JP5875319B2 - Display control apparatus and control method thereof - Google Patents

Description

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

  In an image production site, an image production monitor that is an image display device is required to display an image input from a PC (Personal Computer) with an accurate color and brightness. Therefore, in order to keep the display performance of the image display device constant, the brightness, color temperature, color gamut, and gradation characteristics of the image displayed on the image display device are adjusted by an adjustment operation called calibration.

In recent years, a multi-monitor environment in which a plurality of monitors are connected to one PC to improve the efficiency of image production work has become widespread. As calibration in a multi-monitor environment, there are single unit calibration and copy calibration.
In the single unit calibration, a deviation (such as a change in display performance with time) of display performance (luminance, color temperature, color gamut, gradation characteristics) of one monitor with respect to a target value set in the monitor is calibrated.
In copy calibration, a monitor with a certain display performance is set as a copy source monitor, an image displayed on the copy source monitor is measured by a sensor, and a colorimetric value of the sensor is set as a target value. Thereafter, another monitor is set as the copy destination monitor, and the deviation of the display performance of the copy destination monitor from the determined target value is calibrated. Thereby, the display performance of a plurality of monitors is made equal.

Here, an operation procedure until two conventional calibrations are executed will be described. The calibration is mainly executed by PC monitor adjustment software. The monitor adjustment software has, for example, a single calibration function and a copy calibration function.
FIG. 8 is a display example of a menu image by conventional monitor adjustment software. In order to execute the calibration, the user performs an operation of selecting the calibration to be executed from the carry list displayed in the menu image. In the example of FIG. 8, the user performs an operation of selecting single calibration or copy calibration.
When the user selects copy calibration, the monitor adjustment software displays an image including a list of monitors (monitor list image). The user performs an operation of selecting a copy source monitor and a copy destination monitor from the monitor list.
FIG. 9 is a display example of a monitor list image. The monitor list image includes a list of manufacturer names, model names, serial numbers, etc., of monitors (for example, monitors currently connected to the PC). The user selects a copy source monitor and a copy destination monitor for copy calibration from this list. In general, the manufacturer name and model name of the monitor used at one work site are often the same. The serial number is often a similar character string. The operation of selecting the copy source monitor and the copy destination monitor from such a similar character string is very complicated and causes an erroneous operation (incorrect selection of the copy source monitor and the copy destination monitor).

A method for improving operability in a multi-monitor environment is disclosed in Patent Document 1, for example. Specifically, in the technique disclosed in Patent Document 1, the function displayed on the task bar is limited to the function corresponding to the monitor on which the task bar is displayed.
However, even if the technique disclosed in Patent Document 1 is applied to the monitor adjustment software, it is necessary to display a list image such as the manufacturer name, model name, and serial number of the monitor as a monitor list image. It cannot be solved.

JP 2007-183781 A

  An object of this invention is to provide the technique which can perform desired calibration by simple operation.

The display control device of the present invention
The display performance of the first monitor that is one of the plurality of connected monitors is changed to the display performance of the second monitor that is different from the first monitor of the plurality of monitors. In order to make it closer , the image displayed on the second monitor is color-measured by a sensor, and the deviation of the display performance of the first monitor from the target value is calibrated using the colorimetric value of the sensor as the target value. A display control apparatus capable of executing copy calibration, which is calibration,
When executing calibration, an image display dialog including an image for calibration, and an execution start dialog that prompts the user to start calibration,
Display means for displaying on any of the plurality of monitors,
Change means for changing a display position of the image display dialog and a display position of the execution start dialog between the plurality of monitors according to a user operation,
Execution means for executing calibration based on display positions of the image display dialog and the execution start dialog when the user is instructed to start calibration by operating the execution start dialog When,
Have
When the image display dialog and the execution start dialog are displayed on different monitors, the execution means displays the monitor on which the execution start dialog is displayed as the first monitor and the image display dialog. The copy calibration is performed using the second monitor as the second monitor.

The display control device control method of the present invention includes:
The display performance of the first monitor that is one of the plurality of connected monitors is changed to the display performance of the second monitor that is different from the first monitor of the plurality of monitors. In order to make it closer , the image displayed on the second monitor is color-measured by a sensor, and the deviation of the display performance of the first monitor from the target value is calibrated using the colorimetric value of the sensor as the target value. A control method for a display control apparatus capable of executing copy calibration, which is calibration,
Display step for displaying an image display dialog including an image for calibration and an execution start dialog for prompting the user to start the calibration on any of the plurality of monitors when performing calibration When,
A change step of changing a display position of the image display dialog and a display position of the execution start dialog between the plurality of monitors according to a user operation;
An execution step of executing calibration based on the display positions of the image display dialog and the execution start dialog when the user is instructed to start calibration by operating the execution start dialog. When,
Have
In the execution step, when the image display dialog and the execution start dialog are displayed on different monitors, the monitor on which the execution start dialog is displayed is the first monitor, and the image display dialog is displayed. Copy calibration is performed using the second monitor as the second monitor.

  According to the present invention, a desired calibration can be executed with a simple operation.

Example of configuration of display control system according to embodiment 1 Example of functional configuration of PC according to embodiment 1 Example of operation of PC according to embodiment 1 Display example of dialog according to embodiment 1 Example of operation of PC according to embodiment 2 Display example of dialog according to embodiment 2 Display example of dialog according to embodiment 1 Menu image display example using conventional monitor adjustment software Display example of conventional monitor list image

Embodiments of the present invention will be described below with reference to the drawings.
<Example 1>
FIG. 1 is a conceptual diagram illustrating an example of a configuration of a display control system according to Embodiment 1 of the present invention.
The display control system according to the present embodiment includes a PC 100 that is an information processing apparatus (display control apparatus), and a plurality of monitors (monitors 200 and 300) connected to the PC 100. The PC 100 and the monitor are connected using an image signal cable. The image signal cable is, for example, a DVI (Digital Visual Interface) cable. The DVI cable includes an image line for transmitting a digital image signal, and a data communication line called a DDC (Display Data Channel) line for transmitting unique information and commands of the monitor.
In the present embodiment, two monitors 200 and 300 are connected to the PC 100, but the number of monitors connected to the PC 100 is not limited to this. For example, 3, 5, and 10 monitors may be connected to the PC 100.

  The PC 100 can acquire resolution information of a monitor connected using the DDC line through the DDC line. In the present embodiment, the PC 100 generates and stores display area information for each monitor from the resolution information for each connected monitor. Specifically, information representing 640 pixels in the horizontal direction × 480 pixels in the vertical direction is acquired as the resolution information of the monitor 200 and the monitor 300. Then, information representing a rectangular area whose top left coordinate is (0, 0) and whose bottom right coordinate is (639, 479) is generated and held as display area information of the monitor 200. Also, information representing a rectangular area whose upper left coordinate is (640, 0) and whose lower right coordinate is (1279, 479) is generated and held as display area information of the monitor 300.

A mouse 400 and a sensor 500 are connected to the PC 100. The PC 100, the mouse 400, and the sensor 500 are connected using a communication cable. The communication cable is, for example, a USB (Universal Serial Bus) cable.
The mouse 400 receives a user operation and transmits a signal corresponding to the user operation to the PC 100. The PC 100 performs processing in accordance with a user operation (specifically, the above signal). For example, the user can move a display object such as the mouse cursor 101 displayed on the monitor by the PC 100 by operating the mouse 400. The user can also operate the mouse 400 to generate a dialog (display the dialog on the monitor; execute the software), move or delete the dialog displayed on the monitor, and the like.
The sensor 500 is installed on the monitor screen to measure the monitor screen light. Specifically, the sensor 500 measures the brightness and chromaticity of the monitor screen light at the installation position.

  In this embodiment, monitor adjustment software is installed in the PC 100. The monitor adjustment software is software for calibrating a monitor connected to the PC 100. When the monitor adjustment software is executed (when calibration is executed), the PC 100 displays the image display dialog 102 and the execution start dialog 103 on each of a plurality of connected monitors. The image display dialog 102 is a dialog including a single-color patch image that is an image for calibration (an image measured by the sensor 500). The execution start dialog 103 is a dialog that prompts the user to start the execution of calibration. For example, the execution start dialog 103 includes a button for starting the execution of calibration.

FIG. 2 is a block diagram illustrating an example of a functional configuration of the PC 100 according to the first embodiment.
The user input unit 104 receives, from the mouse 400, user operation information indicating the operation contents of the mouse by the user (contents of the user operation) such as the moving distance of the mouse 400 via the communication cable, and transmits it to the dialog control unit 106. To do.
The sensor value input unit 105 receives sensor values including luminance and chromaticity from the sensor 500 and transmits them to the calibration control unit 110.

  The dialog control unit 106 controls generation, deletion, movement, and the like of the dialog according to the user operation information received from the user input unit 104, and transmits the dialog information including the dialog parts and the position coordinates to the image generation unit 107. To do. Specifically, when calibration is executed, such as when there is a user operation for executing the monitor adjustment software, control for generating the image display dialog 102 and the execution start dialog 103 is performed.

  The image generation unit 107 generates image information based on the dialog information received from the dialog control unit 106 and transmits the image information to the image signal output unit 108. For example, when there is a user operation for displaying a dialog, a generation process for generating the dialog and a combination process for combining the generated dialog with another image are performed. Then, image information representing an image obtained by combining the dialog and another image is transmitted to the image signal output unit 108. When there is a user operation to move the dialog, the compositing position of the dialog in the compositing process is changed.

  The image signal output unit 108 converts the image information into an image signal, and outputs the image signal to the monitor 200 and the monitor 300 via the image signal cable. Thereby, an image based on the image signal is displayed on the monitors 200 and 300. Note that the image information may be generated individually for each monitor, or the image information may be generated so that a screen combining the screen of the monitor 200 and the screen of the monitor 300 is used as one virtual screen. Good.

As described above, in this embodiment, when the calibration is executed by the dialog control unit 106, the image generation unit 107, and the image signal output unit 108, the image display dialog and the execution start dialog are respectively connected to the PC 100. Displayed on one of multiple monitors. Calibration is executed by a CPU (Central Processing Unit) included in the PC 100 controlling the function of each block, reading monitor adjustment software stored in a ROM (Read Only Memory) (not shown), and developing it in the memory. Is done. When executing calibration, the image display dialog and the execution start dialog may be displayed on the same monitor, or may be displayed on different monitors.
Also, with these configurations, the display position of the image display dialog and the display position of the execution start dialog are changed between a plurality of monitors (between the monitor 200 and the monitor 300) in accordance with a user operation.

The dialog position management unit 109 acquires dialog position information representing the display positions (position coordinates) of the image display dialog 102 and the execution start dialog 103 displayed on the screen from the dialog control unit 106.
Further, the dialog position management unit 109 determines a calibration mode based on the display positions of the image display dialog 102 and the execution start dialog 103, and outputs mode information indicating the determined calibration mode to the calibration control unit 110. To do. For example, the dialog position management unit 109 determines the calibration mode every time the display position of the image display dialog 102 or the execution start dialog 103 is changed by a user operation. The dialog position management unit 109 may output the mode information every time the calibration mode is determined, or outputs the mode information only when the determined calibration mode is different from the previously determined calibration mode. May be.

The calibration control unit 110 receives dialog control information including a calibration execution start instruction and an end instruction from the dialog control unit 106, and starts and ends execution of calibration according to the dialog control information.
For example, when the user operates the execution start dialog and is instructed to start calibration, the dialog control unit 106 outputs a calibration execution start instruction to the calibration control unit 110. In response to receiving a calibration execution start instruction from the dialog control unit 106, the calibration control unit 110 starts executing calibration. At this time, the calibration mode to be executed is determined according to the mode information last received from the dialog position management unit 109. The monitor used for calibration is determined based on the dialog position information (display positions of the image display dialog and the execution start dialog). The dialog position information may be acquired from the dialog control unit 106 or may be acquired from the dialog position management unit 109.
During calibration execution, the calibration control unit 110 receives a sensor value (measured value) from the sensor value input unit 105 and evaluates the display performance of the target monitor. Then, the calibration control unit 110 calculates image quality correction data of the monitor (target monitor) to be calibrated and transmits it to the data input / output unit 111.
When the calibration is completed, for example, when the display performance of the target monitor reaches the target value, the dialog control unit 106 outputs a calibration execution end instruction to the calibration control unit 110. In response to receiving the calibration execution end instruction from the dialog control unit 106, the calibration control unit 110 ends the execution of calibration.

  As described above, in this embodiment, when the dialog position management unit 109 and the calibration control unit 110 are instructed to start calibration by a user operating the execution start dialog, the image display dialog is displayed. Calibration is executed based on the display position of the execution start dialog.

  The data input / output unit 111 outputs the image quality correction data received from the calibration control unit 110 to the target monitor (the monitor 200 or the monitor 300) via the data communication line.

Hereinafter, a processing flow until the execution of calibration of the PC 100 according to the first embodiment is described.
In the present embodiment, it is assumed that the PC 100 can execute single unit calibration and copy calibration. The single unit calibration is a calibration that brings the display performance of one of the plurality of monitors connected to the PC 100 close to a predetermined target value. In the copy calibration, the display performance of a first monitor (target monitor; copy destination monitor) that is one of a plurality of monitors connected to the PC 100 is determined according to the first monitor of the plurality of monitors. Is a calibration approaching the display performance of a second monitor (copy source monitor) which is a different monitor.
FIG. 3 is a flowchart illustrating a processing flow until the execution of calibration of the PC 100 according to the first embodiment is started. The following processing flow may be executed with a trigger instructed by the user to execute the monitor adjustment software, or may be executed periodically.

First, the dialog position management unit 109 acquires the position information of the execution start dialog 103 from the dialog control unit 106 (S301). For example, the upper left position coordinates (200, 400) of the rectangular execution start dialog 103 are acquired.
Next, the dialog position management unit 109 acquires position information of the image display dialog 102 (S302). For example, the upper left position coordinate (200, 100) of the rectangular image display dialog 102 is acquired.
Note that the position information of the dialog is not limited to the position coordinates at the upper left of the dialog. The dialog position information may be information representing the position of the dialog, such as the position coordinates of the center of the dialog or the position coordinates of the lower right.

  After S302, the dialog position management unit 109 determines whether the two dialogs are displayed on the same monitor from the position information of the two diagrams and the display area information of a plurality of connected monitors. Determination is made (S303). Specifically, it is determined whether or not the display positions of the two diagrams are located within the display area of the same monitor. The display area information of the monitor is generated by the dialog position management unit 109 when performing the process of S303, for example. The display area information of the monitor may be generated by the dialog position management unit 109 when the monitor is connected to the PC 100. The display area information of the monitor may be generated by a function other than the dialog position management unit 109.

When it is determined that two dialogs are displayed on the same monitor (S303: Yes), the dialog position management unit 109 sets the calibration mode to the single calibration mode in the calibration control unit 110. To instruct. In response to the instruction, the calibration control unit 110 sets the calibration mode to the single calibration mode (S304).
When it is determined that the two dialogs are displayed on different monitors (S303: No), the dialog position management unit 109 causes the calibration control unit 110 to set the calibration mode to the copy calibration mode. To instruct. In response to the instruction, the calibration control unit 110 sets the calibration mode to the copy calibration mode (S305).

Until the calibration control unit 110 receives a calibration execution instruction from the dialog control unit 106 (until the user presses the execution button of the execution start dialog), the processes of S301 to S306 are repeated.
When the user presses the execution button (S306: Yes), the calibration control unit 110 determines a monitor to be used for calibration (S307). Specifically, when the single unit calibration mode is set, the execution start dialog 103 is displayed.
From the position information, the monitor on which the execution start dialog 103 is displayed is the target monitor. When the copy calibration mode is set, from the position information of the execution start dialog 103, the monitor on which the execution start dialog 103 is displayed is set as the copy destination monitor. From the position information of the image display dialog 102, the monitor on which the image display dialog 102 is displayed is set as the copy source monitor.
Subsequent to S307, the calibration control unit 110 starts executing the calibration of the target monitor in the set calibration mode (S308). That is, in this embodiment, when the image display dialog and the execution start dialog are displayed on the same monitor, the single calibration of the monitor is executed. Further, when the image display dialog and the execution start dialog are displayed on different monitors, copy calibration is executed. At this time, the monitor on which the execution start dialog is displayed is the copy destination monitor, and the monitor on which the image display dialog is displayed is the copy source monitor.

FIG. 4 is a display example of the dialog according to the first embodiment.
In the example of FIG. 4, the image display dialog 102 and the execution start dialog 103 are displayed on different monitors. In this case, a No determination is made in S303, and a copy calibration mode is set in S305.
When the user presses the execution button of the execution start dialog 103 in the state of FIG. 4, the monitor on which the execution start dialog 103 is displayed is determined as a copy destination monitor in S307. Further, the monitor on which the image display dialog 102 is displayed is determined as the copy source monitor. Specifically, in the example of FIG. 4, the execution start dialog 103 is displayed on the monitor 200, and the image display dialog 102 is displayed on the monitor 300. Therefore, the monitor 200 is determined as the copy destination monitor and the monitor 300 is determined as the copy source monitor.
In step S308, copy calibration is executed with the monitor on which the execution start dialog 103 is displayed as the copy destination monitor and the monitor on which the image display dialog 102 is displayed as the copy source monitor.

Further, as shown in FIG. 1, when the image display dialog 102 and the execution start dialog 103 are displayed on the same monitor, a Yes determination is made in S303, and a single calibration mode is set in S304.
When the user presses the execution button of the execution start dialog 103 in the state of FIG. 1, the monitor on which the execution start dialog 103 is displayed is determined as the target monitor in S307. Specifically, in the example of FIG. 1, since the execution start dialog 103 is displayed on the monitor 200, the monitor 200 is determined as the target monitor.
In step S308, the single calibration of the monitor on which the execution start dialog 103 is displayed is executed.

Here, an outline of the operation when performing calibration will be described.
First, an outline of the operation when executing single unit calibration will be described.
The single unit calibration is a calibration for calibrating a deviation from a predetermined target value of the display performance of the monitor. Such a shift in display performance is caused by changes over time.
First, the PC 100 reads out a target brightness or a target color gamut preset by a user, a manufacturer, or the like as a target value.
Next, the PC 100 acquires a measurement value of the patch image (patch image in the image display diagram) displayed on the target monitor from the sensor 500. For example, the measurement of the patch image (such as the brightness and chromaticity of the screen light of the monitor in the area where the patch image is displayed) is performed as follows. First, the PC 100 notifies the user of the installation of the sensor 500 when performing calibration. For example, a message such as “Please install a sensor on the patch image” is displayed on the monitor. Thereafter, the PC 100 determines that the sensor 500 is installed on the monitor when the variation in the measurement value of the sensor 500 falls within a predetermined range, and acquires the measurement value at that time as the measurement value of the patch image.
Then, the PC 100 calculates image quality correction data including a correction coefficient that brings the acquired measurement value closer to the target value and gradation correction table data. Thereafter, the calculated image quality correction data is transmitted to the target monitor via the data communication line. As a result, the target monitor displays an image using the transmitted image quality correction data. That is, the display performance of the target monitor is set as the target value.
Note that when calibration is performed, the display position of the patch image may be automatically changed to the center (for example, the center position) of the screen of the target monitor. Since the central portion of the screen is considered to be a region that the user particularly pays attention to, the calibration can be suitably performed by setting the display performance of such a region as a target value.

Next, an outline of operation when performing copy calibration will be described.
Copy calibration is calibration that matches the display performance of the copy source monitor and the copy destination monitor by measuring the display performance of the copy source monitor and targeting the colorimetric value.
First, the PC 100 acquires the measurement value of the patch image displayed on the copy source monitor from the sensor 500. Then, a target value (target luminance, target color gamut, etc.) that is the display performance of the copy source monitor is calculated from the acquired measurement value.
Next, the PC 100 changes the display position of the image display dialog 102 within the screen of the copy destination monitor, and prompts the user to reinstall the sensor 500. Then, the PC 100 acquires the measurement value of the patch image displayed on the copy destination monitor from the sensor 500.
Next, the PC 100 calculates image quality correction data including a correction coefficient that brings the measurement value of the single-color patch image displayed on the copy destination monitor close to the target value and gradation correction table data. Thereafter, the calculated image quality correction data is transmitted to the copy destination monitor via the data communication line. As a result, the copy destination monitor displays an image using the transmitted image quality correction data. That is, the display performance of the copy destination monitor is set to the target value (display performance of the copy source monitor).

  As described above, according to the first embodiment, the calibration mode and the monitor to be used are determined according to the positions of the image display dialog and the execution start dialog that can be moved by the user operation. Thereby, the user can instruct | indicate execution of exact calibration intuitively. That is, it is possible to execute desired calibration by a simple operation of determining the positions of the image display dialog and the execution start dialog and instructing execution of calibration.

In the present embodiment, the case where the display control device is a PC has been described, but the display control device may not be a PC. Any device that calibrates the monitor may be used.
In the present embodiment, the case has been described in which the display control apparatus can execute the single calibration and the copy calibration, but the configuration of the display control apparatus is not limited to this. For example, the display control apparatus may be able to execute only copy calibration. Even with such a configuration, it is possible to intuitively select the copy source monitor and the copy destination monitor, and it is possible to execute accurate copy calibration without erroneous selection of the monitor. .
In the present embodiment, the case where the user operation is performed using the mouse has been described, but the user operation is not limited to this. For example, it may be performed using a keyboard, a touch pad, or the like.
In this embodiment, the case where the calibration image is a patch image has been described. However, the calibration image is not limited to the patch image. For example, a predetermined pattern image may be used. In addition, as a calibration image, one single-color patch image may be displayed, or a plurality of single-color patch images having different colors may be displayed in order.
In addition to the image display dialog and the execution start dialog, for example, a display object including an icon indicating a figure or a picture that can be generated by software, a window for displaying a sentence or an image, or the like may be used.

In this embodiment, the case where the number of monitors connected to the PC 100 is two has been described. However, the number of monitors connected to the PC 100 may be three or more. Even in such a case, the calibration mode and the monitor to be used can be selected by the same process as described above.
In the example of FIG. 7, the execution start dialog 103 is displayed on the monitor 200, and the image display dialog 102 is displayed on the monitor 301. Therefore, copy calibration is executed using the monitor 200 as the copy destination monitor and the monitor 301 as the copy source monitor.

<Example 2>
In the second embodiment, a case where the PC 100 (display control apparatus) can further execute uniformity calibration will be described. Uniformity calibration is calibration that suppresses unevenness in display performance of one of the plurality of monitors connected to the PC 100. Specifically, in uniformity calibration, a calibration image (patch image) is measured for each small region obtained by dividing the display region of one monitor. Thereafter, image quality correction data is calculated using these measured values, and the image quality correction data is applied to the monitor. Thereby, display unevenness of the entire screen is corrected (suppressed). Therefore, in uniformity calibration, patch images are displayed in order not only at one place but at a plurality of places.
In the following, it is assumed that monitors 200 and 300 are connected to the PC 100 as in FIG.

FIG. 5 is a flowchart illustrating a processing flow until the execution of calibration of the PC 100 according to the second embodiment is started.
Since the processing of S301 to S303 and S305 is the same as that of the first embodiment, the description thereof is omitted.
In S303, when it is determined that two dialogs are displayed on the same monitor (S303: Yes), the dialog position management unit 109 displays the image display dialog 102 within a predetermined area of the monitor screen. It is determined whether or not there is (S501). For example, it is determined whether or not the image display dialog 102 is displayed in the central area of the monitor screen. Specifically, it is determined whether or not the center position of the image display dialog is within an area of 150 pixels in the vertical and horizontal directions from the central position of the monitor. That is, when the image display dialog is displayed on the monitor 200, the center position of the image display dialog is (170, 90) at the uppermost left coordinate and (470, 390) at the lowermost right coordinate. It is determined whether or not it is located within a certain rectangular area.

If it is determined that the image display dialog 102 is displayed in a predetermined area (S501: Yes), the dialog position management unit 109 instructs the calibration control unit 110 to change the calibration mode to the single calibration mode. Instruct to do. In response to the instruction, the calibration control unit 110 sets the calibration mode to the single unit calibration mode (S502).
When it is determined that the image display dialog 102 is not displayed within the predetermined area (S501: No), the dialog position management unit 109 causes the calibration control unit 110 to set the calibration mode to the uniformity calibration mode. Instruct. In accordance with the instruction, the calibration control unit 110 sets the calibration mode to the uniformity calibration mode (S503).

Until the user presses the execution button of the execution start dialog, the processes of S301 to S504 are repeated.
When the user presses the execute button (S504: Yes), the calibration control unit 110 determines a monitor to be used for calibration (S505). Specifically, when the single unit or uniformity calibration mode is set, the monitor on which the execution start dialog 103 is displayed is determined as the target monitor from the position information of the execution start dialog 103. When the copy calibration mode is set, as in the first embodiment, the monitor on which the execution start dialog 103 is displayed is the copy destination monitor, and the monitor on which the image display dialog is displayed is the copy source monitor. The
Following S505, the calibration control unit 110 starts executing the calibration of the target monitor in the set calibration mode (S506). That is, in this embodiment, when the image display dialog and the execution start dialog are displayed on the same monitor, and the image display dialog is displayed within a predetermined area of the monitor screen, the monitor alone is displayed. Calibration is performed. When the image display dialog and the execution start dialog are displayed on the same monitor and the image display dialog is displayed outside a predetermined area of the monitor screen, the uniformity calibration of the monitor is executed. Then, when the image display dialog and the execution start dialog are displayed on different monitors, copy calibration is executed as in the first embodiment.

FIG. 6 is a display example of a dialog according to the second embodiment.
In the example of FIG. 6, the image display dialog 102 and the execution start dialog 103 are displayed on the same monitor. In the example of FIG. 6, the image display dialog 102 is displayed outside the central area of the monitor. In other words, the center position of the image display dialog 102 is located outside the central area of the monitor. In such a case, Yes is determined in S303, No is determined in S501, and a uniformity calibration mode is set in S503.
When the user presses the execution button of the execution start dialog 103 in the state of FIG. 6, the monitor on which the execution start dialog 103 is displayed is determined as the target monitor in S505. Specifically, in the example of FIG. 6, since the execution start dialog 103 is displayed on the monitor 200, the monitor 200 is determined as the target monitor.
In step S506, the uniformity calibration of the monitor on which the execution start dialog 103 is displayed is executed.

  As shown in FIG. 1, when the image display dialog 102 and the execution start dialog 103 are displayed on the same monitor and the image display dialog 102 is displayed in the central area of the monitor, the monitor Single calibration is executed. Since the copy calibration is the same as that of the first embodiment, the description thereof is omitted.

  As described above, according to the second embodiment, when the image display dialog and the execution start dialog are displayed on the same monitor, either single unit calibration or uniformity calibration is performed according to the display position of the image display dialog. Is executed. Specifically, single calibration is executed when an image display dialog is displayed within a predetermined area in the screen, and uniformity calibration is performed when an image display dialog is displayed outside the predetermined area within the screen. Is executed. Thereby, the user can instruct | indicate execution of exact calibration intuitively. Specifically, the user can intuitively select the calibration mode and the monitor to be used.

  In the present embodiment, the case where the predetermined area is the central area of the screen has been described. However, the predetermined area is not limited thereto. For example, the predetermined area may be an area on the lower right side of the screen. However, in the single calibration, since it is preferable to match the display performance at the center of the screen to the target value, the patch image is often displayed at the center of the screen. Therefore, the user can select the calibration to be executed more intuitively when the single calibration is executed when the image display diagram is displayed in the center area of the screen.

100 PC
106 Dialog control unit 107 Image generation unit 108 Image signal output unit 109 Dialog position management unit 110 Calibration control unit

Claims (5)

The display performance of the first monitor that is one of the plurality of connected monitors is changed to the display performance of the second monitor that is different from the first monitor of the plurality of monitors. In order to make it closer , the image displayed on the second monitor is color-measured by a sensor, and the deviation of the display performance of the first monitor from the target value is calibrated using the colorimetric value of the sensor as the target value. A display control apparatus capable of executing copy calibration, which is calibration,
Display means for displaying an image display dialog including an image for calibration and an execution start dialog for prompting the user to start the calibration on any of the plurality of monitors when performing calibration When,
Change means for changing a display position of the image display dialog and a display position of the execution start dialog between the plurality of monitors according to a user operation,
Execution means for executing calibration based on display positions of the image display dialog and the execution start dialog when the user is instructed to start calibration by operating the execution start dialog When,
Have
When the image display dialog and the execution start dialog are displayed on different monitors, the execution means displays the monitor on which the execution start dialog is displayed as the first monitor and the image display dialog. A display control apparatus, wherein copy calibration is executed by using the second monitor as the second monitor. The display control device can further execute a unit calibration for bringing the display performance of one of the plurality of monitors close to a predetermined target value,
The display control apparatus according to claim 1, wherein when the image display dialog and the execution start dialog are displayed on the same monitor, the execution unit executes unit calibration of the monitor. The display control device includes: a unit calibration that brings a display performance of one of the plurality of monitors close to a predetermined target value; and a uniformity that suppresses unevenness in the display performance of one of the plurality of monitors. Calibration can be performed further,
The execution means includes
When the image display dialog and the execution start dialog are displayed on the same monitor and the image display dialog is displayed within a predetermined area of the monitor screen, the single calibration of the monitor is executed. And
When the image display dialog and the execution start dialog are displayed on the same monitor and the image display dialog is displayed outside the predetermined area of the monitor screen, the uniformity calibration of the monitor is performed. The display control apparatus according to claim 1, wherein the display control apparatus is executed. The display control apparatus according to claim 3, wherein the predetermined region is a central region of a monitor screen. The display performance of the first monitor that is one of the plurality of connected monitors is changed to the display performance of the second monitor that is different from the first monitor of the plurality of monitors. In order to make it closer , the image displayed on the second monitor is color-measured by a sensor, and the deviation of the display performance of the first monitor from the target value is calibrated using the colorimetric value of the sensor as the target value. A control method for a display control apparatus capable of executing copy calibration, which is calibration,
Display step for displaying an image display dialog including an image for calibration and an execution start dialog for prompting the user to start the calibration on any of the plurality of monitors when performing calibration When,
A change step of changing a display position of the image display dialog and a display position of the execution start dialog between the plurality of monitors according to a user operation;
An execution step of executing calibration based on the display positions of the image display dialog and the execution start dialog when the user is instructed to start calibration by operating the execution start dialog. When,
Have
In the execution step, when the image display dialog and the execution start dialog are displayed on different monitors, the monitor on which the execution start dialog is displayed is the first monitor, and the image display dialog is displayed. A display control apparatus control method, wherein copy calibration is executed using the current monitor as the second monitor.

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