WO2018078813A1 - Correction system and correction method - Google Patents

Abstract

A correction system (1) generates correction data for correcting the display unevenness for a plurality of display panels (2). A signal source (11) in the correction system outputs a signal for displaying a reference image on a display panel. An imaging unit (12) captures the reference image displayed on the display panel to thereby create a captured image. A control unit (30) generates correction data for the display panel on the basis of the captured image. A storage unit (31) stores the correction data for the plurality of display panels. The control unit generates first correction data (D1) on the basis of the image captured with the reference image displayed on the display panel before correction and generates second correction data (ΔD) on the basis of the image captured with the reference image displayed on the display panel when the first correction data is applied. The control unit accumulates the second correction data for the plurality of display panels in the storage unit, carries out statistical processing based on the second correction data accumulated, and generates third correction data (Db).

Description

Correction system and correction method

The present invention relates to a correction system and a correction method for correcting display unevenness in a display panel.

Conventionally, a technique for correcting display unevenness such as brightness unevenness and color unevenness in a display image in a display device including a display panel such as a liquid crystal panel is known (for example, see Patent Document 1).

Patent Document 1 discloses a correction system for correcting display unevenness of a display panel. The correction system of Patent Literature 1 includes a signal source that supplies image data to the display panel, a camera that captures an image of the display area of the display panel, and a computer that generates correction data of the display panel based on the captured image. In the correction system of Patent Document 1, a volatile storage device such as a DRAM provided in the display device is used as a storage device for storing the correction data when the generation of correction data is repeated for one display device including a display panel. Used. As a result, the time for writing correction data and the time for deleting correction data per display device are reduced.

International Publication No. 2012/133890

It is an object of the present invention to provide a correction system and a correction method capable of efficiently generating correction data for correcting display unevenness for a plurality of display panels.

The correction system according to one embodiment of the present invention is a correction system that generates correction data for correcting display unevenness of a plurality of display panels. The correction system includes a signal source, an imaging unit, a control unit, and a storage unit. The signal source outputs a signal for displaying a predetermined reference image on the display panel. The imaging unit captures a reference image displayed on the display panel based on the signal and generates a captured image. The control unit generates correction data for the display panel based on the captured image. The storage unit stores correction data for a plurality of display panels. The control unit generates first correction data based on a captured image obtained by displaying a reference image on the display panel before correction. The control unit generates second correction data based on a captured image obtained by displaying the reference image on the display panel in a state where the first correction data is applied. The control unit accumulates second correction data for the plurality of display panels in the storage unit. The control unit performs statistical processing based on the accumulated second correction data to generate third correction data.

The correction method according to one embodiment of the present invention is a correction method for correcting display unevenness of the display panel. In this method, a reference image for detecting display unevenness is displayed on the display panel before correction, and a reference image displayed on the display panel is captured by an imaging device to generate a first captured image. Steps. The method includes a step of generating first correction data based on the first captured image, and a step of applying the first correction data to the display panel. The method includes a step of displaying the reference image on a display panel to which the first correction data is applied, and capturing the reference image displayed on the display panel to which the first correction data is applied. Generating two captured images. The method includes a step of generating second correction data based on the second captured image, and a step of storing the second correction data in a storage unit. The method includes the steps of accumulating second correction data for a plurality of display panels in the storage unit, and performing statistical processing based on the accumulated second correction data to generate third correction data. Including.

According to the correction system and the correction method according to the present invention, the third correction data is obtained by statistical processing based on the accumulated second correction data. Accordingly, it is possible to provide a correction system and a correction method that can efficiently generate correction data for correcting display unevenness for a plurality of display panels.

1 is a block diagram showing an overall configuration of a correction system according to a first embodiment. Block diagram showing the configuration of the PC in the correction system Flowchart for explaining the operation of the correction system according to the first embodiment. The figure for demonstrating the display nonuniformity of the display panel in a correction system Diagram for explaining characteristic variation of gamma characteristic in display panel Flowchart illustrating an example of unevenness correction data generation processing in the correction system The figure for demonstrating the area where the nonuniformity correction data is produced | generated in a correction system Flowchart showing unevenness correction data regeneration process in correction system Diagram for explaining statistical data in the correction system Flow chart showing processing for updating statistical data in unevenness correction data regeneration processing Flowchart showing offset data generation processing in correction system The figure for demonstrating the tendency of the histogram in the production | generation process of offset data Flowchart illustrating an example of unevenness correction data generation processing using offset data Flowchart showing an example of statistical processing in offset data generation processing The flowchart which shows the modification of the production | generation process of the unevenness correction data using offset data

Hereinafter, embodiments of a correction system and a correction method according to the present invention will be described with reference to the accompanying drawings. In addition, in each following embodiment, the same code | symbol is attached | subjected about the same component.

(Embodiment 1)
1. Configuration The configuration of the correction system according to the first embodiment will be described below.

1-1. System Configuration The overall configuration of the correction system according to the first embodiment will be described with reference to FIG. FIG. 1 is a block diagram showing the overall configuration of a correction system 1 according to this embodiment.

The correction system 1 according to the present embodiment includes a signal source 11, a camera 12, a PC (personal computer) 13, and a panel control circuit 14, as shown in FIG. The correction system 1 is a system that performs settings for correcting display unevenness of an image displayed on each display panel 2 at the time of manufacture and shipment of the plurality of display panels 2.

The display panel 2 is, for example, an open cell liquid crystal panel, and image display is controlled from the outside by a panel control circuit 14 or the like. The display panel 2 has a display area 2a for displaying an image by a plurality of pixels arranged in a matrix, for example. The display panel 2 includes a memory 21 such as an SPI (Serial Peripheral Interface) flash memory. For example, information unique to the display panel 2 is recorded in the memory 21.

The signal source 11 is a signal generation circuit that generates a video signal indicating an image (reference image) to be displayed on the display panel 2 to be processed by the correction system 1. For example, the signal source 11 outputs a video signal to the panel control circuit 14 under the control of the PC 13.

The camera 12 includes an imaging element such as a CCD or CMOS image sensor, and an imaging optical system such as a zoom lens and a focus lens. The camera 12 captures an image displayed on the display area 2a of the display panel 2 to be processed under the control of the PC 13, for example. The camera 12 generates imaging data indicating the captured image and outputs the generated imaging data to the PC 13. The camera 12 is an example of an imaging unit in the present embodiment.

PC 13 controls the operation of each part such as signal source 11 and camera 12 in correction system 1. The PC 13 is connected to the memory 21 of the display panel 2 via a predetermined interface circuit (not shown), for example, and writes various information to the memory 21. Details of the configuration of the PC 13 will be described later.

The panel control circuit 14 is a dedicated circuit for controlling the image display of the display panel 2 and includes, for example, a microcomputer. The panel control circuit 14 in the correction system 1 is connected between the signal source 11 and the display panel 2 to be processed, and controls image display on the display panel 2 based on the video signal from the signal source 11. At this time, the panel control circuit 14 can read and use various information from the memory 21 of the display panel 2.

The panel control circuit 14 in the correction system 1 may be omitted as appropriate when a similar control circuit is incorporated in the display panel 2. In addition, when the backlight of the display panel 2 is externally attached, the correction system 1 may include a backlight for connecting to the display panel 2 to be processed.

1-2. Configuration of PC Details of the configuration of the PC 13 in this embodiment will be described with reference to FIG. FIG. 2 is a block diagram showing the configuration of the PC 13 in the correction system 1.

As shown in FIG. 2, the PC 13 includes a PC control unit 30, a storage unit 31, a RAM 32, a ROM 33, a PC display unit 34, an operation unit 35, a device interface (I / F) 36, and a network interface. (I / F) 37.

The PC control unit 30 is composed of, for example, a CPU or MPU that realizes a predetermined function in cooperation with software, and controls the overall operation of the PC 13. The PC control unit 30 reads out data and programs stored in the storage unit 31 and performs various arithmetic processes to realize various functions. For example, the PC control unit 30 performs image analysis of a captured image indicated by the captured data, and generates information (unevenness correction data) for setting on the display panel 2. The PC control unit 30 is an example of a control unit in the present embodiment.

The PC control unit 30 may be a hardware circuit such as a dedicated electronic circuit or a reconfigurable electronic circuit designed to realize a predetermined function. The PC control unit 30 may be configured by various semiconductor integrated circuits such as a CPU, MPU, microcomputer, DSP, FPGA, and ASIC.

The storage unit 31 is a storage medium that stores programs and data necessary for realizing the functions of the PC 13. The storage unit 31 is configured by, for example, a hard disk (HDD) or a semiconductor storage device (SSD). The storage unit 31 stores, for example, statistical data Da and offset data Db (described later).

The RAM 32 is composed of a semiconductor device such as DRAM or SRAM, and temporarily stores data. The RAM 32 may function as a work area for the PC control unit 30. The RAM 32 stores, for example, imaging data and unevenness correction data.

The ROM 33 stores, for example, programs executed by the PC control unit 30 and fixed parameters.

The PC display unit 34 is composed of, for example, a liquid crystal display or an organic EL display. The PC display unit 34 displays various information such as a captured image indicated by the captured data.

The operation unit 35 is a user interface that is operated by the user. The operation unit 35 includes, for example, a keyboard, a touch pad, a touch panel, buttons, switches, and combinations thereof.

The device interface 36 is a circuit (module) for connecting other devices to the PC 13. The device interface 36 performs communication according to a predetermined communication standard. The predetermined standard includes, for example, USB, HDMI (registered trademark), IEEE 1395, WiFi, Bluetooth (registered trademark), and the like. The PC 13 is connected to, for example, the signal source 11 and the camera 12 via the device interface 36.

The network interface 37 is a circuit (module) for connecting the PC 13 to a communication network via a wireless or wired communication line. The network interface 37 performs communication conforming to a predetermined communication standard. The predetermined communication standard includes, for example, communication standards such as IEEE802.3 and IEEE802.11a / 11b / 11g / 11ac. The PC 13, the signal source 11, and the camera 12 may be connected via a network interface 37.

2. Operation The operation of the correction system 1 configured as described above will be described below.

2-1. Overall Operation The overall operation of the correction system 1 according to the present embodiment will be described with reference to FIGS. 3 and 4. FIG. 3 is a flowchart for explaining the operation of the correction system 1. FIG. 4 is a diagram for explaining display unevenness of the display panel 2 in the correction system 1.

The flowchart in FIG. 3 shows processing executed for each display panel 2 in the correction system 1. This flowchart is started in a state where the display panel 2 to be processed is connected to each part of the correction system 1 and installed. Each process according to this flowchart is executed by the PC 13.

First, the PC 13 of the correction system 1 (FIG. 1) controls the signal source 11, the camera 12, and the like to perform generation processing of unevenness correction data for the display panel 2 to be processed (S1). The unevenness correction data is data that is applied to correct display unevenness when the display panel 2 displays an image. 4A and 4B show display examples on the display panel 2 before and after application of the unevenness correction data D1 in step S1.

In the display example of FIG. 4A, display unevenness occurs in the display area 2a in a state where unevenness correction is not performed, that is, in a state where the unevenness correction data D1 is not applied. In the correction system 1, the camera 12 captures an image of the display area 2a as shown in FIG. 4A, and unevenness correction data D1 is generated in the PC 13 based on the captured image (S1). The display unevenness in the display panel 2 is improved from the state shown in FIG. 4A to the state shown in FIG. 4B, for example, by applying the unevenness correction data D1 generated in step S1. Details of the processing in step S1 will be described later.

3, next, the PC 13 determines whether or not further correction is necessary for the display panel 2 to which the generated unevenness correction data D1 is applied (S2). The determination in step S2 is performed, for example, with reference to a predetermined flag recorded in the storage unit 31 or the like by the PC control unit 30. The predetermined flag indicates, for example, that further correction is necessary when the value is true, and indicates that no further correction is necessary when the value is false. The value of the predetermined flag is set based on an instruction from the user input via the operation unit 35, for example. For example, in the display example of FIG. 4B, visible display unevenness remains on the display panel 2. For this reason, the user instructs the PC 13 to perform further correction, and the PC 13 to which the instruction is input sets a predetermined flag to true. On the other hand, if no visible display unevenness remains on the display panel 2, the user instructs the PC 13 not to perform further correction, and the PC 13 to which the instruction is input sets a predetermined flag to false. To do. If the predetermined flag is true, the PC 13 determines that further correction is necessary, and proceeds to “YES” in step S2. On the other hand, if the predetermined flag is false, the PC 13 determines that no further correction is necessary, and proceeds to “NO” in step S2.

If it is determined that further correction is necessary (YES in S2), the PC 13 again performs the unevenness correction data regeneration process for generating the unevenness correction data D2 on the display panel 2 to be processed (S3). . Details of the processing in step S3 will be described later. FIG. 4C shows a display example of the display panel 2 after application of the unevenness correction data D2 regenerated in step S3.

In the display example of FIG. 4C, the unevenness correction data D2 applied to the display panel 2 includes the unevenness correction data D1 generated in step S1 and additional correction data ΔD. The additional correction data ΔD is correction data added in step S3 due to excess or deficiency of the unevenness correction data D1 in step S1, and corresponds to the difference between the unevenness correction data D1 and D2 in steps S1 and S3. . According to the unevenness correction data D2 in step S3, as shown in FIG. 4C, the display unevenness of the display panel 2 is further improved by the additional correction data ΔD from the state shown in FIG. For example, it is eliminated to a practically acceptable range.

Returning to FIG. 3, the PC 13 completes the process of this flowchart for the display panel 2 to be processed by executing the process of step S3.

On the other hand, if the PC 13 determines that further correction is not necessary after step S1 (NO in S2), the process according to this flowchart is terminated without performing the unevenness correction data regeneration process in step S3.

3. When the correction system 1 completes the process according to the flowchart of FIG. 3 for one display panel 2, the next display panel 2 is sequentially used as the display panel 2 to be processed, and the same process is executed.

According to the above processing, for one display panel 2, generation of unevenness correction data D1 and D2 twice in steps S1 and S3 (YES in S2), or generation of unevenness correction data D1 once in step S1. (NO in S2) is performed. By repeating the processing according to the flowchart of FIG. 3 for a plurality of display panels 2, unevenness correction data for each display panel 2 is generated.

2-2. Outline of Operation The outline of the operation of the correction system 1 according to the present embodiment will be described with reference to FIGS. FIG. 5 is a diagram for explaining variations in gamma characteristics (hereinafter also referred to as “characteristic variations”) in the display panel 2.

4A to 4C illustrate a case where the unevenness correction data D1 and D2 are generated twice for one display panel 2 (YES in S2). In the example of FIGS. 4A to 4C, display unevenness remains as shown in FIG. 4B after application of the unevenness correction data D1 generated in step S1. Such a situation occurs, for example, as described below, because the gamma characteristic in the display panel 2 varies within the display region 2a (FIGS. 5A and 5B).

FIG. 5A shows the first and second positions P1 and P2 having different gamma characteristics in the display panel 2 (FIG. 4B). FIG. 5B is a graph showing a characteristic curve of the gamma characteristic in the display panel 2. In FIG. 5B, the vertical axis represents the luminance for each pixel, and the horizontal axis represents the input value indicating the gradation.

FIG. 5B shows the first and second characteristic curves 41 and 42 showing two different gamma characteristics. As shown in FIG. 5A, the gamma characteristic of the display panel 2 follows the first characteristic curve 41 at the first position P1 and follows the second characteristic curve 42 at the second position P2. Variations in characteristics occur.

3, unevenness correction data D1 is generated based on, for example, the gamma characteristic of the first characteristic curve 41. For this reason, when the unevenness correction data D1 generated in step S1 is applied to the display panel 2, the display unevenness at the first position P1 is appropriately corrected, while the second position P2 corresponds to the deviation of the gamma characteristic. As a result, excessive or insufficient unevenness correction occurs. For example, if a work process for measuring the gamma characteristics of each region for each display panel 2 is employed for such a variation in the characteristics of the gamma characteristics, an enormous amount of time is spent and the production efficiency of the display panel 2 is significantly reduced. End up.

Therefore, in the correction system 1 according to the present embodiment, for example, in the initial stage of system operation, the unevenness correction data D1 and D2 are generated twice for the display panel 2 to be processed (YES in S2). At this time, information indicating the additional correction data ΔD is accumulated in the statistical data Da (FIG. 2) (S3). Further, the PC 13 of the correction system 1 generates and updates offset data Db that is correction data for canceling the characteristic variation in the display area 2a by statistical processing based on the accumulated statistical data Da (see FIG. 11).

In the statistical process, the variation of the gamma characteristic in the display area 2a is predicted according to the tendency of the excess / deficiency of the unevenness correction data D1 across a large number of display panels 2, and as a result of the prediction, offset data Db is generated. The offset data Db can improve the efficiency of processing in the correction system 1. For example, by using the generated offset data Db for the subsequent processing of step S1, it is possible to perform unevenness correction corresponding to the characteristic variation of the gamma characteristic from step S1.

In this embodiment, based on the update status of the offset data Db, the subsequent generation of the unevenness correction data D2 for the display panel 2 is omitted (NO in S2). Thereby, the efficiency which shortens the work process time in the correction | amendment system 1 can be performed. Hereinafter, details of the operation of the correction system 1 according to the present embodiment will be described.

2-3. Generation Process of Unevenness Correction Data (Initial Stage) An example of the unevenness correction data generation process in step S1 of FIG. 3 will be described. Hereinafter, details of the process of step S1 in the initial stage (before setting of the offset data Db) will be described with reference to FIGS.

FIG. 6 is a flowchart showing an example of unevenness correction data generation processing in the correction system 1. FIG. 7 is a diagram for explaining a section where unevenness correction data is generated.

6 is executed in a state before the offset data Db is set, for example, all the offset data Db recorded in the storage unit 31 is the initial value “0”. The processing according to this flowchart is executed by the PC control unit 30 of the PC 13.

First, the PC control unit 30 selects a reference image to be displayed on the display panel 2 to be processed (S11). The reference image is an image serving as a reference for detecting display unevenness in the correction system 1, and is, for example, an image in which all pixels are set to a predetermined reference gradation of gray scale. In the present embodiment, a plurality of reference images having different reference gradations are used. A plurality of reference gradations are set in the intermediate gradation, such as gradation values 100 and 200 in 256 gradations.

In step S11, the PC control unit 30 selects one of the plurality of reference gradations and transmits an instruction to display a reference image corresponding to the selected reference gradation to the signal source 11 (FIG. 1). The signal source 11 generates a video signal of the reference image indicated by the received instruction, and outputs it to the panel control circuit 14. The panel control circuit 14 refers to the information stored in the memory 21 of the display panel 2 to be processed, and controls the display panel 2 to display the reference image based on the video signal from the signal source 11. The memory 21 stores an initial value “0” of correction data in advance. Therefore, in step S11, the reference image is displayed in the display area 2a of the display panel 2 without particularly correcting the display unevenness (see FIG. 4A).

Next, the PC control unit 30 controls, for example, an imaging operation in which the camera 12 captures a reference image displayed on the display panel 2, and acquires imaging data indicating a captured image obtained by capturing the reference image from the camera 12. (S12).

Next, the PC control unit 30 determines whether all the reference images have been selected (S13). If all the reference images have not been selected (NO in S13), an unselected reference image is selected, and the processes after step S11 are repeated. Thereby, imaging data of all reference images is acquired.

When all the reference images are selected (YES in S13), the PC control unit 30 generates unevenness correction data D1 for each of the plurality of reference gradations based on the imaging data of each reference image (S14). The unevenness correction data D1 generated in step S14 is an example of first correction data in the present embodiment. A section in the display area 2a for generating the unevenness correction data D1 will be described with reference to FIG.

FIG. 7 shows an arrangement of a plurality of sections Ra in the display area 2a of the display panel 2. As shown in FIG. 7, the plurality of sections Ra divide the display area 2a into a matrix. Hereinafter, the row direction of the matrix in the display area 2a is defined as the X direction, and the column direction is defined as the Y direction.

The unevenness correction data D1 includes a plurality of correction values assigned to each section Ra. The section Ra is an area including a predetermined number of pixels in the display area 2a of the display panel 2. The section Ra includes, for example, 8 × 8 pixels as illustrated in FIG. The same correction value is assigned to the pixels in one section Ra. Each section Ra in the display area 2a is identified by coordinates (X, Y) within a predetermined range such as X = 0 to 479 and Y = 0 to 269.

In step S14 of FIG. 6, the PC control unit 30 first extracts the luminance of the reference gradation in the captured image from the luminance distribution of the display area in the captured image indicated by the captured data based on the captured data of the specific reference image. To do. The PC control unit 30 detects, for each section Ra, an area having a luminance shifted from the luminance of the extracted reference gradation, a luminance shift width, and the like on the display region 2a in the captured image. Based on a characteristic curve of a predetermined gamma characteristic (for example, the first characteristic curve 41 in FIG. 5A), the PC control unit 30 adjusts the gradation value so as to correct the detected deviation width for each section Ra. An arithmetic process for calculating a correction value is performed. The PC control unit 30 performs the above processing for each captured image data of the reference image, and generates unevenness correction data D1 for each reference gradation.

Next, the PC control unit 30 sets the generated unevenness correction data D1 on the display panel 2 (S15). In step S15, the PC control unit 30 first converts the generated unevenness correction data D1 into a predetermined format. The predetermined format is a format for the panel control circuit 14 to correct display unevenness, and is represented by, for example, a parameter of an arithmetic expression for performing correction according to the correction value. Next, the PC control unit 30 writes the converted information of the unevenness correction data D1 in the memory 21 of the display panel 2.

The PC control unit 30 finishes step S1 of FIG. 3 by performing the process of step S15, and proceeds to step S2.

According to the above processing, unevenness correction data D1 for correcting display unevenness specific to the display panel 2 to be processed is generated (S14), and information indicating the generated unevenness correction data D1 is stored in the memory 21 of the display panel 2. (S15). Thereby, it is possible to perform correction for reducing display unevenness unique to the display panel 2 using the information recorded in the memory 21.

In the above processing, unevenness correction data D1 is generated for a plurality of reference gradations. During display operation of the display panel 2, display unevenness correction is performed by appropriately interpolating the unevenness correction data D <b> 1 for a plurality of reference gradations with respect to a gradation different from the reference gradation.

2-4. Unevenness Correction Data Regeneration Processing Details of the unevenness correction data regeneration processing in step S3 of FIG. 3 will be described with reference to FIG. FIG. 8 is a flowchart showing the non-uniformity correction data regeneration process in the correction system 1.

8 is started in a state in which the unevenness correction data D1 generated in step S1 of FIG. 3 is set on the display panel 2 to be processed (see S15 of FIG. 6). Each process according to this flowchart is executed by the PC control unit 30.

In the flowchart of FIG. 8, the PC control unit 30 executes steps S21 to S23 in the same manner as steps S11 to S13 of FIG. At this time, the panel control circuit 14 (FIG. 1) reads the information recorded in the memory 21 of the display panel 2 in step S21, and displays the reference image corrected by the unevenness correction data D1 on the display panel 2 (FIG. 4). (See (b)).

Next, the PC control unit 30 regenerates the unevenness correction data D2 and updates the statistical data Da instead of step S14 of FIG. 6 (S24). The statistical data Da is data that statistically accumulates information related to the additional correction data ΔD in the unevenness correction data D2 regenerated in each of the display panels 2 to be processed. Details of the processing in step S24 will be described later.

Next, the PC control unit 30 sets the regenerated unevenness correction data D2 on the display panel 2 (S25). Specifically, the PC control unit 30 converts the regenerated unevenness correction data D2 into a format similar to that in step S15 in FIG. 6, and information (first time) written in the memory 21 in advance by the converted unevenness correction data D2. The unevenness correction data D1) is overwritten.

The PC control unit 30 ends the process of step S3 in FIG. 3 by executing the process of step S25.

According to the above processing, the second unevenness correction data D2 is regenerated for the display panel 2 to be processed, and the correction data for the additional portion from the first unevenness correction data D1 in the second unevenness correction data D2. Based on ΔD, the statistical data Da is updated (S24).

2-4-1. Statistical Data The statistical data Da updated in the above process will be described with reference to FIG. FIG. 9 is a diagram for explaining the statistical data Da in the correction system 1.

FIG. 9A shows a three-dimensional array variable H (X, Y, V) in the statistical data Da. As shown in FIG. 9A, the statistical data Da includes a three-dimensional array variable H (X, Y, V) with subscripts X, Y, and V. In the three-dimensional array variable H (X, Y, V), the subscripts X and Y represent the coordinates of the section Ra, for example, X = 0 to 479 and Y = 0 to 269. The subscript V represents a correction value assigned to a specific section Ra in the additional correction data ΔD, and is set within a predetermined range (for example, V = −5 to 5). The statistical data Da includes, for example, three-dimensional array variables H (X, Y, V) for the number of reference gradations.

The three-dimensional array variable H (X, Y, V) stores the number of times the correction value V is assigned to the partition Ra of the coordinates (X, Y) in the additional correction data ΔD for each of the plurality of display panels 2. It is a variable to do. The initial value of each of the three-dimensional array variables H (X, Y, V) is set to “0”, and is incremented each time data of each (X, Y, V) set appears.

FIG. 9B shows a histogram Hist (X, Y) in the statistical data Da. In FIG. 9B, the horizontal axis is the correction value V, and the vertical axis is the value of the three-dimensional array variable H (X, Y, V) for each correction value V. Each (X, Y) component in the three-dimensional array variable H (X, Y, V) of the statistical data Da constitutes a histogram Hist (X, Y) as shown in FIG. 9B. According to the histogram Hist (X, Y), in the additional correction data ΔD (= D2−D1) for each of the plurality of display panels 2 to which the two-time unevenness correction data D1 and D2 are applied, specific coordinates (X , Y), the statistical distribution of the correction value V assigned to the section Ra is accumulated.

In step S24 of FIG. 8, the PC control unit 30 regenerates the unevenness correction data D2 for the display panel 2 to be processed, based on the correction value V for each section Ra of the additional correction data ΔD. Each histogram Hist (X, Y) is updated. The statistical data Da accumulates a statistical distribution related to the additional correction data ΔD of the plurality of display panels 2 for each section Ra by the histogram Hist (X, Y) of each coordinate (X, Y).

2-4-2. Processing at Step S24 Details of the processing at Step S24 in FIG. 8 will be described with reference to FIG. FIG. 10 is a flowchart showing a process (S24 in FIG. 8) for updating the statistical data in the unevenness correction data regenerating process (S3 in FIG. 3).

First, the PC control unit 30 selects one of the imaging data of the reference image captured in step S22 of FIG. 8 (S31).

Next, the PC control unit 30 generates additional correction data ΔD based on the imaging data of the selected reference image (S32). Since the first unevenness correction data D1 is applied to the display panel 2 in the captured image indicated by the selected captured data, the PC control unit 30 performs, for example, the same arithmetic processing as step S14 in FIG. Thus, additional correction data ΔD is generated. The additional correction data ΔD is an example of second correction data in the present embodiment.

Next, the PC control unit 30 selects one of the sections Ra (FIG. 7) in the generated additional correction data ΔD in order from, for example, coordinates (X, Y) = (0, 0) (S33). . This process is a process for updating the statistical data Da and generating the second unevenness correction data D2 as follows for each section Ra of the generated additional correction data ΔD.

Next, the PC control unit 30 determines that the correction value V is assigned to the section Ra in the processing target display panel 2 based on the correction value V of the selected section Ra in the generated additional correction data ΔD. Is stored in the statistical data Da (S34).

Specifically, in step S34, the PC control unit 30 uses the three-dimensional array variable H (X (X) corresponding to the coordinate (X, Y) and the correction value V of the selected section Ra in the statistical data Da recorded in the storage unit 31. , Y, V) (FIG. 9A) is incremented. For example, when the correction value V of the section Ra of the coordinates (0, 0) is “2”, the PC control unit 30 sets “1” to the value of the corresponding three-dimensional array variable H (0, 0, 2). Is added. As a result, the histogram Hist (0, 0) at the coordinates (0, 0) is updated in the statistical data Da.

Next, the PC control unit 30 regenerates the unevenness correction data D2 unique to the processing target display panel 2 for the selected section Ra (S35). For example, the PC control unit 30 adds the correction value V in the additional correction data ΔD to the correction value in the first unevenness correction data D1 recorded in advance in the storage unit 31 for the selected section Ra, and performs processing. A correction value of unevenness correction data D2 for overwriting the target display panel 2 is calculated.

Next, the PC control unit 30 determines whether all the sections Ra have been selected (S36). If all the sections Ra have not been selected (NO in S36), the PC control unit 30 returns to step S33, selects one of the unselected sections Ra, and performs the processes in and after step S33. Thereby, the update of the statistical data Da (S34) and the regeneration of the unevenness correction data D2 (S35) are performed for each section Ra.

When all the sections Ra are selected (YES in S36), the PC control unit 30 determines whether or not all of the imaging data of the reference image captured in step S21 of FIG. 8 has been selected (S37). If all of the imaging data of the reference image has not been selected (NO in S37), the PC control unit 30 returns to step S31, selects one of the imaging data of the unselected reference image, and the steps after step S31. Process. Thereby, in each reference gradation, the statistical data Da is updated and the unevenness correction data D2 is regenerated.

If all the imaging data of the reference image has been selected (YES in S37), the PC control unit 30 ends the process of step S24 in FIG. 8 and proceeds to the process of step S25.

According to the above process, when the process of step S24 is performed on one display panel 2, the coordinates (in the statistical data Da) are determined based on the correction value V of each section Ra in the additional correction data ΔD. The histogram Hist (X, Y) for each X, Y) is updated (S34). Thereby, the statistical data Da is accumulated including the tendency of the additional correction data ΔD over the plurality of display panels 2.

Further, every time each histogram Hist (X, Y) is updated, the correction value of the unevenness correction data D2 unique to the display panel 2 to be processed is calculated (S35). As a result, second-time unevenness correction data D2 for the display panel 2 to be processed is generated in step S24 of FIG. 8, and information in the memory 21 unique to the display panel 2 can be overwritten in step S25.

2-5. Offset Data Generation Processing In the correction system 1 according to the present embodiment, offset data generation processing for generating and updating offset data Db based on the statistical data Da accumulated as described above is executed. The offset data generation process will be described with reference to FIGS.

FIG. 11 is a flowchart showing offset data generation processing in the correction system 1. FIG. 12 is a diagram for explaining the tendency of the histogram Hist (X, Y) in the offset data generation process.

The offset data Db is correction data for canceling the characteristic variation in the display area 2a, and includes an offset value for each section Ra dividing the display area 2a. The offset data Db is an example of third correction data in the present embodiment. The offset data Db is recorded as a data table in which the offset value and the section Ra are associated with each other, for example, in the storage unit 31. For example, in the initial stage, all the offset values in the data table are set to the initial value “0”.

11 is started when statistical data Da for a predetermined number of display panels 2 is accumulated. The predetermined number is a number that is assumed to be a statistically sufficient number of samples, for example, 1000. The process according to this flowchart is executed by the PC control unit 30.

First, the PC control unit 30 selects one of a plurality of reference gradations corresponding to a plurality of reference images used in generating the unevenness correction data D1 and D2 (S41).

Next, the PC control unit 30 selects one of the sections Ra (FIG. 7) in order from, for example, coordinates (X, Y) = (0, 0) (S42).

Next, the PC control unit 30 refers to the statistical data Da recorded in the storage unit 31, and based on the histogram Hist (X, Y) at the coordinates (X, Y) of the selected section Ra, the offset data Db Statistical processing for generating an offset value is performed (S43). Statistical processing based on the histogram Hist (X, Y) will be described with reference to FIGS.

FIG. 12A illustrates a histogram Hist (X, Y) in an ideal case. According to the histogram Hist (X, Y) in FIG. 12A, the correction value V for the additional part is “0” in many display panels 2. In the section Ra having such a histogram Hist (X, Y), it is not necessary to perform additional correction using the offset data Db. Accordingly, in the statistical processing in step S43, an offset value “0” is generated based on the histogram Hist (X, Y) in FIG.

FIG. 12B illustrates a histogram Hist (X, Y) when a remarkable tendency is observed. According to the histogram Hist (X, Y) of FIG. 12B, the additional correction value V is distributed with a peak value of “2” in many display panels 2. When a remarkable tendency is seen in this way, it is predicted that the same additional correction (for example, correction value “2”) is required in the display panel 2 to be processed in the future. Therefore, in the statistical processing in step S43, the PC control unit 30 determines whether or not a statistically significant tendency is seen in the histogram Hist (X, Y), and is remarkable as shown in FIG. If there is a tendency, an offset value “2” corresponding to the tendency is generated.

FIG. 12C illustrates a histogram Hist (X, Y) when no remarkable tendency is observed. According to the histogram Hist (X, Y) in FIG. 12C, the additional correction value V is distributed among the plurality of display panels 2 without any particular bias. When a remarkable tendency is not seen in this way, it is considered that the correction value of the necessary additional correction is not particularly predicted in the display panel 2 to be processed in the future. Therefore, if the PC control unit 30 determines that there is no statistically significant tendency in the histogram Hist (X, Y) as in 12 (c), for example, the PC control unit 30 generates an offset value “0”. Details of the statistical processing in step S43 as described above will be described later.

11, next, the PC control unit 30 updates the offset data Db recorded in the storage unit 31 based on the offset value generated by the statistical processing (S44). In step S44, the PC control unit 30 sets the offset value generated by the statistical processing to the offset value of the selected partition Ra (for example, (X, Y) = (0, 0)) in the offset data Db in the storage unit 31. Is added.

Next, the PC control unit 30 determines whether all the sections Ra have been selected (S45). When all the sections Ra have not been selected (NO in S45), the PC control unit 30 returns to step S42, selects one of the unselected sections Ra, and performs the processing from step S42. Thereby, the offset data Db with respect to the unevenness correction data D1 in the specific reference gradation is updated for each section Ra.

When all the sections Ra are selected (YES in S45), the PC control unit 30 determines whether all the reference gradations are selected (S46). If all the reference gradations have not been selected (NO in S46), the PC control unit 30 returns to step S41, selects one of the unselected reference gradations, and performs the processing from step S41. Thereby, the offset data Db is updated at each reference gradation.

When all the reference gradations are selected (YES in S46), the PC control unit 30 changes the offset data before and after the update based on each reference gradation and all the offset values generated in each section Ra. It is determined whether or not there is (S47). For example, if all the offset values generated in step S43 are “0”, the PC control unit 30 proceeds to “NO” in step S47.

If the PC control unit 30 determines that there is no change in the offset data Db before and after the update (NO in S47), for example, the PC display unit 34 generates a predetermined alert (S48). The predetermined alert is an alert for notifying the user that the offset data Db has not been changed based on the accumulated statistical data Da.

The PC control unit 30 generates an alert (S48), and ends the processing according to this flowchart.

If the PC control unit 30 determines that there is a change in the offset data Db before and after the update (YES in S47), for example, the accumulated statistical data Da is reset, and the processing according to this flowchart ends.

According to the above processing, offset data Db having an offset value for each section Ra is generated based on the histogram Hist (X, Y) accumulated for each coordinate (X, Y) in the statistical data Da.

2-5-1. 3. Unevenness correction data generation process (S1) using offset data In the correction system 1 according to the present embodiment, the offset data Db generated as described above is used, and the processing target of the flowchart of FIG. The unevenness correction data generation process (S 1) is performed on the display panel 2. FIG. 13 illustrates the processing in step S1 when the offset data Db is used.

In the flowchart of FIG. 13, the PC control unit 30 performs the processing of steps S11 to S14 as in FIG. Thereby, in step S14, the unevenness correction data D1 is generated, for example, by a calculation process based on a characteristic curve of a predetermined gamma characteristic.

Next, the PC control unit 30 refers to the offset data Db recorded in the storage unit 31, and adds the offset data Db to the generated unevenness correction data D1 (S14B). Specifically, the PC control unit 30 adds the offset value in the offset data Db to the correction value in the unevenness correction data D1 for each section Ra. Thereby, in the subsequent step S15, the information written on the display panel 2 is information representing data obtained by adding the unevenness correction data D1 generated in step S14 and the offset data Db. Note that the arithmetic processing of steps S14 and S14B may be performed simultaneously.

Through the above processing, the unevenness correction data D1 and the offset data Db generated in step S14 are applied to the display panel 2 to be processed by the correction system 1 after the offset data Db is generated, and the display panel 2 is applied. The unevenness correction can be performed. Thereby, the characteristic variation in the display area 2a can be dealt with by the offset data Db from the time of step S1 in FIG.

In the subsequent processing of step S3, additional correction data ΔD information necessary in a state where the offset data Db recorded in the storage unit 31 is applied is accumulated in the statistical data Da. Based on such statistical data Da, the offset data Db is sequentially updated by further executing the processing of FIG.

If no change occurs before and after the update of the offset data Db as described above, it is considered that the offset data Db is statistically stable. According to such offset data Db, it is expected that the characteristic variation in the display area 2a can be corrected with high accuracy. In this embodiment, an alert is generated in such a case (S48 in FIG. 11). This prompts the user to determine whether or not to switch to an operation (NO in S2 in FIG. 3) that omits the generation of the second unevenness correction data D2.

2-5-2. About the statistical process of step S43 An example is demonstrated about the detail of the statistical process of step S43 of FIG. 11 using FIG. FIG. 14 is a flowchart showing an example of statistical processing (S43) in the offset data generation processing (FIG. 11).

First, the PC control unit 30 refers to the statistical data Da recorded in the storage unit 31, and the histogram Hist (X, Y) of the coordinates (X, Y) corresponding to the section Ra selected in step S42 in FIG. The standard deviation at is calculated (S51).

Next, the PC control unit 30 determines whether or not the calculated standard deviation is within a predetermined range (S52). The predetermined range is a range representing a standard deviation standard when there is a statistically significant tendency in the histogram Hist (X, Y), and is specified by the user, for example. For example, in step S52, the PC control unit 30 proceeds to “YES” in the case of FIGS. 12A and 12B, and proceeds to “NO” in the case of FIG. 12C.

When determining that the standard deviation is within the predetermined range (YES in S52), the PC control unit 30 extracts, for example, the median value in the histogram Hist (X, Y) as the offset value in the selected section Ra of the offset data Db. (S53).

On the other hand, when determining that the standard deviation is not within the predetermined range (NO in S52), the PC control unit 30 determines the offset value in the selected section Ra of the offset data Db to be “0” (S54).

The PC control unit 30 executes the process of step S53 or step S54, thereby ending the process of step S43 in FIG. 11 and proceeds to the process of step S44.

According to the above processing, the correction value V assigned to a specific section Ra (for example, (X, Y) = (0, 0)) by the predetermined number (for example, 1000) of display panels 2 in the additional correction data ΔD. Based on the statistical tendency, an offset value in the partition Ra is generated.

In the above description, the standard deviation is used in steps S51 and S52. However, the present invention is not limited to this. For example, an average deviation may be used, or a deviation regarding a specific sample may be used.

In the above description, the median value of the histogram H (X, Y) is extracted as the offset value in step S53. Not only the median value of the histogram H (X, Y), but the median value of a predetermined interval (for example, an interval corresponding to a standard deviation including a larger number of samples) in the histogram H (X, Y) may be used. A mode value, an average value, or the like may be used. The average value may be calculated for a sample after a predetermined filtering process, for example. In addition, the median value of deviations for each sample of the histogram H (X, Y) may be used.

3. Summary As described above, the correction system 1 according to the present embodiment generates unevenness correction data D1 and D2 for correcting display unevenness of a plurality of display panels 2. The correction system 1 includes a signal source 11, a camera 12, a PC control unit 30, and a storage unit 31. The signal source 11 outputs a video signal for displaying a predetermined reference image on the display panel 2. The camera 12 captures a reference image displayed on the display panel 2 based on the video signal and generates a captured image. The PC control unit 30 generates unevenness correction data D1 and D2 for the display panel 2 based on the captured image. The storage unit 31 stores statistical data Da and offset data Db including additional correction data ΔD for the plurality of display panels 2. The PC control unit 30 generates unevenness correction data D1 based on the captured image obtained by displaying the reference image on the display panel 2 before correction (S14), and the display panel in a state where the unevenness correction data D1 is applied. Based on the captured image obtained by displaying the reference image in FIG. 2, additional correction data ΔD is generated (S <b> 32). The PC control unit 30 accumulates additional correction data ΔD for the plurality of display panels 2 in the storage unit 31 (S34), performs statistical processing (S43) based on the accumulated additional correction data ΔD, and performs offset data Db is generated.

According to the correction system 1 described above, the offset data Db is obtained by the statistical processing (S43) based on the accumulated correction data ΔD for the added amount. Accordingly, it is possible to provide the correction system 1 that can efficiently generate the unevenness correction data D1 for correcting display unevenness for the display panel 2 to be processed later using the offset data Db.

In this embodiment, the PC control unit 30 applies the unevenness correction data D1 and the offset data Db to the display panel 2 before correction, and corrects the display unevenness of the display panel 2 (S14B, S15). Thereby, the statistical tendency of the display panel 2 can be given as an offset, and the display unevenness of the display panel 2 can be corrected.

In this embodiment, the PC control unit 30 applies the unevenness correction data D1 and the offset data Db to the display panel 2 before correction (S14B, S15), thereby correcting display unevenness for the display panel 2. Is completed (NO in S2). As a result, the unevenness correction data regeneration process (S2) can be omitted, and the working time can be shortened.

In the present embodiment, the PC control unit 30 generates unevenness correction data D1, D2 or offset data Db for each divided section Ra of the display area 2a of the display panel 2. The storage unit 31 accumulates additional correction data ΔD for each section Ra (S33 to S36). As a result, the statistical data Da can be managed in units of sections Ra.

In the present embodiment, the reference image is generated for each of a plurality of predetermined gradations. The storage unit 31 accumulates additional correction data ΔD for each gradation (S31 to S37). Thereby, the statistical data Da can be managed in each gradation.

Further, in the present embodiment, the PC control unit 30 generates the offset data Db based on the standard deviation of the accumulated additional correction data ΔD (S51 to S54). For example, a statistical process for generating the offset data Db is realized using the standard deviation.

Further, the correction method in the present embodiment is a method for correcting display unevenness of the display panel 2. In this method, a reference image for detecting display unevenness is displayed on the display panel 2 before correction (S11), and the reference image displayed on the display panel 2 is captured by a camera 12 which is an example of an imaging device. And generating a first captured image (S12). The method includes the step of generating unevenness correction data D1 based on the first captured image (S14) and the step of applying the unevenness correction data D1 to the display panel 2 (S15). In this method, a step of displaying a reference image on the display panel 2 to which the unevenness correction data D1 is applied (S21), and a reference image displayed on the display panel 2 to which the unevenness correction data D1 is applied is imaged. Generating a captured image (S22). The method includes a step of generating additional correction data ΔD based on the second captured image (S32) and a step of storing the additional correction data ΔD in the storage unit 31 (S34). This method accumulates the additional correction data ΔD for the plurality of display panels 2 in the storage unit 31 and performs statistical processing based on the accumulated additional correction data ΔD to generate offset data Db ( S43).

According to the correction method described above, the offset data Db is obtained by statistical processing based on the accumulated additional correction data ΔD, and the generation of unevenness correction data D1 for correcting display unevenness for a plurality of display panels 2 is efficiently performed. A correction method that can be improved can be provided.

(Other embodiments)
In the first embodiment, when the offset data Db is used for the unevenness correction data generation process (FIG. 13), the offset data Db is applied to the processing target display panel 2 together with the unevenness correction data D1 (S14B, S15). The method of using the offset data Db is not limited to this, and may be used for setting a reference image, for example. This example will be described with reference to FIG.

FIG. 15 is a flowchart showing a modification of the unevenness correction data generation process (S1 in FIG. 3) using the offset data Db. In this flowchart, the processes in steps S11a and S11b are performed instead of step S11 in FIGS.

First, the PC control unit 30 selects a reference image to be displayed on the display panel 2 by selecting one of a plurality of reference gradations (S11a).

Next, based on the offset data Db, the PC control unit 30 changes the setting of the selected reference image so that the offset value is shifted from the reference gradation for each section Ra of the offset data Db (S11b). The PC control unit 30 transmits an instruction to display the reference image after the setting change to the signal source 11 (FIG. 1).

Next, the PC control unit 30 executes the processes of steps S12 to S15 in the same manner as the unevenness correction data generation process (FIG. 6) in the first embodiment.

Through the above processing, the unevenness correction data D1 is generated based on the imaging data of the reference image (S11b) whose setting has been changed so as to reduce excess and deficiency due to characteristic variation in the display area 2a by the offset data Db. (S14). Thereby, the characteristic variation in the display area 2a can be dealt with from the time of step S1 in FIG.

As described above, the PC control unit 30 in the correction system 1 sets the reference image output from the signal source 11 based on the offset data Db (S11b). This can also cope with characteristic variations in the display area 2a in the unevenness correction data generation process (S1).

In each of the above-described embodiments, the unevenness correction data regeneration process (S3 in FIG. 3) is performed with the first unevenness correction data D1 set on the display panel 2, but instead, The first unevenness correction data D1 may be used for setting a reference image. For example, instead of step S21 in FIG. 8, the PC control unit 30 changes the setting of the reference image based on the first unevenness correction data D1 in the same manner as in the above example (S11a and S11b in FIG. 15). Also in this case, in the subsequent step S24, the PC control unit 30 displays a reference image (after setting change) on the display panel 2 in a state where the first unevenness correction data D1 is applied, and based on the captured image captured. Various correction data D2, ΔD are generated.

Further, in each of the embodiments described above, the additional correction data ΔD is accumulated in the statistical data Da for each section Ra and for each reference gradation, but may be further accumulated together with the ID for each panel of the display panel 2. Good. Thereby, for example, the accumulated statistical data Da can be classified in the manufacturing process based on the ID of the display panel 2, and the tendency of the classified correction value V can be determined.

Further, in each of the above embodiments, an example has been described in which unevenness correction data is generated once or twice for one display panel 2 (FIG. 3). The generation of unevenness correction data for the panel 2 may be performed three or more times. At this time, data representing the difference between any two of the plurality of unevenness correction data generated for each display panel 2 may be accumulated in the statistical data Da.

Further, in each of the above embodiments, the example in which the reference image is set in grayscale has been described. However, the reference image is not limited to this, and for example, three colors of RGB (four colors when the pixel has a four-color configuration) 1 may be set to a predetermined gradation of a single color. In this case, various data D1, D2, Da, and Db are respectively generated according to the reference image of each color.

Further, in each of the above embodiments, the PC 13 is used in the correction system 1, but various information processing apparatuses including a control unit and a storage unit may be used instead of the PC 13. Further, the control unit and the storage unit in the correction system may be configured as separate devices capable of data communication. In addition, the control unit and the signal source may be integrally configured, for example, by using an information processing apparatus in which the signal source is integrated.

In each of the above embodiments, the display panel 2 to be processed in the correction system 1 is an example of a liquid crystal panel. However, the present invention is not limited to this, and the present invention is also applied to, for example, an organic EL display panel. be able to.

Claims (8)

1. A correction system for generating correction data for correcting display unevenness of a plurality of display panels,
   A signal source for outputting a signal for displaying a predetermined reference image on the display panel;
   An imaging unit that captures a reference image displayed on the display panel based on the signal and generates a captured image;
   A control unit that generates correction data for the display panel based on the captured image;
   A storage unit that stores the correction data for a plurality of display panels;
   The controller is
   Based on a captured image obtained by displaying the reference image on the display panel before correction and generating first correction data,
   Based on a captured image obtained by displaying the reference image on the display panel in a state where the first correction data is applied, second correction data is generated,
   Storing second correction data for a plurality of display panels in the storage unit;
   A correction system that performs statistical processing based on accumulated second correction data to generate third correction data.
2. The correction system according to claim 1, wherein the control unit applies the first correction data and the third correction data to the display panel before correction to correct display unevenness of the display panel.
3. The correction system according to claim 1, wherein the control unit sets the reference image output from the signal source based on the third correction data.
4. The control unit according to any one of claims 1 to 3, wherein the control unit completes correction of display unevenness on the display panel by applying the first and third correction data to the display panel before correction. The correction system described.
5. The control unit generates the first to third correction data for each divided area of the display area of the display panel,
   5. The correction system according to claim 1, wherein the storage unit accumulates the second correction data for each of the divided areas.
6. The reference image is generated for each of a plurality of predetermined gradations,
   6. The correction system according to claim 1, wherein the storage unit stores the second correction data for each gradation.
7. The correction system according to claim 1, wherein the control unit generates the third correction data based on a standard deviation of the accumulated second correction data.
8. A correction method for correcting display unevenness of a display panel,
   Displaying a reference image for detecting display unevenness on the display panel before correction;
   Capturing a reference image displayed on the display panel with an imaging device to generate a first captured image;
   Generating first correction data based on the first captured image;
   Applying the first correction data to the display panel;
   Displaying the reference image on a display panel to which the first correction data is applied;
   Capturing the reference image displayed on the display panel to which the first correction data is applied to generate a second captured image;
   Generating second correction data based on the second captured image;
   Accumulating the second correction data in a storage unit;
   Storing second correction data for a plurality of display panels in the storage unit;
   Performing a statistical process based on the accumulated second correction data to generate third correction data.

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