JP4838228B2 - Output device for outputting image, output method, and program - Google Patents

Description

  The present invention relates to an image adjustment technique for adjusting the brightness of image data.

  In general, the image quality of image data generated by a digital still camera (DSC), scanner, or other image input device is generally automatically adjusted on a personal computer or printer. The image quality parameter to be adjusted includes the brightness (brightness) of the image. In adjusting the brightness of the image, the reflectance corresponding to this brightness is made close to that of, for example, a standard reflecting plate (a plate having a reflectance of 18%) according to the overall brightness of the image represented by the image data. Is done. This prevents the entire image from becoming excessively dark or bright.

JP 2002-344989 A

  However, there is a case where it is desired to appropriately express the brightness of a part of the image, not the entire image. For example, there is a case where only the brightness of the person who is the main subject is emphasized, not the brightness of the entire image as in a portrait photograph. In such a case, if adjustment is performed according to the brightness of the entire image, for example, a person may become excessively bright.

  The present invention has been made to solve the above-described problems in the prior art, and an object of the present invention is to provide a technique for preventing automatic adjustment of image brightness and contrast against a shooting intention. .

A first aspect of the present invention is an output device that outputs an image using image data representing an image and shooting information associated with the image data and set when the image data is generated.
The shooting information includes photometry method information related to the photometry method,
When the photometry method information is first photometry method information for photometry of a partial area of the image, a first image quality adjustment not including brightness adjustment of the image is performed based on the shooting information. When the photometry method information is second photometry method information for photometry of the entire image, image quality adjustment for performing second image quality adjustment including brightness adjustment of the image based on the shooting information. And
An image output unit for outputting an image whose image quality has been adjusted by the image quality adjustment unit;
With
The image quality adjustment unit may perform the first image quality adjustment or the second image quality measurement when the photometry method information is center-weighted photometry in which the center of the image is weighted higher than the periphery. A user interface for allowing the user to select which image quality adjustment to perform is provided, and one of the first and second image quality adjustments is performed based on the user's selection .

  According to the first aspect of the present invention, it is determined whether or not to automatically adjust the brightness for the brightness of the entire image represented by the image data, according to the image processing control information included in the image file. Therefore, for example, when there is a photographing intention to appropriately express the brightness of a part of an image rather than the whole image, automatic adjustment against such intention can be suppressed.

  In the image processing apparatus, the image processing control information includes photometry method information indicating whether or not the image is captured by a specific photometry method that measures only a specific field of view corresponding to a part of the image, and the adjustment amount The determination unit preferably reduces the adjustment amount of the automatic adjustment when the photometry method information indicates that photometry has been performed using the specific photometry method.

If the photo was taken with a specific metering method that metered only a specific field of view, it is assumed that there was an intention to properly express the brightness of the part where the photometry was performed. Automatic adjustment that is not intended can be suppressed. It should be noted that “reducing automatic adjustment” includes reducing the adjustment amount to zero, that is, completely prohibiting automatic adjustment.

  In the image processing apparatus, the photometry method information is information indicating which of a plurality of photometry methods including average photometry, center-weighted photometry, spot photometry, multi-spot photometry, split photometry, and partial photometry. The specific metering method preferably includes spot metering, multi-spot metering, and partial metering.

  In the image processing apparatus, it is preferable that the adjustment amount determination unit provides a user interface that allows a user to select an adjustment amount for the automatic adjustment when the image processing control information is center-weighted metering. Note that “selection of adjustment amount” includes an option for setting the adjustment amount to zero, that is, an option for completely prohibiting automatic adjustment.

  The center-weighted metering method is close to partial metering when the importance level is high, and is close to split metering when the priority level is small, so the user can select whether to perform automatic adjustment. If the user interface allowed is provided, it is possible to realize image processing more suited to the user's intention of shooting.

A second aspect of the present invention is an image processing apparatus that performs image processing on the image data in accordance with an image file including image data and image processing control information used for processing the image data. In addition, the image quality automatic adjustment unit capable of automatically adjusting the brightness and contrast of the image data in any of a plurality of adjustment modes according to the overall brightness of the image represented by the image data, and the image An adjustment mode selection unit that selects any one of the plurality of adjustment modes according to processing control information;
The plurality of modes includes a plurality of adjustment modes in which at least one of a brightness adjustment amount and a contrast adjustment amount is different.

  An image output apparatus of the present invention is an image output apparatus that outputs image data in accordance with an image file including image data and image processing control information used for processing the image data. And an image output unit that outputs an image according to the image data on which the image processing has been performed.

  The present invention can be realized in various modes. For example, an image file generation device, an image output device, an image processing method, a computer program for realizing the functions of these methods or devices, and the computer The present invention can be realized in the form of a recording medium recording the program, a data signal including the computer program and embodied in a carrier wave, and the like.

A. Image processing system configuration:
FIG. 1 is an explanatory diagram showing an image processing system 10 as an embodiment of the present invention. The image processing system 10 includes a digital still camera 12 as an input device that generates original image data, a personal computer PC as an image processing device that performs image processing on the original image data generated by the digital still camera 12, and And a color printer 20 as an output device for outputting the processed image.

  The digital still camera 12, the personal computer PC, and the color printer 20 can be connected to each other with a cable CV. When connected by the cable CV, the digital still camera 12 or the like can transmit and receive an image file via the cable CV. Even when not connected by the cable CV, the digital still camera 12 and the like can exchange image files using the memory card MC.

  FIG. 2 is a block diagram showing an outline of the configuration of the digital still camera 12 as an input device for generating image data. The digital still camera 12 is a camera that electrically records a still image by forming an image on a charge coupled device (CCD) through an optical lens.

  The digital still camera 12 includes an optical circuit 121 having a CCD for converting an optical signal into an electrical signal, an image acquisition circuit 122 for controlling the optical circuit 121 to acquire an image, and processing the acquired image data. Image processing circuit 123 and a control circuit 124 for controlling each of these circuits. The digital still camera 12 further includes a selection / determination button 126 as a user interface, and a liquid crystal display 127 used as a preview of a captured image and a user interface.

  Shooting processing (image data acquisition processing) by the digital still camera 12 includes (1) setting of a shooting mode by a user, (2) imaging (input of image data), (3) image processing, and (4) recording of an image file. It is performed in the order. The setting of the shooting mode includes selection of a photometry method. Options for metering include split metering and spot metering.

  Divided photometry is a photometry method in which an area of a finder screen corresponding to an image area is divided into a plurality of pieces, and a proper exposure is calculated based on the plurality of pieces of information. Spot metering is a metering method in which only a spot area (for example, an area near the center of the finder screen) is metered to calculate an appropriate exposure.

  The metering method can be selected by the user operating the selection / decision button 126 while viewing the display on the liquid crystal display 127. When the photometric method is selected, the proper exposure is calculated in real time, and the proper aperture value and shutter speed are determined based on this.

  Imaging is performed by the user pressing the shutter. When the shutter is pressed, imaging is performed with the aperture value and shutter speed determined by the above method. For example, when the spot photometry method is selected and the face of the person who is the main subject is in the spot area, the aperture value and the shutter speed are determined based on the brightness of the person's face. As a result, imaging is performed with exposure optimized for the main subject rather than the entire viewfinder screen, and original image data is generated.

  When the original image data is generated, image processing for storage is performed on the image data. This image processing is a preprocessing for saving in the memory card MC. Generally, the original image data is converted into a JPEG format suitable for storing a photographic image. After conversion to the JPEG format, shooting information PI is added to the converted image data to generate an image file.

  The photographing information PI is information representing photographing conditions and includes information representing the selected photometry method. The image data acquisition process in the digital still camera 12 is completed by recording the image file on the memory card MC. The configuration of the image file will be described later.

  FIG. 3 is a block diagram showing an outline of the configuration of the computer PC and the color printer 20 as output devices for outputting image data. The computer PC includes a slot 22 that can read an image file from the memory card MC, and a print data generation circuit 23 that generates print data for causing the color printer 20 to perform printing. The print data generation circuit 23 includes an arithmetic processing unit (CPU) 231 that executes arithmetic processing for generating print data, a hard disk 232 that stores programs executed in the CPU 231, arithmetic processing results in the CPU 231, and other data. And a random access memory (RAM) 233 for temporarily storing the programs and data.

  The color printer 20 is a printer that can output a color image. The color printer 20 forms, for example, a dot pattern by ejecting four colors of ink of cyan (C), magenta (M), yellow (Y), and black (K) onto a print medium. An ink jet printer to be formed.

B. Image file structure:
FIG. 4 is an explanatory diagram showing an outline of the structure of the image file GF in the embodiment of the present invention. The image file GF has a file structure in accordance with the digital still camera image file format standard (Exif). This standard is set by the Japan Electronics and Information Technology Industries Association (JEITA). This standard stipulates that a JPEG-Exif file that stores compressed JPEG data as image data is included in an Exif file (Exif standard file).

  The image file GF includes an SOI marker segment 101 indicating the head of the compressed data, an APP1 marker segment 102 that stores Exif attached information, an APP2 marker segment 103 that stores Exif extension data, and a DQT marker that defines a quantization table. A segment 104, a DHT marker segment 105 that defines a Huffman table, a DRI marker segment 106 that defines a restart marker insertion interval, an SOF marker segment 107 that indicates various parameters related to a frame, and an SOS marker that indicates various parameters related to a scan A segment 108, an EOI marker segment 109 indicating the end of the compressed data, and an image data storage area 110 are included.

  The APP1 marker segment 102 stores an APP1 marker 1021, an Exif identification code 1022, a TIFF header and other attached information 1023, and a thumbnail image 1024. The attached information 1023 has a TIFF structure including a file header (TIFF header). In Exif-JPEG, Exif-specific information such as 0th IFD for storing attached information related to compressed image data and shooting information PI is stored. It includes an Exif IFD that stores attached information and a 1st IFD that stores attached information related to thumbnail images. The Exif IFD is pointed at an offset from the TIFF header stored in the 0th IFD. In IFD, tags are used to identify each piece of information, and each piece of information is sometimes called by a tag name.

  FIG. 5 is an explanatory diagram showing an example of attached information stored in the Exif IFD of the image file GF. FIG. 5A shows the configuration of attached information stored in the Exif IFD. The attached information includes various tags including a tag relating to a version and a tag relating to shooting conditions. In the tag relating to the shooting conditions, exposure time, lens F value, ISO sensitivity, shutter speed, aperture value, brightness value, photometric method, and other parameter values are stored as shooting information PI according to a predetermined offset. The recording of the shooting information PI is performed at the time of shooting in the digital still camera 12 as described above.

  FIG. 5B shows data values stored in the photometric segment and their meanings. For example, when the spot photometry method is selected for photographing with the digital still camera 12, the value 3 is recorded when the image file is recorded. On the other hand, when the split photometry method is selected, the value 5 is recorded similarly.

  Of the photometry methods shown in FIG. 5B, spot photometry, multi-spot photometry, and partial photometry are photometry methods that measure only a specific field of view corresponding to a part of a printed image. Another photometric method is a photometric method that measures the entire field of view. The former three photometry methods correspond to “specific photometry methods” in the claims.

C. Image processing on computer PC:
FIG. 6 is a flowchart showing a processing routine of image processing in the computer PC. In step S <b> 100, the CPU 231 reads the image file GF from the memory card MC inserted in the slot 22 and stores it in the RAM 233 included in the print data generation circuit 23. The image file GF stores JPEG file format image data as image data GD. Image data in the JPEG file format is configured as compressed YCbCr data.

  In step S110, the CPU 231 performs color conversion processing after decompressing the compressed YCbCr data. By this color conversion process, YCbCr data is converted into RGB data. The reason for converting to RGB data is that RGB data is used in image processing in the personal computer PC or the color printer 20.

  In step S120, the CPU 231 performs an image quality adjustment process using the reference value on the RGB data. The image quality adjustment process using the reference value is a process for adjusting the image quality using a preferable standard parameter value (reference value) stored in the hard disk 232 in advance. Such image quality adjustment processing is image processing generally called automatic image quality adjustment processing. The parameter adjusted by the automatic image quality adjustment processing includes brightness. Details of the automatic brightness image quality adjustment processing will be described later.

  In step S130, the CPU 231 performs color conversion processing on the image data (RGB data) that has been subjected to the automatic image quality adjustment processing, and converts the image data into CMYK data. The CMYK color space is a color space that can be expressed by four color inks of cyan (C), magenta (M), yellow (Y), and black (K) that can be used by the color printer 20. This color conversion process is performed using a lookup table in which the RGB color system and the CMYK color system are associated with each other. This lookup table is stored in the hard disk 232.

  In step S140, the CPU 231 performs print output processing using image data (CMYK data). In the print output process, the CPU 231 performs halftone processing to generate print data including dot data representing the formation state of each color ink dot, and transmits the print data to the color printer 20. As a result, this processing routine ends.

  FIG. 7 is a flowchart showing a processing routine of automatic image quality adjustment processing in the present embodiment. In step S200, the CPU 231 reads the shooting information PI (FIG. 5) stored in the Exif IFD of the image file GF. The shooting information PI includes information indicating which of the split photometry method and the spot photometry method is selected at the time of shooting (FIG. 5B).

  In step S210, the CPU 231 determines whether or not the photometry method at the time of photographing was the spot photometry method based on this information. As a result, when the metering method is not spot metering, the process proceeds to step S220, and automatic adjustment processing including automatic brightness adjustment is performed. On the other hand, if the metering method is spot metering, the process proceeds to step S230, and automatic adjustment processing that does not include automatic brightness adjustment is performed.

  In step S220, the CPU 231 performs automatic image quality adjustment processing including automatic brightness adjustment. Automatic brightness adjustment is an adjustment that darkens the brightness of an image reproduced on a print medium that is automatically performed when the exposure during shooting is inappropriate, for example, when the image of the image data GD is too bright. Say.

  FIG. 8 is an explanatory diagram showing the contents of automatic brightness adjustment processing in the present embodiment. FIG. 8A shows an example of a tone curve for correcting underexposure, and FIG. 8B shows an example of a tone curve for correcting overexposure. The input level indicates the value of the image data before automatic brightness correction, and the output level indicates the value of the image data after automatic brightness correction.

  The automatic brightness adjustment process adjusts the brightness of the printed image by changing the shape of the tone curve. This adjustment is performed so that the printed image can be reproduced on the print medium so that the reflectance of the entire image approaches the reflectance of a standard reflecting plate (for example, a plate having a reflectance of 18%). For example, in the case of underexposure as shown in FIG. 8A, the reflectance is smaller than that of the standard reflector, so that the shape of the tone curve is on the upper side so that the output level is higher than the input level. To be convex. Such a change in tone curve brings the reflectance of the entire printed image closer to that of the standard reflector.

  However, there is a problem with automatic brightness adjustment. For example, there are cases where you want to adjust the exposure only to the target point on the screen, such as when the subject is exposed to a pin spot light in stage shooting. If there is such an intention to shoot, image data according to the photographic intention is generated if the image is taken by a spot metering method in which exposure is determined by metering only a specific area of several% of the entire screen. However, if the brightness is automatically adjusted with the automatic brightness adjustment based on the entire image, the image data is corrected to be contrary to such shooting intention.

  However, in this embodiment, as described above, it is determined whether or not the photometry method at the time of photographing is the spot photometry method. If the photometry is spot photometry, the automatic image quality adjustment process that does not include the automatic brightness adjustment (step S230). ) Is performed so that the processing routine is performed. For this reason, the problem that the brightness is automatically adjusted against the intention at the time of shooting does not occur.

  As described above, according to the present embodiment, the automatic brightness adjustment is not performed when the spot photometry method is used in accordance with the shooting information PI. It is possible to prevent automatic adjustment of the brightness of the printed image against the intention of photographing to match the exposure.

  The CPU 231 functions as an “image quality automatic adjustment unit and adjustment amount determination unit” in the claims. The photographing information PI is information included in the “image processing control information” in the claims.

D. Variations:
The present invention is not limited to the above-described examples and embodiments, and can be implemented in various modes without departing from the gist thereof. For example, the following modifications are possible.

D-1. In the above-described embodiment, the photometry methods available for the digital still camera 12 include divided photometry and spot photometry, and automatic brightness adjustment is not performed when shooting is performed using the spot photometry method. However, for example, automatic adjustment may be prohibited even when the multi-spot photometry method or the partial photometry method is selected at the time of shooting in another digital still camera.

  Furthermore, the automatic adjustment is not necessarily prohibited, and the adjustment amount of the automatic adjustment may be reduced. The reduction of the adjustment amount may be realized, for example, by generating a tone curve with a reduced adjustment amount and using the generated tone curve.

  The generation of the tone curve with the reduced amount of adjustment may be performed, for example, by superimposing the two tone curves for automatic adjustment (FIG. 8) with appropriate weighting, or alternatively, It may be performed by superimposing one of the tone curves (FIG. 8) with an appropriate weight on a linear tone curve.

  In general, the present invention only needs to be configured so as to reduce the adjustment amount of the automatic adjustment when the image is taken by a specific photometry method in which only a specific visual field area corresponding to a part of the printed image is measured.

  It is preferable that the photometric methods that can be recognized by the image processing apparatus based on the information of the image file include average photometry, center-weighted photometry, spot photometry, multi-spot photometry, split photometry, and partial photometry. . By doing so, there is an advantage that the present invention can be applied to image processing of an image file that conforms to the specifications of Exif Ver. 2.2 and later, which are configured assuming these photometry methods.

D-2. In the embodiment described above, the automatic adjustment processing routine is selected from one of an adjustment processing routine including automatic brightness adjustment and an adjustment processing routine not including automatic brightness adjustment in accordance with the photographing information PI. However, the automatic brightness adjustment process is performed only when the mode that calculates the appropriate exposure according to the overall brightness of the image area, such as the average metering method or the split metering method, is selected at the time of shooting. May be. Generally, in the present invention, it is only necessary that the brightness of the printed image is not automatically adjusted when the partial photometry method is selected at the time of shooting.

D-3. In the above embodiment, whether or not to automatically adjust the brightness is uniformly determined according to the shooting information PI. However, for example, when the center-weighted metering method is selected, the brightness is automatically adjusted. You may make it confirm the selection of whether to do with a user. Here, center-weighted metering is used when there is an intention to shoot with a focus on the exposure value in the center of the viewfinder when there is a main subject in the center of the screen as in portrait photography. This is a photometric method. For example, a photometric method is used in which photometry is performed with an emphasis of about 60% in a circle that occupies an area of about 10% in the center of the viewfinder.

  The center-weighted metering method is close to partial metering when the importance level is high, and is close to split metering when the priority level is small, so the user can select whether to perform automatic adjustment. Providing a user interface (FIG. 9) that allows the image processing has an advantage that it is possible to realize image processing more suited to the user's intention. It is preferable that the user interface further includes an option that enables printing of both an image with automatic brightness adjustment and an image with no brightness adjustment.

D-4. In the above embodiment, automatic adjustment of the brightness of the printed image is prohibited when the partial photometry method is selected at the time of shooting. For example, a command for prohibiting automatic adjustment of the brightness after shooting is manually input. Accordingly, it may be determined whether or not automatic brightness adjustment is permitted. In general, the present invention only needs to be configured to determine whether or not to automatically adjust brightness according to image processing control information. Thereby, it is possible to flexibly prevent the automatic adjustment of the brightness of the printed image against the intention of photographing.

D-5. In the above-described embodiment, it is configured to determine whether or not to automatically adjust the brightness according to the image processing control information. However, according to the image processing control information, the strength of the automatic brightness adjustment is selected. You may comprise. Specifically, the brightness of image data can be automatically adjusted in one of multiple adjustment modes, including a strong adjustment mode that adjusts relatively strongly and a weak adjustment mode that adjusts relatively weakly. Depending on the information, any one of these adjustment modes may be selected.

D-6. In the above embodiment, the personal computer functions as the image processing apparatus. However, for example, a color printer may have the function of the image processing apparatus. The present invention can be applied not only to color printing but also to monochrome printing.

D-7. In the above embodiment, an inkjet color printer is used as the output device. However, the present invention can be applied to a case where a monitor or other device such as a CRT display or LCD display that can display an image is used as the output device. Thus, the present invention can be applied not only to printed images but also to general images.

D-8. In the above embodiment, only the brightness is automatically adjusted. However, for example, a contrast may be adjusted using a tone curve as shown in FIG. Also in this case, it may be configured to select the level of automatic adjustment of brightness and contrast according to the image processing control information. Specifically, the brightness of the image data can be automatically adjusted in any of a plurality of adjustment modes in which at least one of the brightness adjustment amount and the contrast adjustment amount is different, and these adjustments are performed according to the image processing control information. Any one of the modes may be selected.

  When some or all of the functions of the present invention are realized by software, the software (computer program) can be provided in a form stored in a computer-readable recording medium. In the present invention, the “computer-readable recording medium” is not limited to a portable recording medium such as a flexible disk or a CD-ROM, but an internal storage device in a computer such as various RAMs and ROMs, a hard disk, and the like. An external storage device fixed to the computer is also included.

1 is an explanatory diagram showing an image processing system as one embodiment of the present invention. The block diagram which shows the outline of a structure of the digital still camera as an input device which produces | generates image data. FIG. 2 is a block diagram showing an outline of the configuration of a computer PC and a color printer as output devices that output image data. Explanatory drawing which shows schematically the structure of the image file GF in the Example of this invention. Explanatory drawing which shows an example of the attached information stored in Exif IFD of the image file GF. The flowchart which shows the process routine of the image process in computer PC. 6 is a flowchart showing a processing routine of automatic image quality adjustment processing in the present embodiment. Explanatory drawing which shows the content of the automatic brightness adjustment process in a present Example. Explanatory drawing which shows the user interface which permits the selection of whether to perform automatic adjustment to a user. Explanatory drawing which shows the content of the automatic adjustment process of the brightness and contrast in a modification.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Image processing system 12 ... Digital still camera 20 ... Color printer 22 ... Slot 23 ... Print data generation circuit 110 ... Image data storage area 121 ... Optical circuit 122 .. Image acquisition circuit 123 ... Image processing circuit 124 ... Control circuit 126 ... Decision button 127 ... Liquid crystal display 231 ... CPU
232 ... Hard disk 233 ... RAM

Claims (6)

An output device that outputs the image using image data representing an image and shooting information that is associated with the image data and is set when the image data is generated,
The shooting information includes photometry method information related to the photometry method,
When the photometry method information is first photometry method information for photometry of a partial area of the image, a first image quality adjustment not including brightness adjustment of the image is performed based on the shooting information . the photometric method information, if the second metering method information for metering the entirety of the image, based on the shooting information, a second image quality adjustment including brightness adjustment of the image quality adjustment performed respectively And
An image output unit for outputting an image whose image quality has been adjusted by the image quality adjustment unit;
Equipped with a,
The image quality adjustment unit may perform the first image quality adjustment or the second image measurement when the photometry method information is center-weighted photometry in which the center of the image is weighted higher than the periphery. An output device that provides a user interface that allows a user to select which of the image quality adjustments is to be performed, and that performs any of the first and second image quality adjustments based on the user's selection . The output device according to claim 1,
The metering method information is information representing any one of a plurality of metering methods including the center-weighted metering, average metering, spot metering , multi-spot metering, split metering, and partial metering,
The first photometry method information is information representing any one of spot photometry, multi-spot photometry, and partial photometry,
The second metering mode information is output and wherein the averaging metering is information indicating any of the multi-segment metering. The output device according to claim 1 or 2 ,
The output device is a printer that prints the image. The output device according to any one of claims 1 to 3 ,
The output device is a display device that displays the image. An output method for outputting the image using image data representing an image and photographing information set at the time of generating the image data associated with the image data,
The shooting information includes photometry method information related to the photometry method,
When the photometry method information is first photometry method information for photometry of a partial area of the image, a first image quality adjustment not including brightness adjustment of the image is performed based on the shooting information . the photometric method information, if the second metering method information for metering the entirety of the image, based on the shooting information, a second image quality adjustment including brightness adjustment of the image quality adjustment performed respectively Process,
An image output step of outputting an image whose image quality has been adjusted by the image quality adjustment step;
Including
In the image quality adjustment step, when the photometry method information is center-weighted photometry in which the central portion of the image is subjected to photometry with higher weighting than the peripheral portion, the first image quality adjustment or the second image quality adjustment is performed. An output method characterized by providing a user interface that allows a user to select which of the image quality adjustments to perform, and performing either of the first or second image quality adjustment based on the user's selection . A program for outputting the image using image data representing an image and shooting information associated with the image data and set when the image data is generated,
The shooting information includes photometry method information related to the photometry method,
On the computer,
When the photometry method information is first photometry method information for photometry of a partial area of the image, a first image quality adjustment not including brightness adjustment of the image is performed based on the shooting information . the photometric method information, if the second metering method information for metering the entirety of the image, based on the shooting information, a second image quality adjustment including brightness adjustment of the image quality adjustment performed respectively Function and
An image output function for outputting an image whose image quality has been adjusted by the image quality adjustment function;
Is a program for realizing
In the image quality adjustment function, when the photometry method information is center-weighted photometry in which the center portion of the image is weighted with a higher weight than the peripheral portion, the first image quality adjustment or the first image quality adjustment function is performed. A user interface that allows a user to select which of the two image quality adjustments is to be performed, and a function that causes the computer to perform one of the first and second image quality adjustments based on the user's selection Program .

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