JP2017102188A - Control device and method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a display device having double liquid crystal capable of carrying out calibration while preventing degradation in display performance.SOLUTION: The display device includes: light emitting means; a first display panel that adjusts the transmittance of light from the light emitting means; and a second display panel that adjusts the transmittance of light from the first display panel. The control device includes: acquisition means that acquires a measured value and a target value of transmitted light of the second display panel; and calibration means that calibrates the display device by carrying out a series of first correction processing to correct a piece of first image data which is used for controlling the first display panel based on the measured value and the target value acquired by the acquisition means.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a control device and method for calibrating a display device.

  In recent years, the importance of color management for adjusting colors between devices that handle images, such as monitors, digital cameras, and printers, and unifying the colors that are output has increased. In color management, image data is exchanged through a color gamut that does not depend on each device such as a monitor and a printer, thereby realizing accurate color reproduction with respect to the output of each device. In particular, it is necessary to stably reproduce high accuracy with respect to colors output from a monitor used for work that handles accurate colors such as editing of still images and confirmation of printed matter. For this reason, in order to keep the reproducibility of the color output from the monitor constant, it is an important point especially in color management that the calibration process (calibration) is accurately performed periodically.

  As a conventional technique related to calibration, Patent Document 1 discloses calibration of a conversion table of a plurality of colors (RGB colors) based on luminance (white luminance, monochromatic luminance) and chromaticity measured by displaying a white image for a plurality of gradations. Is disclosed. According to Patent Document 1, display characteristics of a color display device can be calibrated. Further, as a conventional technique related to calibration, a function has been developed in which a user can select an adjustment mode (calibration mode) and adjust the image quality desired by the user. As the adjustment mode, for example, a contrast emphasis mode in which the contrast is adjusted to the highest level, a gray balance emphasis mode in which adjustment is performed so as to maintain the balance of the grayscale RGB colors in the intermediate gradation, and the like are known.

In order to improve the contrast in a liquid crystal display device, a technique for overlapping two or more liquid crystal panels has been developed. Such a structure of the liquid crystal display device is referred to as “double liquid crystal”. The dual liquid crystal can realize gradation characteristics obtained by multiplying the number of gradations of each liquid crystal panel, and can improve contrast.
As a conventional technique related to dual liquid crystal, in Patent Document 2, a black and white panel is disposed on the light source side of two liquid crystal panels, and the gray level when the gray level value of a pixel input to the liquid crystal panel exceeds a threshold value. A technique for correcting a value below a threshold is disclosed.

JP 2005-128254 A JP 2008-122536 A

  In the conventional monitor calibration process, the brightness is adjusted by adjusting the offset and gain of the image signal input to the display panel so that the desired image quality set by the user is obtained. However, in such a conventional calibration method, the display performance inherent in the display device may be degraded. In particular, when performing calibration in a display device having a dual liquid crystal structure, the advanced display performance inherent in the dual liquid crystal structure may be reduced, and the advantages of the dual liquid crystal are fully utilized. There was a case that could not be done.

  An object of the present invention is to provide a method for performing calibration while suppressing a decrease in display performance in a display device having dual liquid crystals.

The present invention includes a light emitting means, a first display panel that adjusts the transmittance of light from the light emitting means, and a second display panel that adjusts the transmittance of transmitted light from the first display panel. Obtaining means for obtaining a measured value and a target value of the transmitted light of the second display panel of the apparatus;
Based on the measurement value and the target value acquired by the acquisition means, the display device is calibrated by performing a first correction process for correcting the first image data used for controlling the first display panel. Calibration means;
It is provided with the control apparatus characterized by the above-mentioned.

The present invention includes a light emitting means, a first display panel that adjusts the transmittance of light from the light emitting means, and a second display panel that adjusts the transmittance of transmitted light from the first display panel. Obtaining means for obtaining a measured value and a target value of the transmitted light of the second display panel of the apparatus;
Based on the measurement value and the target value acquired by the acquisition means, the first display panel and the second display panel, which are used for controlling the sub-panel having the lower performance regarding the adjustment of the transmittance of the first display panel and the second display panel. Calibration means for calibrating the display device by performing a first correction process for correcting image data;
It is provided with the control apparatus characterized by the above-mentioned.

The present invention includes a light emitting means, a first display panel that adjusts the transmittance of light from the light emitting means, and a second display panel that adjusts the transmittance of transmitted light from the first display panel. An acquisition step of acquiring a measured value and a target value of the transmitted light of the second display panel of the apparatus;
Based on the measurement value and the target value acquired in the acquisition step, the display device is calibrated by performing a first correction process for correcting the first image data used for the control of the first display panel. Calibration process;
It is the control method characterized by having.

The present invention includes a light emitting means, a first display panel that adjusts the transmittance of light from the light emitting means, and a second display panel that adjusts the transmittance of transmitted light from the first display panel. An acquisition step of acquiring a measured value and a target value of the transmitted light of the second display panel of the apparatus;
Based on the measurement value and the target value acquired in the acquisition step, the first display panel and the second display panel are used for controlling a sub-panel having a lower performance regarding the adjustment of the transmittance of the first display panel and the second display panel. A calibration step of calibrating the display device by performing a first correction process for correcting image data;
It is the control method characterized by having.

  ADVANTAGE OF THE INVENTION According to this invention, it can calibrate, suppressing the fall of display performance in the display apparatus which has a double liquid crystal.

The figure which shows the whole structure of Example 1, 2, 3 and the structure of a display. The block diagram which shows the system configuration | structure of Example 1, 2, 3 Flow chart of overall processing of the first, second, and third embodiments Screen for inputting calibration target value of embodiment 1 Flowchart showing calibration processing of the first, second, and third embodiments Flowchart of calibration process of embodiment 1 Flowchart of backlight luminance adjustment processing in Embodiment 1 The figure which shows a mode when white brightness adjustment processing of Example 1, 2, 3 is performed. The figure explaining the backlight brightness adjustment processing of Examples 1, 2, and 3. Flowchart of black luminance adjustment process of embodiment 1 The figure which shows a mode when the black luminance adjustment process of Example 1, 2, 3 is performed. FIG. 6 is a diagram illustrating black luminance adjustment processing according to the first embodiment. Flowchart of white luminance adjustment processing in Embodiment 1 FIG. 10 is a diagram for explaining white luminance adjustment processing according to the first embodiment. Flowchart of calibration process of embodiment 2 Screen for inputting calibration target value of embodiment 3 Flowchart of processing for determining an adjustment mode according to the third embodiment. Flowchart of backlight luminance adjustment in luminance adjustment processing A of Embodiment 3 Flowchart of black luminance adjustment in luminance adjustment processing A of Embodiment 3 The figure which shows the black luminance adjustment of the luminance adjustment process A of Example 3. The figure which shows the black luminance adjustment of the luminance adjustment process A of Example 3. The figure which shows the black luminance adjustment of the luminance adjustment process A of Example 3. Flowchart of white luminance adjustment in luminance adjustment processing A of Embodiment 3 The figure which shows the white luminance adjustment of the luminance adjustment process A of Example 3. The figure which shows the white luminance adjustment of the luminance adjustment process A of Example 3. The figure which shows the white luminance adjustment of the luminance adjustment process A of Example 3. Flowchart of white luminance adjustment in luminance adjustment processing B of Embodiment 3 The figure which shows the white luminance adjustment of the luminance adjustment process B of Example 3. The figure which shows the white luminance adjustment of the luminance adjustment process B of Example 3.

Example 1
<Description of overall configuration>
With reference to FIG. 1A, an overall configuration of a system according to Embodiment 1 of the present invention will be described.
In this configuration, a PC 101 that executes a program (software or application) that outputs an image signal and performs calibration, a monitor 102 that is a calibration target display device, and a colorimetric sensor 103 that measures transmitted light of the monitor 102. Consists of. In addition, this configuration includes a communication line 105 and an image output line 104 for transmitting and receiving data between the program installed in the PC 101 and the monitor 102 to be calibrated. The colorimetric sensor 103 is connected to either the PC 101 or the monitor 102 in order to transmit the result of measuring the display color of the monitor 102 to the PC 101 or the monitor 102. The colorimetric sensor 103 may be built in the monitor 102.

<Description of system configuration>
With reference to FIG. 2, the system configuration of the calibration apparatus according to the first embodiment of the present invention will be described.
The monitor 102 is a display device that receives an image signal from the PC 101 and displays the input image signal on the display unit 208.
The PC 101 outputs a GUI (Graphical User Interface) image signal generated by the calibration unit 201 from the image signal output unit 202.

The calibration unit 201 acquires data such as a calibration target value from the storage unit 203, and saves and stores the data in the storage unit 203 when data is updated.
The calibration unit 201 transmits data used for calibration of the monitor 102 to the monitor 102 via the communication control unit 204, the communication line 105, and the communication control unit 218. Similarly, the calibration unit 201 receives data processed by the control unit 214 and the like of the monitor 102 via the communication control unit 218, the communication line 105, and the communication control unit 204.

The calibration unit 201 transmits an image signal such as a GUI image to be displayed from the image signal output unit 202 to the image signal input unit 205 of the monitor 102.
The image signal input to the image signal input unit 205 by the calibration unit 201 is adjusted in image quality by the image quality adjustment unit 215 in the display control unit 207. Also, the image signal input to the image signal input unit 205 is combined with an OSD (on-screen display) image signal generated by the GUI control unit 217 by the display control unit 207. The image signal after the image quality adjustment and the combination with the OSD is transmitted to the display unit 208.
The input unit 220 receives information on a user operation performed using the keyboard / mouse 223 and outputs command information corresponding to the user operation to the calibration unit 201.

The backlight control unit 209 controls the light emission amount of the backlight 210 based on the luminance set by the image quality adjustment unit 215.
The interface unit 213 receives a signal transmitted from the remote controller, a user operation using the body button 219, and the like, and outputs a received signal and a control signal corresponding to the user operation. For example, the interface unit 213 transmits a GUI control signal corresponding to the user operation to the GUI control unit 217.

The GUI control unit 217 generates GUI image data based on the control signal received from the interface unit 213. The GUI control unit 217 acquires material data and the like necessary for GUI image data from the storage unit 211 in the monitor 102, and saves and stores the image data in the storage unit 211 when the GUI image data is updated.
The display control unit 207 combines the image signal input to the image signal input unit 205 and the GUI image signal generated by the GUI control unit 217 and outputs the synthesized image signal to the display unit 208.

  The configuration of the backlight 210, the second liquid crystal panel 221, and the first liquid crystal panel 222 in the monitor 102 will be described. In the description, reference is made to FIG. As shown in FIG. 1B, the backlight 210, the second liquid crystal panel 221 and the first liquid crystal panel 222 of the monitor 102 are arranged on the front surface of the backlight 210 and on the front surface of the first liquid crystal panel. In this structure, the second liquid crystal panel 221 is disposed.

  The display unit 208 in FIG. 1A includes the second liquid crystal panel 221 and the first liquid crystal panel 222, and displays an image based on the image signal output from the display control unit 207. The first liquid crystal panel 222 is a first display panel that adjusts the transmittance of light from the backlight 210, and the second liquid crystal panel 221 is a second display panel that adjusts the transmittance of transmitted light from the first liquid crystal panel 222. It is. In the first embodiment, it is assumed that the second liquid crystal panel 221 is a main liquid crystal panel (main panel) having high performance (resolution and number of gradations) related to transmittance adjustment. The first liquid crystal panel 222 is assumed to be a liquid crystal panel (sub-panel) that has lower performance (resolution and number of gradations) related to transmittance adjustment than the second liquid crystal panel 221.

  The backlight 210 is a light source that irradiates the second liquid crystal panel 221 and the first liquid crystal panel 222 of the display unit 208. The backlight 210 controls the amount of light emission based on the luminance determined by the backlight control unit 209. The backlight 210 may have any configuration, and an LED (Light Emitting Diode), a CCFL (Cold Cathode Fluorescent Lamp), or the like can be used as a light source.

The color measurement control unit 216 performs a series of control relating to color measurement on the color measurement sensor 103 connected to the monitor 102 via the communication control unit 218, and the measured value of the transmitted light of the second liquid crystal panel 221. Acquire (colorimetric value). The color measurement control unit 216 stores the acquired measurement value in the storage unit 211.
When the calibration unit 201 calibrates the monitor 102 based on the target value and the measurement value acquired by the colorimetry control unit 216, the control unit 214 changes the image quality of the monitor 102 in response to a request from the calibration unit 201. adjust.
The system control unit 212 comprehensively controls the operation of each functional unit constituting the monitor 102.

<Description of calibration process flow>
The calibration process of the monitor 102 performed by the system including the PC 101 and the monitor 102 described above will be described. In the description, reference is made to FIG. 3 and FIG.
In step S301, the calibration unit 201 acquires a calibration target value. Specifically, the calibration unit 201 displays a calibration target value input screen 401 as shown in FIG. 4 and accepts input of a target value by the user. Here, displaying the screen 401 means outputting image information constituting the GUI of the screen 401 to the monitor 102 for display. The user operates the keyboard / mouse 223 while looking at the calibration target value input screen 401 so that the monitor 102 has a desired image quality (for example, an image quality suitable for the user's usage environment), and various target values for calibration. Is input to the PC 101. Examples of calibration target values include color gamut, luminance, white point, gamma, and the like.

The calibration unit 201 transmits the calibration target value input by the user to the control unit 214 of the monitor 102 via the communication control unit 204. The control unit 214 that has received the calibration target value stores information on the target value in the storage unit 211.
In step S <b> 302, the calibration unit 201 performs initialization processing for the colorimetric sensor 103 connected to the monitor 102. Specifically, the calibration unit 201 outputs an instruction to execute initialization of the colorimetric sensor 103 to the colorimetric control unit 216 of the monitor 102. The colorimetry control unit 216 transmits the result of the initialization process to the control unit 214.

  In step S <b> 303, the calibration unit 201 confirms that the initialization process result of the colorimetric sensor 103 and the set calibration target value are normal, and executes calibration. This calibration is performed so that the calibration target value set on the calibration target value input screen 401 matches the image quality of the monitor 102. The calibration unit 201 adjusts the image quality of the monitor 102 in cooperation with the image quality adjustment unit 215 so that the measurement value obtained by measuring the color and brightness of the monitor 102 by the colorimetric sensor 103 matches the calibration target value. .

In step S <b> 304, the calibration unit 201 acquires, from the control unit 214, information on adjustment parameters by the image quality adjustment unit 215 when it is determined that the target value matches the measurement value. The calibration unit 201 creates an ICC profile based on the acquired adjustment parameter information and applies it to the image output to the monitor 102. The calibration unit 201 instructs the monitor 102 to apply an image quality adjustment value based on the calibration result.
Through the above processing, the calibration unit 201 adjusts (calibrates) the image quality of the monitor 102 so that the target value set by the user is obtained.

<Description of Calibration Process (S303)>
Details of the calibration processing in S303 will be described with reference to FIG. FIG. 5 is a flowchart showing the calibration process.
In step S101, the calibration unit 201 performs color gamut adjustment and color temperature adjustment. In the first embodiment, these adjustment items are not essential and will not be described.
In step S <b> 102, the calibration unit 201 adjusts the luminance so that the white luminance and black luminance target values set by the user on the calibration target value input screen 401 coincide with the measured values of the white luminance and black luminance of the monitor 102. Process.
In step S103, the calibration unit 201 performs gamma adjustment. In the first embodiment, this adjustment item is not essential and will not be described.

<Description of brightness adjustment (S102)>
The brightness adjustment process of S102 is performed according to the flowchart of FIG. The brightness adjustment process is performed in three steps: brightness adjustment 1 (S502), brightness adjustment 2 (S503), and brightness adjustment 3 (S504). These brightness adjustment processes are performed by the calibration unit 201.
The brightness adjustment 1 (S502) is a process of adjusting the brightness of the backlight 210 based on the white brightness target value set by the user.
The brightness adjustment 2 (S503) is a process for adjusting the brightness of the display unit 208 based on the black brightness target value set by the user.
The brightness adjustment 3 (S504) is a process of adjusting the amount that cannot be adjusted by the brightness adjustment 1 (S502) based on the white brightness target value set by the user, based on the brightness of the display unit 208.
Hereinafter, the details of the luminance adjustment 1, the luminance adjustment 2, and the luminance adjustment 3 will be described.

<Luminance Adjustment 1 (S502): Explanation of White Luminance Adjustment (Backlight Emission Amount)>
The luminance adjustment 1 is a process of adjusting the gain of the backlight so that the measured value of white luminance by the colorimetric sensor 103 becomes the set white luminance target value. In the description, reference is made to FIGS. 2, 7, 8 and 9.
FIG. 7 is a flowchart showing the process of luminance adjustment 1.
In step S <b> 601, the calibration unit 201 displays a white patch 701 on the second liquid crystal panel 221 and the first liquid crystal panel 222 of the display unit 208 as illustrated in FIG. 8. Here, the patch displayed on the first liquid crystal panel 222 is larger than the size of the patch displayed on the second liquid crystal panel 221 and includes all the coordinates of the patch area displayed on the second liquid crystal panel 221.

In step S <b> 602, the calibration unit 201 acquires a luminance measurement value (Ywa) from the colorimetric sensor 103 arranged on the white patch 701 via the colorimetry control unit 216.
In step S <b> 603, the calibration unit 201 calculates a backlight gain correction value based on the acquired luminance measurement value (Ywa) and the white luminance target value. The backlight gain correction value can be calculated by, for example, a ratio between a measured value and a target value. The method for calculating the backlight gain correction value is an example and is not limited thereto.

In step S <b> 604, the calibration unit 201 transmits the calculated backlight gain correction value to the backlight control unit 209 and applies the backlight gain correction value to the backlight 210.
In step S <b> 605, the calibration unit 201 applies the luminance gain from the colorimetric sensor 103 disposed on the white patch 701 again via the colorimetry control unit 216 in a state where the backlight gain correction value is applied in step S <b> 604. A measured value (Ywb) is acquired.

In step S606, the calibration unit 201 determines whether or not the luminance measurement value (Ywb) acquired in step S605 is within the range of the white luminance target value. Here, the measurement value being within the target value range is defined as the difference between the measurement value and the target value (the magnitude of the difference) being a predetermined threshold value or less. The same applies hereinafter. Note that the determination method is an example and is not limited thereto.
When the measured luminance value (Ywb) is not within the target value range (S606: No), the calibration unit 201 returns to S603, and based on the measured luminance value (Ywb) and the target value acquired in S605. The backlight gain correction value is calculated again.
When the luminance measurement value (Ywb) is within the target value range (S606: Yes), the process proceeds to S607. In step S <b> 607, the calibration unit 201 stores the backlight gain correction value (Blgain_w) calculated in step S <b> 603 and the luminance measurement value (Ywb) acquired in step S <b> 605 in the storage unit 211.

According to the flowchart described above, the calibration unit 201 performs a process of correcting the light emission amount of the backlight 210 (referred to as a third correction process) based on the measured value and the target value of the white luminance acquired by the colorimetric sensor 103.
Here, the threshold value used for determining whether or not the measured value is within the range of the target value may be determined by the calibration unit 201 based on the value input to the PC 101 by the user via the input unit 220, A value stored in advance in the storage unit 211 of the monitor 102 may be used.

  The calibration unit 201 considers adjustment by luminance adjustment 3 described later, and in the adjustment of the light emission amount of the backlight by luminance adjustment 1, the measured luminance value (Ywb) after adjustment is higher than the target value of white luminance. You may make it become a value. For example, the adjusted brightness can be adjusted to either Ywb1, which is the brightness closest to the target value on the brighter side than the target value, or Ywb2, which is the brightness closest to the target value on the darker side than the target value. To do. At this time, even if Ywb2 is closer to the target value than Ywb1, Ywb1 may be the luminance after final adjustment by luminance adjustment 1. As a result, as shown in FIG. 9, a backlight gain Blgain_w is obtained such that the white luminance Ywb is brighter than the target value.

<Luminance Adjustment 2 (S503): Explanation of Black Luminance Adjustment (RGB Offset)>
The brightness adjustment 2 is a process of adjusting the RGB offset of the image data for controlling the transmittance of the liquid crystal panel so that the black brightness measurement value by the colorimetric sensor 103 becomes the set black brightness target value. In the first embodiment, the image data adjusted by the brightness adjustment 2 is image data (first image data) used for controlling the transmittance of the first liquid crystal panel 222. In the description, reference is made to FIG. 2, FIG. 10, FIG. 11 and FIG.
FIG. 10 is a flowchart showing the brightness adjustment 2 process.
In step S <b> 801, the calibration unit 201 displays a black patch 901 on the second liquid crystal panel 221 and the first liquid crystal panel 222 of the display unit 208 as illustrated in FIG. 11. Here, the patch displayed on the first liquid crystal panel 222 is larger than the size of the patch displayed on the second liquid crystal panel 221 and includes all the coordinates of the patch area displayed on the second liquid crystal panel 221.

In step S <b> 802, the calibration unit 201 acquires a brightness measurement value (Ybm) from the colorimetric sensor 103 arranged on the black patch 901 via the colorimetry control unit 216.
In step S <b> 803, the calibration unit 201 calculates an RGB offset value of image data used for control of the first liquid crystal panel 222 based on the acquired luminance measurement value (Ybm) and the black luminance target value.
In step S804, the calibration unit 201 transmits the RGB offset value calculated in step S803 to the image quality adjustment unit 215 and the display control unit 207. Thereby, the transmittance of the first liquid crystal panel 222 is adjusted.
In step S <b> 805, the calibration unit 201 obtains the luminance measurement value (Ybn) from the colorimetric sensor 103 disposed on the black patch 901 again via the colorimetry control unit 216.

In step S806, the calibration unit 201 determines whether or not the luminance measurement value (Ybn) acquired in step S805 is within the range of the black luminance target value.
When the luminance measurement value (Ybn) is not within the range of the black luminance target value (S806: No), the calibration unit 201 calculates the RGB offset value of S803 based on the measurement value (Ybn) acquired in S805. .
When the luminance measurement value (Ybn) is within the range of the black luminance target value (S806: Yes), the calibration unit 201 proceeds to S807.
In step S <b> 807, the calibration unit 201 stores the RGB offset value (RGBo (Ro, Go, Bo)) calculated in step S <b> 804 and the brightness measurement value (Ybn) acquired in step S <b> 805 in the storage unit 211.

FIG. 12 shows the RGB offset value (RGBo (Ro, Go, Bo)) calculated in the luminance adjustment 2 and the adjusted black luminance (Ybn). As shown in FIG. 12, since the RGB offset of the image data for controlling the first liquid crystal panel 222 is adjusted in the brightness adjustment 2, the original display performance (number of gradations) of the second liquid crystal panel 221 can be maintained. it can.
According to the flowchart described above, the calibration unit 201 corrects the first image data used for controlling the first liquid crystal panel 222 based on the black luminance measurement value and the target value acquired by the colorimetric sensor 103 (first process). 1 correction process).
Here, the threshold value used for determining whether or not the measured value is within the range of the target value may be determined by the calibration unit 201 based on the value input to the PC 101 by the user via the input unit 220, A value stored in advance in the storage unit 211 of the monitor 102 may be used.

<Luminance Adjustment 3 (S504): Explanation of White Luminance Adjustment (RGB Gain)>
The brightness adjustment 3 is a process of adjusting the gain of the image data for controlling the transmittance of the liquid crystal panel so that the white brightness measurement value obtained by the colorimetric sensor 103 becomes the set white brightness target value. In the first embodiment, the image data adjusted by the brightness adjustment 3 is image data (first image data) used for controlling the transmittance of the first liquid crystal panel 222. In the description, reference is made to FIG. 2, FIG. 13 and FIG.
FIG. 13 is a flowchart showing the brightness adjustment 3 process.
In step S1001, the calibration unit 201 displays the white patch 701 on the second liquid crystal panel 221 and the first liquid crystal panel 222 of the display unit 208 as illustrated in FIG. Here, the patch displayed on the first liquid crystal panel 222 is larger than the size of the patch displayed on the second liquid crystal panel 221 and includes all the coordinates of the patch area displayed on the second liquid crystal panel 221.

In step S <b> 1002, the calibration unit 201 acquires a luminance measurement value (Ywu) from the colorimetric sensor 103 arranged on the white patch 701 via the colorimetry control unit 216.
In step S <b> 1003, the calibration unit 201 calculates an RGB gain value of image data used for control of the first liquid crystal panel 222 based on the acquired luminance measurement value (Ywu) and white luminance target value.
In step S1004, the calibration unit 201 transmits the RGB gain value calculated in step S1003 to the image quality adjustment unit 215 and the display control unit 207. Thereby, the transmittance of the first liquid crystal panel 222 is adjusted.
In step S <b> 1005, the calibration unit 201 acquires the luminance measurement value (Ywv) from the colorimetric sensor 103 arranged on the white patch 701 again via the colorimetric control unit 216.

In step S1006, the calibration unit 201 determines whether or not the luminance measurement value (Ywv) acquired in step S1005 is within the range of the white luminance target value.
When the luminance measurement value (Ywv) is not within the range of the white luminance target value (S1006: No), the calibration unit 201 calculates the RGB gain value of S1003 based on the measurement value (Ywv) acquired in S1005. .
When the luminance measurement value (Ywv) is within the range of the white luminance target value (S1006: Yes), the calibration unit 201 proceeds to S1007.
In S1007, the calibration unit 201 stores the RGB gain value (RGBg (Rg, Gg, Bg)) calculated in S1004 and the luminance measurement value (Ywv) acquired in S1005 in the storage unit 211.

FIG. 14 shows the RGB gain value (RGBg (Rg, Gg, Bg)) calculated in the luminance adjustment 3 and the adjusted white luminance (Ywv). As shown in FIG. 14, since the RGB gain of the image data for controlling the first liquid crystal panel 222 is adjusted in the luminance adjustment 3, the original display performance (the number of gradations) of the second liquid crystal panel 221 is maintained by the adjustment. be able to.
According to the flowchart described above, the calibration unit 201 corrects the first image data used for controlling the first liquid crystal panel 222 based on the white luminance measurement value and the target value acquired by the colorimetric sensor 103 (first process). 1 correction process).
Here, the threshold value used for determining whether or not the measured value is within the range of the target value may be determined by the calibration unit 201 based on the value input to the PC 101 by the user via the input unit 220, A value stored in advance in the storage unit 211 of the monitor 102 may be used.

  Through the above processing, the offset and gain of the first liquid crystal panel arranged on the backlight side are preferentially adjusted in the calibration of the monitor constituting the dual liquid crystal. Thereby, it can suppress that the display performance (the number of effective gradations) which the 2nd liquid crystal panel has inherently reduces resulting from adjustment by calibration. Therefore, the display gradation performance of the second liquid crystal panel can be utilized to the maximum, and it is possible to perform calibration of the display device that can achieve both high contrast by the double liquid crystal and high display performance. .

(Example 2)
Even if the calibration for adjusting the offset and gain of the first image data used for controlling the transmittance of the first liquid crystal panel 222 described in the first embodiment is performed, the brightness may not be adjusted within the range of the target value. obtain.
In such a case, first, the brightness is adjusted to the target value by performing the RGB offset adjustment / RGB gain adjustment of the second liquid crystal panel 221 in that state as close as possible to the target value by the RGB offset adjustment / RGB gain adjustment of the first liquid crystal panel 222. Adjust so that it is within the range. In the second embodiment, an example in which the second liquid crystal panel 221 is calibrated after the first liquid crystal panel 222 is calibrated will be described.
Such a situation is likely to occur when, for example, the number of gradations that can be displayed on the first liquid crystal panel 222 is smaller than the number of gradations that can be displayed on the second liquid crystal panel 221. For example, the first liquid crystal panel 222 has 256 gradations, the second liquid crystal panel has 1024 gradations, and the like. However, the second embodiment is applicable regardless of whether there is a difference in display performance between the first liquid crystal panel 222 and the second liquid crystal panel 221.

A calibration method according to the second embodiment will be described. In the description, reference is made to FIG. 2 and FIG. Note that the backlight 210, the second liquid crystal panel 221, and the first liquid crystal panel 222 of the monitor 102 have the same arrangement and structure as in the first embodiment. FIG. 15 is a flowchart illustrating a calibration process according to the second embodiment.
In step S1201, the calibration unit 201 performs adjustment so that the black luminance and white luminance of the monitor 102 match the target values by adjusting the RGB gain of the first liquid crystal panel 222 as in the first embodiment (first correction processing). ).
In step S1202, the calibration unit 201 compares the black luminance and white luminance acquired from the colorimetric sensor 103 in a state where the first liquid crystal panel 222 is controlled by the first image data corrected by the first correction processing in step S1201. It is determined whether the measured value is within the target value range.

In S1202, when the measurement value of black luminance and the measurement value of white luminance are within the target value range (S1202: Yes), the calibration unit 201 normally ends the calibration process.
In S1202, when the measurement value of the measurement value and the measurement value of the white luminance are not within the target value range (S1202: No), the calibration unit 201 proceeds to S1203.
In step S1203, the calibration unit 201 increments the variable A that counts the number of times that the measured value is determined not to be within the target value range by one. Note that the initial value of the variable A is 0.

In S1204, the calibration unit 201 determines whether or not the variable A is equal to or smaller than the threshold value. If the variable A is equal to or smaller than the threshold value (S1204: Yes), the luminance adjustment process of the first liquid crystal panel 222 in S1201 is performed again. . When the variable A is larger than the threshold (S1204: No), the calibration unit 201 proceeds to S1205.
In S1205, the calibration unit 201 performs the same brightness adjustment process as the brightness adjustment process performed on the first liquid crystal panel 222 in S1201 on the second liquid crystal panel 221 (second correction process). That is, the calibration unit 201 performs the second correction process while the first liquid crystal panel 222 is controlled by the first image data corrected by the first correction process. The second correction process is a process for correcting the second image data used for controlling the second liquid crystal panel 221 based on the measurement value acquired by the colorimetric sensor 103 and the target value.

In step S <b> 1206, the calibration unit 201 adjusts the black luminance and white luminance acquired from the colorimetric sensor 103 while the second liquid crystal panel 221 is controlled by the second image data corrected by the second correction process in step S <b> 1205. It is determined whether the measured value is within the target value range.
In S1206, when the measurement value of black luminance and the measurement value of white luminance are within the target value ranges (S1206: Yes), the calibration unit 201 ends the calibration process normally.
In S1206, when the measurement value of black luminance and the measurement value of white luminance are not within the target value range (S1206: No), the calibration unit 201 proceeds to S1207.
In step S <b> 1207, the calibration unit 201 increases the variable B that counts the number of times that the measured value is determined not to be within the target value range by one. Note that the initial value of the variable A is 0.

In S1208, the calibration unit 201 determines whether or not the variable B is less than or equal to the threshold value. If the variable B is less than or equal to the threshold value (S1208: Yes), the brightness adjustment process of the second liquid crystal panel 221 in S1205 is performed again. . When the variable B is larger than the threshold value (S1208: No), the calibration unit 201 proceeds to S1209.
In step S1209, the calibration unit 201 determines that the monitor 102 has not been successfully calibrated.

With the above processing, the calibration unit 201 has a value between the measured value and the target value after performing the first correction processing so that the measured value of the transmitted light of the second liquid crystal panel 221 approaches the target value is larger than the threshold value. In this case, the second correction process is performed. Thereby, the offset of the second image data for controlling the transmittance of the second liquid crystal panel 221 only when the target value cannot be achieved by the offset / gain adjustment of the first image data for controlling the transmittance of the first liquid crystal panel 222.・ Gain adjustment is performed. Therefore, it is possible to calibrate the display brightness with high accuracy while maximizing the gradation performance of the second liquid crystal panel. In particular, when the second liquid crystal panel 221 has higher gradation display performance than the first liquid crystal panel 222, it is preferable to apply the calibration method of the second embodiment.

(Example 3)
The overall configuration of the third embodiment of the present invention is the same as the configuration shown in FIGS. 1A and 2 described in the first embodiment. In the following description, differences from the first embodiment will be mainly described, and the contents described in the first embodiment will be omitted.
In Example 3, a liquid crystal panel having a higher display performance in the dual liquid crystal is specified as a main panel, and a liquid crystal panel having a lower display performance is specified as a sub panel, and whether each liquid crystal panel is a main panel or a sub panel. Based on the brightness adjustment. In the third embodiment, as an example, the second liquid crystal panel 221 is a main panel having a high resolution and the number of gradations, and the first liquid crystal panel 222 is a sub-panel having a resolution and a number of gradations lower than those of the second liquid crystal panel 221. And However, which of the first liquid crystal panel 222 disposed on the backlight side and the second liquid crystal panel 221 disposed on the display surface side is used as the main panel is not limited to this configuration.

<Description of calibration process flow>
A monitor calibration process performed by the PC 101 and the monitor 102 will be described. The flow of the calibration process of the third embodiment is as shown in the flowchart of FIG. 3 described in the first embodiment.
The difference from the calibration process described in the first embodiment is a calibration target value input screen 501 displayed for inputting a target value in S301 shown in FIG. Compared with the screen 401 in FIG. 4 described in the first embodiment, an item for selecting a calibration adjustment mode is added. In the third embodiment, it is assumed that the adjustment mode can be switched between the first mode and the second mode. The first mode is a gray balance emphasizing mode in which gradation performance is adjusted so as to give priority to maintaining the balance of grayscale RGB colors in the intermediate gradation. The second mode is a contrast-oriented mode in which the contrast performance is adjusted with priority.
In the third embodiment, the calibration process of S303 in FIG. 3 is also performed based on the calibration adjustment mode input on the screen 501. The calibration process of S303 is performed according to the flowchart of FIG. Since the processing of S101 and S103 in the flowchart of FIG. 5 is not essential in the third embodiment, a description thereof will be omitted. The brightness adjustment process in S102 will be described below.

<Description of Brightness Adjustment Process (S102)>
The brightness adjustment process of S102 is performed according to the flowchart of FIG.
In step S <b> 701, the calibration unit 201 stores information on the adjustment mode specified by the user through the calibration target value input process via the screen 501 in FIG. 16 via the communication control unit 204 and the communication control unit 218. 211.
In step S <b> 702, the calibration unit 201 acquires information on the second liquid crystal panel 221 and the first liquid crystal panel 222. The acquired panel information is information on display performance (performance relating to transmittance adjustment) such as resolution and the number of gradations.

In step S703, the calibration unit 201 determines a brightness adjustment processing method according to the adjustment mode acquired in step S701.
When the adjustment mode selected by the user is the gray balance emphasis mode (first mode) (S703: Yes), the calibration unit 201 proceeds to S704 and performs brightness adjustment processing A (S704).
When the adjustment mode selected by the user is the contrast emphasis mode (second mode) (S703: No), the calibration unit 201 proceeds to S705 and performs brightness adjustment processing B (S705).
)I do.

In the brightness adjustment process A, first, the first image data used for controlling the sub-panel of the first liquid crystal panel 222 and the second liquid crystal panel 221 is corrected based on the measured value and the target value acquired by the colorimetric sensor 103. A first correction process is performed. Next, in a state where the sub panel is controlled by the first image data corrected by the first correction process, the second used for controlling the main panel based on the measured value and the target value acquired by the colorimetric sensor 103. A second correction process for correcting the image data is performed. At this time, when the measured value after the first correction process is performed so that the measurement value obtained by the colorimetric sensor 103 approaches the target value and the target value are larger than the threshold value, the second correction process is performed. . Thereby, only when the target value cannot be achieved by the calibration of the sub panel, the main panel is calibrated, so that it is possible to suppress the deterioration of the display performance due to the calibration.
Hereinafter, the brightness adjustment process A and the brightness adjustment process B will be described in detail.

<Description of Brightness Adjustment Processing A (Brightness Adjustment when Adjustment Mode Emphasizes Gray Balance)>
A calibration method (luminance adjustment processing A) of the second liquid crystal panel 221 and the first liquid crystal panel 222 when the designated adjustment mode is the first mode in which gray balance is emphasized will be described. In the brightness adjustment processing A, (1) white brightness adjustment by adjusting the light emission amount of the backlight 210, (2) black brightness adjustment by adjusting the gain / offset of the liquid crystal panel, and (3) white brightness adjustment by adjusting the gain / offset of the liquid crystal panel. Execute in this order.

<Description of white luminance adjustment (B / L) in luminance adjustment processing A>
First, the backlight gain is adjusted so that the measured value by the colorimetric sensor 103 approaches the set white luminance target value. In the description, reference is made to FIG. 2, FIG. 18, FIG. 8, and FIG.
In step S901, the calibration unit 201 displays the white patch 701 on the second liquid crystal panel 221 and the first liquid crystal panel 222 of the display unit 208 as illustrated in FIG. Here, the patch displayed on the first liquid crystal panel 222 is larger than the size of the patch displayed on the second liquid crystal panel 221 and includes all the coordinates of the patch area displayed on the second liquid crystal panel 221.

In step S <b> 902, the calibration unit 201 acquires a luminance measurement value (Ywa) from the color measurement sensor 103 arranged on the white patch 701 via the color measurement control unit 216.
In step S903, the calibration unit 201 calculates a backlight gain correction value based on the luminance measurement value (Ywa) acquired in step S902 and the white luminance target value. The backlight gain correction value can be calculated by, for example, a ratio between a measured value and a target value. The method for calculating the backlight gain correction value is an example and is not limited thereto.
In step S904, the calibration unit 201 transmits the backlight gain correction value calculated in step S903 to the backlight control unit 209, and applies the backlight gain correction value to the backlight 210.
In step S905, the calibration unit 201 applies the luminance gain from the colorimetric sensor 103 disposed on the white patch 701 again via the colorimetry control unit 216 in a state where the backlight gain correction value is applied in step S904. A measured value (Ywb) is acquired.

In step S906, the calibration unit 201 determines whether or not the luminance measurement value (Ywb) acquired in step S905 is within the range of the white luminance target value.
When the measured luminance value (Ywb) is within the target value range (S906: Yes), the process proceeds to S907. In step S907, the calibration unit 201 calculates the backlight gain correction value (Blgain_w) calculated in step S903 and the measured luminance value (Ywb) acquired in step S905.
Are stored in the storage unit 211.

When the measured luminance value (Ywb) is not within the range of the target value (S906: No), in S908, the calibration unit 201 acquires the number of executions (determination number) Cn of the determination process in S906 and reaches the threshold value. It is determined whether or not.
When the determination count Cn is equal to or greater than the threshold (S908: Yes), in S909, the calibration unit 201 determines that the white luminance cannot be adjusted to the target value, and ends the calibration process.

When the determination count Cn is smaller than the threshold (S908: No), the calibration unit 201 returns to S903, and recalculates the backlight gain correction value based on the luminance measurement value (Ywb) acquired in S906 and the target value. To do. Subsequently, the calibration unit 201 executes the processing after S904. Here, the determination count Cn is initialized (Cn = 0) when the white luminance calibration process by adjusting the light emission amount of the backlight is started, and is incremented by 1 each time the determination process of S906 is performed.
The calibration unit 201 adjusts the backlight 210 in consideration of luminance adjustment by gain / offset adjustment of the liquid crystal panel described later. Specifically, the backlight emission amount is adjusted by calculating the backlight gain correction value (Blgain_w) so that the measured brightness value (Ywb) after adjustment is higher than the target value of white brightness. Then, the backlight 210 is adjusted.

<Description of black luminance adjustment (RGB offset) in luminance adjustment processing A>
Next, adjustment is performed so that the set black luminance target value is obtained by the RGB offset of the liquid crystal panel. In the description, reference is made to FIGS. 2, 11, 19, 20, 21, and 22.
FIG. 19 is a flowchart showing black luminance adjustment by offset adjustment of the liquid crystal panel in luminance adjustment processing A.
In step S1901, the calibration unit 201 displays the black patch 901 on the second liquid crystal panel 221 and the first liquid crystal panel 222 of the display unit 208 as illustrated in FIG. Here, the patch displayed on the first liquid crystal panel 222 is larger than the size of the patch displayed on the second liquid crystal panel 221 and includes all the coordinates of the patch area displayed on the second liquid crystal panel 221.

  In step S1902, the calibration unit 201 adjusts the luminance of the first liquid crystal panel 222, which is a sub-panel having a low resolution and number of gradations. The calibration unit 201 acquires a luminance measurement value (Ybno) obtained by measuring the black patch 901 displayed on the screen with the colorimetric sensor 103 as shown in FIG. The calibration unit 201 adjusts the RGB offset value of the first liquid crystal panel 222 so that the luminance measurement value (Ybno) is as close as possible to the target value (Ybt) (RGBo (Ro, Go, Bo)). . At this time, it is assumed that the second liquid crystal panel 221 outputs black with the RGB offset value as the minimum value (RGBox (Rox, Gox, Bgx)).

  In step S1903, the calibration unit 201 determines whether or not the luminance measurement value (Ybno) is within the target value range in the state in which the luminance adjustment in step S1902 is performed. Here, the calibration unit 201 determines whether or not the difference (Dyb) between the luminance measurement value (Ybno) and the target value (Ybt) is equal to or less than a predetermined threshold value. Here, the threshold value used for determining whether or not the measured value is within the range of the target value may be determined by the calibration unit 201 based on the value input to the PC 101 by the user via the input unit 220, A value stored in advance in the storage unit 211 of the monitor 102 may be used.

When the difference (Dyb) between the luminance measurement value (Ybno) and the target value (Ybt) is equal to or smaller than the threshold value (S1903: Yes), the calibration unit 201 determines that the luminance has been adjusted to the target value and performs calibration. Exit.
When the difference (Dyb) between the luminance measurement value (Ybno) and the target value (Ybt) is larger than the threshold value (S1903: No), the calibration unit 201 determines that the luminance measurement value (Ybno) is the target value (S1904: No). Ybt) is determined.

If the measured luminance value (Ybno) is greater than the target value (Ybt) (S1904: Yes), the process proceeds to S1905.
When the measured value (Ybno) of the luminance is equal to or less than the target value (Ybt) (S1904: No), the process proceeds to S1906.

In step S1905, the calibration unit 201 adjusts the luminance of the first liquid crystal panel 222 again. Here, the calibration unit 201 corrects the RGB offset value so that the adjusted luminance is one gradation lower than Ybno (Ybna) (RGBon (Ron, Gon, Bon)).
According to the processing of S1904 and S1905, in the third embodiment, when adjusting the black luminance on the liquid crystal panel, the sub-panel is adjusted so that the luminance measurement value by the colorimetric sensor 103 is closer to the target value with a darker value than the target value. A first correction process for correcting the first image data used for the control is performed. Specifically, the difference between the measured value and the target value after performing the first correction process so that the luminance measured value by the colorimetric sensor 103 approaches the target value is larger than the threshold value, and the measured value is the target value. If it is brighter, the correction value for correcting the first image data obtained by the first correction process is corrected. Specifically, the correction value (RGB offset) is corrected in the direction in which the transmitted light of the sub panel becomes dark. In the third embodiment, the correction value is corrected so that the transmitted light becomes darker by one step at the gradation of the sub panel.

  In step S1906, the calibration unit 201 adjusts the RGB offset value of the second liquid crystal panel 221 in order to bring the luminance closer to the target value (Ybt). The calibration unit 201 performs adjustment so that the luminance measurement value (Ybm) obtained by measuring the displayed black patch 901 by the colorimetric sensor 103 is as close as possible to the target value (Ybt). Specifically, the calibration unit 201 adjusts the RGB offset set in the second image data used for controlling the transmittance of the second liquid crystal panel 221 (RGBom (Rom, Gom, Bom)). At this time, the first liquid crystal panel 222 outputs black in a state where the RGB offset value is set to RGBo (Ro, Go, Bo) obtained in S1902 or RGBon (Ron, Gon, Bon) corrected in S1905. Shall.

  In step S <b> 1907, the calibration unit 201 determines whether the luminance measurement value (Ybna) is within the target value range in the state where the luminance adjustment in step S <b> 1906 has been performed. Here, the calibration unit 201 determines whether or not the difference (Dybm) between the luminance measurement value (Ybna) and the target value (Ybt) is equal to or less than a threshold value. Here, the threshold value used for determining whether or not the measured value is within the range of the target value may be determined by the calibration unit 201 based on the value input to the PC 101 by the user via the input unit 220, A value stored in advance in the storage unit 211 of the monitor 102 may be used.

When the difference (Dybm) between the luminance measurement value (Ybna) and the target value (Ybt) is equal to or smaller than the threshold value (S1907: Yes), the calibration unit 201 determines that the luminance has been adjusted to the target value and performs calibration. Exit.
When the difference (Dybm) between the luminance measurement value (Ybna) and the target value (Ybt) is larger than the threshold (S1907: No), the calibration unit 201 determines in S1908 that the luminance cannot be adjusted to the target value. And finish the calibration.

  FIG. 20A shows a case where the measured value Ybno of the black luminance is within the range of the target value Ybt by adjusting the RGB offset value of the first liquid crystal panel 222 to RGBo (Ro, Go, Bo) in S1902 (difference). Dyb ≦ threshold). In this case, as shown in FIG. 20B, since the second liquid crystal panel 221 is not adjusted for RGB offset, the number of displayable gradations of the second liquid crystal panel 221 can be maintained to the maximum after calibration. is there.

In FIG. 21A, by adjusting the RGB offset value of the first liquid crystal panel 222 to RGBo (Ro, Go, Bo) in S1902, the measured value Ybno of the black luminance does not fall within the target value Ybt, and The case where the measured value is larger than the target value (Ybno> Ybt) is shown. In this case, the RGB offset value is corrected by one gradation, the RGB offset value of the first liquid crystal panel 222 becomes RGBon (Ron, Gon, Bon), and the adjusted black luminance measurement value Ybna is the target value Ybt. It is getting smaller. Further, as shown in FIG. 21B, the RGB offset value of the second liquid crystal panel 221 is adjusted to RGBom (Rom, Gom, Bom) in order to bring the black luminance closer to the target value. Thereby, the measured value Ybm of the black luminance is adjusted to a value at which the difference Dybm from the target value Ybt is equal to or less than the threshold value.
In FIG. 22, the black luminance Ybm is adjusted to a target value as a dual liquid crystal display device by adjusting the light emission amount of the backlight 210, the RGB offset of the first liquid crystal panel 222, and the RGB offset of the second liquid crystal panel 221. The situation is shown conceptually.

<Description of white luminance adjustment (RGB gain) in luminance adjustment processing A>
Next, adjustment is performed by the RGB gain of the liquid crystal panel so that the set target value of white luminance is obtained. In the description, reference is made to FIGS. 2, 8, 23, 25, and 26.
FIG. 23 is a flowchart showing white luminance adjustment by gain adjustment of the liquid crystal panel in luminance adjustment processing A.

  In step S1401, the calibration unit 201 displays the white patch 701 on the second liquid crystal panel 221 and the first liquid crystal panel 222 of the display unit 208 as illustrated in FIG. Here, the patch displayed on the first liquid crystal panel 222 is larger than the size of the patch displayed on the second liquid crystal panel 221 and includes all the coordinates of the patch area displayed on the second liquid crystal panel 221.

  In step S1402, the calibration unit 201 adjusts the luminance of the first liquid crystal panel 222, which is a sub-panel having a low resolution and number of gradations. The calibration unit 201 acquires a luminance measurement value (Ywno) obtained by measuring the white patch 701 displayed on the screen with the colorimetric sensor 103 as shown in FIG. The calibration unit 201 adjusts the RGB gain value of the first liquid crystal panel 222 so that the measured luminance value (Ywno) is as close as possible to the target value (Ywt) (RGBg (Rg, Gg, Bg)). . At this time, it is assumed that the second liquid crystal panel 221 outputs white with the RGB gain value set to the maximum value (RGBgx (Rgx, Ggx, Bgx)).

  In step S1403, the calibration unit 201 determines whether the luminance measurement value (Ywno) is within the target value range in the state where the luminance adjustment is performed in step S1402. Here, the calibration unit 201 determines whether or not the difference (Dyw) between the luminance measurement value (Ywno) and the target value (Ywt) is equal to or less than a predetermined threshold value. Here, the threshold value used for determining whether or not the measured value is within the range of the target value may be determined by the calibration unit 201 based on the value input to the PC 101 by the user via the input unit 220, A value stored in advance in the storage unit 211 of the monitor 102 may be used.

When the difference (Dyw) between the luminance measurement value (Ywno) and the target value (Ywt) is equal to or smaller than the threshold value (S1403: Yes), the calibration unit 201 determines that the luminance has been adjusted to the target value and performs calibration. Exit.
When the difference (Dyw) between the luminance measurement value (Ywno) and the target value (Ywt) is larger than the threshold (S1403: No), in S1404, the calibration unit 201 determines that the luminance measurement value (Ywno) is the target value (Ywno). Ywt) is smaller than whether or not.

When the measured luminance value (Ywno) is smaller than the target value (Ywt) (S1404: Yes), the process proceeds to S1405.
When the measured luminance value (Ywno) is equal to or greater than the target value (Ywt) (S1404: No), the process proceeds to S1406.
In step S1405, the calibration unit 201 adjusts the luminance of the first liquid crystal panel 222 again. Here, the calibration unit 201 corrects the RGB gain value so that the adjusted luminance is one gradation higher than Ywno (Ywna) (RGBgn (Rgn, Ggn, Bgn)).

  According to the processing of S1404 and S1405, in the third embodiment, when the white luminance is adjusted on the liquid crystal panel, the luminance value measured by the colorimetric sensor 130 is adjusted to a value brighter than the target value and close to the target value. A first correction process for correcting the first image data used for the control is performed. Specifically, the difference between the measured value and the target value after performing the first correction process so that the luminance measured value by the colorimetric sensor 103 approaches the target value is larger than the threshold value, and the measured value is the target value. If it is darker, the correction value for correcting the first image data obtained by the first correction process is corrected. Specifically, the correction value (RGB gain) can be corrected in the direction in which the transmitted light of the sub panel becomes brighter. In the third embodiment, the correction value is corrected so that the transmitted light becomes brighter by one step at the gradation of the sub panel.

  In step S1406, the calibration unit 201 adjusts the RGB gain value of the second liquid crystal panel 221 in order to bring the luminance closer to the target value (Ywt). The calibration unit 201 performs adjustment so that the luminance measurement value (Ywm) obtained by measuring the displayed white patch 701 by the colorimetric sensor 103 is as close as possible to the target value (Ywt). Specifically, the calibration unit 201 adjusts the RGB gain set in the second image data used for controlling the transmittance of the second liquid crystal panel 221 (RGBgm (Rgm, Ggm, Bgm)). At this time, the first liquid crystal panel 222 outputs white in a state where the RGB gain value is set to RGBg (Rg, Gg, Bg) obtained in S1402 or RGBgn (Rgn, Ggn, Bgn) corrected in S1405. Shall.

  In step S <b> 1407, the calibration unit 201 determines whether or not the measured luminance value (Ywna) is within the target value range in the state in which the luminance is adjusted in step S <b> 1406. Here, the calibration unit 201 determines whether or not the difference (Dywm) between the luminance measurement value (Ywna) and the target value (Ywt) is equal to or less than a threshold value. Here, the threshold value used for determining whether or not the measured value is within the range of the target value may be determined by the calibration unit 201 based on the value input to the PC 101 by the user via the input unit 220, A value stored in advance in the storage unit 211 of the monitor 102 may be used.

When the difference (Dywm) between the luminance measurement value (Ywna) and the target value (Ywt) is equal to or smaller than the threshold value (S1407: Yes), the calibration unit 201 determines that the luminance has been adjusted to the target value and performs calibration. Exit.
When the difference (Dym) between the measured luminance value (Ywna) and the target value (Ywt) is larger than the threshold (S1407: No), in S1408, the calibration unit 201 cannot adjust the luminance to the target value. Determine and end the calibration.

FIG. 24A shows a case where the measured value Ywno of white luminance is within the range of the target value Ywt by adjusting the RGB gain value of the first liquid crystal panel 222 to RGBg (Rg, Gg, Bg) in S1402 (difference). Dyw ≦ threshold). In this case, as shown in FIG. 24B, since the second liquid crystal panel 221 is not adjusted for RGB gain, the number of displayable gradations of the second liquid crystal panel 221 can be maintained to the maximum after calibration. is there.
FIG. 25A shows that the white luminance measurement value Ywno does not fall within the range of the target value Ywt by adjusting the RGB gain value of the first liquid crystal panel 222 to RGBg (Rg, Gg, Bg) in S1402. The measured value is smaller than the target value (Ywno <Ywt). In this case, the RGB gain value is corrected by one gradation, the RGB gain value of the first liquid crystal panel 222 is RGBgn (Rgn, Ggn, Bgn), and the adjusted white luminance measurement value Ywna is the target value Ywt. It is getting bigger. Further, as shown in FIG. 25B, the RGB gain value of the second liquid crystal panel 221 is adjusted to RGBgm (Rgm, Ggm, Bgm) so as to be closer to the white luminance target value. Thereby, the measured value Ywm of the white luminance is adjusted to a value at which the difference Dywm from the target value Ywt is equal to or less than the threshold value.
In FIG. 26, the white luminance Ywm is adjusted to a target value as a dual liquid crystal display device by adjusting the light emission amount of the backlight 210, the RGB gain of the first liquid crystal panel 222, and the RGB gain of the second liquid crystal panel 221. The situation is shown conceptually.

<Description of brightness adjustment processing B (brightness adjustment when the adjustment mode is focused on contrast)>
A calibration method (luminance adjustment processing B) for the second liquid crystal panel 221 and the first liquid crystal panel 222 in the case where the designated adjustment mode is the second mode other than gray balance emphasis (contrast emphasis) will be described. In luminance adjustment processing B, (1) white luminance adjustment by adjusting the light emission amount of the backlight 210, (2) black luminance adjustment by adjusting the gain / offset of the liquid crystal panel, and (3) white luminance adjustment by adjusting the gain / offset of the liquid crystal panel. Execute in this order.

<Description of white luminance adjustment (B / L) in luminance adjustment processing B>
First, the backlight gain is adjusted so that the measured value by the colorimetric sensor 103 approaches the set white luminance target value. The white luminance adjustment by the backlight gain is the same as the white luminance adjustment by the backlight gain in the case of the luminance adjustment processing A, and thus description thereof is omitted.

<Description of black luminance adjustment (RGB offset) in luminance adjustment processing B>
Next, adjustment is performed so that the set black luminance target value is obtained by the RGB offset of the liquid crystal panel. Here, since the adjustment mode is a contrast-oriented mode, adjustment is performed so that the RGB offset values of the second liquid crystal panel 221 and the first liquid crystal panel 222 are minimum values so that the contrast is maximized.

<Description of white luminance adjustment (RGB gain) in luminance adjustment processing B>
Next, adjustment is performed by the RGB gain of the liquid crystal panel so that the set target value of white luminance is obtained. In the description, reference is made to FIGS. 2, 8, 27, 28, and 29.
In step S1801, the calibration unit 201 displays the white patch 701 on the second liquid crystal panel 221 and the first liquid crystal panel 222 of the display unit 208 as illustrated in FIG. Here, the patch displayed on the first liquid crystal panel 222 is larger than the size of the patch displayed on the second liquid crystal panel 221 and includes all the coordinates of the patch area displayed on the second liquid crystal panel 221.

In step S1802, the calibration unit 201 adjusts the luminance of the first liquid crystal panel 222, which is a sub-panel having a low resolution and the number of gradations. The calibration unit 201 acquires a luminance measurement value (Ywn) obtained by measuring the white patch 701 displayed on the screen with the colorimetric sensor 103 as shown in FIG. The calibration unit 201 sets the RG of the first liquid crystal panel 222 so that the luminance measurement value (Ywn) is as close as possible to the target value (Ywt).
The B gain value is adjusted (RGBg (Rg, Gg, Bg)). At this time, the calibration unit 201 sets the luminance measurement value (Ywn) to a value equal to or greater than the target value (Ywt), and the luminance measurement value (Ywn) and the target value (Ywt) are as close as possible. The brightness of the first liquid crystal panel 222 is adjusted.

  In step S1803, the calibration unit 201 determines whether the luminance measurement value (Ywn) is within the target value range in the state where the luminance adjustment is performed in step S1802. Here, the calibration unit 201 determines whether or not the difference (Dyw) between the luminance measurement value (Ywn) and the target value (Ywt) is equal to or less than a predetermined threshold value. Here, the threshold value used for determining whether or not the measured value is within the range of the target value may be determined by the calibration unit 201 based on the value input to the PC 101 by the user via the input unit 220, A value stored in advance in the storage unit 211 of the monitor 102 may be used.

When the difference (Dyw) between the measured luminance value (Ywn) and the target value (Ywt) is equal to or smaller than the threshold (S1803: Yes), the calibration unit 201 determines that the luminance has been adjusted to the target value and performs calibration. Exit.
When the difference (Dyw) between the luminance measurement value (Ywn) and the target value (Ywt) is larger than the threshold (S1830: No), the process proceeds to S1804.

  In step S1804, the calibration unit 201 adjusts the RGB gain value of the second liquid crystal panel 221 in order to bring the luminance closer to the target value (Ywt). The calibration unit 201 performs adjustment so that the luminance measurement value (Ywm) obtained by measuring the displayed white patch 701 by the colorimetric sensor 103 is as close as possible to the target value (Ywt). Specifically, the RGB gain set in the second image data used for controlling the transmittance of the second liquid crystal panel 221 is adjusted (RGBgm (Rgm, Ggm, Bgm)). At this time, it is assumed that the first liquid crystal panel 222 outputs white in a state where the RGB gain value is set to RGBg (Rg, Gg, Bg) obtained in S1802.

  In step S1805, the calibration unit 201 determines whether or not the luminance measurement value (Ywm) is within the target value range in the state where the luminance adjustment in step S1804 has been performed. Here, the calibration unit 201 determines whether or not the difference (Dywm) between the luminance measurement value (Ywm) and the target value (Ywt) is equal to or less than a threshold value.

When the difference (Dywm) between the luminance measurement value (Ywm) and the target value (Ywt) is equal to or smaller than the threshold value (S1805: Yes), the calibration unit 201 determines that the luminance has been adjusted to the target value and performs calibration. Exit.
When the difference (Dym) between the measured luminance value (Ywm) and the target value (Ywt) is larger than the threshold value (S1805: No), the calibration unit 201 cannot adjust the luminance to the target value in S1806. Determine and end the calibration.
Through the above processing, appropriate brightness adjustment in a liquid crystal display device having a dual liquid crystal structure is enabled in accordance with the designated calibration adjustment mode.

As mentioned above, although the preferable Example of this invention was described, this invention is not limited to these Examples, A various deformation | transformation and change are possible within the range of the summary.
In the first embodiment, in the dual liquid crystal, the first display panel is exemplified to have a lower performance regarding the adjustment of the transmittance than the second display panel. However, the optical performance of both may be the same.
Although the example in which the colorimetric sensor 103 is connected to the monitor 102 has been described in the first embodiment, the colorimetric sensor 103 may be connected to the PC 101. In that case, the PC 101 as the calibration device is configured to include measurement means for measuring the transmitted light from the second liquid crystal panel 221 that is the second display panel. When the colorimetric sensor is connected to the PC 101, the colorimetric sensor 1
The PC 101 includes a function of the communication control unit 218 that acquires the measurement value from 03 and a function of the colorimetry control unit 216 that stores the control of the colorimetric sensor 103 and the measurement value.

  In the third embodiment, the case where the performance relating to the adjustment of the transmittance of one liquid crystal panel is lower than the performance relating to the adjustment of the transmittance of the other liquid crystal panel in the dual liquid crystal has been described as an example. In the configuration of the third embodiment, the first display panel (backlight side panel) for adjusting the transmittance of light from the backlight is a sub-panel, and the second display panel for adjusting the transmittance of transmitted light from the first display panel. (Front panel) was the main panel. However, the first display panel that adjusts the transmittance of light from the backlight may be a main panel, and the second display panel that adjusts the transmittance of transmitted light from the first display panel may be a sub-panel.

  In the first and second embodiments, the configuration in which black luminance calibration is performed on the sub-panel (backlight side panel) and white luminance calibration is performed on the main panel (display surface side panel) is illustrated. However, black luminance calibration may be performed on the main panel, and white luminance calibration may be performed on the sub panel. A feature of the first and second embodiments is that the calibration by the sub panel is performed first. As a result, the opportunity for calibration of the main panel accompanied by correction of image data used for control of the main panel is suppressed, so that the high-performance transmittance adjustment function of the main panel can be effectively utilized. Accordingly, when the black luminance calibration is performed on the main panel and the white luminance calibration is performed on the sub panel, the white luminance calibration is performed first, and then the black luminance calibration is performed. By performing the black luminance calibration only when the target value cannot be achieved by the white luminance calibration, the transmittance adjustment function of the high-performance panel (main panel) can be used more effectively.

  In each of the above-described embodiments, the configuration in which the calibration unit 201 that calibrates the display device is provided in the PC 101 that is separate from the monitor 102 that is the display device to be calibrated is exemplified. In this configuration, the PC 101 having the calibration unit 201 is the calibration apparatus of the present invention. However, the monitor 102 may include the calibration unit 201. In that case, the monitor 102 is a display device having a display unit and the calibration device of the present invention. Programs and software that realize various functions of the calibration unit 201 described in the above embodiments by being executed by a computer are included in the embodiments of the present invention. Such a program or software is recorded, and a storage medium or recording medium for supplying the program or software to a computer is included in the embodiment of the present invention. Such a program or software may be supplied to the computer from the outside via a wired or wireless network. A function expansion board and an external device that can add various functions of the calibration unit 201 described in the above embodiments to the computer by being mounted on the computer are included in the embodiments of the present invention.

(Other examples)
The present invention supplies a program that realizes one or more functions of the above-described embodiments to a system or apparatus via a network or a storage medium, and one or more processors in a computer of the system or apparatus read and execute the program This process can be realized. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions.

101: PC, 102: monitor, 103: colorimetric sensor, 201: calibration unit, 208: display unit, 210: backlight, 215: image quality adjustment unit, 221: second liquid crystal panel, 222: first liquid crystal panel

Claims (30)

A first display panel comprising: a light emitting unit; a first display panel that adjusts a transmittance of light from the light emitting unit; and a second display panel that adjusts the transmittance of transmitted light from the first display panel. 2 acquisition means for acquiring a measured value and a target value of transmitted light of the display panel;
Based on the measurement value and the target value acquired by the acquisition means, the display device is calibrated by performing a first correction process for correcting the first image data used for controlling the first display panel. Calibration means;
A control device comprising:   The calibration means is based on the measurement value and the target value acquired by the acquisition means in a state where the first display panel is controlled by the first image data corrected by the first correction process. The control device according to claim 1, wherein a second correction process is performed to correct second image data used for controlling the second display panel.   When the difference between the measured value and the target value after performing the first correction processing so that the measured value of the transmitted light of the second display panel approaches the target value is greater than a threshold value, the calibration means The control device according to claim 2, wherein the second correction process is performed. The acquisition unit acquires a target value of black luminance,
The control device according to claim 1, wherein the calibration unit performs the first correction process with respect to black luminance. The acquisition unit acquires a target value of white luminance,
The control device according to claim 1, wherein the calibration unit performs the first correction process with respect to white luminance. A first display panel comprising: a light emitting unit; a first display panel that adjusts a transmittance of light from the light emitting unit; and a second display panel that adjusts the transmittance of transmitted light from the first display panel. 2 acquisition means for acquiring a measured value and a target value of transmitted light of the display panel;
Based on the measurement value and the target value acquired by the acquisition means, the first display panel and the second display panel, which are used for controlling the sub-panel having the lower performance regarding the adjustment of the transmittance of the first display panel and the second display panel. Calibration means for calibrating the display device by performing a first correction process for correcting image data;
A control device comprising:   The calibration means is based on the measured value and the target value acquired by the acquisition means in a state where the sub panel is controlled by the first image data corrected by the first correction processing. The control device according to claim 6, wherein a second correction process for correcting second image data used for controlling a main panel that is not the sub-panel of the one display panel and the second display panel is performed.   When the difference between the measured value and the target value after performing the first correction processing so that the measured value of the transmitted light of the second display panel approaches the target value is greater than a threshold value, the calibration means The control device according to claim 7, wherein the second correction process is performed. The acquisition unit acquires a target value of black luminance,
The control device according to claim 7, wherein the calibration unit performs the first correction process and the second correction process with respect to black luminance.   10. The control device according to claim 9, wherein the calibration unit performs the first correction process so that a measured value of transmitted light of the second display panel is closer to the target value with a darker value than the target value.   The calibration means calculates a correction value for correcting the first image data by the first correction processing, and the measured value of the transmitted light of the second display panel is brought close to the target value. When the difference between the measured value and the target value after performing the first correction process is larger than a threshold value and the measured value is brighter than the target value, the correction is made in the direction in which the transmitted light of the sub-panel becomes darker. The control device according to claim 9, wherein the second correction process is performed in a state where the value is corrected and the sub-panel is controlled by the first image data corrected with the corrected correction value.   The control device according to claim 11, wherein the calibration unit corrects the correction value so that transmitted light is darkened by one step at the gradation of the sub panel. The acquisition unit acquires a target value of white luminance,
The control device according to claim 7 or 8, wherein the calibration unit performs the first correction process and the second correction process with respect to white luminance.   The control device according to claim 13, wherein the calibration unit performs the first correction process so that a measured value of transmitted light of the second display panel is a value brighter than the target value and approaches the target value.   The calibration means calculates a correction value for correcting the first image data by the first correction processing, and the measured value of the transmitted light of the second display panel is brought close to the target value. When the difference between the measured value and the target value after performing the first correction process is larger than a threshold value and the measured value is darker than the target value, the correction is performed in a direction in which the transmitted light of the sub panel becomes brighter. The control device according to claim 13, wherein the second correction process is performed in a state where the value is corrected and the sub-panel is controlled by the first image data corrected with the corrected correction value.   The control device according to claim 15, wherein the calibration unit corrects the correction value so that transmitted light becomes brighter by one step at the gradation of the sub panel.   The calibration unit performs the calibration by switching between a first mode in which priority is given to the gradation performance of the display device and a second mode in which priority is given to contrast performance. The control device according to claim 11, wherein the correction value is corrected in the first correction processing.   The control device according to claim 17, wherein the calibration unit performs the first correction processing so that a measured value of the transmitted light of the second display panel is as close as possible to the target value in the second mode. The first display panel is the sub-panel;
The control device according to claim 7, wherein the second display panel is the main panel. The first display panel is the main panel;
The control device according to claim 7, wherein the second display panel is the sub panel.   The calibration unit calibrates the display device by further performing a third correction process for correcting a light emission amount of the light emitting unit based on the measurement value and the target value acquired by the acquisition unit. Item 21. The control device according to any one of Items 1 to 20.   The control device according to claim 21, wherein the calibration unit performs the first correction process after performing the third correction process.   The calibration unit further performs a third correction process for correcting the light emission amount of the light emitting unit based on the measurement value and the target value acquired by the acquisition unit, and after performing the third correction process, 21. The control device according to claim 2, wherein the display device is calibrated by performing the first correction process and the second correction process. The calibration means acquires a target value of white luminance,
The control device according to any one of claims 21 to 23, wherein the calibration unit performs the third correction process with respect to white luminance. A measuring means for measuring the transmitted light of the second display panel;
The control device according to claim 1, wherein the acquisition unit acquires the measurement value from the measurement unit.   The control device according to claim 1, further comprising an input unit that receives an input of the target value from a user. The light emitting means, the first display panel, the second display panel,
A display device comprising: the control device according to claim 1. A first display panel comprising: a light emitting unit; a first display panel that adjusts a transmittance of light from the light emitting unit; and a second display panel that adjusts the transmittance of transmitted light from the first display panel. 2 an acquisition step of acquiring a measured value and a target value of transmitted light of the display panel;
Based on the measurement value and the target value acquired in the acquisition step, the display device is calibrated by performing a first correction process for correcting the first image data used for the control of the first display panel. Calibration process;
A control method characterized by comprising: A first display panel comprising: a light emitting unit; a first display panel that adjusts a transmittance of light from the light emitting unit; and a second display panel that adjusts the transmittance of transmitted light from the first display panel. 2 an acquisition step of acquiring a measured value and a target value of transmitted light of the display panel;
Based on the measurement value and the target value acquired in the acquisition step, the first display panel and the second display panel are used for controlling a sub-panel having a lower performance regarding the adjustment of the transmittance of the first display panel and the second display panel. A calibration step of calibrating the display device by performing a first correction process for correcting image data;
A control method characterized by comprising:   A program for causing a computer to execute each step of the control method according to claim 28 or 29.

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