JP4804866B2 - Digital camera, program, recording medium, and image analyzer - Google Patents

Description

The present invention relates to a digital camera and a control method thereof .

  In recent years, it has become widespread to acquire digital image data from devices such as digital cameras and scanners, and further process and use the image data. For example, in the camera customization software described in Patent Document 1, shooting parameters corresponding to various shooting situations are set in advance, and by selecting and inputting a shooting situation desired by the user, shooting according to the shooting situation is performed. It is possible to set parameters.

In the image processing method described in Patent Document 2, gradation correction processing, color correction processing, and the like are performed on image data acquired by a digital camera. Initial processing defaults are used as processing conditions for performing these processings. It is possible to set processing conditions and processing conditions for each type of digital camera, and the user can customize these processing conditions according to his / her own shooting technology so that the user's preferences can be reflected in the image. ing.
JP 2001-24938 A JP 2002-16874 A

  However, in the case of the above-mentioned patent document 1, since the shooting parameters cannot be changed unless a user's desired one is included in a plurality of preset shooting situations, a user-preferred image is displayed. It may not be obtained. Further, in the method described in Patent Document 2, it is necessary to manually input a complicated change in shooting process condition, and it takes time and effort until the user's ideal shooting process condition is reached. It will be. In particular, the preference of the photographed image is very different, and the more the user's tendency and preference are pursued, the more choices become.

The present invention has been made in view of the above circumstances, and an object thereof is to provide a digital camera capable of easily changing shooting parameters in accordance with the tendency and preference of an image taken by a user, and a control method thereof.

In order to solve the above problems, a digital camera of the present invention includes a photographing optical system, an image sensor that photoelectrically converts subject light incident from the photographing optical system and outputs an image signal, and an image output from the image sensor. Signal processing means for processing image signals to generate image data; and imaging parameter storage means for storing imaging parameters relating to control of the imaging optical system, the imaging element, and the signal processing means; An imaging parameter storage unit that can be rewritten to the latest imaging parameter every time a parameter is generated, and an initial value stored in the imaging parameter storage unit or a control that reflects the latest imaging parameter is performed to perform the imaging optical Image data is stored in the data storage means, and control means for performing photographing by the system, the image sensor, and the signal processing means. An image data storage control means for deleting the image data, a selection input means for selecting enter either the storage or deletion the image data, based on a selection result by the selection input means, generated by the signal processing means Image analysis determination means for analyzing the captured image data to determine the tendency and preference of the captured image, and parameter generation for generating the latest shooting parameters in accordance with the tendency and preference determined by the image analysis determination means And a parameter changing unit for changing the shooting parameter stored in the shooting parameter storage unit to the latest shooting parameter generated by the parameter generation unit.

3. The digital camera control method according to claim 2 , wherein an imaging signal output step for photoelectrically converting subject light incident from the imaging optical system and outputting an imaging signal, and an image for generating image data by performing signal processing on the imaging signal. A data generation step, a shooting parameter storage step in which shooting parameters relating to the output of the imaging signal and control for generating the image data are stored in the shooting parameter storage means, and reflect the initial value or the latest shooting parameter One of a shooting control step for performing shooting by performing the above-described control, an image data storage control step for storing image data in the data storage means or deleting the image data, and storage or deletion of the image data. a selection input selecting input, based on a selection result of the above selection input step, the image An image analysis determination step that analyzes the image data generated in the data generation step to determine the tendency and preference of the captured image, and the latest shooting parameters according to the trend and preference determined in the image analysis determination step And a parameter changing step for changing the shooting parameter stored in the shooting parameter storage means to the latest shooting parameter generated in the parameter generation step.

According to the digital camera and the digital camera control method of the present invention, based on the selection result of selecting and inputting either storage or deletion of the image data for changing the shooting parameter, the image data is Analysis to determine the tendency and preference of the captured image, generate the latest shooting parameters according to the determined tendency and preference, and change the shooting parameters stored in the shooting parameter storage means to the latest shooting parameters. Since the shooting is performed by performing control reflecting the initial value or the latest shooting parameter, the shooting parameter can be easily changed according to the tendency and preference of the image to be shot by the user.

  A digital camera 10 shown in FIGS. 1 and 2 is provided with a photographing lens 12 and a strobe light emitting unit 13 on the front surface of a substantially rectangular parallelepiped camera body 11. In addition, an LCD 15 serving as a display unit for displaying an image is provided on the rear surface of the camera body 11. Further, a touch panel (see FIG. 3) 58 is provided on the surface of the LCD 15 as will be described later. A shutter button 16 and a power button 17 are provided on the upper surface of the camera body 11. Further, a slot 18 in which a memory card for storing image data is detachably loaded is provided on the right side surface of the camera body 11.

  The digital camera 10 has a moving image shooting mode, a still image shooting mode, and a playback mode. Furthermore, under the still image shooting mode, a manual shooting mode and an auto shooting mode can be selected. The digital camera 10 does not include an operation button in addition to the shutter button 16 and the power button 17. Instead, a plurality of operation icons and the like are displayed on the LCD 15, and these operation icons are operated by touching the touch panel 58 with a user's finger or an attached operation pen (not shown).

  Next, the electrical configuration of the digital camera 10 will be described. As shown in FIG. 3, the digital camera 10 includes a system controller 25 that is a control unit that controls the entire camera, and a ROM 25a and a RAM 25b that are storage units are provided in the system controller 25. . The ROM 25a stores a control program and various control data. The RAM 25b temporarily stores work data and stores shooting parameters described later. The system controller 25 controls each unit based on a control program, various control data, and imaging parameters. Note that, when the digital camera 10 is shipped from the factory, the initial value set in advance is stored in the RAM 25b. However, every time a new shooting parameter is generated by the shooting parameter growth circuit 60 described later, the latest shooting parameter is stored. It is rewritten to shooting parameters.

  Behind the photographic lens 12, a CCD image sensor 32, which is an imaging means for imaging subject light that has passed through the photographic lens 12, is disposed. The photographing lens 12 includes a fixed lens 26, a zoom lens 27, and a focus lens 28. The zoom lens and the focus lens 28 are moved by driving a zoom lens drive motor 31 and a focus lens drive motor 32, respectively. A diaphragm mechanism 33 is arranged in front of the CCD 21. The aperture mechanism 33 switches the F value (aperture value) by driving the aperture drive motor 34.

  The zoom drive motor 31, the focus drive motor 32, and the aperture drive motor 34 are connected to drivers 39, 40, and 41, respectively, and the drive is controlled by the system controller 25 through these drivers 39 to 41.

  A CCD driver 43 is connected to the CCD image sensor 32. The CCD driver 43 inputs a vertical drive signal and a horizontal drive signal to the CCD image sensor 31 according to the clock pulse input from the timing generator 44 and drives the CCD image sensor 31. The timing generator 44 is connected to the system controller 25. The system controller 25 controls the timing generator 44 to control the drive of the CCD image sensor 32 by generating clock pulses.

  Further, a correlated double sampling circuit (CDS) 45 and an amplifier (AMP) 46 are connected to the CCD image sensor 32. Thus, noise removal and amplification are performed on the imaging signal output from the CCD image sensor 31.

  Thereafter, the noise-removed and amplified imaging signal is converted from an analog signal to a digital signal by the A / D converter 47 and output to the image input controller 48 as image data.

  The image input controller 48 is connected to the system controller 25 via the data bus 49 and is controlled by the system controller 25. A buffer memory 50 and a video memory 51 are connected to the image input controller 48 via a data bus 49. The system controller 25 controls the image input controller 48 to store the image data in the buffer memory 50 or the video memory 51.

  An image signal processing circuit 52 is connected to the system controller 25 via a data bus 49. While the captured high-resolution image data is temporarily stored in the buffer memory 50, the image data Various image processing such as gradation conversion, white balance correction, γ correction, and YC conversion processing are performed.

  The video memory 51 temporarily stores low-resolution image data when an image is displayed on the LCD 15, and simple image processing and simple YC conversion processing are performed by the image signal processing circuit 52. . The image data stored in the video memory 51 is transmitted to the LCD driver 53 via the data bus 49. The LCD driver 53 performs signal processing on the image data so that an image can be displayed on the LCD 15, and displays the image on the LCD 15.

  Further, a compression / decompression processing circuit 54 and a media controller 55 are connected to the system controller 25 via a data bus 49. The compression / decompression processing circuit 54 performs compression processing on the image data stored in the buffer memory 50 in a compression format such as the JPEG method. Further, the system controller 25 controls the media controller 55 to store the compressed image data in the memory card 56. The compression / decompression processing circuit 54 performs decompression processing on the compressed image data when reproducing the image data stored in the memory card 56.

  Furthermore, a strobe device 57 and a touch panel 58 are connected to the system controller 25 via a data bus 49. The system controller 25 controls the strobe device 57 to emit strobe light from the strobe light emitting unit 13 toward the subject.

  Further, the touch panel 58 is provided on the display surface of the LCD 15 as described above. The touch panel 58 detects the contact position when touched by the user. As this touch panel 58, an analog capacitive coupling system, a 5-wire analog resistive film system, an ultrasonic surface acoustic wave system, a 4-wire analog resistive film system, etc. can be used. It is preferable to use an ultrasonic surface acoustic wave type touch panel capable of displaying an image.

  The touch panel 58 detects a contact position and outputs contact position information to the system controller 25. When the touch panel 58 is touched by the user while a plurality of operation icons are displayed on the LCD 15, the system controller 25 acquires contact position information from the touch panel 58, and any operation icon is obtained based on the contact position information. It is determined whether is selected. The system controller 25 executes processing corresponding to this operation icon.

  Further, the shutter button 16 and the power button 17 are connected to the system controller 25, and when an operation signal is acquired from these, processing corresponding to each operation signal is executed.

  Further, a photographing parameter growth circuit 60 is connected to the system controller 25 via a data bus 49. As shown in detail in FIG. 4, the shooting parameter growth circuit 60 includes a shooting image pattern analysis unit 61, a user tendency / preference determination unit (image analysis determination unit) 62, a shooting parameter generation unit (parameter generation unit) 63, and a user. A profile generation unit (user profile generation means) 64 is provided.

  The captured image pattern analysis unit 61 analyzes the image data read from the buffer memory 50 and analyzes the pattern of the captured image. Based on the analyzed captured image pattern, the user tendency / preference determination unit 62 determines the tendency and preference of the user for shooting.

The user's shooting tendency and preference determined by the user tendency / preference determination unit 62 are sent to the shooting parameter generation unit 63 and the user profile generation unit 64. The shooting parameter generation unit 63 determines the shooting tendency and preference of the user, generates and changes shooting parameters based on the shooting tendency and preference, and thereafter performs shooting based on the shooting parameters. The user profile generation unit 64 generates the shooting parameter generated by the shooting parameter generation unit 63 as a user profile, and the generated user profile is written to the memory card 56 via the media controller 55.

  In the user tendency / preference determination unit 62 described above, as the user's shooting tendency / preference, as shown in FIG. 5A, the ratio of light / dark (under / over / low key / high key), exposure correction, contrast, focus, Determinations are made regarding depth of field, color temperature, roughness, color, gradation, sharpness, and backlight. In addition, under in the ratio of light and dark refers to a photographed image in a dark state due to underexposure or such a state, and conversely, over refers to a photographed image in an overexposed and whitish state or such a state. Low key refers to a captured image that is dark overall and has low brightness. Note that what is darkened up to the highlight portion is simply an underexposed (under) photographed image, not low key. Furthermore, the high key is a photographed image in which the bright portion occupies the majority, and indicates the overall bright tone. A photo that has become brighter to the dark part is a photo with no contrast (over) and is different from the high key. Or contrast refers to the difference between highlight (the brightest part) and shadow (the darkest part). The small difference between highlight and shadow is called “low contrast”, and the screen is not sharp. The hue refers to the balance and ratio of RGB three values representing color information.

  Furthermore, the user's shooting tendency / preference (see FIG. 5A) determined by the user tendency / preference determination unit 62 and the shooting parameters generated by the shooting parameter generation unit 63 described above (see FIG. 5B). The relationship is as follows. In other words, the aperture, shutter speed, ISO sensitivity, and exposure correction value parameters are determined from the ratio of brightness and darkness. Similarly, the gamma correction value from the contrast, the focus accuracy from the focus position, and the aperture depth from the depth of field. Taken from the focal length and color temperature, white balance, ISO sensitivity from roughness, hue from hue, gamma correction from gradation, aperture from sharpness, and exposure correction from backlight. Determine the parameters.

  In the present embodiment, the shooting parameter setting is rewritten while the image capturing by the digital camera 10 is executed and the image data is repeatedly stored or erased. From the shooting execution to the rewriting of the shooting parameter. The sequence will be described with reference to the flowchart shown in FIG.

  When the user first performs photographing with the digital camera 10, the system controller 25 controls each part based on the photographing parameters of initial values, that is, drivers 39 to 41 for driving the photographing lens 12 and the CCD image sensor 32, and a CCD driver. 43, and further controls a correlated double sampling circuit (CDS) 45, an amplifier (AMP) 46, an image input controller 48, and an image signal processing circuit 52 that process an image pickup signal. Then, shooting is performed with the default shooting parameters, and image data obtained by the shooting is selected to be saved or deleted by operating the touch panel 58 or the like, and saved in the memory card 56 based on this selection. Or deletion is executed. When this selection operation is performed, the above-described shooting parameter growth circuit 60 operates to determine the shooting tendency and preference of the user, to generate shooting parameters, and to generate a user profile.

  When saving of image data is selected, the user's shooting tendency and preference are acquired from the image data. On the other hand, when the image data is deleted, this image is opposite to the shooting tendency of the user, it is determined that the captured image is not preferred by the user, and the shooting tendency determined from the deleted image data is determined. In addition, the opposite result to the preference is determined as the user-preferred shooting tendency and preference. Then, based on the user's shooting tendency and preference, the shooting parameter generating unit 63 determines a new shooting parameter suitable for the shooting expression desired by the user. As for the shooting tendency and preference of the user, for example, all data may be accumulated from the time of shipment from the factory, and an average value thereof may be taken and reflected in the shooting parameters. The determination may be made using only those analyzed from the image data. When the shooting parameters are determined, the ROM 25b rewrites them with the latest shooting parameters. A user profile is created based on the shooting parameters and written to the memory card 56. These pieces of information are encrypted and protected so that the data can be modified or initialized only when the user is authenticated by a personal authentication system such as a fingerprint authentication device.

  As described above, the user's shooting tendency and preference are determined from the image data every time shooting is performed, and shooting parameters are automatically rewritten based on these shooting trends and preferences. Therefore, the more the digital camera 2 is used, the more the image can be taken with an image expression that matches the user's shooting tendency and preference.

  In the first embodiment, the determination of the photographing tendency and the preference is performed when the image data is stored or deleted. However, the present invention is not limited to this. For example, a sequence as shown in FIG. The execution of shooting, determination of shooting tendency and preference, rewriting of shooting parameters, and the like may be performed. In the example shown in FIG. 7, shooting is performed after selecting one of the following three modes in the setting mode, that is, a complete manual shooting mode, a semi-auto shooting mode, and a full auto shooting mode. Will be.

  Then, after shooting, in the case of the complete manual mode, the user manually adjusts all shooting parameters (operation by the touch panel 58 or the like) while referring to the shot image to generate new shooting parameters. In the semi-automatic shooting mode, the user selects a desired shooting situation setting and sets shooting parameters according to the shooting situation. Furthermore, in the case of the fully automatic shooting mode, as in the above embodiment, the shooting tendency and preference of the user are determined for all the image data, and the shooting parameters are determined based on the determination of the shooting tendency and preference. Is generated. The shooting parameters determined according to the mode selected in this way are rewritten, and thereafter, shooting is performed based on the latest shooting parameters.

  Further, in the above embodiment, the shooting tendency and the preference are determined based on the result of the selection input of saving or deleting the image data. However, the present invention is not limited to this, and more options are set. It is also possible to select from among them. For example, one of four options for the obtained image data is “very good”, “good”, “dissatisfied”, “failed”, etc. To select. Then, the selection of the photographing tendency and the preference may be performed by reflecting this selection input.

  Furthermore, the user's selection input is not limited to the above, but for example, when there are general choices about the reason why the image data is well taken and the reason why the image is taken badly, and it matches it, Selection input may be performed, and the result may be reflected in the determination of the shooting tendency and preference. And “reasons for taking pictures well” include, for example, “the balance between bright and dark places is good”, “shadows are black and tightened”, “highlights appear white and bright”, “contrast is just right ”,“ Overall focus ”,“ Focus only on what you want to shoot ”,“ Out of focus ”,“ Out of focus ”,“ Overall blur ”, Set options such as “I like the color”, “Just the darkness of the color”, “Just the sharpness”, “Good for blurring”, etc. "Too bright", "too dark", "shadows are crushed black", "highlights are crushed white", "contrast is too strong", "contrast is too weak", "overall focus "Not fit", "Back is blurred", " The front is out of focus, the whole image is in focus, the image is too blue, the image is too red, the image is too yellow, the color is too dark, the color is too light, or the color is clear Options such as “Too much”, “Color is dull”, “Too sharp”, “Not enough sharp”, “I got backlit”, “I didn't get backlit”, “I got blurred” Should be set. These options are options linked to individual shooting parameters, and the result of the selection input may be reflected in the change of the shooting parameters.

  In the above embodiment, the digital camera has been described as an example. However, the present invention may be applied to a digital video camera capable of taking a still image or a mobile phone with a camera.

  In the first embodiment, a digital camera is described as an example of a device that analyzes a user's shooting tendency and preference from image data and acquires shooting parameters from the shooting tendency and preference. The invention is not limited to this. In the second embodiment of the present invention described below, an example of an image analysis apparatus that inputs an image obtained by shooting, analyzes shooting tendency and preference from the input image data, and determines shooting parameters will be described. To do.

  In FIG. 8, an image analysis apparatus 80 to which the present embodiment is applied includes a system controller 83 that functions as a control unit 82 by executing an image analysis program PG 1 stored in a ROM 81. The image analysis apparatus 80 is composed of an electronic computer such as a personal computer. To the system controller 83, an image data reading unit 84, an image display unit 85, and an operation panel 86 are connected. The image data reading unit 84 includes a connector for reading image data from a memory card and a disk drive for reading image data from an optical disk such as a CD. The image display unit 85 includes a liquid crystal display, and displays a captured image read as image data, a corrected image created by correcting the captured image, and the like. The operation panel 86 detects a user input operation necessary when creating a corrected image, and sends an operation signal to the system controller 83.

  The ROM 81 stores an image analysis program PG1, template data TD1 used for album creation, and the like. The RAM 87 stores image data PD1 read from the image data reading unit 84, user profile data YD1 created by the system controller 83, and the like. The system controller 83 executes the image analysis program PG1, and functions as a captured image pattern analysis unit 91, a user tendency / preference determination unit 92, a capture parameter generation unit 93, and a user profile generation unit 94.

  As in the first embodiment, the captured image pattern analysis unit 91, the user tendency / preference determination unit 92, the shooting parameter generation unit 93, and the user profile generation unit 94 determine the user's shooting tendency and preference from the image data, A user profile based on the shooting tendency and preference is created. The created user profile data YD 1 is temporarily stored in the RAM 87 and stored in the recording medium via the image data reading unit 84.

  A process from reading of image data to creation of a user profile by the image analysis apparatus 80 having the above configuration will be described with reference to a flowchart shown in FIG. First, in the image analysis device 80, the image data reading unit 84 first reads image data photographed by a digital camera or the like via a storage medium such as a memory card or an optical disk. The read image data is displayed on the image display unit 85, and the user confirms this, and either “an image to be saved” or “an image to be deleted”, or “an image that is well taken” and “an image that is poorly taken” are displayed. A selection such as “Any image” is input through the operation panel 86. Then, from the image data selected as “image to be saved” or “image taken well”, the image data selected as “image to be deleted” or “image taken poorly” from the shooting tendency and preference of the user From this, the tendency etc. that are not the user's preference are determined.

  Alternatively, when “good image” or “bad image” is selected, as in the first embodiment, there are general options for why the image is well taken and why the image is badly taken. Prepare a selection input. It should be noted that the display of such options may be made so that the user can instruct validity or invalidity by setting on the program. Or when it is determined that it is difficult to automatically analyze the program. A general selection may be prepared and a selection input may be performed.

  In this way, the image analysis device 80 analyzes the user's shooting tendency and preference, generates a user profile and shooting parameters based on the tendency, and writes them to the recording medium. In this way, the image analysis device 80 determines the user's shooting tendency and preference from the image data, and the shooting parameters are automatically rewritten based on these shooting trends and preferences. If reflected and used, the same effect as in the first embodiment can be obtained.

It is a perspective view which shows the structure of the front side of a digital camera. It is a perspective view which shows the structure of the back side of a digital camera. It is a block diagram which shows the electric constitution of a digital camera. It is a block diagram which shows the structure of an imaging parameter growth circuit. It is explanatory drawing which shows the relationship of a user's imaging | photography tendency and preference, and an imaging | photography parameter. It is a flowchart which shows the sequence until it produces | generates and rewrites a photography parameter by photography execution. It is a flowchart which shows a different sequence from the example shown in FIG. It is a block diagram which shows the electric constitution of an image analyzer. It is a flowchart which shows the sequence which reads image data with an image analyzer, and produces | generates a photography parameter.

Explanation of symbols

10 Digital Camera 22 Shooting Lens 32 CCD Image Sensor (Image Sensor)
60 shooting parameter growth circuit 61, 91 shooting image pattern analysis unit 62, 92 user tendency / preference determination unit 63, 93 shooting parameter generation unit 64, 94 user profile generation unit

Claims (2)

An imaging optical system, an imaging element that photoelectrically converts subject light incident from the imaging optical system and outputs an imaging signal, and a signal processing unit that performs image processing on the imaging signal output from the imaging element to generate image data Shooting parameter storage means for storing shooting parameters relating to control of the shooting optical system, the image sensor, and the signal processing means, and can be rewritten to the latest shooting parameters each time the shooting parameters are generated Photographing parameter storage means, and control by reflecting the initial value or the latest photographing parameter stored in the photographing parameter storage means to perform photographing by the photographing optical system, the image sensor, and the signal processing means. and control means for causing the image data storage control means for deleting the stored or the image data of image data in the data storage means, said A selection input means for selecting input either save or of deletion of the image data, the imaging based on said by the selection result selection input means, performing an analysis on the image data generated by said signal processing means Image analysis determination means for determining the tendency and preference of the image, parameter generation means for generating the latest shooting parameters in accordance with the tendency and preference determined by the image analysis determination means, and the shooting stored in the shooting parameter storage means A digital camera comprising parameter changing means for changing a parameter to the latest photographing parameter generated by the parameter generating means. An imaging signal output step of photoelectrically converting subject light incident from the imaging optical system and outputting an imaging signal;
An image data generation step for generating image data by performing signal processing on the imaging signal;
An imaging parameter storage step in which imaging parameters relating to control when performing output of the imaging signal and generation of the image data are stored in an imaging parameter storage unit;
An imaging control step for performing imaging by performing control reflecting the initial value or the latest imaging parameter;
An image data storage control step for storing image data in the data storage means or deleting the image data;
A selection input step for selectively inputting one of storage or deletion of the image data ;
An image analysis determination step for analyzing the image data generated in the image data generation step based on the selection result performed in the selection input step and determining a tendency and preference of the captured image;
A parameter generation step for generating the latest imaging parameters in accordance with the tendency and preference determined in the image analysis determination step;
A digital camera control method comprising: a parameter changing step of changing the shooting parameter stored in the shooting parameter storage means to the latest shooting parameter generated in the parameter generation step.

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