JP2016194456A - Color fidelity environment correction device and color fidelity environment correction method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent mismatching of article selection by accurately providing color fidelity information to a user even if a time zone or place of article imaging is different.SOLUTION: A color fidelity environment correction system 1 comprises: a camera 2; and a computer 5 which is connectable to the camera 2, a tablet 3 and a display device 4 and includes a CPU, a ROM, a RAM, a hard disc, a bus line and the like. In a factory or the like, a red car 6 is imaged by the camera 2 (RC-500), and an XYZ color fidelity image (color) is recorded in a storage part 51 of the computer 5. Another blue car 7 is imaged by the RGB tablet 3 outdoors, and an RGB color image is recorded in a storage part 52. A blue color of the RGB color image of the car 7 is replaced by red colors of 3-band visual sensitivity images S1i, S2i and S3i of the car 6 to create an RGB color image of the red car. Otherwise, the images are not replaced but are displayed on the display device 4 in a contrast manner.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a color fidelity environment correction device and a color fidelity environment correction method that enable a faithful simulation of the color of an object.

  In order to provide an image processing method for easily and naturally converting the color of the visualized image into a favorite color when the image information is visualized, for example, when photographing including a person or a blue sky, the color By specifying a person or a blue sky as the target to change, the range of colors that can be changed can be narrowed down to some extent, and the range of colors that can be changed is further narrowed down by the race and sky conditions of the subject. There has been proposed an invention in which a user can select a color to be changed from the narrowed colors, thereby facilitating the selection of a color.

  Also, in order to give a presentation considering beginners based on the budget and shape, multimedia information input from input devices such as keyboards and scanners is edited, and image / video information is externally in the form of digital images / videos. Accumulate in storage. The sound is similarly stored in the external storage device. Based on the information, a rough selection is made from the budget, shape, etc., and the information is displayed on the display device via the processing device. Next, the history information is read from the portable storage medium, and the previous and current specifications are displayed. In presenting the instruction specification and finalizing the specification, a specification is selected from the selection screen, a presentation is made if necessary, and the specification is finalized. When the specifications are finalized, rough estimation processing including assessment calculation based on history information is performed. If the rough estimate process is approved, an invention for order processing has been proposed.

Japanese Patent Laid-Open No. 11-168620 JP-A-10-240800

  In the sale of goods, for example, the sale of cars, a predetermined color and several actual cars are arranged as samples, and the colors of the other colors are displayed by showing the colors of miniature cars. It is also conceivable that real vehicles of various colors are picked up by a camera, and a car image picked up by the camera is displayed on a display device of a store to allow the user to select a car color.

  In addition, for example, there are situations in which a large number of types of vehicles cannot be placed in car dealerships due to location restrictions. There is a desire to show colors on the spot that are not in the store when they open to users. Assuming that sales are based on car image data taken at different locations and times, the colors may still be used as they are, but there is a risk of mismatch due to differences in times and locations. is there. For example, when a car is actually purchased, the color of the delivered car may be different from the color of the car seen at the dealership due to the difference in the display environment, and there is a need for accurate color simulation.

  In addition, for example, when you want to compare and inspect the color of a reference product that has been manufactured in a local environment in Japan, and the product color at a remote location overseas, the environmental light (temperature) differs between Japan and overseas. There is a need to display the product on the monitor screen in an accurate color to see how the product looks under the light. In particular, it is necessary to eliminate complaints about high-fashion clothes, furniture, etc. that are not accurate colors at online shops.

  Furthermore, in the present day, online shopping has been developed in which products are selected on the Internet screen. However, there is a need for dealing with complaints that the color of the ordered product is different from the color of the actually purchased product.

  Further, the reference object can be imaged with a visual sensitivity camera at a temperature T = 6500K on the local side, and S1S2S3 three-band visual sensitivity image data can be acquired. For example, when this data is transmitted to the remote side on the network and the reference object is to be viewed on the remote tablet, for example, when T = 5000K under illumination of a fluorescent lamp, the tablet is used as it is. If displayed on the screen, there is a possibility that the color cannot be accurately seen due to the color temperature difference of the environment.

  Therefore, the present invention responds to the demand for the acquisition and selection of faithful color information in the field of simulation under different environments, and also based on this, acquiring accurate color information that is faithful to the human eye, It is an object of the present invention to provide a color fidelity environment correction device and a color fidelity environment correction method for accurately displaying a user's favorite color by simulation and using it for user product selection.

  By the way, the color replacement may be an invention in which a color created by a personal computer is pasted on CAD data and displayed on a screen. However, this has a problem that it does not look like a real color. In addition, manufacturers are still not enough because they do not want to disclose the 3D CAD data of cars as much as possible.

  It is also conceivable to select a color of the vehicle by capturing a plurality of colors of real vehicles, storing the images of the vehicles in a computer, and displaying them on a display device. However, it is possible for the color information to have a color temperature at a specific time zone, for example, an accurate color when shooting with 6500K daytime lighting, but the color selection time zone at the store is If they are different, there is a problem that the color of the image changes depending on the color temperature at the time of shooting, and there is a possibility that a mismatch occurs in the user's color selection.

  Therefore, in view of the above problems, the present invention provides color fidelity information accurately to the user and prevents mismatches in manufacturing color inspection, product selection, etc. An environment correction device and a color fidelity environment correction method are provided.

The present invention relates to a camera having three spectral sensitivities (S ₁ (λ), S ₂ (λ), S ₃ (λ)) linearly converted equivalently to the CIE XYZ color matching function, and a reference color temperature by the camera. 3 to obtain a reference 3-band visual sensitivity image obtained by imaging the observation object, calculate the spectral sensitivity under a condition of a color temperature different from the reference color temperature, and calculate the 3 of the camera corresponding to this different color temperature. By calculating a gain of the band spectral sensitivity and adjusting the gain based on the color temperature, the three-band visual sensitivity image is corrected, and the tristimulus values X ′, Y ′, Z are corrected from the corrected three-band visual sensitivity image. And a display device that replaces the colors of RGB images captured at different color temperatures and displays them on the screen based on the corrected tristimulus values X ′, Y ′, and Z ′. And a color fidelity environment correction device.

By adjusting the gain so that the data outputs of the spectral sensitivities (S ₁ (λ), S ₂ (λ), S ₃ (λ)) at the color temperature coincide with each other, the spectral sensitivity (S ₁ (λ), S ₂ (λ), S ₃ (λ)) coincident with the color temperature, the spectral sensitivity (S ₁ (λ), S ₂ (λ), S ₃ (λ)) ) To XYZ values are preferably associated with a reference color temperature.

  The gain adjustment is preferably performed based on an output value of a spectrum of the spectroscope under the different color temperature.

  It is preferable that the gain is adjusted based on the spectrum output value and the normalized sensitivity of the spectroscope to obtain an output value of the spectrum normalized sensitivity and obtain a gain from the corresponding integrated value.

  It is preferable to adjust the gain of the camera by obtaining a multiplication value from the output value of the illumination spectrum at the reference temperature and the spectral sensitivity, and adjusting the respective integral values.

  It is preferable to create a conversion table or conversion matrix from the tristimulus values X ′, Y ′, Z ′ to RGB values based on the spectrum output value of the spectrometer.

According to the present invention, an object to be observed is measured with a camera at a reference color temperature according to three spectral sensitivities (S ₁ (λ), S ₂ (λ), and S ₃ (λ)) that are linearly converted equivalently to the CIE XYZ color matching functions. An imaging step of imaging, a spectral sensitivity acquisition step of acquiring a reference three-band visual sensitivity image captured by the camera, and a step of calculating spectral sensitivity under a condition of a color temperature different from the reference color temperature; The three-band spectral sensitivity gain of the camera corresponding to the different color temperature is calculated, and the gain is adjusted based on the color temperature, thereby correcting the three-band visual sensitivity image and correcting the three-band visual sensitivity. Simulation image calculation step for calculating tristimulus values X ′, Y ′, and Z ′ from an image, and RGB imaged at different color temperatures based on the corrected tristimulus values X ′, Y ′, and Z ′ Change the image color A color fidelity environment correction method comprising: a display step of displaying on a surface.

The spectral sensitivity (S ₁ (λ), S ₂ (λ), S ₃ (λ)) of the camera is a mountain shape having a single peak that has no negative value from the CIE XYZ spectral characteristics. The curve is equivalently converted from the condition that the peak values of the curves are equal and the overlapping of the spectral sensitivity curves is minimized. The curve of the spectral characteristic S1 has a peak wavelength of 582 nm and a half-value width of 523 to 629 nm. The 1/10 width is 491 to 663 nm. The curve of the spectral characteristic S2 has a peak wavelength of 543 nm, a full width at half maximum of 506 to 589 nm, and a 1/10 width of 464 to 632 nm. The curve of the spectral characteristic S3 has a peak wavelength of 446 nm, a full width at half maximum of 423 to 478 nm, and a 1/10 width of 409 to 508 nm.

  The display here refers to a computer screen as an example, and it is possible to clearly grasp the appearance and color of the product.

  The image in the present invention may be a still image or a moving image, and the imaging step, the acquisition step, the calculation step, and the display step may be performed immediately and continuously. desirable.

  As the reference color temperature, for example, a xenon lamp that is illumination close to the artificial sun can be used as a light source.

The camera according to the present invention captures images with three spectral sensitivities (S ₁ (λ), S ₂ (λ), S ₃ (λ)), that is, the observation object is divided into three channels. The means can be used regardless of whether it is an optical filter, a dichroic mirror or a dichroic prism set in order to obtain these spectral sensitivities.

  According to the color fidelity environment correction device or the color fidelity environment correction method of the present invention, the spectral sensitivity of the reference image that is faithful to the sensitivity of the human eye is obtained from the image picked up by the camera, and this spectral sensitivity depends on the temperature by computer computation. Correction can be performed to replace the color of the other image displayed on the screen with the color of the reference image.

  As a typical use of the color fidelity environment correction device or the color fidelity environment correction method of the present invention, it is possible to provide a simulation by replacing the color of a product in the sale of a product such as a car, thereby providing convenience for manufacturing and sales. In addition, since the color of the product selection and the color of the purchased product are approximated from the viewpoint of the human eye, there is an effect of reducing the uncomfortable color.

1 is a block diagram of a color fidelity environment correction system 1 according to Embodiment 1 of the present invention. FIG. It is explanatory drawing which shows the example by the color fidelity environment correction system 1 of Example 1 of this invention. It is a block diagram of the camera 2 of the color fidelity environment correction system 1 of Example 1 of this invention. This is a specific example of a method for acquiring image information according to three spectral sensitivities (S ₁ (λ), S ₂ (λ), S ₃ (λ)) in the first embodiment of the present invention. (A) is explanatory drawing in the case of using a dichroic mirror. (B) is explanatory drawing in the case of using a filter turret. (C) is explanatory drawing at the time of attaching optical filter 22a, 22b, 22c to the image pick-up element 23 microscopically. It is a function which shows the spectral sensitivity of the camera 2 which is an XYZ color system camera in Example 1 of this invention. It is a flowchart in the camera 2 of this invention Example 1. FIG. It is a flowchart in the computer 5 of the color fidelity environment correction system 1 of Example 1 of this invention. It is a graph (reference color temperature 6500K) which shows the relationship between the relative intensity of the spectrum of black body radiation, and color temperature. It is a graph (reference color temperature 5000K) which shows the relationship between the relative intensity of the spectrum of black body radiation, and color temperature. It is a graph which shows the relationship between the spectral sensitivity of this invention Example 1, the relative intensity of a spectrum, and a spectral sensitivity gain. It is a graph which shows the relationship between the relative intensity of a spectrum about three spectral sensitivity of this invention Example 1, and color temperature. It is a block diagram of the color fidelity environment correction system 201 of Example 2 of the present invention. It is a block diagram of the change form of the color fidelity environment correction system 201 of Example 2 of this invention. It is a block diagram of the portable information terminal and spectroscope of Example 2 of the present invention. It is a flowchart of the process performed with the electronic circuit of the portable information terminal of Example 2 of this invention. It is explanatory drawing of the process performed by the electronic circuit of the local computer of Example 2 of this invention. It is explanatory drawing of the process performed by the electronic circuit of the portable information terminal of the remote side of Example 2 of this invention.

  FIG. 1 shows a schematic configuration of a real color simulation system (RCS) by the color fidelity environment correction system 1 of the first embodiment and a flow of image processing. The color fidelity environment correction system 1 includes a camera 2, a camera 2, a tablet 3, and a computer 5 that can be connected to a display device 4 and includes a CPU, a ROM, a RAM, a hard disk, a bus line, and the like. Even when the camera 2, the tablet 3, and the computer 5 are separated from each other, or in the same place, the present invention can be applied. Here, the case of a remote place will be described. The red car 6 is imaged by the camera 2 (part number RC-500 of Paparabo Co., Ltd.) on the local side such as a factory, and three-band visual sensitivity images S1i, S2i, S3i (T = 6500K) (T = 6500K) ( i = 1 to m, where m is the number of pixels). Another blue car 7 is photographed by the tablet 3 equipped with an RGB camera in the field on the remote side, and an RGB color image is recorded in the storage unit 52. T = 6500K in the local environment, T = 2900K in the remote environment, and 3 colors of blue color of the RGB color image of the car 7 is displayed to overcome the difference in ambient light and display the correct color. An RGB color image of the red car is created by replacing the red color of the XYZ color faithful image of the car 6 converted from the visual sensitivity image and displayed on the display device 4.

  2 (1) to (3) are screen examples of the display device 4. FIG. In (1), a display frame is formed on the display screen of the display device 4, and a color image of the car 7 on which color simulation is to be performed is set in the left frame. The color of the car 7 is blue. In (2), the color image of the car 6 whose color is to be extracted is set in the right frame. In this case, the color of the car 6 is red, and this red color is extracted. In (3), when the color simulation of the present embodiment is executed, the blue color of the car 7 displayed in the left frame is replaced with the red color of the car 6 displayed in the right frame, and the color images of the cars 6 and 7 are the same. It turns red. For this reason, even if the color does not actually exist in the store, it is possible to provide an environment close to a state where the color of the actual vehicle exists. Hereinafter, the configuration and operation will be described in detail.

  As shown in FIG. 3, the camera 2 is disposed behind the photographing lens 21, the three optical filters 22a, 22b, and 22c disposed behind the photographing lens 21, and the optical filters 22a, 22b, and 22c. An image sensor 23 (CCD, CMOS, etc.). The three spectral sensitivities (S1 (λ), S2 (λ), and S3 (λ)) of the camera 2 are given by the product of the spectral transmittance of the optical filters 22a, 22b, and 22c and the spectral sensitivity of the image sensor 23. It is. The arrangement relationship between the optical filters 22a, 22b, and 22c and the image sensor 23 in FIG. 3 is merely shown schematically. Specific examples of the method of acquiring image information according to the three spectral sensitivities (S1 (λ), S2 (λ), and S3 (λ)) will be given below. In the present embodiment, any of these can be adopted. Also, other methods can be adopted.

  As shown in FIG. 3, the camera 2 has three spectral sensitivities (S1 (λ), S2 (λ), and S3 (λ)) that are linearly converted equivalently to the CIE XYZ color matching functions. An arithmetic processing unit 24 that converts three spectral sensitivities into tristimulus values X, Y, and Z in the CIE XYZ color system and an image display unit 25 that displays an image are provided.

  The system shown in FIG. 4A is a system using a dichroic mirror. This is because light of a specific wavelength is reflected by the dichroic mirror 22c ′, and the remaining light that has been transmitted is further reflected by another dichroic mirror 22a ′ to be spectrally separated, and the image pickup devices 23a, 23b. , 23c are read in parallel. Here, the dichroic mirror 22a ′ corresponds to the optical filters 22a and 22b, and the dichroic mirror 22c ′ corresponds to the optical filter 22c. Light incident from the photographic lens 21 is reflected by the dichroic mirror 22c ′ according to the spectral sensitivity S3, and the remaining light is transmitted. The light reflected by the dichroic mirror 22c ′ is reflected by the reflecting mirror 26, and the spectral sensitivity S3 is obtained by the imaging device 23c. On the other hand, the light transmitted through the dichroic mirror 22c ′ is reflected by the dichroic mirror 22a ′, and the light according to the spectral sensitivity S1 is reflected, and the remaining light according to the spectral sensitivity S2 is transmitted. Therefore, the light is captured by the image sensor 23a and the image sensor 23b, respectively. To obtain the spectral sensitivities S1 and S2. Instead of the dichroic mirror, a dichroic prism having the same characteristics may be used to split the light into three, and the image sensors 23a, 23b, and 23c may be bonded to the positions where each light is transmitted.

  The system shown in FIG. 4B uses a filter turret 27. Optical filters 22a, 22b, and 22c are provided on a filter turret 27 having the same direction as the incident light from the photographing lens 21 as a rotation axis, and these are mechanically rotated. S1, S2, and S3 are obtained.

  FIG. 4C shows a system in which the optical filters 22 a, 22 b, and 22 c are microscopically attached to the image sensor 23. The optical filters 22a, 22b, and 22c on the image sensor 23 are provided in a Bayer array type. This arrangement is such that the optical filter 22b is provided in half of the area on the image sensor 23 divided into a grid, and the optical filter 22a and the optical filter 22c are equally arranged in the remaining half of the area. That is, the arrangement amount is optical filter 22a: optical filter 22b: optical filter 22c = 1: 2: 1. The arrangement of the optical filters 22a, 22b, and 22c other than the Bayer arrangement is not particularly hindered in the first embodiment. Each of the optical filters 22a, 22b, and 22c is very fine and is attached to the image sensor 23 by printing. However, in the present invention, this arrangement is not meaningful, but a filter having characteristics of spectral sensitivity (S1 (λ), S2 (λ), S3 (λ)) is attached to the image sensor.

The spectral sensitivity of the camera 2 satisfies the router condition, and the spectral sensitivity (S1 (λ), S2 (λ), S3 (λ)) is negative from the XYZ color matching function as shown in FIG. It is a mountain shape having no value and a single peak, and is equivalently converted from the condition that the peak values of the respective spectral sensitivity curves are equal and the overlapping of spectral sensitivity curves is minimized. Specifically, the spectral sensitivities (S1 (λ), S2 (λ), S3 (λ)) have the following characteristics.
Peak wavelength Half width 1/10 width S1 582nm 523-629nm 491-663nm
S2 543nm 506-589nm 464-632nm
S3 446 nm 423-478 nm 409-508 nm

  The peak wavelength of the spectral characteristic S1 can be handled as 580 ± 4 nm, the peak wavelength of the spectral characteristic S2 is 543 ± 3 nm, and the peak wavelength of the spectral characteristic S3 can be handled as 446 ± 7 nm.

The three spectral sensitivities (S1 (λ), S2 (λ), S3 (λ)) are obtained using Equation 1. For details on the spectral characteristics themselves, refer to Japanese Patent Application Laid-Open No. 2005-257827.

  The camera 2 includes an arithmetic processing unit 24, acquires three-band visual sensitivity images S1i, S2i, S3i (T = 6500K) by spectral sensitivity (S1 (λ), S2 (λ), S3 (λ)), The recorded and visualized image is displayed on the image display unit 25 and then transmitted to the computer 5 via a communication line such as the Internet. Transmission is not limited to a communication line, and may be performed by transporting a storage medium or other means.

  The display device 4 is connected to a computer 5, receives an image signal processed by the computer 5, and displays an image on a screen. The computer 5 or the display device 4 appropriately includes input means (not shown). The input means is a keyboard, a mouse, a touch panel provided in the image display device, or the like.

  The configuration and operation of the color fidelity environment correction system 1 will be described with specific examples. As shown in FIG. 1, the color fidelity environment correction system 1 operates using a camera 2, a tablet 3, a computer 5, and a display device 4. The connection method can be selected regardless of wired or wireless. A flowchart of the camera 2 is shown in FIG. 6, and a flowchart of the computer 5 is shown in FIG.

  When the local camera 2 is turned on, initialization is performed as shown in FIG. 6 (initialization S1). Next, the vehicle 6 is imaged with the spectral sensitivity (S1 (λ), S2 (λ), S3 (λ)) (imaging process S2). The imaging process S2 is a process of imaging the automobile 6 with the camera 2 having three spectral sensitivities (S1 (λ), S2 (λ), S3 (λ)) (see FIG. 5). The spectral sensitivities (S1 (λ), S2 (λ), S3 (λ)) are given according to Equation 1. Input processing S3 is continuously performed at the same time as imaging is performed by the photographing lens 21, the optical filters 22a, 22b, and 22c, and the image sensor 23.

  Thereafter, the picked-up three-band visual sensitivity images S1i, S2i, S3i (T = 6500K) are input by the image pickup device 23 (input processing S3), and the arithmetic processing unit 24 uses the three-band visual sensitivity images S1i, S2i, S3i ( T = 6500K) is transmitted to the computer 5 (transmission process S4), these are recorded on a recording medium such as the camera 2 (recording process S5), it is determined whether or not to end (S6), and the process ends.

  Next, when the computer 5 on the remote side is turned on, initialization is performed as shown in FIG. 7 (S110). The 3-band visual sensitivity images S1i, S2i, S3i (T = 6500K) transmitted from the camera 2 are received and recorded in the storage unit 51 (data reception S120). An RGB color image relating to the car 7 is acquired from the tablet 3 and recorded in the storage unit 52 (S120). When the image is a moving image, a series of processing is continuously performed.

  Next, based on the XYZ color faithful image from the camera 2 and the RGB color image from the tablet 3, the color of the XYZ color faithful image is extracted, and the color of the RGB color image is replaced with this color (S130). Hereinafter, this process will be described in detail.

  First, the XYZ color faithful image from the camera 2 is acquired as follows. That is, the received three-band visual sensitivity images S1i, S2i, S3i (T = 6500K) are subjected to temperature correction for each pixel in the arithmetic processing unit 24 of the camera 2 and converted to tristimulus values X, Y, and Z. . The XYZ conversion is performed by Equation 2 on the local side, but on the remote side where the environment is different from the local side, conversion considering the correction is performed according to Equation 3 in relation to temperature correction. The tristimulus values X, Y, and Z of the XYZ color faithful image are corrected to tristimulus values X ′, Y ′, and Z ′ as shown in Equation 3, and based on this correction value, an image from the local side is remoted. The image on the side is replaced.

Here, the matrix coefficient correction with the D65 standard white light source (T = 6500K) is performed so that the heads of the curves of the spectral sensitivity S1S2S3 appearing in the XYZ-S1S2S3 conversion formula of the following formula 2 are aligned. For details, see IEICE TRANS.INF. & SYST., VOL.E93-D, No.3 MAR 2010 copy rght 2010 The Institute of Electronics, Information and Communication Engineers, Development of an XYZ Digital Camera with Embedded Color Calibration System for Accurate Refer to Color Acquisition, Maciej KRETKOWSKI, Ryszard JABLONSKI, SHIMODAIRA P651-653 for white balance and color calibration.

  Thus, the imaging of the car 7 in the evening in the outdoors and the imaging of the car 6 under the xenon lamp in the factory can be corrected in relation to the color temperature.

  From the formula for thermal radiation by Planck, the relationship between the spectral intensity I and the absolute temperature t (K: KeIvin; K) is calculated by normalizing the maximum value of the intensity to 1, and as shown in FIG. In (On), the unit is meter (m), the vertical axis is the relative intensity of the spectrum, and the numerical value is the absolute temperature (K). The wavelength of visible light (on) is approximately 0.4 μm to 0.8 μm. Red (R) corresponds to a wavelength of 0.675 μm, green (G) corresponds to a wavelength of 0.525 μm, and blue (B) corresponds to a wavelength of 0.475 μm. In the first embodiment, black body radiation at a certain temperature is defined as white light at that temperature, and conversely, the temperature of black body radiation determined from the spectral distribution of white light is defined as a color temperature. From this, it is possible to calculate what the relative intensities of the three primary colors (RGB) are based on the color temperature.

  During the day, the color temperature of natural light is equivalent to 6500K. This means that light from the sun from directly above is equivalent to an absolute temperature of 6500 K in terms of black body radiation. Imaging under a xenon lamp in a factory is a reproduction of natural daylight and a color temperature of 6500K. When the sun is slightly inclined, the color temperature decreases to 5000K because the light from the sun passes through the atmosphere layer for a long distance. Furthermore, in the evening, the color temperature is generally around 2900K.

  In the sense that all colors corresponding to all visible rays with a wavelength (on) of 0.4 μm to 0.7 μm are included, the daytime natural light of the color temperature is considered white, and this is the reference value 1 and the spectral intensity Is what we asked for.

  When the spectrum at a color temperature of 5000K is used as a white reference, when the value at a wavelength of 0.525 μm is normalized to 1, the relationship between the color temperature and the spectrum intensity is as shown in FIG. The relationship between the relative intensity of the spectrum of blackbody radiation and the color temperature (reference color temperature 5000K) is shown. The horizontal axis is the wavelength (on), the unit is meter (m), the vertical axis is the relative intensity of the spectrum, and the numerical value is absolute. Temperature (K). From such a calculation result, the color temperature becomes red as the color temperature decreases, and the color becomes bluish green as it increases. A quantitative relationship between the color temperature of the illumination light and the three primary colors (RGB) can be seen. Since the color temperature can be changed by adjusting the luminance of RGB based on such a calculation result, an image having an evening color temperature of 2900K can be obtained from an image having a color temperature of 6500K in a factory. In this way, the calculation for adapting to the color temperature is performed to create a faithful color that is close to the sense of the human eye.

  Here, three-band visual sensitivity images S1i, S2i, S3i (T = 6500K) obtained by irradiating a car 6 with a xenon lamp having a color temperature of 6500K (D65) in the factory are displayed outdoors in the evening sunset ( It can be converted into three-band visual sensitivity images S1i2900K, S2i2900K, and S3i2900K (T = 2900K) that can be seen at a color temperature of 2900K.

  In Formula 3, it is converted to 2900K based on 6500K. Based on the color temperature of 6500K, as shown in FIG. 11, the color at the color temperature of 2900K has a blue component of the illumination light, the single component has a numerical value falling, and the long wavelength component is relatively high This operation is valid. If the color temperature 6500K is set to 1 and the other color temperatures are digitized, the distribution of colors with a wavelength of 2900K has the relationship shown in the figure.

  Spectral relative gains S1gain, S2gain, and S3gain (T = 2900K) shown in FIG. 10 are obtained when integral values indicating areas in the spectral spectrum characteristic curves of illumination spectra S1, S2, and S3 of T = 2900K are obtained. The relative ratio of the values (S2gain is 1). The source of this calculation is a relational expression of black body radiation, and this relational expression is a completely determined value as shown in FIG. In FIG. 8 (reference color temperature 6500K) and FIG. 9 (reference color temperature 5000K), the horizontal axis represents wavelength (λm) and the vertical axis represents the relative intensity of the spectrum. Using the relational expression of FIG. 8, as shown in FIG. 11, the peaks of the three gain peaks of the spectral relative gains S1gain, S2gain and S3gain (T = 2900K) are matched when illuminated with a color temperature of 6500K. The gain of the camera 2 is adjusted (see FIGS. 10 and 11). Here, the reference temperature is 6500K, but FIG. 9 is used instead of FIG. 8 for other temperatures, for example, 5000K.

  As shown in FIG. 10, when the color temperature is changed to 2900K, the relative spectrum I of the illumination light becomes such a curve that rises to the right relative to the wavelength λ. As the wavelength λ goes to the longer wavelength side, the relative intensity of the spectrum increases. As shown in the diagram on the right side of FIG. 10, the gains S1gain, S2gain, and S3gain have a distribution in which the peak on the long wavelength side is high and the area is large according to the relative intensity I of the spectrum. Then, since the original gain changes, when the color temperature changes, this gain must be obtained by calculation. When the color temperature is changed from 6500K to 2900K, the spectral sensitivity S3 of the camera 2 decreases and the spectral sensitivity S1 increases. Using the spectral sensitivity S2 as a reference, the relative intensities of the spectral sensitivities S1 and S3 are calculated. In order to calculate it for each color temperature, a graph as shown in FIG. 11 is created in advance. Then, the spectral sensitivities S1, S2, and S3 when the car 6 is imaged at a color temperature of 6500K (D65) are calculated as S1, S3gain at 2900K, and the above equation 3 is corrected with this gain. Thus, the three-band visual sensitivity images S1i, S2i, S3i (T = 6500K) are converted into the three-band visual sensitivity images S1i2900k, S2i2900k, S3i2900k, and the tristimulus values X ′, Y ′, Z ′ are calculated. The color can be replaced by a numerical value, and an accurate RGB color image of the car 7 is displayed on the display device 4.

  Based on the corrected tristimulus values X ′, Y ′, and Z ′, XYZ-RGB conversion is performed to replace the color data of the RGB image captured by the tablet (S 130).

  The RGB color image thus replaced is displayed on the display device 4 (S140). It is determined whether or not to end the process. If the process is not ended, the process returns to S120, and if the process is ended, the process returns.

  As described above, when the color data of the XYZ color faithful image of the car 6 under the xenon lamp in the factory is replaced with the color data of the RGB image captured in the evening in the outdoors, it is exactly the same as the image captured in the evening in the outdoors. The color of the red car 7 is displayed on the display device 4. If the image is taken in the daytime in the daytime, it is corrected to a color temperature of 8000K to 9000K and calculation is performed. As a result, even if the weather conditions change, such as morning, noon, and cloudy days, the car 7 of the color desired by the user can be freely displayed on the screen according to the appropriate color temperature.

  The actual colors of cars that exist in dealers are limited, and there are many colors that cannot be seen directly by the user, but they can be accurately reproduced with color fidelity. If the car of various paint colors is imaged in advance at the factory, the color of the RGB color image can be replaced while performing environmental correction by the color temperature based on the image data of these XYZ color faithful images. Can do.

  Since the colors are replaced by imaging the real vehicles 6 and 7, there is a real feeling, which is preferable for the user. The weather conditions can be reflected, and the colors of the images can be accurately displayed when viewed under different conditions according to the user's site.

  Based on the above characteristics, the color fidelity color simulation system 1 can change the color of the RGB color image based on the color data of the XYZ color faithful image and reflect the color fidelity with high accuracy in consideration of the color temperature. It is convenient for both users, and besides the car, there are building colors such as furniture interior and clothing, and other general-purpose uses.

  The color fidelity environment correction system 1 according to the first embodiment performs temperature correction of color data on the basis of black body radiation data and replaces the image. The color fidelity environment correction system 201 according to the second embodiment is similar to that illustrated in FIG. As shown in FIG. 5, a car 206 is manufactured as a reference product in the country on the local side, and a car 207 manufactured overseas on the remote side is compared by color to determine the degree of color matching. For example, in the local environment, T = 6500K, and in the remote environment, for example, the environmental color temperature is assumed to be T = 5000K for explanation. However, since the color temperature is actually measured by the micro-spectrometer 228, the color temperature is not particularly relevant. However, it is intended to improve the accuracy of the color data by performing correction based on the temperature difference. Here, the remote-side portable information terminal 203 (here, a tablet terminal equipped with an RGB color system camera) and a spectroscope 228 (here, a small spectroscope such as a micro-spectrometer) connectable thereto. It is different in that the configuration is used. The difference between the second embodiment and the first embodiment will be described with reference to FIGS. 13 to 17. Since the other configuration of the color fidelity environment correction system 201 of the second embodiment is substantially the same as that of the first embodiment, the description thereof is incorporated. As will be described later, refer to FIG. 13 when comparing images on the RGB screen.

  In Example 1, the color temperature determined by this physical formula is used in the simulation on the computer, and the color temperature of the actual illumination measured by the spectroscope 228 is used in Example 2. Their spectra do not necessarily match ( Color engineering Noboru Ota (Tokyo Denki University Press) defines color temperature by drawing isochromatic temperature lines, and uses such color temperature, S1, S2, S3 from black body radiation from color temperature Even if it is not derived from the spectral sensitivity of the local, the three values of the illumination light on the local side and the remote side are the three values obtained by multiplying the spectral sensitivity of S1, S2, S3 and the illumination spectrum measured on the local side and the remote side. The S1gain and S3gain are calculated using the ideal temperature from the color temperature and the spectrum measurement can be arbitrarily selected for each of the local side and the remote side. It is characterized by determining the ratio of the spectral characteristic output of S123 moat side lighting.

  The portable information terminal 203 is exemplified by a smartphone or a tablet. As shown in FIG. 14, an RGB digital camera 224 having a lens, a calculation unit 225 having a CPU, ROM, RAM, etc., an input / output unit 226, an RGB color system A display device 227 is integrated. The portable information terminal 203 can be connected to the spectrometer 228 with a cable. The arithmetic unit 225 obtains the rgb value of the image captured by the RGB digital camera 224, and the 3-band visual sensitivity images S1i, S2i, S3i of the car 206 transmitted overseas via the Internet (T = 6500K). ), The temperature is corrected from T = 6500K to T = 5000K, and the image data is calculated and visualized. Note that a personal computer may be used instead of the portable information terminal 203.

  An example of the micro-spectrometer 228 is C12666MA manufactured by Hamamatsu Photonics. This is a fingertip-sized micro-spectrometer head that combines MEMS technology and image sensor technology, and has a sensitivity wavelength range of 340 to 780 nm and a wavelength resolution of 15 nm max. The object is imaged by the micro-spectrometer 228, and the spectral sensitivity characteristic, that is, the relative sensitivity (%) that is the output value of the spectrum with respect to the wavelength in the sensitivity wavelength range is obtained.

  As shown in FIG. 15, processing performed by the portable information terminal 203 will be described. In S200, the remote side receives three-band visual sensitivity images S1i, S2i, S3i (T = 6500K) obtained by imaging the car 206 with the camera 202 on the local side from the local side. On the local side, as shown in FIG. 16, by multiplying the output value of the illumination spectrum of 6500K and the spectral sensitivities S1, S2, and S3 (see Equation 1, FIG. 5), the multiplied values S1, S2, and S3 as shown by diagonal lines are obtained. Is obtained. These are integrated to calculate the integral values IS1, IS2, IS3 within the curve range shown by the oblique lines, and these integral values are adjusted, for example, the camera 202 (see FIG. 12) so that IS1 = IS2 = IS3. The gain is adjusted to be the normalized sensitivity of the camera 202.

  In S210, the remote micro-spectrometer 228 calculates S1gain, S2gain (which is relatively 1), and S3gain at T = 5000K. As shown in FIG. 17, the output value of the illumination spectrum of T = 5000K on the remote side (5000K is an example and may be other temperature) is multiplied by the normalized sensitivity S1, S2, S3 (see Equation 1, FIG. 5). Then, these are integrated to calculate integral values I03, I02, I01 within the curve range indicated by the oblique lines, and S1gain = I01 / I02 and S3gain = I03 / I02 are obtained. This calculation makes it easy to calculate the gain value obtained by the next calculation on the remote side. Even if you do not adjust the gain, set S1gain = (IO1 / IO2) / (IS1 / IS2), S3gain = (IO3 / IO2) / (IS3 / IS2) If the gain calculation on the remote side transmits the integral value on the local side to the remote side, the calculation on the remote side becomes possible based on that. As described above, since it is not necessary to perform more calculations for preparing in advance for aligning the heads of S1S2S3 as in the matrix coefficient correction described in Equation 2, such gain adjustment is performed. As a result, the S1S2S3-XYZ conversion formula of Formula 2 described above is associated with the illumination on the local side.

  In S220, the three-band visual sensitivity images S1i, S2i, and S3i (T = 6500K) acquired in S200 are corrected by S1gain and S3gain calculated in S210 to correct S1i and S3i, and the three-band visual sensitivity images S1i5000k and S2i5000k (same as S2i). ), S3i5000k (T = 5000K). This is a calculation in the same manner as Equation 3 in the first embodiment.

In S230, the light incident portion (slit) of the micro-spectrometer 228 is pressed against the image displayed on the screen of the display device 227 of the portable information terminal 203, the image is captured, and R data (for example, R = 255: 8 bits) Conversion table for converting values from XYZ values to RGB values by linking with values, G data and Xg, Yg, Zg, B data and Xb, Yb, Zb. ). This processing is intended to capture remote environment light into the portable information terminal 203 via the spectroscope 228 and accurately reflect the spectrum of remote environment light on the XYZ-RGB conversion by the spectroscope 228. The RGB R, G, and B data are displayed at 228, and the spectrum for each is acquired. As a result, X _R , Y _R , and Z _{R for R} are obtained. Similarly, when G and B are obtained, X _G , Y _G , Z _G for _G and X _B , Y _B , Z for _{B B} asks. In this way, a conversion table from XYZ to RGB is obtained. This step 230 may be processed in advance and processed.

  In S240, the spectral relative gains S1gain, S2gain, and S3gain (T = 5000K) obtained in S220 are multiplied by S1i5000k, S2i5000k, and S3i5000k (i = 1 to m, where m is the number of pixels). The XYZ value (T = 5000K) is obtained. The calculation is performed according to Equation 2 described above in the first embodiment.

  In S250, the XYZ value (T = 5000K) obtained in S240 is used to obtain the corresponding RGB value (T = 5000K) using the XYZ-RGB conversion table. For details, refer to the description of the first embodiment. With the above color temperature correction calculation, an image can be accurately displayed on an RGB monitor.

  In S260, the image is displayed on the display device 227 of the portable information terminal 203 based on the RGB value (T = 5000K) obtained in S250. At this time, as shown in FIG. 12, an image 152 obtained by capturing an image of a comparative vehicle 207 produced overseas with an RGB digital camera 224 (or a digital camera) of the portable information terminal 203 was produced in Japan. The image replaced with the image 151 of the reference product can be compared, and the color matching degree can be determined in real time according to the appearance. As a modification, as shown in FIG. 13, an image of the car 207 is captured by an RGB digital camera 224 (or a digital camera) of the portable information terminal 203, and the portable information terminal 203 is provided with an XYZ-based conversion function. An RGB image 155 obtained by performing XYZ correction conversion on the image may be displayed on the RGB screen (see Japanese Patent Application No. 2015-37450 for details). In other words, color fidelity RGB images captured at different color temperatures can be compared and displayed, and a numerical value of the degree of coincidence can also be compared.

  Thereby, for example, it can be applied by extracting a car from the manufactured car 207 and measuring whether or not the paint is properly applied and checking the color of the paint. Also, for example, if there is one original shoe made by a designer at the headquarters in Japan, whether the shoe and the shoe that is going to be produced at the factory in Thailand match the two colors in the final state, The operator can see and confirm on the spot. Also, for example, when shooting a Japanese tile and wanting to see it under the California sky, the data captured in a Japanese factory is in real time on the portable information terminal 203 under the California spectrum environment. I can confirm.

  The embodiments of the present invention are not limited to the above-described embodiments, and modifications and the like can be made without departing from the technical idea of the present invention. Needless to say, objects and the like are also included in the technical scope of the present invention and can take various forms as long as they belong to the technical scope. For example, with respect to the method of acquiring image information according to the three-band visual sensitivity images S1i, S2i, and S3i, the methods given in the present embodiment are merely specific examples, and the present invention is not limited to these, and other methods may be used. The technical idea of the invention is to be implemented.

  The present invention can provide a simulation by changing the color of a product in the sale of a product such as a car, or a comparison display, and can provide convenience for manufacturing and sales. Since the color is approximated from the human eye and the color is less uncomfortable, the industrial utility value is great.

1 is a block diagram of a color fidelity environment correction system 1 according to Embodiment 1 of the present invention. FIG. It is explanatory drawing which shows the example by the color fidelity environment correction system 1 of Example 1 of this invention. It is a block diagram of the camera 2 of the color fidelity environment correction system 1 of Example 1 of this invention. This is a specific example of a method for acquiring image information according to three spectral sensitivities (S1 (λ), S2 (λ), S3 (λ)) in the first embodiment of the present invention. (A) is explanatory drawing in the case of using a dichroic mirror. (B) is explanatory drawing in the case of using a filter turret. (C) is explanatory drawing at the time of attaching optical filter 22a, 22b, 22c to the image pick-up element 23 microscopically. It is a function which shows the spectral sensitivity of the camera 2 which is an XYZ color system camera in Example 1 of this invention. It is a flowchart in the camera 2 of this invention Example 1. FIG. It is a flowchart in the computer 5 of the color fidelity environment correction system 1 of Example 1 of this invention. It is a graph (reference color temperature 6500K) which shows the relationship between the relative intensity of the spectrum of black body radiation, and color temperature. It is a graph (reference color temperature 5000K) which shows the relationship between the relative intensity of the spectrum of black body radiation, and color temperature. It is a graph which shows the relationship between the spectral sensitivity of this invention Example 1, the relative intensity of a spectrum, and a spectral sensitivity gain. It is a graph which shows the relationship between the relative intensity of a spectrum about three spectral sensitivity of this invention Example 1, and color temperature. It is a block diagram of the color fidelity environment correction system 201 of Example 2 of the present invention. It is a block diagram of the change form of the color fidelity environment correction system 201 of Example 2 of this invention. It is a block diagram of the portable information terminal and spectroscope of Example 2 of the present invention. It is a flowchart of the process performed with the electronic circuit of the portable information terminal of Example 2 of this invention. It is explanatory drawing of the process performed by the electronic circuit of the local computer of Example 2 of this invention. It is explanatory drawing of the process performed by the electronic circuit of the portable information terminal of the remote side of Example 2 of this invention.

Claims (7)

A camera having three spectral sensitivities (S ₁ (λ), S ₂ (λ), S ₃ (λ)) linearly converted equivalently to the CIE XYZ color matching function;
A reference three-band visual sensitivity image obtained by imaging an observation object with a reference color temperature is acquired by the camera, and a spectral sensitivity under a condition of a color temperature different from the reference color temperature is calculated. The three-band spectral sensitivity gain of the camera corresponding to is calculated, and the gain is adjusted based on the color temperature to correct the three-band visual sensitivity image. A simulation image calculation unit for calculating ', Y', Z ';
Based on the corrected tristimulus values X ′, Y ′, Z ′, a display device that replaces the colors of RGB images captured at different color temperatures and displays them on the screen;
Color fidelity environment correction device. By adjusting the gain so that the data outputs of the spectral sensitivities (S ₁ (λ), S ₂ (λ), S ₃ (λ)) at the color temperature coincide with each other, the spectral sensitivity (S ₁ (λ), S ₂ (λ), S ₃ (λ)) coincident with the color temperature, the spectral sensitivity (S ₁ (λ), S ₂ (λ), S ₃ (λ)) The color fidelity environment correcting device according to claim 1, wherein the conversion formula from (3) to tristimulus values (X, Y, Z) is associated with a reference color temperature.   The color fidelity environment correction device according to claim 1, wherein the gain adjustment is performed based on an output value of a spectrum of the spectroscope under the different color temperature.   4. The color fidelity environment according to claim 3, wherein the gain is adjusted based on a spectrum output value and a normalized sensitivity of a spectroscope to obtain an output value of a spectrum normalized sensitivity and obtain a gain from an integrated value corresponding thereto. Correction device.   5. The color fidelity environment correction device according to claim 1, wherein a gain value of the camera is adjusted by obtaining a multiplication value from the output value of the illumination spectrum at the reference temperature and the spectral sensitivity, and adjusting each integral value. .   6. The color fidelity environment correction device according to claim 1, wherein the conversion table or conversion matrix from the tristimulus values X ′, Y ′, Z ′ to RGB values is created based on the spectrum output value of the spectrometer. . An imaging step of imaging an observation object at a reference color temperature with a camera according to three spectral sensitivities (S ₁ (λ), S ₂ (λ), S ₃ (λ)) linearly converted equivalent to the CIE XYZ color matching function When,
A spectral sensitivity acquisition step of acquiring a reference three-band visual sensitivity image captured by the camera;
Calculating a spectral sensitivity under a condition of a color temperature different from the reference color temperature;
By calculating the gain of the 3-band spectral sensitivity of the camera corresponding to the different color temperature, and adjusting the gain based on the color temperature, the 3-band visual sensitivity image is corrected, and the corrected 3-band visual sensitivity image is corrected. A simulation image calculation step for calculating tristimulus values X ′, Y ′, Z ′ from
Based on the corrected tristimulus values X ′, Y ′, and Z ′, a display step of replacing the colors of RGB images captured at different color temperatures and displaying them on the screen;
Color fidelity environment correction method with

Images