JP6925489B2 - Chart device - Google Patents

Description

The present invention relates to a chart device. This chart device relates to the technology of broadcasting system and video system.

When shooting and recording video of a television broadcast program, multiple cameras are usually used. At least before the actual shooting / recording starts, each camera shoots a predetermined chart and adjusts the color of the shot image. In the color adjustment, the parameters of the image captured by each camera are adjusted so that the colors of the images output by all the cameras are the same. The charts used for color adjustment include, for example, the Japan Electronics and Information Technology Industries (JEITA) and the Japan Electronics and Information Technology Industries (JEITA). There is a standardized test chart. The chart 80 illustrated in FIG. 1 is an ITE grayscale chart. Chart 80 is a reflective chart including an achromatic region having 12 levels of density from black to white.

"Test chart", [online], General Incorporated Association Video Information Media Society, [Search on February 29, 2016], Internet <URL: https://www.ite.or.jp/data/p_t/test_chart/>

In the color adjustment of the camera, as shown in FIG. 2, the chart is irradiated with the illumination light from the illumination used at the time of shooting / recording. While the chart used for color adjustment is one set, the number of cameras used for color adjustment of the captured image may be a plurality of units. Therefore, there is a problem that it is difficult to make all the cameras face the chart. In addition, since the lighting used in the actual shooting / recording is used for color adjustment, the chart may be placed on the stage, which is the shooting site. Since the stage is occupied during the color adjustment of the camera, there is also a problem that rehearsals and other operations cannot be performed at the same time.

The present invention has been made to solve the above problems. [1] In one aspect of the present invention, a measuring unit for measuring the spectral distribution of incoming light and a region representing a predetermined color are arranged. A data acquisition unit that acquires image data showing a chart, a display unit that displays a color image having a spectral distribution obtained by acting the spectral distribution measured by the measurement unit on the spectral reflectance of the predetermined color, and a display unit. It is a chart device provided with.
According to the configuration of [1], as the color of the chart displayed on the display unit, the color of the chart at the shooting site where the light source of the light whose spectral distribution is measured is installed is reproduced. Since it is not necessary to use the lighting used at the time of shooting in the color adjustment, the color adjustment of the camera can be performed at the same time as other work. Further, by using the chart device of [1] for each camera, it is possible to adjust the colors of a plurality of cameras in parallel in the same time zone. Therefore, the work related to color adjustment is streamlined.

[2] One aspect of the present invention is the chart device described above, wherein the display unit emits a light emitting unit that emits light having a spectral distribution measured by the measuring unit and an image of the light emitted from the light emitting unit. A transmission unit that transmits light with a spectral transmittance corresponding to the spectral reflectance of the color represented by the data is provided.
According to the configuration of [2], the measured spectral distribution is used as the spectral reflectance of the chart color without providing a calculation means for multiplying the spectral distribution measured by the measuring unit and the spectral reflectance of the chart color for each pixel. Can act.

[3] One aspect of the present invention is the chart device described above, further comprising a control unit that stops the display of an image on the display unit when the measuring unit measures the spectral distribution of the incoming light.
According to the configuration of [3], since the light of the image from the display unit is not incident on the measurement unit, the measurement unit can accurately measure the spectral distribution of the light from the target light source.

[4] One aspect of the present invention is the chart device, which is a storage unit that stores the spectral distribution measured by the measurement unit in association with the light source information of the spectral distribution, and a spectral distribution corresponding to the light source information. Is further provided with a control unit that acts on the spectral reflectance of the predetermined color.
According to the configuration of [4], the display unit can display a color chart on which the spectral distribution corresponding to the light source information instructed by the user acts. Therefore, the user can select the spectral distribution of an arbitrary light source as the spectral distribution of the illumination used in the color adjustment of the camera.

According to the present invention, the work related to color adjustment before shooting is streamlined without using the illumination used at the time of shooting.

It is a figure which shows the example of the conventional chart. It is a figure which shows the example of the positional relationship between a chart and a camera in the conventional color adjustment. It is an external view which shows the external appearance structure of the chart apparatus which concerns on this embodiment. An example of the positional relationship between the chart device and the lighting according to the present embodiment is shown. It is a figure which shows an example of the spectral distribution of illumination light. It is a schematic block diagram which shows the functional structure of the chart apparatus which concerns on this embodiment. It is a figure which shows the example of the positional relationship between the chart device and a camera which concerns on this embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 3 is an external view showing an external configuration of the chart device 10 according to the present embodiment.
The chart device 10 includes a spectroradiometer 11 and a display unit 17.
The spectroradiometer 11 is arranged close to the outer edge of the display unit 17 within a predetermined distance on the same surface as the display unit 17. The spectroradiometer 11 measures the spectral distribution of the incoming light.
The spectral distribution is the ratio of the components of the light from the light source for each wavelength. The color of light depends on the spectral distribution. The spectroradiometer 11 includes, for example, a charge-coupled device (CCD) as a light receiving element. The CCD element is also used as an image sensor of a camera.

The display unit 17 displays a chart which is an image of a color having a spectral distribution obtained by acting on the spectral reflectance of a predetermined reference color with the spectral distribution measured by the spectroradiometer 11. The spectral reflectance is the reflectance of the components of each wavelength of the incoming light. As the image data representing the chart in which the regions representing the predetermined reference colors are arranged, for example, the image data representing the standardized test chart is used. The image data is, for example, data indicating a pixel value for each pixel forming an image. The pixel value is a color signal value based on a predetermined color system, for example, an RGB value.

FIG. 4 shows an example of the positional relationship between the chart device 10 and the lighting according to the present embodiment.
In the example shown in FIG. 4, the illumination 70 is installed at a position obliquely upward from the front of the chart device 10, and the radiation direction of the illumination light is directed toward the chart device 10. At this time, the spectroradiometer 11 measures the spectral distribution of the illumination light coming from the illumination 70. FIG. 5 is a diagram showing an example of the measured spectral distribution of the illumination light. In the spectral distribution illustrated in FIG. 5, the component having a wavelength of 470 nm has the highest intensity, and the component having a wavelength shorter than that wavelength or the component having a super wavelength has a lower intensity.
Therefore, the display unit 17 displays a chart representing a color having a spectral distribution obtained by acting the spectral reflectance of the color represented on the chart by the spectral distribution of the illumination light coming from the illumination 70. Therefore, the display unit 17 can reproduce the color (spectral distribution) of the chart in which a predetermined reference color is colored under the condition of reflecting the illumination light from the illumination 70. Under this arrangement, an image obtained by photographing the chart represented by the display unit 17 is used for color adjustment of the camera.

(Configuration of chart device)
Next, the configuration of the chart device 10 according to the present embodiment will be described.
FIG. 6 is a schematic block diagram showing a functional configuration of the chart device 10 according to the present embodiment.
The chart device 10 includes a spectroradiometer 11 and a display unit 17, as well as a data acquisition unit 12, an operation unit 13, a control unit 14, and a storage unit 16.

The data acquisition unit 12 acquires image data. As image data, data representing a chart including a plurality of regions representing a predetermined reference color is acquired. The data acquisition unit 12 outputs the acquired image data to the control unit 14. The data acquisition unit 12 is, for example, a data input / output interface for inputting / outputting data from another device connected by wire or wirelessly.

The operation unit 13 receives the user's operation, generates an operation signal according to the received operation, and outputs the generated operation signal to the control unit 14. The operation signal includes a signal indicating various operations, a signal indicating identification information of chart data input from the data acquisition unit 12, and the like. The operation unit 13 may be configured to include physical members such as buttons and knobs, a general-purpose member such as a touch sensor, and a display device for displaying a guidance screen instructed by a predetermined control program. , It may be a user interface configured to include a control device that executes an operation instructed by a control program. The control device is, for example, a CPU (Central Processing Unit).

The control unit 14 includes a spectral distribution acquisition unit 141, a light emission control unit 142, and an image output unit 143.
The spectral distribution acquisition unit 141 acquires spectral distribution data indicating the measured spectral distribution from the spectroradiometer 11 when the light emission control unit 142 stops displaying the image from the display unit 17. Therefore, the spectral distribution measured by the spectroradiometer 11 does not include the component of the image light emitted from the display unit 17, but includes the component of the illumination light. The spectral distribution acquisition unit 141 outputs the acquired spectral distribution data to the light emission control unit 142.

The light emission control unit 142 generates a light emission control signal which is an electric signal instructing light emission having a spectral distribution indicated by the spectral distribution data input from the spectral distribution acquisition unit 141. The light emission control unit 142 outputs the generated light emission control signal to the display unit 17.
The image output unit 143 generates an image output signal indicating a signal value for driving each pixel constituting the image, based on the pixel value for each pixel represented by the image data input from the data acquisition unit 12. The image output unit 143 outputs the generated image output signal to the display unit 17.

As will be described later, the display unit 17 displays an image having a spectral distribution obtained by applying the spectral distribution indicated by the emission control signal to the spectral reflectance of the image indicated by the image output signal. When the operation signal input from the operation unit 13 instructs the acquisition of the spectral distribution data from the spectroradiometer 11, the light emission control unit 142 stops the output of the light emission control signal to the display unit 17. At this time, the display of the image from the display unit 17 is stopped.

The spectral distribution acquisition unit 141 may store the spectral distribution data in the storage unit 16 in association with the identification information indicated by the operation signal input from the operation unit 13. As the identification information, for example, information for identifying the illumination related to the acquired spectral distribution may be used. As the information for identifying the lighting, a name, an ID (Identifier), a model name, a model number, an installation location, and the like may be used.
Even if the spectral distribution acquisition unit 141 reads the spectral distribution data associated with the identification information indicated by the operation signal input from the operation unit 13 from the storage unit 16 and outputs the read spectral distribution data to the light emission control unit 142. good. The user can select not only the chart shown in FIG. 1 but also any chart by operating the operation unit 13 as the chart to be displayed on the display unit 17.

The storage unit 16 stores various data used for processing in the control unit 14 and various data acquired by the control unit 14. The storage unit 16 includes, for example, a storage medium such as a RAM (Random Access Memory) and a ROM (Read Only Memory).

The display unit 17 includes a light emitting unit 171 and a transmissive unit 172.
The light emitting unit 171 emits light having a spectral distribution indicated by an image output signal input from the light emitting control unit 142. Therefore, the light emitted by the light emitting unit 171 has a spectral distribution measured by the spectroradiometer 11. The light emitting unit 171 is, for example, a backlight in which a plurality of types of light emitting units are regularly arranged. A repeating unit in which one type of light emitting unit is arranged in a predetermined order among a plurality of types of light emitting units is periodically repeated on a two-dimensional plane. The light emitted by the plurality of types of light emitting units is superimposed on each other on the back surface of the transmitting portion 172.

The range of wavelengths having a higher intensity than the range of other wavelengths in the spectral distribution of light emitted by a light emitting unit differs depending on the type of light emitting unit. However, the wavelength range in which the intensity is higher than the predetermined intensity overlaps with each other among the types of light emitting units. Therefore, it is possible to adjust the spectral distribution of the light emitted by the entire light emitting unit 171 by using the intensity ratio between the types of light emitting units. In the light emission control unit 142, spectral distribution data showing the correspondence between the spectral distribution and the intensity ratio between the types of light emitting units is set in advance. Then, the light emission control unit 142 generates an image output signal indicating an intensity ratio corresponding to the target spectral distribution with reference to the spectral distribution data, and outputs the generated image output signal to the light emitting unit 171. The plurality of types of light emitting units included in the light emitting unit 171 emit light having an intensity ratio among the types indicated by the image output signal input from the light emitting control unit 142. Therefore, the light emitting unit 171 can emit light having a target spectral distribution as a whole. The plurality of types of light emitting units are, for example, light emitting diodes (LEDs) that emit light containing components of each color of red, green, and blue as main components. In that case, the light emission control unit 142 can use an image output signal indicating a common RGB value among the repeating units as the image output signal.

The transmission unit 172 transmits the color component indicated by the signal value indicated by the image output signal input from the image output unit 143 among the light arriving from the light emitting unit 171 for each pixel. The spectral transmittance of each pixel of the transmission unit 172 corresponds to the spectral reflectance of the color indicated by the signal value. Spectral reflectance is the transmittance of components for each wavelength of incoming light. The transmission unit 172 transmits the light from the light emitting unit 171 at a spectral transmittance corresponding to the spectral reflectance of the color of the chart shown by the image data acquired by the data acquisition unit 12. Therefore, the spectral distribution of each pixel transmitted and emitted by the transmitting unit 172 corresponds to the product of the spectral distribution of the light emitted by the light emitting unit 171 and the spectral reflectance of the color indicated by the signal value of each pixel. The transmissive unit 172 is, for example, a liquid crystal display panel unit. The liquid crystal display panel unit is formed by filling liquid crystal between two transparent glass substrates arranged in parallel with each other, and arranging a plurality of pixels along the inner side surface of the glass substrate. The spectral transmittance of the liquid crystal changes according to the electric signal representing the signal value applied to each pixel. Therefore, the display unit 17 represents a color image having a spectral distribution obtained by acting on the spectral distribution of the light arriving at the light emitting unit 171 with the spectral reflectance corresponding to the spectral transmittance of each pixel.

For example, when the light arriving from the light emitting unit 171 is white light having a constant intensity regardless of the wavelength, the color of the light from the transmitting unit 172 is the color indicated by the signal value of the image output signal. .. When the color of the light coming from the light emitting unit 171 is yellow, the color of the light from the transmitting unit 172 is more yellowish than the color indicated by the signal value indicated by the image output signal. Further, it is assumed that the display unit 17 selects image data showing a chart similar to the chart 80 shown in FIG. 1 by a user operation. The transmission unit 172 functions as a transmission chart that transmits light from the light emitting unit 171 and represents a chart 80 selected by the user. When the light emitting unit 171 emits light having a spectral distribution equal to the spectral distribution of the illumination 70 shown in FIG. 4, the light having a spectral distribution to which the spectral transmittance of the color of the chart 80 is applied is emitted from the transmitting unit 172. The spectral distribution of the light emitted from the transmitting portion 172 corresponds to the spectral distribution of the light obtained by reflecting the light from the illumination 70 shown in FIG. 4 by the chart 80 shown in FIG. More specifically, when the light from the patch portion arranged at the center of the chart 80 shown in FIG. 1 has the spectral distribution shown in FIG. 5, it is transmitted from the patch portion of the chart represented by the transmission portion 172. The spectral distribution of light becomes equal to the spectral distribution shown in FIG. Therefore, the user of the chart device 10 can take a picture of the chart represented by the transmission unit 172 and adjust the color of the camera used for taking a picture, similarly to the chart 80 which is a conventional reflection type chart.

(Camera adjustment)
Next, the color adjustment of the camera 50 using the chart device 10 will be described.
FIG. 7 is a diagram showing an example of the positional relationship between the chart device 10 and the camera 50 according to the present embodiment. In the example shown in FIG. 7, three cameras 50-1 to 50-3 are arranged in front of one common chart device 10, and the chart displayed on the display unit 17 is imaged. Then, color adjustment is performed so that the colors of the images captured by each camera 50 are approximately the same between the cameras 50. The chart represented by the display unit 17 represents the color of the spectral distribution on which the spectral distribution of pre-measured illumination is applied to any chart selected by the user's operation. Further, as a light source of light having a spectral distribution affected by the spectral reflectance of the color of the chart, the spectral characteristics of the illumination used at the shooting site can be selected by the user's operation. Therefore, it is possible to adjust the color of the camera 50 without arranging the lighting used for the actual shooting at the shooting site such as a stage. Further, by preparing one chart device 10 for each camera 50, it is possible to easily face the chart displayed on the display unit 17. Therefore, more precise color adjustment becomes possible.

As described above, the chart device 10 according to the present embodiment acquires a spectroradiometer 11 for measuring the spectral distribution of the incoming light and image data showing a chart in which regions representing a predetermined color are arranged. A data acquisition unit 12 is provided. Further, the chart device 10 includes a display unit 17 that displays a color image having a spectral distribution obtained by acting the spectral distribution measured by the spectroradiometer 11 on the spectral reflectance of a predetermined color.
With this configuration, as the color of the chart displayed on the display unit 17, the color of the chart displayed at the shooting site where the illumination that is the light source of the light whose spectral distribution is measured is installed is reproduced. Since it is not necessary to use the lighting used at the time of shooting in the color adjustment, the color adjustment of the camera 50 can be performed at the same time as other operations. Further, by using the chart device 10 for each camera 50, it is possible to adjust the colors of a plurality of cameras in parallel in the same time zone. Therefore, the work related to color adjustment is streamlined.

Further, in the chart device 10 according to the present embodiment, the display unit 17 is a color represented by a light emitting unit 171 that emits light having a spectral distribution measured by the spectroradiometer 11 and image data obtained from the light emitting unit. It is characterized by including a transmission unit 172 that transmits light with a spectral transmittance corresponding to the spectral reflectance of the above.
With this configuration, the measured spectral distribution acts on the spectral reflectance of the color of the chart without providing a calculation means for multiplying the spectral distribution measured by the spectroradiometer 11 and the spectral reflectance of the color of the chart for each pixel. Can be done.

Further, the chart device 10 according to the present embodiment further includes a control unit 14 that stops the display of the image on the display unit 17 when the spectroradiometer 11 measures the spectral distribution of the incoming light.
With this configuration, since the light of the image from the display unit 17 is not incident on the spectroradiometer 11, the spectroradiometer 11 can accurately measure the spectral distribution of the light from the illumination which is the target light source.

Further, the chart device 10 according to the present embodiment has a storage unit 16 that stores the spectral distribution measured by the spectroradiometer 11 in association with the light source information, and the spectral reflection of the color of the chart that corresponds to the light source information. A control unit 14 that acts on the rate is further provided.
With this configuration, the display unit 17 can display a color chart on which the spectral distribution corresponding to the light source information instructed by the user acts. Therefore, the user can select the spectral distribution of an arbitrary light source as the spectral distribution of the illumination used in the color adjustment of the camera.

Although one embodiment of the present invention has been described above with reference to the drawings, the specific configuration is not limited to the above, and various design changes and the like can be made without departing from the gist of the present invention. It is possible to do.

In the above-described embodiment, the case where the spectroradiometer 11 and the display unit 17 are integrated with the main body of the chart device 10 is taken as an example, but the present invention is not limited to this. As long as the spectroradiometer 11 and the display unit 17 are arranged close to each other and connected to the main body of the chart device 10, it may be configured as a separate body from the main body of the chart device 10.
Further, the measuring unit for measuring the incoming light is not limited to the dedicated spectroradiometer 11, and may be composed of an imaging unit such as a camera and an analysis unit for analyzing the spectral distribution of the color represented by the captured image. ..

In the above-described embodiment, the case where the display unit 17 is a liquid crystal display including the light emitting unit 171 and the transmissive unit 172 is taken as an example, but the present invention is not limited to this. If the display unit 17 can display an image of a color having a spectral distribution obtained by applying the spectral distribution indicated by the spectral distribution data to the spectral reflectance of the color represented by the image data acquired from the control unit 14. , Any type of display may be used. At that time, the display unit 17 may include a processing unit (not shown) that generates a display image signal for indicating the image to be displayed, or the control unit 14 includes the processing unit and the processing unit generates the processing unit. The displayed display image signal may be output to the display unit 17 via the image output unit 143.

The chart device 10 may be realized as a dedicated chart device for displaying a chart, or may be realized as a general-purpose computer. In that case, the chart device 10 includes a control device such as a CPU. The control device functions as a control unit 14 by executing a process instructed by the installed control program.

10 ... chart device, 11 ... spectroradiometer, 12 ... data acquisition unit, 13 ... operation unit, 14 ... control unit, 141 ... spectral distribution acquisition unit, 142 ... emission control unit, 143 ... image output unit, 16 ... storage unit , 17 ... Display unit, 171 ... Light emitting unit, 172 ... Transmissive unit

Claims (3)

A measuring unit that measures the spectral distribution that shows the ratio of components for each wavelength of the incoming light,
A data acquisition unit that acquires image data indicating a chart in which regions representing a predetermined color are arranged, which is a chart used for color adjustment of a camera.
A display unit for displaying the chart of a color having a spectral distribution obtained by acting on the spectral reflectance indicating the reflectance of a component for each wavelength of the predetermined color with the spectral distribution measured by the measuring unit is provided.
The display unit
A light emitting unit that emits light having a spectral distribution measured by the measuring unit, and a light emitting unit.
A transmission unit that transmits light from the light emitting unit at a spectral transmittance corresponding to the spectral reflectance of the color represented by the image data, and a transmission unit.
A chart device equipped with. The chart device according to claim 1, wherein the display unit includes a control unit that stops the display of the chart when the measuring unit measures the spectral distribution of the incoming light. A storage unit that stores the spectral distribution measured by the measurement unit in association with the light source information of the spectral distribution.
A control unit that causes the spectral distribution corresponding to the light source information to act on the spectral reflectance of the predetermined color.
The chart device according to claim 1 or 2.

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