JP2006135887A - Image processing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To determine an optimal color conversion parameter from observation environment conditions of image data. <P>SOLUTION: An image processing apparatus 100 acquires observation environment information representing an observation environment of image data of an image processing system 1000 from a display device 10, illumination 30, motor-driven curtain 40, and illuminance sensor 50, and acquires Exif information of image data GD from the image data GD. The observation environment information indicates, for example, ON/OFF information of a power source of the illumination, luminance setting information of the display device 10 and the like. The image processing apparatus 100 determines a color conversion parameter for the inputted image data GD according to the acquired observation environment information and Exif information and uses the color conversion parameter to perform image processing including color conversion processing taking color matching into account. The image processing apparatus 100 outputs image data GD2 after image processing onto the display device 10 and outputs image data GD3 after image processing onto electronic paper 60. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an image processing technique for executing color conversion processing on image data.

  2. Description of the Related Art Conventionally, a color appearance model that predicts a perceptual amount related to color appearance under various observation light sources and observation conditions and expresses color appearance independent of the observation environment has been used. The parameters necessary for calculating the color appearance model include, for example, the luminance of the adaptive visual field and the tristimulus value of the reference white. These parameters are set based on the conditions of the observation environment input and set by the user. The condition of the observation environment represents, for example, the type of light source such as a fluorescent lamp and sunlight, the intensity of illumination, and the like (see Patent Document 1).

JP 2001-143064 A JP 2004-72758 A

  However, there are a wide variety of observation environmental conditions for specifying parameters for calculating the color appearance model. For this reason, it is very complicated and difficult for the user to appropriately input and set the observation environment condition. There is also a problem that proper color conversion cannot be performed due to a setting error.

  The present invention has been made to solve the above-described problem, and an object of the present invention is to easily set appropriate parameters used for calculation of a color appearance model when using the color appearance model.

The present invention adopts the following configuration as the first configuration in order to solve at least a part of the problems described above. That is,
In an image processing apparatus that performs color conversion processing on image data,
Observation environment information acquisition means for acquiring observation environment information representing an environment in which the image data is observed;
Variable determining means for determining a color conversion variable for equalizing the color appearance of the image data based on the acquired observation environment information without depending on the observation environment;
Color conversion processing means for executing color conversion on the image data using the determined color conversion variable may be provided.

  According to the image processing apparatus of the first configuration of the present invention, it is possible to acquire observation environment information and determine a color conversion variable based on the acquired observation environment information. Therefore, it is possible to easily determine an appropriate color conversion variable that reflects the environment in which image data is browsed. Since the image processing apparatus performs color conversion using the determined color conversion variable, the image data observation environment can be accurately reflected in the color space after color conversion. In addition, the user does not need to input and set observation environment information, the operation burden can be reduced, and input errors can be prevented.

As a second configuration of the present invention, in an image processing device that performs color conversion processing on image data input from an input device and outputs it to an output device,
Observation environment information acquisition means for acquiring observation environment information representing the observation environment at the time of outputting the image data;
First variable determining means for determining a first color conversion variable for realizing color appearance reflecting the observation environment at the time of outputting the image data based on the acquired observation environment information;
First color conversion processing means for performing color conversion from a device-dependent color space of the input device to a device-independent color space, the color space representing the input image data;
Input observation environment reflecting means for performing color conversion from the device-independent color space to a first uniform color space representing the appearance of a color independent of the observation environment at the time of input;
Coordinate conversion processing for executing a coordinate conversion that associates a color gamut reproducible by the input device and a color gamut reproducible by the output device with respect to the first uniform color space to obtain a second uniform color space. Means,
An output observation environment reflecting means for performing color conversion to the device independent color space based on the first color conversion variable in consideration of the observation environment at the time of outputting the second uniform color space;
The gist of the invention is to include second color conversion processing means for performing color conversion from the color-converted device-independent color space to the device-dependent color space of the output device.

  According to the image processing apparatus of the second configuration of the present invention, it is possible to determine a color conversion variable reflecting the acquired observation environment information, and perform color conversion using the determined color conversion variable. Therefore, an appropriate color conversion variable can be determined easily and easily. In addition, color conversion that makes a color appearance independent of the influence of the observation environment can be performed on the color space representing the image data by using the determined color conversion variable, and the accuracy of color conversion can be improved. .

In the image processing apparatus according to the second configuration of the present invention,
The first color conversion variable is
A reference white tristimulus value that becomes the standard white color in the observation environment, and
The brightness of the adaptive field of view, representing absolute brightness,
It is good also as a variable containing the observation condition coefficient matched with the observation condition showing the surrounding state at the time of observation.

  According to the present invention, it is possible to easily determine the reference white tristimulus value, the luminance of the adaptive visual field, and the observation condition coefficient, which are color conversion variables necessary for color conversion, from the acquired observation environment information.

In the image processing apparatus according to the second configuration of the present invention,
The observation environment information includes display device setting information representing setting contents of a display device that displays the image data,
The display device setting information includes color temperature setting information which is color temperature setting information of the display device,
The first variable determining means may determine a reference white tristimulus value of the first color conversion variable based on the color temperature setting information.

In the image processing apparatus according to the second configuration of the present invention,
The observation environment information includes a surrounding color value in the observation environment of the image data,
The first variable determining means may determine a reference white tristimulus value of the first color conversion variable based on the color value.

In the image processing apparatus according to the second configuration of the present invention,
The observation environment information includes display device setting information representing setting contents of a display device that displays the image data,
The display device setting information includes luminance setting information of the display device,
The first variable determining means may determine the luminance of the adaptation visual field of the first color conversion variable based on the luminance setting information.

In the image processing apparatus according to the second configuration of the present invention,
The observation environment information includes dimming setting information representing setting contents of a dimming device that adjusts the brightness of the surroundings of the observation environment of the image data,
The dimming setting information includes a dimming state of the dimming device,
The first variable determining means may determine an observation condition coefficient of the first color conversion variable based on the dimming state.

In the image processing apparatus according to the second configuration of the present invention,
The observation environment information includes an ambient illuminance value in the observation environment of the image data,
The first variable determining means may determine an observation condition coefficient of the first color conversion variable based on the illuminance value.

  According to the present invention, various color conversion variables can be easily determined from acquired observation environment information. Therefore, the user can easily determine the color conversion variable and perform the image processing by using the image processing apparatus according to the present invention, so that the convenience can be improved. In addition, in a series of processes performed by the image processing apparatus of the present invention, an operation such as input setting by the user is not involved, so that setting mistakes can be prevented and color conversion accuracy can be improved.

In the image processing apparatus according to the second configuration of the present invention,
The first variable determining means may determine the first color conversion variable suitable for the display form based on the display form of the image data of the output device.

  According to the configuration of the present invention, since color conversion is performed using a color conversion variable suitable for the display form of the output device, color conversion processing that reflects the observation environment in which the image data output device is installed can be performed. . Therefore, a highly accurate color conversion variable can be set, and the accuracy of color conversion can be improved.

In the image processing apparatus according to the second configuration of the present invention,
When the output device is the display device, the output observation environment reflecting means uses the first color conversion variable determined by the first variable determination unit based on the display device setting information, and uses the color conversion variable. Conversion may be executed.

  According to the configuration of the present invention, when the image data is output to the display device, it is not necessary to set the observation environment information of the user, and the display device setting information acquired from the display device is simply set as the observation environment information. Therefore, convenience can be improved. In addition, since the color conversion variable is determined based on the observation environment information acquired from the display device, the color conversion variable suitable for the output device can be set, so that the accuracy of color conversion can be improved.

In the image processing apparatus according to the second configuration of the present invention,
Furthermore,
Shooting environment information acquisition means for acquiring shooting environment information representing a shooting environment at the time of shooting the image data;
Second variable determining means for determining a second color conversion variable for realizing color appearance independent of the shooting environment at the time of shooting the image data based on the acquired shooting environment information;
The input observation environment reflecting means may execute color conversion from the device independent color space to the first uniform color space based on the second color conversion variable.

  In this way, the color conversion to the first uniform color space can be executed reflecting the environment at the time of shooting, so that the accuracy of the color conversion can be further improved.

In the image processing apparatus according to the second configuration of the present invention,
The second color conversion variable is
A reference white tristimulus value that is standard white in the shooting environment,
The brightness of the adaptive field of view, representing absolute brightness,
It is good also as a variable containing the imaging condition coefficient matched with the imaging condition showing the surrounding state at the time of imaging | photography.

  According to the present invention, the reference white tristimulus value, the luminance of the adaptation field, and the imaging condition coefficient, which are color conversion variables necessary for color conversion, can be easily determined from the acquired imaging environment information.

In the image processing apparatus according to the second configuration of the present invention,
The photographing environment information acquisition unit acquires image information related to the image data,
The image information includes incidental information of the image data,
The second variable determining means may determine a reference white tristimulus value of the second color conversion variable based on incidental information of the image data.

In the image processing apparatus according to the second configuration of the present invention,
Furthermore,
Analyzing the image data, comprising an average luminance value calculating means for calculating an average luminance value of the image data,
The second variable determining means may determine the luminance of the adaptation visual field of the second color conversion variable based on the average luminance value.

In the image processing apparatus according to the second configuration of the present invention,
The photographing environment information acquisition unit acquires image information related to the image data,
The image information includes incidental information of the image data,
The second variable determining means may determine the luminance of the adaptation visual field of the second color conversion variable based on incidental information of the image data.

  In the image processing apparatus according to the second configuration of the present invention, the incidental information of the recorded image data may be Exif information. Since the Exif information stores various information indicating the shooting environment of the image data, various shooting environment conditions can be easily acquired.

  In the present invention, the various aspects described above can be applied by appropriately combining or omitting one means. In addition to the configuration as the output device described above, the present invention provides an output method by the output device, an output data generation device that generates output data, an output device, and information exchange between the data generation device and the output device. An output system including a portable recording medium to be performed, an output method using the output system, a computer program for causing the output device to output output data, a recording medium on which the computer program is recorded in a computer-readable manner, and the like can be configured. In any configuration, the above-described aspects can be appropriately applied.

  As a computer-readable recording medium, various media such as a flexible disk, a CD-ROM, a DVD-ROM, a magneto-optical disk, an IC card, and a hard disk can be used.

Hereinafter, embodiments of the present invention will be described in the following order based on examples.
A. Example:
A1. System configuration:
A2. Function block:
A3. Image processing:
B. Variations:

A. Example:
A1. System configuration:
FIG. 1 is an explanatory diagram illustrating a system configuration in the present embodiment. The image processing system 1000 includes an image processing device 100, a display device 10, a digital camera 20, an illumination 30, an electric curtain 40, an illuminance sensor 50, and an electronic paper 60. The display device 10, the digital camera 20, the illumination 30, the electric curtain 40, the illuminance sensor 50, and the electronic paper 60 are locally connected to the image processing apparatus 100 via, for example, a USB cable. The image processing system 1000 is configured in a predetermined space, for example, a room.

The digital camera 20 is an input device that inputs image data GD to the image processing apparatus 100. The digital camera 20 is a camera that acquires an image by combining light information with an image sensor. In this embodiment, a CCD (Charge Coupled Devices) is provided as an image sensor. The imaging element may be a CMOS or the like. The digital camera 20 includes a CCD in which R, G, and B filters are arranged according to a predetermined rule for each constituent pixel, and generates digital image data corresponding to a subject. The digital camera 20 stores the generated image data in a memory card (not shown).

  The display device 10 includes a display that displays image data, and displays the image data GD2 output from the image processing device 100 on the display. The display device 10 is a self-luminous display device that displays image data GD2 and the like using a backlight.

  The electronic paper 60 is a display device that displays input image data. The electronic paper 60 is a reflection type display device that does not include a backlight and displays information such as image data GD by reflecting ambient light such as sunlight or illumination light.

  The illumination 30 is a general fluorescent lamp and illuminates the environment in which the image processing system 1000 is configured. The electric curtain 40 includes an electric curtain rail 41 and a curtain 42. The electric curtain 40 controls the motor 43 to drive the curtain rail 44 to open and close the curtain 42, thereby shielding sunlight incident from the window 41.

  The illuminance sensor 50 is a sensor that measures the illuminance and color value of light in an environment where the image processing system 1000 is configured. Since the illuminance, luminance value, color value, and the like of the room in which the image processing system 1000 is configured vary depending on the state of the illumination 30 and the electric curtain 40, the illuminance sensor 50 acquires the illuminance of the room.

  The image processing apparatus 100 acquires observation environment information representing the observation environment of the image data of the image processing system 1000 from the display device 10, the illumination 30, the electric curtain 40, and the illuminance sensor 50. The observation environment information indicates information acquired from the display device 10, the illumination 30, the electric curtain 40, and the illuminance sensor 50, such as power ON / OFF information of the illumination 30 and luminance setting information of the display device 10. Further, the image processing apparatus 100 acquires image information that is information at the time of shooting from the image data GD, and calculates an average luminance value of all the pixels of the image data GD. The image information is Exif information recorded in the header portion of the image data GD.

  The image processing apparatus 100 determines color conversion parameters for the input image data GD based on the obtained observation environment information, Exif information, and average luminance value, and considers color matching using the color conversion parameters. Image processing including the color conversion processing performed is performed. The image processing apparatus 100 outputs the image data GD2 after the image processing to the display device 10 and the image data GD3 after the image processing to the electronic paper 60. Color conversion processing that takes color matching into account is color conversion processing that reflects the shooting environment at the time of shooting, the type of output device, and the environment of the installation location of the output device to make the color look independent of the influence of the observation environment. is there. The process of determining the color conversion parameter used in the color conversion process is a characteristic part of the invention of the present application and will be described in detail later.

A2. Function block:
FIG. 2 is an explanatory diagram illustrating functional blocks in the present embodiment. The image processing apparatus 100 is a computer that includes a CPU 110, an input / output unit 120, and a memory 130. Each functional block of the image processing apparatus 100 is controlled by the CPU 110. The memory 130 includes a color conversion processing unit 140, an observation environment information acquisition unit 150, an image information acquisition unit 160, and a color conversion parameter determination unit 170. Each functional block configured in the memory 130 is configured by software. Each functional block may be configured by hardware.

  The input / output unit 120 includes an interface for transmitting / receiving image data to / from an input device such as the digital camera 20 and an output device such as a display device or electronic paper 60. Also, exchange of information with various dimming devices that constitute the observation environment of the image processing system 1000 such as the electric curtain 40 and the illumination 30, and measuring devices that measure environmental information of the image processing system 1000 such as the illuminance sensor 50, etc. An interface for performing

  The observation environment information acquisition unit 150 includes color temperature setting information, luminance setting values of the display device 10, open / closed state of the electric curtain 40, power ON / OFF information of the lighting 30, and image processing measured by the illuminance sensor 50. An illuminance value, a color value, etc. in the environment of the system 1000 are acquired. The observation environment information acquisition unit 150 corresponds to “observation environment information acquisition means” in the present invention.

  The image information acquisition unit 160 acquires shutter speed and ISO sensitivity information recorded in the Exif information of the input image data GD. In addition, the image information acquisition unit 160 analyzes the image data GD and calculates an average value of the pixel values. The image information acquisition unit 160 corresponds to “imaging environment information acquisition means” in the present invention.

The color conversion parameter determination unit 170 determines a color conversion parameter used for calculation in a color conversion process described later based on the information acquired by the observation environment information acquisition unit 150 and the image information acquisition unit 160. In this embodiment, color conversion processing of image data is performed using CIECAM02 defined by the CIE (International Commission on Illumination) standard. The color conversion parameters of CIECAM02 include reference white tristimulus values (Xw, Yw, Zw), adaptation field luminance (La [cd / m ² ]), background luminance rate (Yb), and observation condition coefficient ( A coefficient C relating to the magnitude of the influence of the surroundings, a chromatic induction coefficient Nc, a brightness contrast coefficient FLL, and a coefficient F) representing the degree of adaptation. In this embodiment, the color conversion parameter determination unit 170 determines a parameter other than the background luminance rate (Yb) among the color conversion parameters described above. As the background luminance ratio (Yb), a value arbitrarily input by the user is used. The color conversion parameter determination unit 170 corresponds to the first variable determination unit and the second variable determination unit in the present invention.

  The color conversion processing unit 140 uses the color conversion parameters determined by the color conversion parameter determination unit 170 to perform color conversion processing based on the color conversion formula defined in CIECAM02. Details of the color conversion process will be described later.

  The CPU 110 outputs the color-converted image data to the display device 10 and the electronic paper 60 that are output devices.

  FIG. 3 is a block chart schematically showing color conversion processing in the present embodiment. Each process described below is realized by the CPU 110 executing each functional block stored in the memory 130.

  The input signal color conversion processing unit 141, the input observation environment reflection unit 142, the color gamut mapping processing unit 143, the output observation environment reflection unit 144, and the output signal color conversion processing unit 145 are configured as a part of the color conversion processing unit 140. Yes. The input signal color conversion processing unit 141 is the “first color conversion processing unit” in the present invention, the input observation environment reflection unit 142 is the “input observation environment reflection unit” in the present invention, and the color gamut mapping processing unit 143 is the In the “coordinate conversion processing means” in the present invention, the output observation environment reflecting unit 144 is in the “output observation environment reflecting means” in the present invention, and the output signal color conversion processing unit 145 is in the “second color conversion in the present invention”. It corresponds to “processing means”.

  The input signal color conversion processing unit 141 performs color conversion processing from the device-dependent color space of the input device, that is, the digital camera 20, to the device-independent color space. Specifically, when the input signal color conversion processing unit 141 detects the input of the image data GD, the input device profile PF1 stored in the memory 130 is used to change from the device-dependent color space of the input device to the device-independent color space. Color conversion information is acquired, and the color space of the image data is converted using the acquired color conversion information. In this embodiment, the device-dependent color space of the digital camera 20 that is an input device is an RGB color space, and the device-independent color space is an XYZ color space. The color conversion information includes a color conversion table from the RGB color space to the XYZ color space. The color conversion information may include an RGB-XYZ color conversion matrix. FIG. 4 illustrates the contents of the input device profile PF1.

  FIG. 4 is an explanatory diagram illustrating the contents of the input device profile PF1 in the present embodiment. The input device profile PF1 includes a header part PF11, device-independent color space conversion information PF12, and color space information (input profile) PF13. In the header part PF11, a device type indicating the type of the input device, a model name, and the creation date and time of the input device profile PF1 are set. In the device independent color space conversion information PF12, as color conversion information necessary for converting the device dependent color space (RGB color space) of the digital camera 20 as an input device into the device independent color space (XYZ color space), An RGB-XYZ color conversion table is set.

  In the color space information PF13, information related to a color space that can be reproduced by the digital camera as the input device is set. The input device profile PF1 is stored in the memory 130 together with the installation of the input device driver. The input device profile PF1 may be provided in association with the image data, for example, included in the image data.

  The input observation environment reflection unit 142 has a function of reflecting the observation environment such as a light source in the image data GD represented by the device-independent color space to make the color appearance independent of the influence of the observation environment. Specifically, the input observation environment reflection unit 142 applies the XYZ-JCh conversion formula of CIECAM02 using the color conversion parameter received from the color conversion parameter determination unit 170, and changes the color space of the image data to the XYZ color space. To the JCh color space which is the first uniform color space. The color conversion parameter determination unit 170 determines a color conversion parameter used in the input observation environment reflection unit 142 based on image information acquired from the image data GD. The color conversion parameter determination process will be described below.

  The image information acquisition unit 160 acquires ISO sensitivity, exposure time, and the like from the Exif information 21 recorded as part of the input image data GD. Further, the image information acquisition unit 160 calculates an average luminance value of all the pixels of the image data GD. The contents of the Exif information 21 will be described with reference to FIG.

  FIG. 5 is an explanatory diagram illustrating a part of the Exif information 21 of the image data GD in the present embodiment. The Exif information 21 includes, as shown in the figure, information on the image data GD such as “image title”, “shooting date / time”, “color space information”, “ISO sensitivity”, “shutter speed”, “aperture value”, A photographing environment at the time of photographing image data GD such as “luminance value” is recorded. The Exif information 21 can be easily referred to, and various values can be acquired. Therefore, the Exif information 21 is suitable as a determination material for determining the environment at the time of shooting.

  The image information acquisition unit 160 acquires “ISO sensitivity”, “shutter speed”, and “aperture value” from the Exif information 21 and passes them to the color conversion parameter determination unit 170. The image information acquisition unit 160 passes the average luminance value of the image data GD to the color conversion parameter determination unit 170. The image information acquisition unit 160 sets the number of pixels of the image data GD to “n”, the R, G, and B values of each pixel as “R”, “G”, and “B”, respectively, By applying, the average luminance value Lav of the image data GD is calculated, and the average luminance value Lav is passed to the color conversion parameter determination unit 170.

(Formula 1)

In addition, the color conversion parameter determination unit 170 applies the following (Equation 2) using the luminance value Bv [ft-L] recorded in the Exif information 21, and the white luminance Lw [cd of the normal adaptation field of view. / M ² ] is calculated.

(Formula 2)

  The color conversion parameter determination unit 170 also calculates the white luminance Lw of the normal adaptation field of view by applying the following (Equation 3) using the aperture value Av, the shutter speed Tv, and the ISO sensitivity ISO. Can do.

(Formula 3)

  The color conversion parameter determination unit 170 sets the passed average luminance value Lav as the luminance ratio Ra of the adaptive visual field (Ra = Lav), and the white luminance Lw of the normal adaptive visual field calculated by (Expression 2) or (Expression 3). Is used to calculate the luminance La of the adaptation field of view by applying the following (Equation 4).

(Formula 4)

  The color conversion parameter determination unit 170 passes the luminance La of the adaptation field calculated in this way to the input observation environment reflection unit 142.

  The input observation environment reflection unit 142 converts the color space of the image data from the XYZ color space to the JCh color space based on the passed color conversion parameters. As described above, by performing color conversion using the color conversion parameters determined based on the Exif information 21 of the image data and the average luminance value of the image data, the JCh color space does not depend on the influence of the shooting environment at the time of shooting. The appearance of color, in other words, the influence of the observation environment can be removed.

  The color gamut mapping processing unit 143 associates the color gamut of the color space that can be reproduced by the input device with the color gamut that can be reproduced by the output device, that is, the color gamut mapping processing unit 143 can reproduce the input device. A function of mapping the color gamut of the color space to the color gamut of the color space that can be reproduced by the output device is provided. Specifically, conversion is performed from the first uniform color space (JCh color space) to the second uniform color space (J′C′h ′ color space) based on a preset color conversion table.

  The output observation environment reflecting unit 144 has a function of reflecting the observation environment of the image data at the time of outputting the image and making the color appear depending on the influence of the observation environment. Specifically, the output observation environment reflection unit 144 uses the color conversion parameter received from the color conversion parameter determination unit 170 to generate an inverse conversion formula of the CIECAM02 XYZ-JCh conversion formula defined by the CIE standard. By applying this, the color space of the image data is converted from the J′C′h ′ color space that is the second uniform color space to the XYZ color space that is the device independent color space. The color conversion parameter determination unit 170 is a color used in the output observation environment reflection unit 144 based on the observation environment information acquired from the display device setting information acquisition unit 151, the environmental condition acquisition unit 152, and the dimming setting information acquisition unit 153. Determine conversion parameters. The color conversion parameter determination process will be described below.

  The display device setting information acquisition unit 151, the environmental condition acquisition unit 152, and the dimming setting information acquisition unit 153 are configured as a part of the observation environment information acquisition unit 150.

  The display device setting information acquisition unit 151 acquires the color temperature setting information, the luminance setting value, and the like of the display device 10 from the display device 10. Color temperature is a numerical value that represents the relative intensity of bluish purple light and red light contained in a light source that emits a certain color. The black body emits light of the same color as that light. Temperature. The unit is K (Kelvin). The display device setting information acquisition unit 151 also acquires the brightness setting value of the display device 10. The display device setting information acquisition unit 151 passes the acquired color temperature setting information and luminance setting value of the display device 10 to the color conversion parameter determination unit 170.

  The environmental condition acquisition unit 152 acquires the illuminance value Ev [lux] and the color value (X, Y, Z) measured by the illuminance sensor 50 in the environment where the image processing system 1000 is installed, and the color conversion parameter determination unit 170. Pass to.

  The dimming setting information acquisition unit 153 acquires information on ON / OFF of the power supply of the illumination 30 and information on the open / close state (close / open) of the electric curtain 40 and passes the information to the color conversion parameter determination unit 170.

  The color conversion parameter determination unit 170 has parameter correspondence information 171. The parameter correspondence information 171 includes output device parameter correspondence information 171a, reference white tristimulus value determination information 171b, observation condition specifying information 171c, and observation condition coefficient determination information 171d. The display device setting information acquisition unit 151, This is information that associates the color conversion parameters with various observation environment information passed from the environmental condition acquisition unit 152, the dimming setting information acquisition unit 153, and the image information acquisition unit 160. The contents of the output device parameter correspondence information 171a, the reference white tristimulus value determination information 171b, the observation condition specifying information 171c, and the observation condition coefficient determination information 171d will be described with reference to FIGS.

  FIG. 6 is an explanatory diagram illustrating the output device parameter correspondence information 171a in the present embodiment. The output device parameter correspondence information 171a includes “an open / close state of the electric curtain”, “a lighting power state”, “a display device parameter”, and “an electronic paper parameter”.

  The “opening / closing state of the electric curtain” indicates the opening / closing state of the electric curtain 40 and is represented by a value of “close” or “open”. The “illumination power supply state” indicates the On / Off state of the power supply of the illumination 30 and is displayed by the value “On” or “Off”.

  The “display device parameters” are color conversion parameters used when color conversion processing is performed on the image data output to the display device 10, and reference white tristimulus values (Xw, Yw, Zw), It is composed of a luminance value (Lw) and an observation condition coefficient (coefficient C related to the surrounding size, chromatic induction coefficient Nc, brightness contrast coefficient FLL, coefficient F representing the degree of adaptation).

  “Electronic paper parameters” are color conversion parameters used when color conversion processing is performed on image data to be output to the electronic paper 60. Reference white tristimulus values (Xw, Yw, Zw), It is composed of a luminance value (Lw) and an observation condition coefficient (coefficient C related to the surrounding size, chromatic induction coefficient Nc, brightness contrast coefficient FLL, coefficient F representing the degree of adaptation).

  The color conversion parameter determination unit 170 determines the “display device parameters” based on the output device parameter correspondence information 171a as follows. For example, when the electric curtain 40 is “close”, that is, when the electric curtain 40 is closed and the illumination power source is “On”, as shown in the drawing, the reference white tristimulus values (Xw, Yw, Zw) is determined based on the color temperature setting information of the display device, the luminance value (Lw) is determined based on the luminance setting value of the display device 10, and the observation condition coefficients (C, Nc, FLL, F) are Lwd. / Lws is determined.

  The reference white tristimulus values are determined as described below. The color conversion parameter determination unit 170 determines a reference white tristimulus value based on the reference white tristimulus value determination information 171b. The contents of the reference white tristimulus value determination information 171b will be described with reference to FIG.

  FIG. 7 is an explanatory diagram illustrating the reference white tristimulus value determination information 171b in the present embodiment. The reference white tristimulus value determination information 171b includes color temperature setting information and reference white tristimulus values (Xw, Yw, Zw). As shown in the figure, for example, when the color temperature setting information of the display device 10 is “6500K”, “Xw” of the reference white tristimulus value which is a color conversion parameter is “95.0” and “Yw”. "Is determined to be" 100.0 "and" Zw "is determined to be" 108.9 ".

  The observation condition coefficients (C, Nc, FLL, F) are determined as described below. The color conversion parameter determination unit 170 specifies an observation condition based on the observation condition specification information 171c, and determines an observation condition coefficient based on the specified observation condition and the observation condition coefficient determination information 171d. The contents of the observation condition specifying information 171c will be described with reference to FIG. 8, and the contents of the observation condition coefficient determination information 171d will be described with reference to FIG.

  FIG. 8 is an explanatory diagram illustrating the observation condition specifying information 171c in the present embodiment. The observation condition specifying information 171c includes the observation condition and the ratio of “Lwd / Lws”, that is, the white luminance value Lws of the display device and the white luminance value Lws in the installation environment of the image processing system 1000 acquired from the illuminance sensor 50. Consists of The observation condition represents a state of brightness around which the image data GD is observed in the image processing system 1000. As shown in the figure, for example, when the value of Lwd / Lws is “0 to 0.2”, the observation condition is “dim surrounding”. The color conversion parameter determination unit 170 determines the viewing condition coefficient based on the viewing condition specified in this way and the viewing condition coefficient determination information 171d described below.

  FIG. 9 is an explanatory diagram illustrating the observation condition coefficient determination information 171d in the present embodiment. The observation condition coefficient determination information 171d includes an observation condition and an observation condition coefficient. The observation condition refers to the observation condition described in FIG. The observation condition coefficient includes a coefficient C related to the magnitude of the surrounding influence, a chromatic induction coefficient Nc, a brightness contrast coefficient FLL, and a coefficient F representing the degree of adaptation. As shown in the figure, for example, when the observation condition is “dim surroundings”, the coefficient C relating to the magnitude of the influence of the surroundings is “0.59”, the chromatic induction coefficient Nc is “0.9”, and the brightness contrast coefficient. FLL is “1.0”, and the coefficient F indicating the degree of adaptation is “0.9”.

  The color conversion parameter determination unit 170 determines “electronic paper parameters” as follows based on the output device parameter correspondence information 171a. For example, when the electric curtain 40 is “open”, that is, when the electric curtain 40 is open and the illumination power source is “On”, the color conversion parameter determination unit 170 determines the reference white tristimulus values (Xw, Yw). , Zw) is determined based on the color value measured by the illuminance sensor 50 as shown. That is, since the electronic paper 60 is a reflective display device, if the color values of the illuminance sensor 50 are X, Y, and Z, the reference white tristimulus values (Xw, Yw, Zw) are relative values. Therefore, calculation is performed by applying the following (Formula 5).

(Formula 5)

  In addition, since the color conversion parameter determination unit 170 is set to “average surrounding” as the observation condition coefficient, the color conversion parameter determination unit 170 calculates the observation condition coefficient (C, Nc, FLL, F) based on the observation condition coefficient determination information 171d. decide. The color conversion parameter determination unit 170 also determines the luminance value (Lw) using the illuminance value Ev measured by the illuminance sensor 50. Since the electronic paper 60 is a reflective display device, it is calculated by applying the following (formula 6) on the assumption that the light illuminating the illuminance sensor 50 illuminates the image data displayed on the electronic paper 60. To do.

(Formula 6)

  The color conversion parameter determination unit 170 handles the white luminance value Lws calculated by (Equation 5) as the luminance value Lw.

  The “reference value” shown in FIG. 6 is a default value used when an accurate environmental parameter cannot be obtained. In the present embodiment, the default value is preset as a standard value for each device. For example, the user may arbitrarily set a default value.

  The color conversion parameter determination unit 170 passes the color conversion parameter acquired in this way to the output observation environment reflection unit 144. The output observation environment reflecting unit 144 converts the color space of the image data from the J′C′h ′ color space to the XYZ color space based on the passed color conversion parameters. In this way, by performing color conversion using the color conversion parameters determined based on the setting information of the image data output device and the information about the environment in which the output device is installed, the influence of the observation environment is affected in the XYZ color space. It can make the appearance of the dependent color. Therefore, when the image data GD is output to the display device 10 and the electronic paper 60, the color appearance reflecting the observation environment can be reproduced in each device.

  The output signal color conversion processing unit 145 performs color conversion processing from the device-independent color space to the device-dependent color space of the display device 10 and the electronic paper 60 that are output devices. Specifically, the output signal color conversion processing unit 145 acquires and acquires color conversion information from the device independent color space of the output device to the device dependent space from the output device profiles PF2 and PF3 stored in the memory 130. The color space of the image data is converted using the converted color conversion information.

  In this embodiment, the output device includes the display device 10 and the electronic paper 60, the output device profile PF2 is a profile corresponding to the display device 10, and the output device profile PF3 is a profile corresponding to the electronic paper 60. It is. For example, the device independent color space of the display device 10 that is an output device is an XYZ color space, and the device dependent color space is an RGB color space. The output device profile PF2 has the same configuration as the input device profile PF1, and the color conversion information of the output device profile PF2 includes a color conversion table from the XYZ color space to the RGB color space of the display device that is the output device. It is. The output signal color conversion processing unit 145 outputs the color-converted image data GD2 to the display device 10 and the image data GD3 to the electronic paper 60.

A3. Image processing:
FIG. 10 is a flowchart illustrating image processing in the present embodiment. The image processing apparatus 100 executes input signal color conversion processing for converting the color space of the image data from the RGB color space, which is a device-dependent color space, to the XYZ color space, which is a device-independent color space (step S10). Next, when detecting the input of the image data GD, the image processing apparatus 100 acquires image information such as the Exif information 21 and the average luminance value of the pixels from the image data GD (Step S11), and based on the acquired image information, A color conversion parameter used in the color conversion process performed by the input observation environment reflecting unit 142 is determined (step S12).

  The image processing apparatus 100 performs color conversion processing from the XYZ color space, which is the device independent color space, to the JCh color space, which is the first uniform color space, using the determined color conversion parameters (step S13). Next, the image processing apparatus 100 performs a color gamut mapping process on the image data GD that has been color-converted to the JCh color space, and changes from the JCh color space, which is the first uniform color space, to the second uniform color space. A color conversion process is performed for a certain J′C′h ′ color space (step S14).

  The image processing apparatus 100 acquires observation environment conditions such as color temperature setting information of the display device 10 from the display device 10, the illumination 30, the electric curtain 40, and the illuminance sensor 50 (step S15), and based on the acquired observation environment conditions. The color conversion parameter used in the color conversion process performed by the output observation environment reflecting unit 144 is determined (step S16). In this embodiment, since the display device 10 and the electronic paper 60 exist as output devices, color conversion parameters appropriate for each observation environment are determined.

  The image processing apparatus 100 performs color conversion processing from the J′C′h ′ color space, which is the second uniform color space, to the XYZ color space, which is the device independent color space, using the determined color conversion parameters. (Step S17). In such a color conversion process, image data GD2 output to the display device 10 and image data GD3 output to the electronic paper 60 are created.

  The image processing apparatus 100 performs color conversion processing from the XYZ color space, which is a device-independent color space, to the RGB color space, which is a device-dependent color space, using the determined color conversion parameters (Step S18). The GD2 is output to the display device 10 and the image data GD3 is output to the electronic paper 60 (step S19).

  According to the image processing system 1000 of the embodiment described above, the color conversion parameter can be determined based on the observation environment information acquired from the display device 10, the illumination 30, and the electric curtain 40. It is possible to easily set highly accurate color conversion parameters that are reflected appropriately. In addition, since it is not necessary for the user to set the color conversion parameters directly by manual input, setting errors can be prevented and convenience can be improved.

  Further, according to the image processing system 1000 of the present embodiment, it is possible to set a color conversion parameter that reflects the shooting environment at the time of shooting image data, and to make the color look independent of the influence of the observation environment, that is, It is possible to improve the accuracy of color conversion using the color appearance model.

  Further, according to the present embodiment, the image information representing the photographing environment at the time of photographing the image data is obtained from the Exif information attached to the image data, so that the image information can be obtained easily.

  Further, according to the present embodiment, for different output devices (display device 10, electronic paper 60) installed in the same environment, the display device is a self-luminous display device, and the electronic paper 60 is a reflective display device. The color conversion parameters are set in consideration of the characteristics of the respective display formats, and image data to be output can be generated for each output device. Accordingly, when outputting image data to an output device having different characteristics at the same time, the color appearance can be made independent of the influence of the observation environment.

B. Variations:
Although various embodiments of the present invention have been described above, it is needless to say that the present invention is not limited to these embodiments and can take various configurations without departing from the spirit of the present invention. For example, it is good also as taking the following structures.

B1. Modification 1:
In the above-described embodiment, the color conversion parameter suitable for each output device is determined based on the output device parameter correspondence information 171a. However, the present invention is not limited to this. For example, based on observation environment information acquired from various dimming devices arranged in the environment of the image processing system 1000 such as the illumination 30 and the electric curtain 40, a plurality of patterns of reference white tristimulus values are calculated, It is good also as providing the selection part which selects which is used from the pattern of a reference white tristimulus value. In this way, an optimal color conversion parameter can be set.

B2. Modification 2:
In the above-described embodiments, the color conversion parameters used in the input observation environment reflection unit 142 and the output observation environment reflection unit 144 are determined immediately before the color conversion process in which each color conversion parameter is used. I can't. It may be determined at any timing. Similarly, the environmental condition parameter may be acquired at any timing.

B3. Modification 3:
The output observation environment reflection unit 144 may store the obtained environment parameters as an observation environment parameter file, and perform color conversion with reference to this. In this way, when output processing is performed under the same environment, it is not necessary to acquire the observation environment again, and the processing accuracy can be improved.

B4. Modification 4:
When the light source information at the time of photographing is recorded in the Exif information of the image data, the reference white tristimulus value among the color conversion parameters used in the input observation environment reflecting unit 142 is calculated based on the light source information. It may be determined.

B5. Modification 5:
In the embodiment described above, the display device 10 and the electronic paper 60 are output devices. For example, a printer may be included as the output device. In such a case, the output device profile can be realized by including a color conversion table for converting from the XYZ color space to the CMYK color space.

It is explanatory drawing which illustrates the system configuration | structure in an Example. It is explanatory drawing which illustrates the functional block in an Example. It is a block chart which shows the color conversion process in an Example typically. It is explanatory drawing which illustrates the content of input device profile PF1 in an Example. It is explanatory drawing which illustrates some Exif information of the image data in an Example. It is explanatory drawing which illustrates the output device parameter corresponding | compatible information in an Example. It is explanatory drawing which illustrates the reference white tristimulus value determination information in an Example. It is explanatory drawing which illustrates the observation condition specific information in an Example. It is explanatory drawing which illustrates the observation condition coefficient determination information in an Example. It is a flowchart explaining the image processing in an Example.

Explanation of symbols

1000 ... Image processing system 10 ... Display device 20 ... Digital camera 30 ... Lighting 40 ... Electric curtain 41 ... Electric curtain rail 41 ... Window 42 ... Curtain 43 .. Motor 44 ... Curtain rail 50 ... Illuminance sensor 60 ... Electronic paper 100 ... Image processing device 120 ... Input / output unit 130 ... Memory 140 ... Color conversion processing unit 141 .. Input signal color conversion processing unit 142 ... Input observation environment reflection unit 143 ... Color gamut mapping processing unit 144 ... Output observation environment reflection unit 145 ... Output signal color conversion processing unit 150 ... Observation environment Information acquisition unit 151 ... Display device setting information acquisition unit 152 ... Environmental condition acquisition unit 153 ... Dimming setting information acquisition unit 160 ... Image information acquisition unit 170 ... Color conversion parameter determination unit 171. .. Parameter correspondence information 171a ... Output device parameter correspondence information 171b ... Reference white three Super value determination information 171c ... observation conditions specific information 171d ... observation conditions coefficient determination information

Claims (18)

An image processing device that performs color conversion processing on image data input from an input device and outputs the image data to an output device,
Observation environment information acquisition means for acquiring observation environment information representing an environment in which the image data is observed;
Variable determining means for determining a color conversion variable for equalizing the color appearance of the image data based on the acquired observation environment information without depending on the observation environment;
An image processing apparatus comprising color conversion processing means for performing color conversion on the image data using the determined color conversion variable. An image processing device that performs color conversion processing on image data input from an input device and outputs the image data to an output device,
Observation environment information acquisition means for acquiring observation environment information representing the observation environment at the time of outputting the image data;
First variable determining means for determining a first color conversion variable for realizing color appearance reflecting the observation environment at the time of outputting the image data based on the acquired observation environment information;
First color conversion processing means for performing color conversion from a device-dependent color space of the input device to a device-independent color space, the color space representing the input image data;
Input observation environment reflecting means for performing color conversion from the device-independent color space to a first uniform color space representing the appearance of a color independent of the observation environment at the time of input;
Coordinate conversion processing for executing a coordinate conversion that associates a color gamut reproducible by the input device and a color gamut reproducible by the output device with respect to the first uniform color space to obtain a second uniform color space. Means,
An output observation environment reflecting means for performing color conversion to the device independent color space based on the first color conversion variable in consideration of the observation environment at the time of outputting the second uniform color space;
An image processing apparatus comprising: a second color conversion processing unit configured to perform color conversion from the color-converted device-independent color space to a device-dependent color space of an output device. The image processing apparatus according to claim 2,
The first color conversion variable is
A reference white tristimulus value that becomes the standard white color in the observation environment, and
The brightness of the adaptive field of view, representing absolute brightness,
An image processing apparatus which is a variable including an observation condition coefficient associated with an observation condition representing a surrounding state at the time of observation. The image processing apparatus according to claim 3,
The observation environment information includes display device setting information representing setting contents of a display device that displays the image data,
The display device setting information includes color temperature setting information which is color temperature setting information of the display device,
The first variable determination unit is an image processing apparatus that determines a reference white tristimulus value of the first color conversion variable based on the color temperature setting information. The image processing apparatus according to claim 3,
The observation environment information includes a surrounding color value in the observation environment of the image data,
The first variable determination unit is an image processing apparatus that determines a reference white tristimulus value of the first color conversion variable based on the color value. An image processing apparatus according to any one of claims 3 to 5,
The observation environment information includes display device setting information representing setting contents of a display device that displays the image data,
The display device setting information includes luminance setting information of the display device,
The first variable determination unit is an image processing apparatus that determines a luminance of an adaptation visual field of the first color conversion variable based on the luminance setting information. The image processing apparatus according to claim 3, wherein:
The observation environment information includes dimming setting information representing setting contents of a dimming device that adjusts the brightness of the surroundings of the observation environment of the image data,
The dimming setting information includes a dimming state of the dimming device,
The image processing apparatus, wherein the first variable determination unit determines an observation condition coefficient of the first color conversion variable based on the dimming state. The image processing apparatus according to claim 3, wherein:
The observation environment information includes an ambient illuminance value in the observation environment of the image data,
The first variable determination unit is an image processing apparatus that determines an observation condition coefficient of the first color conversion variable based on the illuminance value. The image processing apparatus according to claim 2, wherein:
The first variable determination means determines the first color conversion variable suitable for the display form based on the display form of the image data of the output device. The image processing apparatus according to claim 9,
When the output device is the display device, the output observation environment reflecting means uses the first color conversion variable determined by the first variable determination unit based on the display device setting information, and uses the color conversion variable. An image processing apparatus that performs conversion. The image processing apparatus according to claim 2, wherein:
Furthermore,
Shooting environment information acquisition means for acquiring shooting environment information representing a shooting environment at the time of shooting the image data;
Second variable determining means for determining a second color conversion variable for realizing color appearance independent of the shooting environment at the time of shooting the image data based on the acquired shooting environment information;
The input observation environment reflecting unit is an image processing apparatus that performs color conversion from the device independent color space to the first uniform color space based on the second color conversion variable. The image processing apparatus according to claim 11,
The second color conversion variable is
A reference white tristimulus value that is standard white in the shooting environment,
The brightness of the adaptive field of view, representing absolute brightness,
An image processing apparatus which is a variable including a shooting condition coefficient associated with a shooting condition representing a surrounding state at the time of shooting. The image processing apparatus according to claim 12,
The photographing environment information acquisition unit acquires image information related to the image data,
The image information includes incidental information of the image data,
The second variable determining means is an image processing apparatus that determines a reference white tristimulus value of the second color conversion variable based on incidental information of the image data. The image processing apparatus according to claim 12 or 13,
Furthermore,
Analyzing the image data, comprising an average luminance value calculating means for calculating an average luminance value of the image data,
The second variable determination unit is an image processing apparatus that determines the luminance of the adaptation visual field of the second color conversion variable based on the average luminance value. The image processing apparatus according to claim 12 or 13,
The photographing environment information acquisition unit acquires image information related to the image data,
The image information includes incidental information of the image data,
The second variable determination means is an image processing apparatus that determines the luminance of the adaptation visual field of the second color conversion variable based on the incidental information of the image data. The image processing apparatus according to claim 13 or 15,
The auxiliary information of the image data is an image processing apparatus that is Exif information. An image processing method for performing color conversion processing on image data,
(A) obtaining observation environment information representing an environment in which the image data is observed;
(B) determining a color conversion variable for equalizing the color appearance of the image data based on the acquired observation environment information without depending on the observation environment;
(C) An image processing method for executing a step of performing color conversion on the image data using the determined color conversion variable. An image processing method for performing color conversion processing on image data input from an input device and outputting the image data to an output device,
(A) obtaining observation environment information representing an observation environment at the time of outputting the image data;
(B) determining a first color conversion variable for realizing color appearance reflecting the observation environment at the time of outputting the image data based on the acquired observation environment information;
(C) performing a color conversion from the device-dependent color space of the input device to a device-independent color space for the color space representing the input image data;
(D) performing a color conversion from the device-independent color space to a first uniform color space representing a color appearance independent of an observation environment at the time of input;
(E) A coordinate conversion that associates a color gamut reproducible by the input device with a color gamut reproducible by the output device is performed on the first uniform color space to obtain a second uniform color space. Process,
(F) performing a color conversion of the second uniform color space into the device independent color space based on the first color conversion variable in consideration of an observation environment at the time of output;
(G) An image processing method comprising: performing color conversion from the color-converted device-independent color space to a device-dependent color space of an output device.

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