JP2013157676A - Photographing support system, photographing support device, control method for photographing support device, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable an appropriate photographing parameter to be set for a photographing device even when photographing work is carried out while a photographing situation is changing.SOLUTION: A photographing support system for determining a photographing parameter to be used in a photographing device comprises: an image acquisition unit that acquires a photographed image photographed by the photographing device; an image processing unit that performs image processing on the photographed image; and a determination unit that determines the photographing parameter on the basis of the result of image processing by the image processing unit.

Description

  The present invention relates to a photographing support system, a photographing support device, a control method for the photographing support device, and a program, and relates to a photographing support system, a photographing support device, and a photographing support device that support a photographing task of photographing a photograph using the photographing device. The present invention relates to a control method and a program.

  In recent years, a photography support system has been introduced in which a photographer can display a photograph taken with a digital camera on a personal computer monitor and check the photograph on the spot at a studio in a photo studio that takes commemorative photos. Has been. In such a photographing system, in order to assist the photographer to determine the success or failure of photographing, the photographed image is captured and displayed, the face of the person in the photographed image is extracted, and the extracted face image is captured. Is displayed on the same screen. This makes it possible to check facial expressions and focus.

  Japanese Patent Application Laid-Open No. 2004-151620 discloses a technique for determining the focus and exposure of a captured image and warning the photographer.

  In Patent Document 2, shooting parameters scheduled to be used are registered in the system in advance, the shooting parameters are set from the system to the shooting device at the start of shooting, and further, the shooting parameters added to the shot image and the advance A technique is disclosed in which the set parameters are compared, a warning is given if the values are different, and the imaging parameters are reset from the system.

JP 2006-180404 A JP 2011-091512 A

  However, in Patent Document 1, since it is necessary to manually set shooting parameters to be used for the shooting apparatus, there is a problem that there is no guarantee that the shooting parameters to be used are set correctly.

  Further, in Patent Document 2, the imaging parameters that can be set for the imaging apparatus are only limited to parameters that are set in advance in the system. Therefore, in order to follow the illuminance and the like of the lighting that changes every day in the studio, it is necessary to reset the shooting parameters for the system. However, since only pre-set shooting parameters can be set, it is not possible to change to appropriate shooting parameters during the shooting operation. Therefore, there is a possibility that even an image shot with preset shooting parameters may not be the best image, and there is a problem that image correction work may have to be performed.

  In view of the above problems, an object of the present invention is to make it possible to set appropriate shooting parameters for a shooting apparatus even when shooting work is performed while shooting conditions change.

The shooting support system according to the present invention that achieves the above-described object,
A shooting support system for determining shooting parameters used in a shooting device,
Image obtaining means for obtaining a photographed image photographed by the photographing device;
Image processing means for image processing the captured image;
Determining means for determining the imaging parameter based on an image processing result by the image processing means.

  According to the present invention, it is possible to set appropriate photographing parameters for the photographing apparatus even when photographing work is performed while the photographing situation changes.

1 is a diagram conceptually illustrating a photographing support system according to a first embodiment. FIG. 3 is a system block diagram in a case where each of the captured image confirmation apparatus, the imaging support apparatus, and the image processing apparatus according to the first embodiment is realized using a PC (personal computer). The figure which shows the module structure of the picked-up image confirmation apparatus which concerns on 1st Embodiment. The figure which shows the module structure of the imaging | photography assistance apparatus which concerns on 1st Embodiment. 1 is a diagram illustrating a module configuration of an image processing apparatus according to a first embodiment. The figure which shows an example of the user interface used for the captured image confirmation with the captured image confirmation apparatus which concerns on 1st Embodiment. FIG. 3 is a diagram showing an example of a user interface used when displaying an image information list in the image processing apparatus according to the first embodiment. FIG. 4 is a diagram illustrating an example of a user interface used when manual image correction is performed in the image processing apparatus according to the first embodiment. FIG. 6 is a diagram illustrating an example of an image processing flow table that manages settings of an image processing flow managed by the imaging support apparatus according to the first embodiment. 6 is a flowchart illustrating a procedure for performing a shooting support process in the shooting support system according to the first embodiment. 6 is a flowchart illustrating a procedure for performing shooting parameter determination processing in the shooting support system according to the first embodiment. 9 is a flowchart illustrating a procedure for performing shooting support processing in the shooting support system according to the second embodiment.

(First embodiment)
With reference to FIG. 1, a configuration example of a photographing support system according to the first embodiment will be described. The shooting support system includes a shooting device 100, a shot image confirmation device 101, a shooting support device 102, and an image processing device 103. Each device may be realized by a single computer device, or may be realized by distributing functions to a plurality of computer devices as necessary. When configured by a plurality of computer devices, they are connected by a local area network (LAN) or the like so that they can communicate with each other. Note that the transmission of information performed between the devices may be performed by relaying an arbitrary device, but may be performed directly between devices without relaying. Note that the system configuration in the present embodiment is merely an example, and may be a system configuration in which a single information processing apparatus executes processes and functions described later that are executed by several apparatuses. For example, the system may be configured such that a single information processing apparatus executes all of the processes and functions executed by the captured image confirmation apparatus 101, the imaging support apparatus 102, and the image processing apparatus 103.

  FIG. 2 is a block diagram when the captured image confirmation apparatus 101, the imaging support apparatus 102, and the image processing apparatus 103 are each configured by a computer such as a PC (personal computer). In addition to PCs (personal computers), each device is a home appliance such as a workstation, notebook PC, palmtop PC, television with built-in computer, game machine, telephone, FAX, mobile phone, PHS, electronic notebook , Etc., or a combination thereof.

  The computer includes a CPU 201, a RAM 202, a ROM 203, a NETIF 204, a VRAM 205, a display device 206, a controller 207, an external input device 208, an HDD 209, and an FDD 210. Yes.

  The CPU 201 is a central processing unit that controls the computer system. A RAM 202 is a random access memory, and functions as a main memory of the CPU 201 and also as a program execution area and a data area. A ROM 203 is a read-only memory that records operation processing procedures of the CPU 201. The ROM 203 includes a program ROM that records basic software (OS) that is a program for controlling the equipment of the computer, and a data ROM that stores information necessary for operating the computer. An HDD 209 described later may be used instead of the ROM 203.

  The NETIF 204 is a network interface, and performs control for transferring data between computer systems via the network and diagnoses connection status. A VRAM 205 is a video RAM, and develops an image displayed on a screen of a display device 206 (to be described later) indicating the operating state of the computer, and controls the image display.

  The display device 206 is a display, for example. The controller 207 controls an input signal from an external input device 208 described later. The external input device 208 is a keyboard, for example, and accepts an operation performed by a user on a computer. The HDD 209 is a storage device such as a hard disk, and is used for storing application programs and data such as image information. The application program in the present embodiment is a software program that executes shooting support. The FDD 210 is an external input / output device that inputs / outputs a removable disk such as a flexible disk drive or a CD-ROM drive, and is used for reading the above-described application program from the medium. Note that application programs and data stored in the HDD 209 can also be stored in the FDD 210 and used.

  Next, referring to FIGS. 3, 4, and 5, schematic configurations of the captured image confirmation apparatus 101, the imaging support apparatus 102, and the image processing apparatus 103 will be described.

  FIG. 3 is a schematic configuration of the captured image confirmation apparatus 101. The captured image confirmation apparatus 101 includes a user interface 300, an image display unit 301, a rating change unit 305, a shooting parameter change notification unit 306, a face area detection unit 307, an image processing request unit 308, and a shooting parameter transmission unit. 309, a captured image transfer unit 310, and a message transmission / reception unit 311.

  The image display unit 301 includes a captured image display unit 302, a face area display unit 303, and a thumbnail image display unit 304. The message transmission / reception unit 311 includes a message transmission unit 312 and a message reception unit 313.

  The user interface 300 accepts input from a user such as a photographer or notifies the user of information. The image display unit 301 displays a captured image, a face area image, and a thumbnail image through the user interface 300. More specifically, the captured image display unit 302 displays a captured image, the face region display unit 303 displays a face region image, and the thumbnail image display unit 304 displays a thumbnail image. The rating changing unit 305 changes the rating of the captured image. The imaging parameter change notification unit 306 notifies the user through the user interface 300 that the imaging parameter change has been notified from the imaging support apparatus 102 and the image processing apparatus 103. The face area detection unit 307 detects a face area from the captured image. The image processing request unit 308 receives an image correction request from the user through the user interface 300 and transmits the image correction request to the imaging support apparatus 102.

  The imaging parameter transmission unit 309 transmits imaging parameters to the imaging apparatus 100. The captured image transfer unit 310 transfers all the captured images to the imaging support apparatus 102. The message transmission / reception unit 311 transmits / receives messages to / from the imaging apparatus 100 and the imaging support apparatus 102. More specifically, the message transmission unit 312 transmits a message, and the message reception unit 313 receives the message.

  Note that the Internet protocol (IP) is used when sending and receiving messages. In this case, both IPv4 and IPv6 can be used as the IP version. In addition, a medium that is actually used as a communication path can be wired or wireless. Depending on the protocol, communication protocols such as TCP, UDP, HTTP, SMTP, SNMP, and FTP may be used.

  FIG. 4 is a schematic configuration of the photographing support apparatus 102. The imaging support apparatus 102 includes a captured image storage unit 400, a corrected image storage unit 401, a correction information storage unit 402, an image correction information analysis unit 403, a shooting parameter determination unit 404, a shooting parameter transmission unit 405, and an image. A processing request unit 406, an imaging parameter change notification unit 407, and a message transmission / reception unit 408 are provided. The message transmission / reception unit 408 includes a message transmission unit 409 and a message reception unit 410.

  The captured image storage unit 400 stores the captured image transmitted from the captured image confirmation apparatus 101. The corrected image storage unit 401 stores the corrected image transmitted from the image processing apparatus 103. The correction information storage unit 402 stores image correction information (automatic image correction information and manual image correction information) that is an automatic and manual image correction result as an image processing result performed by the image processing apparatus 103. An image correction information analysis unit 403 analyzes image correction information that is a result of automatic and manual image correction performed by the image processing apparatus 103.

  The shooting parameter determination unit 404 determines shooting parameters based on the analysis result of the image correction information analysis unit 403. The imaging parameter transmission unit 405 transmits the imaging parameters determined by the imaging parameter determination unit 404 to the captured image confirmation apparatus 101 (imaging parameter transmission process). The image processing request unit 406 manages the automatic image correction procedure, requests the image processing apparatus 103 to perform automatic image correction on the captured image transmitted from the captured image confirmation apparatus 101, and is transmitted from the captured image confirmation apparatus 101. A manual image correction process is requested to the image processing apparatus 103 based on the image processing request.

  The shooting parameter change notification unit 407 notifies the shot image confirmation apparatus 101 that the shooting parameter change is to be performed when the shooting parameter determination unit 404 determines that the shooting parameter needs to be changed. . A message transmission / reception unit 408 transmits / receives a message to / from the captured image confirmation apparatus 101 and the image processing apparatus 103. More specifically, the message transmission unit 409 transmits a message, and the message reception unit 410 receives the message.

  Note that the Internet protocol (IP) is used when sending and receiving messages. In this case, both IPv4 and IPv6 can be used as the IP version. In addition, a medium that is actually used as a communication path can be wired or wireless. Depending on the protocol, communication protocols such as TCP, UDP, HTTP, SMTP, SNMP, and FTP may be used.

  FIG. 5 is a schematic configuration of the image processing apparatus 103. The image processing apparatus 103 includes an automatic image correction unit 500, a user interface 504, an automatic image correction result display unit 505, a manual image processing request display unit 506, a manual image correction unit 507, and a message transmission / reception unit 508. The automatic image correction unit 500 includes an automatic image correction unit A501, an automatic image correction unit B502, and an automatic image unit correction C503. After image acquisition, the automatic image correction unit 500 manages each automatic image correction module and executes image correction. . Although only three automatic image correction modules are described in this embodiment, the number of automatic image correction modules can be added or deleted, and the number is not limited. The message transmission / reception unit 508 includes a message transmission unit 509 and a message reception unit 510.

  The automatic image correction unit 500 controls automatic image correction instructed from the photographing support apparatus 102 according to an image processing procedure. The user interface 504 receives input from the user and notifies the user of information. The automatic image correction result display unit 505 displays the result of automatic image correction performed by the automatic image correction unit 500. The image state is displayed on the manual image processing request display unit 506 and the user interface 504, and an image for which an image correction request has been received from the imaging support apparatus 102 is displayed. The manual image correction unit 507 executes manual image correction by the user. A message transmission / reception unit 508 transmits / receives a message to / from the imaging support apparatus 102. More specifically, the message transmission unit 509 transmits a message, and the message reception unit 510 receives the message.

  Note that the Internet protocol (IP) is used when sending and receiving messages. In this case, both IPv4 and IPv6 can be used as the IP version. In addition, a medium that is actually used as a communication path can be wired or wireless. Depending on the protocol, communication protocols such as TCP, UDP, HTTP, SMTP, SNMP, and FTP may be used. FIG. 6 shows an example of a user interface 300 used for confirming a photographed image by the photographed image confirmation apparatus 101, and is a user interface displayed at the time of photographing. The user interface 300 includes a camera list 600, a histogram 601, a shooting parameter list 602, a thumbnail image list 603, a captured image panel 604, a face area image panel 605, a rating change button 606, and an edit request button 607. And an edit cancel button 608.

  The above components are used for notifying a user such as a photographer of information of a captured image when a captured image is received from the image capturing apparatus 100. In parallel with the notification of information to a user such as a cameraman, a captured image is transmitted to the imaging support apparatus 102.

  When a captured image is received from the imaging apparatus 100, the camera list 600 displays a number unique to the imaging apparatus 100 that captured the captured image. The histogram 601 displays a histogram indicating information related to the captured image. The shooting parameter list 602 displays a list of shooting parameters for the shot image. The thumbnail image list 603 is displayed through the thumbnail image display unit 304 to display all captured images. The photographed image panel 604 displays the photographed image received from the photographing apparatus 100 through the photographed image display unit 302.

  The face area image panel 605 displays the face area image detected by the face area detection unit 307 from the image received from the photographing apparatus 100 through the face area display unit 303. The rating change button 606 is used by the user to set a rating for the captured image. When the rating change button 606 is pressed, the rating changing unit 305 changes the rating. The edit request button 607 is pressed when a user such as a cameraman determines that manual image correction is necessary. At this time, an image correction request is notified from the image processing request unit 308 to the imaging support apparatus 102. The edit cancel button 608 is used when canceling the image correction request issued by the edit request button 607.

  FIG. 7 is an example of a user interface 504 used when displaying an image information list in the image processing apparatus 103. The user interface 504 includes an image information list 700 and an image edit button 706. The image information list 700 includes a thumbnail image display column 701, an edit request column 702, a rate column 703, a file name column 704, And a shooting date / time column 705.

  The thumbnail image display column 701 displays the thumbnail image after automatic image correction by the automatic image correction result display unit 505. The edit request column 702 displays the presence / absence of an image correction request from the captured image confirmation apparatus 101. The rate column 703 displays the rating determined by the captured image confirmation apparatus 101. The file name column 704 displays the file name. The shooting date / time column 705 displays the shooting date / time.

  The user can perform image correction using an image correction application by selecting image information from the image information list 700 and pressing an image edit button 706.

  FIG. 8 is an example of a user interface 504 used when manual image correction is performed by the image processing apparatus 103. The user interface 504 includes an image display unit 800, a histogram 801, a correction parameter setting unit 802, and a thumbnail display unit 803.

  First, the automatic image correction result display unit 505 displays the automatic image correction result image implemented by the automatic image correction unit 500. The user performs manual image correction by operating and adjusting the correction parameter setting unit 802 while viewing the image after automatic image correction. The result of adjusting the correction parameter setting unit 802 is displayed on the image display unit 800. In the correction parameter setting unit 802 in FIG. 8, brightness, contrast, hue, saturation, and sharpness can be adjusted. However, this is an example, and at least one of these can be adjusted, or other items can be adjusted. A configuration capable of correction is also possible. A histogram for the image currently displayed on the image display unit 800 is displayed in the histogram 801. The thumbnail display unit 803 can store the progress of image correction results, and can compare several patterns of image correction results. When the user interface displayed in FIG. 8 is closed, the manual image correction is completed, image correction information that combines the automatic image correction and the manual image correction is created, and the image correction information and the corrected image are captured. 102.

  FIG. 9 is an example of an image processing flow table that manages the image processing request unit 406 of the imaging support apparatus 102. The image processing flow table includes an automatic image correction column 900, an execution presence / absence column 901, and a related imaging parameter column 902. Each item is registered in the automatic image correction column 900, and whether or not correction is performed is managed in the execution column 901. The presence or absence of this implementation may be changed as appropriate. Further, in the related shooting parameter column 902, shooting parameters of the shooting apparatus 100 related to the corresponding image correction are managed. The items and values in this image processing flow table are examples, and the present invention is not limited to these.

  With reference to the flowchart of FIG. 10, a processing procedure of the entire photographing support system according to the first embodiment will be described. In step S1000, the photographed image confirmation apparatus 101 starts photographing by a user operation.

  In step S <b> 1001, the shooting parameter transmission unit 309 of the shot image confirmation apparatus 101 transmits shooting parameters to the shooting apparatus 100. The shooting parameters transmitted at this time are at least one of shooting mode, Av value, Tv value, ISO sensitivity, exposure correction value, picture style, white balance, color temperature, and the like. The parameter to be transmitted is an example, and the present invention is not limited to this.

  In step S <b> 1002, the photographing apparatus 100 performs photographing by a user operation. An image photographed by the photographing apparatus 100 is transmitted to the photographed image confirmation apparatus 101.

  In step S <b> 1003, after the captured image confirmation apparatus 101 receives the captured image from the imaging apparatus 100, the captured image display unit 302 of the captured image confirmation apparatus 101 displays the captured image on the captured image panel 604. Further, the face area display unit 303 displays the face area image detected by the face area detection unit 307 on the face area image panel 605. The thumbnail image display unit 304 displays thumbnail images in the thumbnail image list 603. In addition, a histogram of the captured image is displayed in the histogram 601. Further, shooting parameters of the shot image are displayed in the shooting parameter list 602.

  In step S <b> 1004, the captured image confirmation apparatus 101 transmits the captured image to the imaging support apparatus 102. The imaging support apparatus 102 stores the captured image received from the captured image confirmation apparatus 101 in the captured image storage unit 400.

  In step S <b> 1005, the imaging support apparatus 102 requests the image processing apparatus 103 to perform image correction based on the image processing flow managed by the image processing request unit 406. The image processing apparatus 103 performs automatic image correction by the automatic image correction unit 500 according to the image processing flow notified from the imaging support apparatus 102. The image correction executed here corresponds to an item that is set to be implemented as shown in FIG.

  In step S1006, the automatic image correction result display unit 505 of the image processing apparatus 103 displays the automatic image correction result image in the thumbnail image display column 701.

  In step S1007, the image processing apparatus 103 determines whether there is an instruction from the user who has confirmed the automatic image correction result or the presence / absence of an image correction request notified from the captured image confirmation apparatus 101 via the imaging support apparatus. It is determined whether manual image correction is necessary.

  If it is determined that manual image correction is necessary (S1007; YES), the process proceeds to step S1008. On the other hand, when it is determined that manual image correction is not required (S1007; NO), the process proceeds to step S1012.

  In step S1008, the manual image correction unit 507 of the image processing apparatus 103 accepts manual image correction using a user interface as shown in FIG.

  In step S <b> 1009, the image processing apparatus 103 notifies the captured image confirmation apparatus 101 that there is a possibility that the imaging parameters may be changed due to the image correction. When the captured image confirmation apparatus 101 receives the notification, the imaging parameter change notification unit 306 of the captured image confirmation apparatus 101 notifies the user of a warning.

  In step S <b> 1010, the image processing apparatus 103 transmits image correction information, which is an image correction result executed by the automatic image correction unit 500 and the manual image correction unit 507, to the imaging support apparatus 102.

  In step S <b> 1011, the correction information storage unit 402 of the photographing support apparatus 102 stores the image correction information received from the image processing apparatus 103.

  In step S <b> 1012, the image processing apparatus 103 transmits the corrected image to the imaging support apparatus 102. The corrected image storage unit 401 of the photographing support apparatus 102 stores the corrected image received from the image processing apparatus 103. If it is determined in step S1007 that manual correction is unnecessary and the process proceeds to step 1012, the corrected image storage unit 401 stores an image on which only automatic image correction has been performed.

  In step S <b> 1013, the image correction information analysis unit 403 of the photographing support apparatus 102 performs the same manual correction for the specified number of times and determines whether the correction values at that time are substantially the same (within a specified amount of error). Whether or not). That is, it is determined whether or not manual image correction within a predetermined range has been performed a predetermined number of times or more on the captured image. If it is determined that the same manual correction has been executed with the substantially same correction value over the specified number of times (S1013; YES), the process proceeds to step S1014. On the other hand, if not (S1013; NO), the process proceeds to step S1017.

  In step S1014, the shooting parameter determination unit 404 of the shooting support apparatus 102 determines a new shooting parameter. Details of this new shooting parameter determination process will be described later with reference to FIG.

  In step S1015, the shooting parameter change notification unit 407 of the shooting support apparatus 102 notifies the shot image confirmation apparatus 101 that the shooting parameters are changed. When receiving the notification from the imaging support apparatus 102, the imaging parameter change notification unit 306 of the captured image confirmation apparatus 101 warns the user that the imaging parameter is changed.

  In step S1016, the shooting parameter transmission unit 405 of the shooting support apparatus 102 transmits a new shooting parameter to the shot image confirmation apparatus 101. When new shooting parameter acquisition is performed by the shot image confirmation apparatus 101, the shooting parameter transmission unit 309 of the shot image confirmation apparatus 101 transmits the new shooting parameter to the shooting apparatus 100.

  In step S1017, the photographing apparatus 100 determines whether or not the photographing is finished based on the presence or absence of a photographing end instruction from the user. When it is determined that the photographing is finished (S1017; YES), the process is finished. On the other hand, if it is determined that shooting is to be continued (S1017; NO), the process returns to step S1002.

  With reference to the flowchart of FIG. 11, the procedure for creating a new shooting parameter in S1014 will be described. This process is executed by the shooting parameter determination unit 404 of the shooting support apparatus 102. Note that the procedure for creating a new shooting parameter in FIG. 11 is an example, and the shooting parameter may be created from the image correction result by other methods. In step S1100, the shooting parameter determination unit 404 analyzes the correction item and determines whether the correction item is an item that can be directly set in the shooting apparatus 100, whether the correction item is an item unrelated to the shooting parameter adjustment, or It is determined whether the correction item is related to exposure such as brightness. Here, the items that can be directly set in the photographing apparatus 100 are, for example, white balance, color temperature, or picture style.

  If it is determined that the correction item is an item that can be directly set in the photographing apparatus 100, the process advances to step S1101. If it is determined that the correction item is an item unrelated to the shooting parameter adjustment, the process advances to step S1102. If it is determined that the correction item is an item relating to exposure such as brightness, the process advances to step S1103.

  In step S1101, the shooting parameter determination unit 404 sets the correction value as a new shooting parameter.

  In step S <b> 1102, the shooting parameter determination unit 404 notifies the image processing apparatus 103 that the shooting parameters cannot be changed based on the result of repeated image correction. Further, in response to the notification, the image processing apparatus 103 notifies the user that the shooting parameter cannot be changed based on repeated image correction results.

  In step S1103, the shooting parameter determination unit 404 determines whether the shooting mode of the shooting apparatus 100 is shutter priority AE, manual, or aperture priority AE. If it is determined that the shooting mode is shutter priority AE, the process proceeds to step S1104. If it is determined that the shooting mode is manual, the process advances to step S1105. If it is determined that the shooting mode is aperture priority AE, the process proceeds to step S1106.

  In step S <b> 1104, the shooting parameter determination unit 404 calculates an Av value and ISO sensitivity to be newly set from the image correction information performed by the image processing apparatus 103 and the Tv value currently set in the imaging apparatus 100. This is because when the shooting mode is shutter priority AE, the photographer's intention is respected and the exposure is controlled so as not to change the Tv value. The exposure correction value may be determined based on the image correction information performed by the image processing apparatus 103. The system may calculate the Tv value, and the photographing apparatus 100 may perform automatic exposure correction based on the designated Tv value to determine the Av value and ISO sensitivity.

  In step S <b> 1105, the shooting parameter determination unit 404 calculates an exposure correction value from the image correction information performed by the image processing apparatus 103. When the shooting mode is manual, the Tv value, Av value, and ISO sensitivity can be fixedly set from the system, but which value of the three shooting parameters should be given priority depends on the user. Change the exposure compensation value to be used.

  In step S <b> 1106, the shooting parameter determination unit 404 calculates a newly set Tv value and ISO sensitivity from the image correction information performed by the image processing apparatus 103 and the Av value currently set in the imaging apparatus 100. This is because when the shooting mode is aperture priority AE, the intention of the photographer is respected and the exposure is controlled so as not to change the Av value. The exposure correction value may be determined based on the image correction information performed by the image processing apparatus 103. Further, the system may be configured to calculate the Av value, and the photographing apparatus 100 performs automatic exposure correction based on the designated Av value to determine the Tv value and the ISO sensitivity.

  In step S1107, the shooting parameter determination unit 404 determines the Tv value, exposure correction value, Av value, or ISO sensitivity calculated in S1104, S1105, or S1106 as a shooting parameter.

  In step S1108, the imaging parameter determination unit 404 determines whether there is automatic image correction (automatic image correction to be stopped) related to the determined (changed) imaging parameter, and the image processing flow table illustrated in FIG. To determine. If it is determined that there is automatic image correction related to the changed shooting parameter (S1108; YES), the process proceeds to step S1109. On the other hand, if it is determined that there is no automatic image correction related to the changed shooting parameter (S1108; NO), the process is terminated.

  In step S1109, the imaging parameter determination unit 404 stops the corresponding automatic image correction. This is because the result of automatic image correction may be different from the result of manual image correction by the user. For example, consider a case where the picture style is set to monochrome by automatic image correction and the picture style is changed to portrait in manual correction. In this case, even if the photographing parameter of the photographing apparatus 100 is changed to the portrait based on the manual correction result, it is considered that the monochrome is set again by the automatic image correction, and it is necessary to prevent such an adverse effect. It is.

  With the above processing, it is possible to determine the shooting parameters of the shooting apparatus 100 to be used at the time of shooting based on the image correction information performed by the image processing apparatus 103. Therefore, appropriate shooting parameters are set even during shooting. be able to. In addition, since it is possible to determine the shooting parameters simply by performing image correction such as changing the brightness on the image by the image processing apparatus 103, even a user who has little knowledge about the shooting parameter setting in the shooting apparatus 100 can easily set the shooting parameters. Can be set. Further, by determining the shooting parameters based on the image correction information and setting the shooting parameters in the shooting apparatus, it is not necessary to perform correction on an image shot after setting the shooting parameters.

  Note that the photographing apparatus 100 may be configured to perform automatic exposure correction on the photographing parameter value designated by the system in accordance with a change in the photographing state of the studio. In the case of automatic exposure correction, the photographing apparatus 100 may be configured to inquire whether the system or / and the user may perform automatic exposure correction, or to notify the automatic exposure correction.

  According to the present embodiment, it is possible to set appropriate photographing parameters for the photographing apparatus even when photographing work is performed while the photographing situation changes.

(Second Embodiment)
In the first embodiment, a case has been described in which new shooting parameters are derived by performing the same manual image correction a predetermined number of times. On the other hand, in the present embodiment, a case will be described in which new shooting parameters are derived by performing the same image correction a specified number of times regardless of automatic image correction or manual image correction. Since the configuration of each device is the same as that of the first embodiment, description thereof is omitted.

  With reference to the flowchart of FIG. 12, the procedure of the process of the whole imaging | photography assistance system which concerns on 2nd Embodiment is demonstrated.

  In step S1200, the photographed image confirmation apparatus 101 starts photographing by a user operation.

  In step S <b> 1201, the shooting parameter transmission unit 309 of the shot image confirmation apparatus 101 transmits shooting parameters to the shooting apparatus 100. The shooting parameters transmitted at this time are at least one of shooting mode, Av value, Tv value, ISO sensitivity, exposure correction value, picture style, white balance, color temperature, and the like. The parameter to be transmitted is an example, and the present invention is not limited to this.

  In step S1202, the imaging device 100 performs imaging by a user operation. An image photographed by the photographing apparatus 100 is transmitted to the photographed image confirmation apparatus 101.

  In step S <b> 1203, after the captured image confirmation apparatus 101 receives the captured image from the imaging apparatus 100, the captured image display unit 302 of the captured image confirmation apparatus 101 displays the captured image on the captured image panel 604. Further, the face area display unit 303 displays the face area image detected by the face area detection unit 307 on the face area image panel 605. The thumbnail image display unit 304 displays thumbnail images in the thumbnail image list 603. In addition, a histogram of the captured image is displayed in the histogram 601. Further, shooting parameters of the shot image are displayed in the shooting parameter list 602.

  In step S <b> 1204, the captured image confirmation apparatus 101 transmits a captured image to the imaging support apparatus 102. The imaging support apparatus 102 stores the captured image received from the captured image confirmation apparatus 101 in the captured image storage unit 400.

  In step S1205, the photographing support apparatus 102 requests the image processing apparatus 103 to perform image correction based on the image processing flow managed by the image processing request unit 406. The image processing apparatus 103 performs automatic image correction by the automatic image correction unit 500 according to the image processing flow notified from the imaging support apparatus 102. The image correction executed here corresponds to an item that is set to be implemented as shown in FIG.

  In step S1206, the automatic image correction result display unit 505 of the image processing apparatus 103 displays the automatic image correction result image in the thumbnail image display column 701.

  In step S <b> 1207, the image processing apparatus 103 needs to perform manual image correction according to the presence or absence of an instruction from the user who confirmed the automatic image correction result, the presence or absence of an image correction request notified from the captured image confirmation apparatus 101, and the like. It is determined whether or not. If it is determined that manual image correction is necessary (S1207; YES), the process proceeds to step S1208. On the other hand, if it is determined that manual image correction is not required (S1207; NO), the process proceeds to step S1211.

  In step S1208, the manual image correction unit 507 of the image processing apparatus 103 accepts manual image correction using a user interface as shown in FIG.

  In step S <b> 1209, the image processing apparatus 103 transmits image correction information, which is an image correction result executed by the automatic image correction unit 500 and the manual image correction unit 507, to the imaging support apparatus 102.

  In step S <b> 1210, the correction information storage unit 402 of the photographing support apparatus 102 stores the image correction information received from the image processing apparatus 103.

  In step S <b> 1211, the image processing apparatus 103 transmits the corrected image to the imaging support apparatus 102. The corrected image storage unit 401 of the photographing support apparatus 102 stores the corrected image received from the image processing apparatus 103. If it is determined in step S1207 that manual correction is not necessary and the process proceeds to step 1211, the corrected image storage unit 401 stores an image for which only automatic image correction has been performed.

  In step S1212, the imaging support apparatus 102 determines whether automatic image correction or manual image correction has been performed. If it is determined that automatic image correction or manual image correction has been performed (S1212; YES), the process proceeds to step S1213. On the other hand, if it is determined that automatic image correction or manual image correction has not been performed (S1212; NO), the process proceeds to step S1214.

  In step S <b> 1213, the imaging support apparatus 102 notifies the captured image confirmation apparatus 101 that there is a possibility that the imaging parameters may be changed because image correction has been performed. The imaging parameter change notification unit 306 of the captured image confirmation apparatus 101 that has received the notification notifies the user of a warning.

  In step S1214, the image correction information analysis unit 403 of the photographing support apparatus 102 performs the same correction over a specified number of times regardless of automatic correction or manual correction, and determines whether or not the correction values at that time are substantially the same (specified amount). Whether or not the error is within the error range. If it is determined that the same correction has been performed with substantially the same value over the specified number of times (S1214; YES), the process proceeds to step S1215. On the other hand, if not (S1214; NO), the process proceeds to step S1218.

  In step S1215, the shooting parameter determination unit 404 of the shooting support apparatus 102 determines a new shooting parameter. Since the process for determining the new imaging parameter is the same as that shown in FIG.

  In step S1216, the shooting parameter change notification unit 407 of the shooting support apparatus 102 notifies the shot image confirmation apparatus 101 that the shooting parameters are changed. When receiving the notification from the imaging support apparatus 102, the imaging parameter change notification unit 306 of the captured image confirmation apparatus 101 warns the user that the imaging parameter is changed.

  In step S1217, the shooting parameter transmission unit 405 of the shooting support apparatus 102 transmits a new shooting parameter to the shot image confirmation apparatus 101. The imaging parameter transmission unit 309 of the captured image confirmation apparatus 101 that has received the new imaging parameter transmits the new imaging parameter to the imaging apparatus 100.

  In step S <b> 1218, the image capturing apparatus 100 determines whether the image capturing is ended based on the presence / absence of an image capturing end instruction from the user. When it is determined that the photographing is finished (S1218; YES), the process is finished. On the other hand, if it is determined that shooting is to be continued (S1218; NO), the process returns to step S1202.

  As described above, new imaging parameters are derived when the same image correction is performed a specified number of times regardless of automatic image correction or manual image correction. According to the present embodiment, it is possible to set more appropriate shooting parameters for the shooting apparatus even when shooting work is performed while shooting conditions change.

(Other embodiments)
The present invention can also be realized by executing the following processing. That is, software (program) that realizes the functions of the above-described embodiments is supplied to a system or apparatus via a network or various storage media, and a computer (or CPU, MPU, or the like) of the system or apparatus reads the program. It is a process to be executed.

Claims (9)

A shooting support system for determining shooting parameters used in a shooting device,
Image obtaining means for obtaining a photographed image photographed by the photographing device;
Image processing means for image processing the captured image;
Determining means for determining the imaging parameter based on an image processing result by the image processing means;
A photographing support system comprising:   The imaging support system according to claim 1, wherein the image processing unit performs image processing on the captured image in response to an image correction request from a user who has confirmed the captured image.   The imaging support system according to claim 2, further comprising imaging parameter transmission means for transmitting the imaging parameters determined by the determination means to the imaging apparatus. The image processing means includes
Automatic image correction means for automatically performing image correction on the captured image in accordance with a predetermined image correction procedure;
Manual image correction means for accepting manual image correction by the user for the automatic image correction result,
The photographing support system includes:
Automatic image correction result display means for displaying the automatic image correction result performed by the automatic image correction means,
4. The image processing result according to claim 2, wherein the image processing result includes automatic image correction information performed by the automatic image correction unit and manual image correction information performed by the manual image correction unit. Shooting support system. A determination unit that determines whether or not correction within a predetermined range has been performed a predetermined number of times or more by the manual image correction unit with respect to a captured image captured by the imaging device;
The photographing support system according to claim 4, wherein the determination unit determines the photographing parameter when the determination unit determines that the correction within the predetermined range has been performed a predetermined number of times or more.   6. The photographing support system according to claim 5, further comprising warning means for warning a user that the photographing parameter is determined by the determining means. A shooting support device for determining shooting parameters used in the shooting device,
Obtaining means for obtaining an image processing result of a photographed image photographed by the photographing device;
Determining means for determining the imaging parameter based on the image processing result;
An imaging support apparatus comprising: An acquisition means, a determination means, and a control method of a shooting support apparatus for determining shooting parameters used in the shooting apparatus,
The acquisition unit acquires an image processing result of a captured image captured by the imaging device;
A determining step in which the determining means determines the imaging parameter based on the image processing result;
A method for controlling a photographing support apparatus, comprising:   The program for making a computer perform each process of the control method of the imaging | photography assistance apparatus of Claim 8.

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