utilizing a second point-by-point thermal compensation correction coefficient; if the temperature of the LED display screen box body is not less than the first threshold value and not more than the second threshold value, correcting the LED display screen box body by utilizing a third point-by-point thermal compensation correction coefficient; the first point-by-point thermal compensation correction coefficient, the second point-by-point thermal compensation correction coefficient and the third point-by-point thermal compensation correction coefficient are point-by-point thermal compensation correction coefficients with different values.

In the embodiment of the application, different point-by-point thermal compensation correction coefficients are adopted to correct the LED display screen box body according to different temperatures of the LED display screen box body. Because the thermal compensation correction coefficients of the LED display screen box body at different temperatures are different, and the product results of different thermal compensation correction coefficients and point-by-point correction coefficients also correspond to a plurality of different point-by-point thermal compensation correction coefficients, the temperature monitoring and point-by-point thermal compensation correction coefficients of the LED display screen box body can be associated, namely, a plurality of temperature thresholds, such as a first threshold, a second threshold and the like, are set, and when the temperature of the LED display screen box body is monitored to be lower than the first threshold, the LED display screen box body is corrected by using the first point-by-point thermal compensation correction coefficient; when the temperature of the LED display screen box body is monitored to be larger than a second threshold value, correcting the LED display screen box body by utilizing a second point-by-point thermal compensation correction coefficient; and when the temperature of the LED display screen box body is not less than the first threshold value and not more than the second threshold value, correcting the LED display screen box body by utilizing a third point-by-point thermal compensation correction coefficient. Therefore, the automatic point-by-point thermal compensation correction function of the LED display screen box body can be realized through the correction method.

In another possible embodiment, the correcting unit 502 is further configured to perform cold screen correction on the LED display screen box body to obtain a sample box, where the sample box is the LED display screen box body after the cold screen correction;

the aging unit 503 is configured to perform white light aging processing on the sample box until the sample box reaches a thermal equilibrium state, where the thermal equilibrium state is that the thermal distribution and the highest temperature of the sample box do not change any more;

the acquisition unit 504 is used for acquiring a red brightness value matrix of the sample box in a thermal equilibrium state;

the calculating unit 501 is further configured to calculate a thermal compensation correction coefficient matrix of the LED display screen box according to the red luminance value matrix, where the thermal compensation correction coefficient matrix includes thermal compensation correction coefficients.

In the embodiment of the application, a method for obtaining a thermal compensation correction coefficient is provided, the cold screen correction is performed on the LED display screen box body, then the white light aging treatment is performed until the thermal distribution and the highest temperature of the LED display screen box body do not change any more, then a red brightness value matrix of the LED display screen box body is collected, and the thermal compensation correction coefficient is obtained through calculation according to the collected red brightness value matrix. The thermal compensation correction coefficient obtained by the method has relevance with the mechanical structure of the LED display screen box body and is irrelevant with the module position of the LED display screen box body.

In yet another possible embodiment, the calculating unit 501 is further configured to divide the maximum value in the red luminance value matrix by the red luminance value matrix to obtain a thermal compensation correction coefficient matrix of the LED display panel box.

In the embodiment of the application, a method for calculating a thermal compensation correction coefficient matrix is provided, in which a maximum value in a collected red brightness value matrix of a sample box is divided by the red brightness value matrix to obtain the thermal compensation correction coefficient matrix, and the thermal compensation correction coefficient matrix includes thermal compensation correction coefficients of an LED display screen box body at different temperatures.

In another possible embodiment, the collecting unit 504 is further configured to collect a first red luminance value matrix and a second red luminance value matrix of the LED display screen box, where the first red luminance value matrix includes a red luminance value of the LED display screen box in a cold screen state, and the second red luminance value matrix includes a red luminance value of the LED display screen box in a thermal equilibrium state, where the thermal equilibrium state is that the thermal distribution and the maximum temperature of the LED display screen box do not change any more;

the calculating unit 501 is further configured to calculate a thermal compensation correction coefficient matrix of the LED display screen box according to the first red luminance value matrix and the second red luminance value matrix, where the thermal compensation correction coefficient matrix includes a thermal compensation correction coefficient.

In the embodiment of the application, the camera can be placed right in front of the LED display screen box body, so that the camera lens is right opposite to the central position of the display surface of the LED display screen box body, and the focal length and the aperture of the camera lens are adjusted to enable the LED display screen box body to be located at the central position of the camera viewfinder. Adjusting the camera to enable the imaging of each pixel in the camera to be clearly visible, enabling the LED display screen box body to display red through the LED controller, and controlling the camera to acquire cold screen red brightness distribution data (namely the first red brightness value matrix) of each pixel by the upper computer control software. The LED display screen box body is subjected to cold screen correction, then white light aging treatment is carried out to enable the LED display screen box body to reach a thermal equilibrium state, the LED display screen box body displays red through the LED controller, and the upper computer control software controls the camera to collect and finish hot screen red brightness distribution data (namely the second red brightness value matrix) of each pixel within a specified time. And then according to the collected first red brightness value matrix and the second red brightness value matrix, calculating to obtain a thermal compensation correction coefficient matrix of the LED display screen box body, wherein the thermal compensation correction coefficient matrix comprises thermal compensation correction coefficients. The thermal compensation correction coefficient obtained by the method has relevance with the mechanical structure of the LED display screen box body and is irrelevant with the module position of the LED display screen box body, and the product of the same LED display screen box body only needs to be collected once, so that the time for each LED display screen box body to be corrected to reach a thermal balance state is greatly reduced, the operation is simple, and the efficiency is higher.

In yet another possible embodiment, the calculating unit 501 is further configured to divide the difference between the red luminance value in the first red luminance value matrix and the red luminance value in the second red luminance value matrix by the maximum value of the difference, so as to obtain a thermal compensation correction coefficient matrix of the LED display screen box.

In the embodiment of the present application, a method for calculating a thermal compensation correction coefficient matrix is provided, where differences between red luminance values in a first red luminance value matrix and red luminance values in a second red luminance value matrix are calculated, and the obtained differences are respectively divided by a maximum value of the differences to obtain a thermal compensation correction coefficient matrix of an LED display screen box, where the thermal compensation correction coefficient matrix includes thermal compensation correction coefficients of the LED display screen box at different temperatures.

In yet another possible implementation, the collecting unit 504 is further configured to collect luminance and chrominance data of the LED display screen box;

the calculating unit 501 is further configured to calculate, according to the luminance and chrominance data of the LED display screen box, a point-by-point correction coefficient matrix of the LED display screen box, where the point-by-point correction coefficient matrix includes point-by-point correction coefficients.

In the embodiment of the application, a method for obtaining a point-by-point correction coefficient is provided, wherein luminance and chrominance data of an LED display screen box body are collected, a point-by-point correction coefficient matrix is obtained through calculation according to the luminance and chrominance data, the point-by-point correction coefficient matrix comprises point-by-point correction coefficients, and the point-by-point correction coefficients are associated with the position of a module of the LED display screen box body.

In yet another possible embodiment, the point-by-point correction coefficients and the thermal compensation correction coefficients are stored in different locations.

In the embodiment of the application, the point-by-point correction coefficient and the thermal compensation correction coefficient are stored separately, the point-by-point thermal compensation correction coefficient is calculated according to the thermal compensation correction coefficient and the point-by-point correction coefficient and then is corrected at one time, the problem that the thermal compensation correction cannot achieve the expected effect due to the change of the position of the module of the LED display screen box body after the thermal compensation correction can be solved, the separately stored thermal compensation correction coefficient only needs to be collected once for the LED display screen box body with the same structure and the same PCB layout, and the correction efficiency is greatly improved.

According to the embodiment of the present application, the units in the apparatus shown in fig. 5 may be respectively or entirely combined into one or several other units, or some unit(s) therein may be further split into multiple functionally smaller units to form the unit(s), which may achieve the same operation without affecting the achievement of the technical effect of the embodiment of the present application. The units are divided based on logic functions, and in practical application, the functions of one unit can be realized by a plurality of units, or the functions of a plurality of units can be realized by one unit. In other embodiments of the present application, the terminal-based terminal may also include other units, and in practical applications, these functions may also be implemented by being assisted by other units, and may be implemented by cooperation of multiple units.

It should be noted that the implementation of each unit may also correspond to the corresponding description of the method embodiments shown in fig. 2, fig. 3, and fig. 4.

In the LED display screen correction apparatus described in fig. 5, the thermal compensation correction coefficients originally included in the point-by-point correction coefficients are separated, the thermal compensation correction coefficients and the point-by-point correction coefficients are stored respectively, and the point-by-point thermal compensation correction coefficients are calculated according to the thermal compensation correction coefficients and the point-by-point correction coefficients and then corrected once, so that the problem that the thermal compensation correction cannot achieve the expected effect due to the change of the module position of the LED display screen box after the thermal compensation correction can be solved, and the separately stored thermal compensation correction coefficients only need to be collected once for the LED display screen box of the same structure and PCB layout, thereby greatly improving the correction efficiency.

Referring to fig. 6, fig. 6 is a schematic structural diagram of an LED display screen calibration apparatus 60 according to an embodiment of the present disclosure, where the LED display screen calibration apparatus 60 may include a memory 601 and a processor 602. Further optionally, a bus 603 may be included, wherein the memory 601 and the processor 602 are coupled via the bus 603.

The memory 601 is used to provide a storage space, and data such as an operating system and a computer program may be stored in the storage space. The memory 601 includes, but is not limited to, a Random Access Memory (RAM), a read-only memory (ROM), an erasable programmable read-only memory (EPROM), or a portable read-only memory (CD-ROM).

The processor 602 is a module for performing arithmetic operations and logical operations, and may be one or a combination of plural kinds of processing modules such as a Central Processing Unit (CPU), a Graphics Processing Unit (GPU), a microprocessor unit (MPU), or the like.

The memory 601 stores a computer program, and the processor 602 calls the computer program stored in the memory 601 to perform the following operations:

calculating to obtain a point-by-point thermal compensation correction coefficient according to the thermal compensation correction coefficient and the point-by-point correction coefficient of the LED display screen box body; the thermal compensation correction coefficient is correlated with the mechanical structure of the LED display screen box body, the point-by-point correction coefficient is correlated with the module position of the LED display screen box body, and the point-by-point thermal compensation correction coefficient is correlated with the mechanical structure of the LED display screen box body;

and correcting the LED display screen box body according to the point-by-point thermal compensation correction coefficient.

In the embodiment of the application, because the thermal compensation correction coefficient used by the original correction method is included in the point-by-point correction coefficient, and the point-by-point correction coefficient has a correlation with the module position of the LED display screen box body, the thermal compensation correction coefficient also has a correlation with the module position of the LED display screen box body, that is, under the condition that the module position of the LED display screen box body is changed, the thermal compensation correction coefficient is affected by the change of the module position, so that the thermal compensation correction cannot achieve the expected effect; according to the embodiment of the application, the thermal compensation correction coefficients originally contained in the point-by-point correction coefficients are separated, the thermal compensation correction coefficients and the point-by-point correction coefficients are stored respectively, and the point-by-point thermal compensation correction coefficients are calculated according to the thermal compensation correction coefficients and the point-by-point correction coefficients and then are corrected once, so that the problem that the thermal compensation correction cannot achieve the expected effect due to the change of the module position of the LED display screen box body after the thermal compensation correction is solved, the separately stored thermal compensation correction coefficients only need to be collected once for the LED display screen box body with the same structure and PCB layout, and the correction efficiency is greatly improved.

In a possible implementation manner, in terms of calculating the point-by-point thermal compensation correction coefficient according to the thermal compensation correction coefficient and the point-by-point correction coefficient of the LED display screen box, the processor 602 is specifically configured to: and multiplying the thermal compensation correction coefficient and the point-by-point correction coefficient to obtain the point-by-point thermal compensation correction coefficient.

In one possible embodiment, in terms of correcting the LED display screen box according to the point-by-point thermal compensation correction coefficient, the processor 602 is specifically configured to: and under the condition that the position of the module of the LED display screen box body is changed, correcting the LED display screen box body according to the point-by-point thermal compensation correction coefficient.

In one possible embodiment, in terms of correcting the LED display screen box according to the point-by-point thermal compensation correction coefficient, the processor 602 is specifically configured to: if the temperature of the LED display screen box body is smaller than a first threshold value, correcting the LED display screen box body by utilizing a first point-by-point thermal compensation correction coefficient; if the temperature of the LED display screen box body is larger than a second threshold value, correcting the LED display screen box body by utilizing a second point-by-point thermal compensation correction coefficient; if the temperature of the LED display screen box body is not less than the first threshold value and not more than the second threshold value, correcting the LED display screen box body by utilizing a third point-by-point thermal compensation correction coefficient; the first point-by-point thermal compensation correction coefficient, the second point-by-point thermal compensation correction coefficient and the third point-by-point thermal compensation correction coefficient are point-by-point thermal compensation correction coefficients with different values.

In a possible implementation, before calculating the point-by-point thermal compensation correction coefficient, the processor 602 is further specifically configured to: performing cold screen correction on the LED display screen box body to obtain a sample box, wherein the sample box is the LED display screen box body subjected to cold screen correction; carrying out white light aging treatment on the sample box until the sample box reaches a thermal equilibrium state, wherein the thermal equilibrium state is that the thermal distribution and the highest temperature of the sample box are not changed any more; collecting a red brightness value matrix of a sample box in a thermal equilibrium state; and calculating to obtain a thermal compensation correction coefficient matrix of the LED display screen box body according to the red brightness value matrix, wherein the thermal compensation correction coefficient matrix comprises thermal compensation correction coefficients.

In a possible implementation manner, in terms of calculating a thermal compensation correction coefficient matrix of the LED display screen box according to the red luminance value matrix, the processor 602 is specifically configured to: and dividing the maximum value in the red brightness value matrix by the red brightness value matrix to obtain a thermal compensation correction coefficient matrix of the LED display screen box body.

In one possible embodiment, before calculating the point-by-point thermal compensation correction coefficient, the processor 602 is specifically configured to: collecting a first red brightness value matrix and a second red brightness value matrix of the LED display screen box body, wherein the first red brightness value matrix comprises a red brightness value of the LED display screen box body in a cold screen state, the second red brightness value matrix comprises a red brightness value of the LED display screen box body in a heat balance state, and the heat balance state is that the heat distribution and the highest temperature of the LED display screen box body are not changed any more; and calculating to obtain a thermal compensation correction coefficient matrix of the LED display screen box body according to the first red brightness value matrix and the second red brightness value matrix, wherein the thermal compensation correction coefficient matrix comprises thermal compensation correction coefficients.

In a possible implementation manner, in terms of calculating a thermal compensation correction coefficient matrix of the LED display screen box according to the first red luminance value matrix and the second red luminance value matrix, the processor 602 is specifically configured to: and respectively dividing the difference value between the red brightness value in the first red brightness value matrix and the red brightness value in the second red brightness value matrix by the maximum value of the difference value to obtain a thermal compensation correction coefficient matrix of the LED display screen box body.

In one possible embodiment, before calculating the point-by-point thermal compensation correction coefficient, the processor 602 is specifically configured to: collecting brightness and chrominance data of the LED display screen box body; and calculating to obtain a point-by-point correction coefficient matrix of the LED display screen box body according to the brightness and chrominance data of the LED display screen box body, wherein the point-by-point correction coefficient matrix comprises point-by-point correction coefficients.

In one possible embodiment, the point-by-point correction coefficients and the thermal compensation correction coefficients are stored in different locations.

It should be noted that, the specific implementation of the LED display screen correction apparatus may also correspond to the corresponding description of the method embodiments shown in fig. 2, fig. 3 and fig. 4.

The LED display screen calibration apparatus 60 described in fig. 6 separates the thermal compensation calibration coefficients originally included in the point-by-point calibration coefficients, stores the thermal compensation calibration coefficients and the point-by-point calibration coefficients, calculates the point-by-point thermal compensation calibration coefficients according to the thermal compensation calibration coefficients and the point-by-point calibration coefficients, and then performs one-time calibration, so as to solve the problem that the thermal compensation calibration cannot achieve the desired effect due to the change of the module position of the LED display screen box after the thermal compensation calibration, and the separately stored thermal compensation calibration coefficients only need to be collected once for the LED display screen box of the same structure and PCB layout, thereby greatly improving the calibration efficiency.

The embodiment of the present application further provides a computer-readable storage medium, in which a computer program is stored, and when the computer program runs on one or more processors, the LED display screen correction method shown in fig. 2, 3, and 4 can be implemented.

The embodiment of the present application further provides a computer program product, which when running on a processor, can implement the LED display screen calibration method shown in fig. 2, fig. 3, and fig. 4.

In summary, by implementing the embodiment of the present application, the thermal compensation correction coefficients originally included in the point-by-point correction coefficients are separated, the thermal compensation correction coefficients and the point-by-point correction coefficients are respectively stored, and the point-by-point thermal compensation correction coefficients are calculated according to the thermal compensation correction coefficients and the point-by-point correction coefficients and then are corrected at a time, so that the problem that the thermal compensation correction cannot achieve the expected effect due to the change of the module position of the LED display screen box after the thermal compensation correction can be solved, and the separately stored thermal compensation correction coefficients only need to be collected once for the LED display screen box with the same structure and the same PCB layout, thereby greatly improving the correction efficiency.

One of ordinary skill in the art will appreciate that all or part of the processes in the methods of the above embodiments can be implemented by hardware associated with a computer program, which can be stored in a computer-readable storage medium, and when executed, can include the processes of the above method embodiments. And the aforementioned storage medium includes: various media that can store computer program code, such as a read-only memory ROM or a random access memory RAM, a magnetic disk, or an optical disk.

Claims (13)

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

calculating to obtain a point-by-point thermal compensation correction coefficient according to the thermal compensation correction coefficient and the point-by-point correction coefficient of the LED display screen box body; the thermal compensation correction coefficient is correlated with a mechanical structure of the LED display screen box body, the point-by-point correction coefficient is correlated with a module position of the LED display screen box body, and the point-by-point thermal compensation correction coefficient is correlated with the mechanical structure of the LED display screen box body;

and correcting the LED display screen box body according to the point-by-point thermal compensation correction coefficient.

2. The method of claim 1, wherein the calculating the point-by-point thermal compensation correction coefficient according to the thermal compensation correction coefficient and the point-by-point correction coefficient of the LED display screen box comprises:

and multiplying the thermal compensation correction coefficient and the point-by-point correction coefficient to obtain the point-by-point thermal compensation correction coefficient.

3. The method of claim 1 or 2, wherein the correcting the LED display screen box according to the point-by-point thermal compensation correction coefficient comprises:

and under the condition that the position of the module of the LED display screen box body is changed, correcting the LED display screen box body according to the point-by-point thermal compensation correction coefficient.

4. The method of claim 3, wherein the calibrating the LED display screen box according to the point-by-point thermal compensation calibration coefficient comprises:

if the temperature of the LED display screen box body is smaller than a first threshold value, correcting the LED display screen box body by utilizing a first point-by-point thermal compensation correction coefficient;

if the temperature of the LED display screen box body is larger than a second threshold value, correcting the LED display screen box body by utilizing a second point-by-point thermal compensation correction coefficient;

if the temperature of the LED display screen box body is not less than the first threshold value and not more than the second threshold value, correcting the LED display screen box body by utilizing a third point-by-point thermal compensation correction coefficient;

wherein the first point-by-point thermal compensation correction coefficient, the second point-by-point thermal compensation correction coefficient, and the third point-by-point thermal compensation correction coefficient are different values of the point-by-point thermal compensation correction coefficient.

5. The method of claim 1, wherein before the calculating obtains the point-by-point thermal compensation correction coefficient, the method further comprises:

performing cold screen correction on the LED display screen box body to obtain a sample box, wherein the sample box is the LED display screen box body subjected to cold screen correction;

carrying out white light aging treatment on the sample box until the sample box reaches a thermal equilibrium state, wherein the thermal equilibrium state is that the thermal distribution and the highest temperature of the sample box are not changed any more;

collecting a red brightness value matrix of the sample box in the thermal equilibrium state;

and calculating to obtain a thermal compensation correction coefficient matrix of the LED display screen box body according to the red brightness value matrix, wherein the thermal compensation correction coefficient matrix comprises the thermal compensation correction coefficient.

6. The method according to claim 5, wherein said calculating a thermal compensation correction coefficient matrix of the LED display screen box according to the red luminance value matrix comprises:

and dividing the maximum value in the red brightness value matrix by the red brightness value matrix to obtain the thermal compensation correction coefficient matrix of the LED display screen box body.

7. The method of claim 1, wherein before the calculating obtains the point-by-point thermal compensation correction coefficient, the method further comprises:

collecting a first red brightness value matrix and a second red brightness value matrix of the LED display screen box body, wherein the first red brightness value matrix comprises a red brightness value of the LED display screen box body in a cold screen state, the second red brightness value matrix comprises a red brightness value of the LED display screen box body in a heat balance state, and the heat balance state is that the heat distribution and the highest temperature of the LED display screen box body are not changed any more;

and calculating to obtain a thermal compensation correction coefficient matrix of the LED display screen box body according to the first red brightness value matrix and the second red brightness value matrix, wherein the thermal compensation correction coefficient matrix comprises the thermal compensation correction coefficient.

8. The method of claim 7, wherein the calculating a thermal compensation correction coefficient matrix of the LED display screen box according to the first red luminance value matrix and the second red luminance value matrix comprises:

and respectively dividing the difference value between the red brightness value in the first red brightness value matrix and the red brightness value in the second red brightness value matrix by the maximum value of the difference value to obtain the thermal compensation correction coefficient matrix of the LED display screen box body.

9. The method of claim 1, wherein before the calculating obtains the point-by-point thermal compensation correction coefficient, the method further comprises:

collecting brightness and chrominance data of the LED display screen box body;

and calculating to obtain a point-by-point correction coefficient matrix of the LED display screen box body according to the brightness data of the LED display screen box body, wherein the point-by-point correction coefficient matrix comprises the point-by-point correction coefficients.

10. The method of claim 1, wherein the point-by-point correction coefficients and the thermal compensation correction coefficients are stored in different locations.

11. A correcting device of an LED display screen is characterized by comprising:

the calculation unit is used for calculating a point-by-point thermal compensation correction coefficient according to the thermal compensation correction coefficient and the point-by-point correction coefficient of the LED display screen box body; the thermal compensation correction coefficient has relevance with a mechanical structure of the LED display screen box body and is irrelevant with a module position of the LED display screen box body, the point-by-point correction coefficient has relevance with the module position of the LED display screen box body, and the point-by-point thermal compensation correction coefficient has relevance with the mechanical structure of the LED display screen box body and is irrelevant with the module position of the LED display screen box body;

and the correction unit is used for correcting the LED display screen box body according to the point-by-point thermal compensation correction coefficient.

12. An electronic device, comprising: a processor and a memory, wherein the memory stores program instructions that, when executed by the processor, cause the processor to perform the method of any of claims 1 to 10.

13. A computer-readable storage medium, in which a computer program is stored which, when run on one or more processors, performs the method of any one of claims 1 to 10.

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