JP2022015916A - Calibration system - Google Patents

Abstract

To obtain a color profile making system with a simple monitor without using a dedicated color measurement sensor.SOLUTION: The present invention relates to a calibration system for a monitor 12, including a PC 10, the monitor 12 for displaying information on the basis of a signal output from the PC 10, and a digital camera 14. In the calibration system, reference data output from the PC 10 is displayed on the monitor 12, the display image of the monitor 12 is taken by the digital camera 14 so that evaluation image data is obtained, and the evaluation image data and the reference data are compared so that a new color profile is made between the PC 10 and the monitor 12.SELECTED DRAWING: Figure 1

Description

The present invention relates to a calibration system for calibrating the accuracy of the displayed color of a monitor that displays data emitted by a personal computer (hereinafter referred to as "PC") including a device such as a smartphone, and particularly a monitor (display). Including a device that includes a screen) and a digital camera, specifically, it relates to a system called software calibration, which creates a color profile when a PC instructs a monitor to display.

Conventionally, as a calibration system for calibrating the accuracy of colors displayed by a monitor integrated with a device or a separate monitor, a method using a device (color measurement sensor) for measuring the color of an image (see, for example, Patent Document 1). )It has been known.

However, the above-mentioned conventional calibration system has a problem of high price because it requires a dedicated color measuring sensor (measuring device 1 shown in FIG. 1 of Patent Document 1).

Japanese Patent Application Laid-Open No. 2002-99265

The problem to be solved is the high price of a calibration system that calibrates the accuracy of the colors displayed by the monitor. An object of the present invention is to obtain a calibration system capable of easily creating a color profile without using a dedicated color measurement sensor.

The calibration system of the present invention is a calibration system of the monitor including a monitor that displays information based on a signal emitted from a personal computer and a digital camera, and uses reference data emitted from the personal computer. Create a new color profile between the personal computer and the monitor by displaying it on the monitor, taking the display image of the monitor with a digital camera, obtaining the evaluation image data, and comparing the evaluation image data with the reference data. It is characterized by doing.

In the calibration system of the present invention, a color profile can be created by using a digital camera used for general photography as a color measurement sensor for a monitor image, so that the colors displayed on the monitor can be easily and inexpensively displayed. You can get a calibration system that calibrates the accuracy.

It shows the calibration system which concerns on Example 1 of this invention. It is the appearance of the personal computer seen from the upper part of FIG. This is the content of the calibration software executed on a personal computer. It shows the calibration system which concerns on Example 2 of this invention.

Hereinafter, the calibration system according to the embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a diagram showing an outline of a calibration system according to a first embodiment of the present invention. The PC 10 is a general smartphone, and the appearance seen from above of FIG. 1 is shown in FIG. The PC 10 includes a monitor 12 and a digital camera 14 on the same side surface. Further, as will be described later, a mirror 16 having a mirror surface 16a for the digital camera 14 to photograph the screen of the monitor 12 is provided. Here, the mirror 16 may be a mirror provided with a dedicated mirror box, or a general hand mirror or a mirror such as a mirror stand may be used. The color chart 12c, which will be described later, shows an image of reflection from the monitor 12 on the mirror surface 16a to the digital camera 14 as a two-dot chain line in FIG.

The PC 10 includes a CPU (central processing unit: hardware) and a program (software) (not shown), and the monitor 12 is required in order to display necessary information and images on the screen 12a of the monitor 12 by these. It has control data called a color profile so that it can be displayed in color, and as a part of calibration as described later, this color profile can be overwritten or switched to the color profile (updated data) newly created by calibration. You can do it.

The PC 10 is provided with a battery, a memory, and the like in addition to the above-mentioned digital camera 14, but since these are well known, detailed description thereof will be omitted. Further, as is well known, the digital camera 14 includes a touch-type shutter button 12b on the screen 12a, a lens (not shown), an image sensor, a focusing mechanism, and the like.

Further, the program of the PC 10 has color chart data as reference data together with software for performing calibration described later. The color chart is image data consisting of a plurality of colors including the three primary colors of light or similar colors and achromatic colors. For example, 16 squares as shown in the color chart 12c displayed on the screen 12a of FIG. It is a rectangle having squares of, and the above-mentioned plurality of colors are assigned to each square. It is desirable that the color chart 12c includes a plurality of data having different brightnesses.

Further, bright detection points 12d, 12e, 12f, and 12g having a white or similar color are formed at the four corners of the color chart 12c. In addition, 12g also serves as one of the above-mentioned 16 squares. Further, the outer shape of the color chart 12c is not limited to a rectangle, and may be a circle or an ellipse.

The color chart 12c, which is standard data, is displayed on the screen 12a of the monitor 12 on the side close to the digital camera 14 of the screen 12a for calibration described later, and the child screen provided on the side far from the digital camera 14 of the screen 12a. On 12h, the main part of the image data obtained by the image sensor of the digital camera 14 can be projected.

FIG. 2 shows a video 12g of the color chart 12c obtained by the digital camera 14 on the sub screen 12h. Further, when the guide marks 12k are displayed at the four corners on the sub screen 12h and the mirror 16 is a hand mirror held in the hand, the position and angle of the mirror surface 16a are adjusted to obtain an image of the color chart 12c. 12m makes it easy to match the guide mark 12k.

Next, the operation of Example 1 will be described. First, the PC 10 and the digital camera 14 set as shown in FIG. 1 are prepared with the above-mentioned program for performing the calibration described below, thereby performing the following operations. Further, it is assumed that the mirror 16 is a hand mirror held by the operator, and that there are a plurality of color charts.

Then, it is desirable to provide a light-shielding curtain or the like around the PC 10 in FIG. 1 or to dim the indoor lighting so that the external light that interferes with the calibration is not reflected on the screen 12a and the mirror surface 16a of the monitor 12. .. When the operator touches the shutter button 12b in this state, the PC 10 executes the calibration program shown in FIG. 3 as follows.

First, it is initialized in step S1. Subsequently, in step S2, as the first calibration, the first color chart of the reference data is displayed as an image on the screen 12a. At this time, the reference data is displayed based on the existing color profile.

Next, in step S3, the image of the color chart 12c displayed on the screen 12a is photographed by the digital camera 14 via the mirror surface 16a, and the evaluation image data is acquired. The shooting conditions at this time are set in the program in advance.

At this time, in the setting as shown in FIG. 1, since the image obtained by the image sensor of the digital camera 14 passes through the mirror surface 16a, the image 12m of the rectangular color chart 12c reflected on the sub screen 12h is a trapezoid or it. The position of the mirror surface 16a is adjusted so that it has a similar shape and is inside the guide mark 12k.

As shown in FIG. 2, when the image 12g is reflected inside the guide mark 12k and the digital camera 14 is in focus and recognizes the detection points 12d, 12e, 12f, 12g, shooting is automatically performed, indicating that effect. A signal sound is emitted as a signal, and the reference data displayed on the screen 12a is switched to the second color chart, the image is taken in the same manner as the first color chart, and the signal sound is emitted again.

When shooting while switching the color chart in this way, the digital camera 14 obtains the positions of the detection points 12d, 12e, 12f, and 12g described above, and based on this, the digital camera 14 is converted into a rectangle close to the color chart 12c on the program. Can be converted into evaluation image data.

Subsequently, in step S4, the evaluation image data taken by the digital camera 14 is compared with the reference data to derive the correction content to be added to the existing color profile, and a new color profile is created based on this. This is a color profile as update data, and by using it in place of the existing color profile, the monitor 12 can display an image with more accurate colors.

At this time, in step S5, the existing color profile provided for the PC 10 can be overwritten and changed, or the existing color profile can be switched to the updated data color profile and used. .. Then, it returns in step S6.

When the calibration is completed in this way, the existing color profile and the color profile of the update data may be alternately switched so that the colors of the monitor 12 before and after the update can be compared and viewed.

As described above, according to the calibration system of the first embodiment, calibration can be performed using a general digital camera 14 without using a dedicated color measurement sensor. Therefore, if the existing mirror 16 can be used, the calibration can be executed only by incorporating a predetermined program in the PC 10, so that a calibration system at a significantly lower cost than the conventional one can be obtained.

Further, since calibration can be performed by taking an image of reference data consisting of a plurality of colors displayed on the monitor 12, even if the reference data consists of a plurality of color charts, the conventional color measurement sensor can be used. When measuring a color in a narrow range as described above, it is not necessary to display a plurality of colors in sequence and measure each time, so that there is an effect that the time required for calibration can be shortened.

The above has been described with an example of fixing the PC 10 and moving the mirror surface 16a of the mirror 16 held in the hand, but conversely, the position and angle of the PC 10 held in the hand with respect to the stationary mirror surface 16a such as a mirror stand. May be adjusted as shown in FIG. In this case, the operator adjusts the position and angle of the PC 10 while viewing the image displayed on the sub screen 12h through the mirror surface 16a.

Further, it is also possible to easily calibrate the other party's personal computer (hereinafter referred to as "the other party's PC") and its monitor, which are different from the PC 10 and are not shown. That is, the monitor screen of the other PC can be photographed by the digital camera 14 of the PC 10, and calibration can be performed in the same manner as described above.

At this time, the software of the other PC may include a program that allows the above calibration and may have reference data. Further, the PC 10 and the partner PC are linked by wire or wirelessly.

At this time, a monitor screen of the other PC may be photographed by a digital camera provided separately from the digital camera 14 on the same side as the monitor 12 included in the PC 10, for example, a digital camera provided on the opposite side of the monitor of the smartphone.

In the above, the PC 10 has been described as a smartphone, but the PC 10 may be a so-called tablet terminal, a notebook-type or desktop-type computer, or a general digital camera. When the PC 10 is a general digital camera, the digital camera itself is equipped with a CPU and a program.

Next, the calibration system of the second embodiment of the present invention will be described. The difference between the second embodiment and the first embodiment is that a dedicated mirror box 20 is used as shown in FIG. 4, and the mirror box 20 has a first mirror 16 having a first mirror surface 16a and a second mirror surface 18a. It has two mirrors 18. The size (area) of the first mirror surface 16a and the second mirror surface 18a can be set to an appropriate size without being bound by FIG.

FIG. 4 shows a main part as in FIG. 1, and details thereof will be omitted. However, the digital camera 14 can photograph the screen 12a via the first mirror surface 16a and the second mirror surface 18a, as in the first embodiment. The rectangular chart 12c does not appear as a trapezoid.

Although not shown, the mirror box 20 is configured to substantially surround the digital camera 14, the screen 12a, the first mirror surface 16a, and the second mirror surface 18a, so as to take pictures in a dark room. .. Of course, it is also possible to calibrate in an environment where the PC 10 is placed and calibrate under a more realistic brightness without intentionally surrounding the surroundings in this way.

Subsequently, although the operation of the second embodiment is basically the same as that of the first embodiment, detailed description thereof will be omitted.

The second embodiment requires a dedicated mirror box 20, but has an advantage that calibration can be easily performed as if it were performed in a dark room in a bright place.

The above explanation is based on the premise that the monitor is calibrated using a general digital camera, but by applying this, the reference data printed by the printer is photographed with the digital camera, and the color profile of the printer is obtained. It can also be used for renewal color calibration.

Based on the general knowledge of those skilled in the art, the calibration system of the present invention can be used for applications by utilizing the performance and software technology of image sensors and CPUs of monitors and digital cameras, which are advancing year by year, without being bound by the above configurations. It can be carried out in a manner that has been improved and devised accordingly.

The calibration system of the present invention can be used to improve color accuracy not only in photographic images but also in displays such as video images and computer games.

10 Personal computer (PC)
12 Monitor 12a Screen 12h Child screen 12k Guide mark 14 Digital camera 16a Mirror surface, 1st mirror surface 18a 2nd mirror surface 20 Mirror box

Claims (6)

A monitor that displays information based on signals emitted from a personal computer,
A calibration system for the monitor equipped with a digital camera.
By displaying the reference data emitted from the personal computer on the monitor, photographing the display image of the monitor with the digital camera to obtain evaluation image data, and comparing the evaluation image data with the reference data. A calibration system characterized by creating a new color profile between the personal computer and the monitor. Claim 1 is characterized in that the reference data is a rectangular, circular, or elliptical color chart composed of a plurality of colors, and the color chart has a plurality of detection points recognizable by the digital camera. The calibration system described in. One of claims 1 or 2, wherein the personal computer integrally includes the digital camera and the monitor on the same side surface, reflects the display image of the monitor on a mirror surface, and captures the image with the digital camera. The calibration system described in. The calibration system according to any one of claims 1 to 3, wherein a sub screen is provided on the monitor, and an image to be taken by the digital camera is displayed on the sub screen. The calibration system according to any one of claims 1 to 4, wherein the digital camera automatically obtains the evaluation image when the digital camera is in focus and recognizes the detection point. The digital camera of the personal computer calibrates a monitor provided in a personal computer different from the personal computer, so that the personal computer and the other personal computer can exchange data wirelessly. The calibration system according to any one of claims 1 to 5.

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