JP6058084B2 - Imaging operation terminal, imaging system, software extraction method, and program - Google Patents

Description

  The present invention relates to an imaging operation terminal, an imaging system, a software extraction method, and a program.

  2. Description of the Related Art Conventionally, a lot of software for operating imaging of a digital camera and software for editing an image obtained by imaging are provided. In addition, a digital camera is connected to a computer and remotely operated for shooting, and images shot with the digital camera are transferred to the computer for management. Patent Document 1 discloses a terminal device that acquires operation modes of a camera device and a cradle device, and automatically determines and starts an application to be executed on the terminal device according to the acquired operation mode. .

JP 2007-89093 A

  In the technique of Patent Document 1, the software to be activated in the terminal device is determined based on the operation mode between the camera device and the cradle device. However, even if the optical module of the camera device is changed, the same software is activated. For this reason, every time the optical module is changed, there is a problem that the user needs to select software, which is troublesome for the user.

  Accordingly, an aspect of the present invention has been made in view of the above-described problem, and provides an imaging operation terminal, an imaging system, a software extraction method, and a program that can reduce a user's trouble in selecting software. Is an issue.

One embodiment of the present invention performs at least one of an operation related to imaging of an imaging module to which an optical module is attached and editing of an image obtained by imaging of the imaging module, and the imaging module and the optical module Software identification information for identifying imaging editing software that is highly likely to be used for shooting by a combination of the image capturing module is stored for each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module. When wireless connection is established between the storage unit and the imaging module, imaging module identification information for identifying the imaging module from the imaging module and optical module identification information for identifying the optical module mounted on the imaging module are wirelessly transmitted. Received by the communication unit and the communication unit. Equipped with a software extractor for extracting software identification information corresponding from the storage unit to the combination of the imaging module identification information and the optical module identification information, the storage unit, and the said imaging module optical module The imaging operation terminal stores the software identification information for identifying the imaging editing software that is highly likely to be used when shooting an imaging target estimated in combination .
In one embodiment of the present invention, at least one of an operation related to imaging of an imaging module to which an optical module is mounted and editing of an image obtained by imaging of the imaging module are performed, and the imaging module and the optical module Software identification information for identifying imaging editing software that is highly likely to be used for shooting in combination with a module is stored for each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module. And when the wireless connection is established with the imaging module, the imaging module identification information for identifying the imaging module from the imaging module, and the optical module identification information for identifying the optical module attached to the imaging module And a communication unit that wirelessly receives the A software extraction unit that extracts software identification information corresponding to the received combination of the imaging module identification information and the optical module identification information from the storage unit, and the storage unit includes the imaging module and the optical module. This is an imaging operation terminal that stores the software identification information for identifying the imaging editing software that is likely to be used when shooting in a surrounding state at the time of shooting estimated by the combination.

One embodiment of the present invention is an imaging system including an imaging module to which an optical module is mounted and an imaging operation terminal for operating the imaging module, and the imaging operation terminal is mounted with an optical module. Imaging that performs at least one of operations related to imaging of the imaging module and editing of an image obtained by the imaging module, and is highly likely to be used for imaging by a combination of the imaging module and the optical module Software identification information for identifying editing software has been stored for each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module, and wireless connection has been established with the imaging module Imaging to identify the imaging module from the imaging module A module for wirelessly receiving module identification information and optical module identification information for identifying an optical module mounted on the imaging module, and the imaging module identification information and the optical module identification information received by the communication unit. And a software extraction unit that extracts software identification information corresponding to the combination from the storage unit, and the storage unit captures an imaging target estimated by a combination of the imaging module and the optical module. The imaging system stores the software identification information for identifying the imaging editing software that is likely to be used .
One embodiment of the present invention is an imaging system including an imaging module to which an optical module is mounted and an imaging operation terminal for operating the imaging module, and the imaging operation terminal is mounted with an optical module. Imaging that performs at least one of operations related to imaging of the imaging module and editing of an image obtained by the imaging module, and is highly likely to be used for imaging by a combination of the imaging module and the optical module Software identification information for identifying editing software has been stored for each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module, and wireless connection has been established with the imaging module Imaging to identify the imaging module from the imaging module A module for wirelessly receiving module identification information and optical module identification information for identifying an optical module mounted on the imaging module, and the imaging module identification information and the optical module identification information received by the communication unit. And a software extraction unit that extracts software identification information corresponding to the combination of the imaging module and the storage unit, and the storage unit is in a surrounding state at the time of photographing estimated by a combination of the imaging module and the optical module. The imaging system stores the software identification information for identifying the imaging editing software that is highly likely to be used when shooting.

In one embodiment of the present invention, at least one of an operation related to imaging of an imaging module to which an optical module is mounted and editing of an image obtained by imaging of the imaging module are performed, and the imaging module and the optical module Software identification information for identifying imaging editing software that is highly likely to be used for shooting in combination with a module is stored for each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module. An imaging operation method executed by an imaging operation terminal including a storage unit, wherein when the communication unit establishes a wireless connection with the imaging module, imaging module identification information for identifying the imaging module from the imaging module; and Optics for identifying optical modules installed in imaging modules Module identification information received wirelessly, and a software extraction unit extracts software identification information corresponding to the combination of the imaging module identification information and the optical module identification information received by the communication unit from the storage unit a step of, have a, by the storage unit, the software identification for identifying the imaging editing software is likely to be used when shooting the shooting target estimated by combination of the optical module and the imaging module A software extraction method for storing information .
In one embodiment of the present invention, at least one of an operation related to imaging of an imaging module to which an optical module is mounted and editing of an image obtained by imaging of the imaging module are performed, and the imaging module and the optical module Software identification information for identifying imaging editing software that is highly likely to be used for shooting in combination with a module is stored for each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module. An imaging operation method executed by an imaging operation terminal including a storage unit, wherein when the communication unit establishes a wireless connection with the imaging module, imaging module identification information for identifying the imaging module from the imaging module; and Optics for identifying optical modules installed in imaging modules Module identification information received wirelessly, and a software extraction unit extracts software identification information corresponding to the combination of the imaging module identification information and the optical module identification information received by the communication unit from the storage unit And the storage unit identifies the imaging editing software that is likely to be used when shooting in a surrounding state at the time of shooting estimated by a combination of the imaging module and the optical module. A software extraction method for storing the software identification information.

In one embodiment of the present invention, at least one of an operation related to imaging of an imaging module to which an optical module is mounted and editing of an image obtained by imaging of the imaging module are performed, and the imaging module and the optical module Software identification information for identifying imaging editing software that is highly likely to be used for shooting in combination with a module is stored for each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module. When wireless connection is established with an imaging module to an imaging operation terminal having a storage unit, imaging module identification information for identifying the imaging module from the imaging module and an optical module mounted on the imaging module are identified. Wireless communication to receive optical module identification information A step, wherein the storage unit stores the software identification information identifying the imaging editing software is likely to be used when shooting the shooting target estimated by combination of the optical module and the imaging module, wherein is a program for executing a software extracting the software identification information corresponding to the combination of the imaging module identification information received by the communication step and said optical module identification information from the storage unit.
In one embodiment of the present invention, at least one of an operation related to imaging of an imaging module to which an optical module is mounted and editing of an image obtained by imaging of the imaging module are performed, and the imaging module and the optical module Software identification information for identifying imaging editing software that is highly likely to be used for shooting in combination with a module is stored for each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module. When wireless connection is established with an imaging module to an imaging operation terminal having a storage unit, imaging module identification information for identifying the imaging module from the imaging module and an optical module mounted on the imaging module are identified. Wireless communication to receive optical module identification information And the storage unit includes software identification information for identifying the imaging editing software that is likely to be used when shooting in a surrounding state at the time of shooting estimated by a combination of the imaging module and the optical module. A software extraction step for storing and extracting the software identification information corresponding to the combination of the imaging module identification information and the optical module identification information received in the communication step from the storage unit; is there.

  According to one embodiment of the present invention, it is possible to reduce time and effort required for user software selection.

It is a schematic block diagram which shows the structure of the imaging operation terminal in 1st Embodiment. It is table T1 which shows an example of the software specific information memorize | stored in the memory | storage part. It is a flowchart which shows an example of the flow of a process of the imaging operation terminal in 1st Embodiment. It is a schematic block diagram which shows the structure of the imaging operation terminal in the modification 1 of 1st Embodiment. It is a flowchart which shows an example of the flow of a process of the imaging operation terminal in the modification 1 of 1st Embodiment. It is a schematic block diagram which shows the structure of the imaging operation terminal 12 in the modification 2 of 1st Embodiment. It is table T2 which shows an example of the software specific information memorize | stored in the memory | storage part in the modification 2. 11 is a table T3 illustrating an example of software specifying information when software identification information corresponding to a set of imaging module identification information and optical module identification information is not stored in Modification 2 . It is a schematic block diagram which shows the structure of the imaging operation terminal in the modification 3 of 1st Embodiment. It is table T4 which shows an example of the software specific information memorize | stored in the memory | storage part in the modification 3. It is a flowchart which shows an example of the flow of a process of the imaging operation terminal in the modification 3 of 1st Embodiment. It is a schematic block diagram which shows the structure of the imaging operation terminal in the modification 4 of 1st Embodiment. It is table T5 which shows an example of the software specific information memorize | stored in the memory | storage part in the modification 4. It is a flowchart which shows an example of the flow of a process of the imaging operation terminal in the modification 4 of 1st Embodiment. It is a schematic block diagram which shows the structure of the imaging operation terminal in the modification 5 of 1st Embodiment. It is the figure by which an example of the conversion table of an element value and a score was shown for every element. It is an example of a table T11 that the priority level assigning unit generates to determine the priority level of software. It is a flowchart which shows an example of the flow of a process of the imaging operation terminal in the modification 5 of 1st Embodiment. It is a schematic block diagram which shows the structure of the imaging operation terminal in the modification 6 of 1st Embodiment. It is a flowchart which shows an example of the flow of a process of the imaging operation terminal in the modification 6 of 1st Embodiment. It is a schematic block diagram which shows the structure of the imaging operation terminal in the modification 7 of 1st Embodiment. It is a flowchart which shows an example of the flow of a process of the imaging operation terminal in the modification 7 of 1st Embodiment. It is a schematic block diagram which shows the structure of the imaging operation terminal in the modification 8 of 1st Embodiment. It is an example before and after a change of software specific information. It is a flowchart which shows an example of the flow of a process of the imaging operation terminal in the modification 8 of 1st Embodiment. It is a schematic block diagram which shows the structure of the imaging operation terminal in the modification 9 of 1st Embodiment. It is a flowchart which shows an example of the flow of a process of the imaging operation terminal in the modification 9 of 1st Embodiment. It is a schematic block diagram which shows the structure of the imaging operation terminal in the modification 10 of 1st Embodiment. It is a flowchart which shows an example of the flow of a process of the imaging operation terminal in the modification 10 of 1st Embodiment. It is a schematic block diagram which shows the structure of the imaging operation terminal in 2nd Embodiment. It is table T16 which shows an example of the software specific information memorize | stored in the memory | storage part. It is a flowchart which shows an example of the flow of a process of the imaging operation terminal in 2nd Embodiment. It is a schematic block diagram which shows the structure of the imaging operation terminal in the modification 1 of 2nd Embodiment. It is a flowchart which shows an example of the flow of a process of the imaging operation terminal in the modification 1 of 2nd Embodiment. It is a schematic block diagram which shows the structure of the imaging operation terminal in the modification 2 of 2nd Embodiment. It is a schematic block diagram which shows the structure of the imaging operation terminal in the modification 3 of 2nd Embodiment. It is a figure for demonstrating the process in which software specific information is updated by the information update part.

<First Embodiment>
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a schematic block diagram illustrating the configuration of the imaging operation terminal 10 according to the first embodiment. The imaging operation terminal 10 includes a communication unit 101, a storage unit 102, and a software extraction unit 103. The imaging operation terminal 10 is, for example, a multifunctional mobile terminal (so-called smartphone), a tablet terminal, an electronic book browsing terminal, a notebook computer, or a personal computer.

  The communication unit 101 establishes wireless connection with an imaging module (not shown), imaging module identification information for identifying the imaging module, and optical module identification information for identifying an optical module (not shown) attached to the imaging module. Are wirelessly received from the imaging module. Here, the imaging module is a module including at least an image sensor (for example, a CCD) that converts light guided from the optical module into an electrical signal and a communication unit that can communicate with the imaging operation terminal 10. The optical module is a module including at least an optical system (for example, a lens) that guides light incident from the outside to the imaging module. The communication unit 101 outputs the received imaging module identification information and optical module identification information to the software extraction unit 103.

  The storage unit 102 stores software identification information for identifying imaging editing software, software identification information associated with each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module. ing. Here, the imaging editing software is software that performs at least one of an operation related to imaging of the imaging module to which the optical module is mounted and editing of an image obtained by imaging by the imaging module. Here, the operation relating to imaging is an operation of the imaging module as an example in the present embodiment. Note that the operation related to imaging may include an operation of an accessory used together with the imaging module in addition to the operation of the imaging module.

  The software extraction unit 103 extracts software identification information corresponding to the combination of the imaging module identification information and the optical module identification information received by the communication unit 101 from the storage unit 102. Specifically, for example, the software extraction unit 103 reads the software identification information stored in the storage unit 102, and the imaging module identification information and the optical module identification received by the communication unit 101 from the read software identification information. Software identification information corresponding to the combination with information is extracted.

FIG. 2 is a table T <b> 1 showing an example of software specifying information stored in the storage unit 102. Table T1 shows a set of imaging module identification information, optical module identification information, and software identification information. For example, in the first row of the table T1, when the imaging module identification information is a 3D imaging module and the optical module identification information is a macro lens, 3D creation software is associated with the software identification information. Here, the processing of the software extraction unit 103 will be described using the data in the first row of the table T1. For example, when the communication unit 101 receives the 3D imaging module as the imaging module identification information and the macro lens as the optical module identification information, the software extraction unit 103 refers to the information in the first row of the table T1 as the software identification information. Extract 3D creation software.
In the table T1, person detection software and constellation search software are examples of imaging operation software. In contrast, album creation software and 3D creation software are examples of editing software.

  In the example of FIG. 2, even when the same macro lens is used for the optical module, if the imaging module is a 3D imaging module that also acquires information in the depth direction, the software extraction unit 103 supports the creation of a 3D image. 3D creation software is extracted. If a high-sensitivity imaging module that can shoot with the same small amount of light is used for the imaging module, if the optical module is a portrait lens suitable for portrait shooting, there is a possibility of shooting a person in an environment with a small amount of light. Therefore, the software extraction unit 103 extracts person detection software. On the other hand, when the high-sensitivity imaging module is used, the software extraction unit 103 extracts the constellation search software because the optical module can capture the night sky if it is a wide-angle lens that can capture a wide range of images. As described above, since software suitable for the combination of the imaging module and the optical module is stored in the storage unit 102 in advance, the software extraction unit 103 can extract software that the user is likely to use.

  Note that the imaging module may be a high-definition module, a module with a large image sensor, a module with a high pixel density, or the like. The optical module may be a fisheye lens, a telephoto lens, a zoom lens, a telescope optical system, a microscope optical system, or the like. Also, the software is not limited to the example of FIG.

FIG. 3 is a flowchart illustrating an example of a processing flow of the imaging operation terminal 10 according to the first embodiment.
(Step S101) First, the communication unit 101 establishes a wireless connection with an imaging module on which an optical module is mounted.
(Step S102) First, the communication unit 101 acquires imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module attached to the imaging module from the imaging module.
(Step S <b> 103) Next, the software extraction unit 103 reads the software specifying information stored in the storage unit 102.
(Step S104) Next, the software extraction unit 103 extracts software identification information corresponding to the combination of the imaging module identification information and the optical module identification information received by the communication unit 101 from the software identification information. Above, the process of this flowchart is complete | finished.

  As described above, in the imaging operation terminal 10 according to the first embodiment, the software extraction unit 103 can extract the software identification information corresponding to the combination of the imaging module identification information and the optical module identification information received by the communication unit 101. Thereby, since the imaging operation terminal 10 can select software suitable for the combination of the imaging module and the optical module, it is possible to reduce time and effort required for the user to select software.

<Modification 1>
Subsequently, Modification 1 of the first embodiment will be described. FIG. 4 is a schematic block diagram illustrating the configuration of the imaging operation terminal 11 according to the first modification of the first embodiment. Elements common to those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof is omitted. The configuration of the imaging operation terminal 11 in Modification 1 is such that a software activation unit 104 and a display unit 105 are added to the configuration of the imaging operation terminal 10 in the first embodiment.

As an example, the imaging module 302 is mounted with an optical module 301. The optical module 301 includes, for example, an electrically rewritable nonvolatile memory (not shown), and optical module identification information for identifying the optical module 301 is stored in advance. The imaging module 302 is provided with an attachment / detachment detection switch (not shown) near the mount opening in the imaging module 302, for example, and detects the mounting state of the optical module 301 and the imaging module 302. When the mounting of the optical module 301 is detected, the imaging module 302 supplies power to the optical module 301 via a contact (not shown) of the imaging module 302 and a contact (not shown) of the optical module 301. When the optical module 301 is supplied with power, the optical module identification information stored in the non-volatile memory is transmitted to the imaging module 302 via a contact (not shown) included in the optical module 301. Thereby, the imaging module 302 acquires the optical module identification information for identifying the optical module 301, and holds the acquired optical module identification information.
The imaging module 302 includes a communication unit (not shown), and the communication unit can wirelessly communicate with the communication unit 101 of the imaging operation terminal 11.

The software activation unit 104 activates the software extracted by the software extraction unit 103, generates a screen signal indicating a software screen, and outputs the generated screen signal to the display unit 105.
The display unit 105 displays a software screen from the screen signal input from the software activation unit 104.

FIG. 5 is a flowchart illustrating an example of a processing flow of the imaging operation terminal according to the first modification of the first embodiment.
(Step S201) First, the communication unit 101 establishes a wireless connection with the imaging module 302 on which the optical module 301 is mounted.
(Step S202) First, the communication unit 101 wirelessly acquires imaging module identification information for identifying the imaging module 302 and optical module identification information for identifying an optical module mounted on the imaging module 302 from the imaging module 302. To do.
(Step S <b> 203) Next, the software extraction unit 103 reads the software specifying information stored in the storage unit 102.

(Step S204) Next, the software extraction unit 103 stores the software identification information corresponding to the combination of the imaging module identification information and the optical module identification information received by the communication unit 101 in the storage unit 102. Extract from information.
(Step S205) Next, the software activation unit 104 activates the imaging editing software identified by the software identification information extracted by the software extraction unit 103.
(Step S206) Next, the display unit 105 displays a screen of the imaging editing software activated by the software activation unit 104. Above, the process of this flowchart is complete | finished.

  As described above, in Modification 1, in addition to the effects of the first embodiment, the software activation unit 104 activates the imaging editing software extracted by the software extraction unit 103. Therefore, when the imaging editing software is imaging operation software, Time required for shooting preparation can be shortened. Further, when the imaging editing software is editing software, the time required for image editing preparation can be shortened.

<Modification 2>
Then, the modification 2 of 1st Embodiment is demonstrated. The imaging operation terminal 12 of the second modification extracts a plurality of imaging editing software when there are a plurality of imaging editing software suitable for the situation. FIG. 6 is a schematic block diagram illustrating a configuration of the imaging operation terminal 12 according to the second modification of the first embodiment. In addition, the same code | symbol is attached | subjected to the element which is common in FIG. 4, and the specific description is abbreviate | omitted. The configuration of the imaging operation terminal 12 in the modification 2 is changed from the configuration of the imaging operation terminal 11 in the modification 1 to the storage unit 102b and the software extraction unit 103 to the software extraction unit 103b. An operation unit 106 is added.

The storage unit 102b stores a plurality of pieces of software identification information corresponding to combinations of imaging module identification information and optical module identification information in association with each other.
The software extraction unit 103b reads a plurality of pieces of software identification information corresponding to the set of the imaging module identification information and the optical module identification information received by the communication unit 101 from the storage unit 102b. Specifically, for example, the software extraction unit 103b reads the software identification information, and corresponds to the combination of the imaging module identification information and the optical module identification information received by the communication unit 101 in the software identification information. Extract multiple pieces of software identification information. For example, the software extraction unit 103b causes the display unit 105 to display the name of the imaging editing software identified by the plurality of read software identification information.

The operation unit 106 receives a user operation for selecting the name of one imaging editing software from the names of the plurality of imaging editing software displayed on the display unit 105. The operation unit 106 outputs operation information indicating the accepted operation to the software activation unit 104. The operation unit 106 is a user interface, for example, a contact sensor stacked on the surface of the display unit 105.
The software activation unit 104 activates imaging editing software corresponding to the operation information input from the operation unit 106. Thereby, the software activation unit 104 can activate the imaging editing software selected by the user.

  FIG. 7 is a table T2 illustrating an example of the software specifying information stored in the storage unit 102b according to the second modification. In the table T2 in the figure, a plurality of pieces of software identification information are associated with a set of imaging module identification information and optical module identification information. For example, with a combination of a high-sensitivity imaging module suitable for shooting in a dark place and a wide-angle lens with a wide angle of view, suitable imaging operation software differs when shooting a night view of a city and shooting a starry sky. Night scene shooting software is suitable when shooting a night view of the city, and constellation search software is appropriate when shooting a starry sky. Therefore, as an example, night view shooting software and constellation search software are associated with the table T2 as imaging editing software corresponding to a combination of a high-sensitivity imaging module and a wide-angle lens.

  Also, even when shooting your pet with a combination of a high-definition imaging module and a low F-number lens that makes it easy to capture bright images, album software is used to manage images, and web posting software is used to share images on the Internet. Image processing software is suitable for editing images. Here, the low F value lens is a lens having an F value lower than a predetermined reference. Therefore, as an example, album software, web posting software, and image processing software are associated with the table T2 as imaging editing software corresponding to a combination of a high-definition imaging module and a low F-number lens.

  As described above, in the second modification, the software extraction unit 103b extracts a plurality of pieces of software identification information corresponding to the set of the imaging module identification information and the optical module identification information received by the communication unit 101 from the storage unit 102c. As a result, the software extraction unit 103b extracts a plurality of imaging editing software suitable for the combination of the imaging module and the optical module, so that candidates for the imaging editing software can be narrowed down. Therefore, the imaging editing software suitable for the situation It is possible to reduce the time and labor of the user who selects.

  FIG. 8 is a table T3 showing an example of software specifying information when software identification information corresponding to a set of imaging module identification information and optical module identification information is not stored. In the table T3 in the figure, the software identification information is blank.

Note that the software extraction unit 103b, when the software identification information corresponding to the set of the imaging module identification information and the optical module identification information is not stored in the storage unit 102b, is a predetermined imaging editing software (hereinafter referred to as default software). ) May be activated. In this case, the software extraction unit 103b may display a message indicating that the default software is to be activated for the user on the display unit 105 before activation, and wait for the user's approval. When the operation unit 106 receives an operation for approval by the user, the software activation unit 104 activates the default software. On the other hand, when the operation unit 106 accepts an operation not approved by the user, the software extraction unit 103b may display a software selection screen on the display unit 105 and wait for the user to select imaging editing software. When the operation unit 106 receives an operation for selecting imaging / editing software by the user, the software activation unit 104 may activate the imaging / editing software selected by the user. Thereby, the user can select and start arbitrary imaging editing software.
The default software may be determined in advance by the user.

<Modification 3>
Then, the modification 3 of 1st Embodiment is demonstrated. When the imaging operation terminal 13 according to Modification 3 can communicate with a plurality of sets of imaging modules and optical modules, the imaging operation terminal 13 extracts and starts imaging editing software corresponding to the plurality of sets. FIG. 9 is a schematic block diagram illustrating a configuration of the imaging operation terminal 13 in Modification 3 of the first embodiment. In addition, the same code | symbol is attached | subjected to the element which is common in FIG. 6, and the specific description is abbreviate | omitted. The configuration of the imaging operation terminal 13 in Modification 3 is changed from the configuration of the imaging operation terminal 12 in Modification 2 of FIG. 6 in that the communication unit 101 is changed to the communication unit 101c and the storage unit 102b is changed to the storage unit 102c. The software extraction unit 103b is changed to the software extraction unit 103c.

When the communication unit 101c searches for an imaging module that can be connected within a communicable range and finds it, the communication unit 101c establishes wireless communication with the discovered imaging module. Then, the communication unit 101c wirelessly receives imaging module identification information for identifying the imaging module and optical module identification information for identifying the optical module mounted on the imaging module from the discovered imaging module. In FIG. 9, as an example, the imaging module 302 to which the optical module 301 is attached and the imaging module 312 to which the optical module 311 is attached can be connected within a communicable range. In this example, the communication unit 101c wirelessly receives first optical module identification information for identifying the optical module 301 and first imaging module identification information for identifying the imaging module 302 from the imaging module 302, and identifies the optical module 311. The second optical module identification information and the second imaging module identification information for identifying the imaging module 312 are wirelessly received from the imaging module 312.
On the other hand, when the connectable imaging module is not found even after searching for a certain period, the communication unit 101c ends the search.

The storage unit 102c stores software specifying information in which software identification information is associated with a plurality of sets of imaging module identification information and optical module identification information.
The software extraction unit 103c corresponds to two sets received by the communication unit 101c: a set of first imaging module identification information and first optical module identification information, a set of second imaging module identification information and second optical module identification information. Software identification information to be extracted.
If there is one piece of software identification information, the software extraction unit 103 c outputs the software identification information to the software activation unit 104. Thereby, the software activation unit 104 activates the imaging editing software identified by the software identification information. On the other hand, when there are a plurality of pieces of software identification information, the software extraction unit 103c causes the display unit 105 to display the name of the imaging editing software identified by the plurality of extracted software identification information, for example. Thereby, the user can select one imaging editing software from the displayed names of the plurality of imaging editing software.

FIG. 10 is a table T4 showing an example of software specifying information stored in the storage unit 102c in the third modification. In the table T4 in the figure, one or two pieces of software identification information are associated with two sets of imaging module identification information and optical module identification information.
As an example, in the table T4, 3D software and panorama software are associated with the same two groups of the micro four thirds and the lens group. Here, Micro Four Thirds is an imaging module that optimizes the specifications of a Four Thirds system, which is a standard for digital single lens reflex cameras, to a mirrorless structure. For example, the imaging operation terminal 13 can acquire information in the depth direction by performing known stereo matching by software using two same combinations of Micro Four Thirds and lenses, and can create a three-dimensional (3D) image. If you use panorama software in the same combination, you can create an image with a wider field of view.

  As an example, in the table T4, image partial magnification software is associated with a combination of a micro four thirds and a telephoto lens and a combination of a micro four thirds and a wide angle lens. Here, the imaging operation terminal 13 executes the image partial enlargement software, combines the images obtained by the telephoto lens and the wide-angle lens, and combines the images with the software to capture the image with the wide-angle lens. While grasping the entire imaging range with the image obtained in this way, it is possible to display an image obtained by enlarging a part of the imaging range with the image obtained by imaging with the telephoto lens.

FIG. 11 is a flowchart illustrating an example of a processing flow of the imaging operation terminal 13 according to the third modification of the first embodiment.
(Step S301) First, the communication unit 101c searches for an unconnected imaging module for a certain period. When an unconnected imaging module is found (YES), the communication unit 101c proceeds to the process of step S302. When an unconnected imaging module is not found (NO), the imaging operation terminal 13 proceeds to the process of step S304.
(Step S302) Next, the communication unit 101c establishes wireless communication with the found imaging module.
(Step S303) Next, the communication unit 101c wirelessly acquires imaging module identification information and optical module identification information from the discovered imaging module, and returns to the process of step S301.
(Step S304) Next, the software extraction unit 103c reads the software specifying information from the storage unit 102c.
(Step S305) Next, the software extraction unit 103c, based on the read software identification information, sets of the first imaging module identification information, the first optical module identification information, the second imaging module identification information, and the first information acquired by the communication unit 101c. Software identification information corresponding to two sets of two optical module identification information sets is read.
(Step S306) Next, the software activation unit 104 activates the imaging editing software identified by the identification information extracted by the software extraction unit 103c.
(Step S307) Next, the display unit 105 displays a screen of the imaging editing software activated by the software activation unit 104. Above, the process of this flowchart is complete | finished.

  Note that the software extraction unit 103c has two sets of combinations of the first imaging module identification information, the first optical module identification information, the second imaging module identification information, and the second optical module identification information received by the communication unit 101c. Although the software identification information corresponding to is extracted, it is not limited to this. When the communication unit 101c is wirelessly communicating with three or more imaging modules, the communication unit 101c receives imaging module identification information and optical module identification information from all imaging modules, and the software extraction unit 103c is configured by the communication unit 101c. Software identification information corresponding to all sets of received imaging module identification information and optical module identification information may be extracted.

  As described above, in the imaging operation terminal 13 in Modification 3 of the first embodiment, the software extraction unit 103c reads out software identification information corresponding to a plurality of sets of imaging module identification information and optical module identification information software. Then, the software activation unit 104 activates the imaging editing software identified by the software identification information. Thereby, for example, when the activated software is for controlling a set of a plurality of modules, the user can control the set of a plurality of modules. In addition to the effects of the first embodiment, the imaging operation terminal 13 Can provide users with more diverse functions.

<Modification 4>
Then, the modification 4 of 1st Embodiment is demonstrated. The imaging operation terminal 14 according to the modified example 4 has a priority assigned to each of a plurality of imaging editing software corresponding to the combination of the imaging module and the optical module, and starts by extracting the one with the highest priority. FIG. 12 is a schematic block diagram illustrating a configuration of the imaging operation terminal 14 according to Modification 4 of the first embodiment. In addition, the same code | symbol is attached | subjected to the element which is common in FIG. 4, and the specific description is abbreviate | omitted. In the configuration of the imaging operation terminal 14 in the modification 4, the storage unit 102 is changed to the storage unit 102d and the software extraction unit 103 is changed to the software extraction unit 103d with respect to the configuration of the imaging operation terminal 11 in the modification 1 of FIG. It has been done.

The storage unit 102d stores a plurality of pieces of software identification information associated with each combination of the imaging module identification information and the optical module identification information, and further stores a plurality of images indicated by the plurality of software identification information in each of the software identification information. Stored is software identification information associated with priority information indicating priority among related software.
For example, the software extraction unit 103d reads the software identification information from the storage unit 102d, and among the plurality of software identification information corresponding to the combination of the imaging module identification information and the optical module identification information received by the communication unit 101, the software extraction unit 103d One piece of software identification information is extracted based on the priority order associated with each piece of software identification information. Specifically, the software extraction unit 103d extracts software identification information having the highest priority among the plurality of software identification information. The software extraction unit 103d outputs the extracted software identification information to the software activation unit 104. Accordingly, the software activation unit 104 can activate the imaging editing software with the highest priority among the imaging editing software suitable for the combination of the imaging module identification information and the optical module identification information.

  FIG. 13 is a table T5 showing an example of software specifying information stored in the storage unit 102d according to the fourth modification. In the table T5 in the figure, a plurality of software identification information is associated with a set of imaging module identification information and optical module identification information, and each of the plurality of software identification information is associated with a priority. Here, the priority order is a priority order among the imaging editing software identified by the plurality of software identification information. For example, in the case of a set of “imaging module A” and “optical module A”, “imaging operation software 1” has the second highest priority, “imaging operation software 2” has the first priority, and “editing software 3”. "Is ranked 3rd. In this case, the software extraction unit 103d reads “imaging operation software 2” having the highest priority.

FIG. 14 is a flowchart illustrating an example of a process flow of the imaging operation terminal 14 according to the fourth modification of the first embodiment. The processing from step S401 to S403 is the same as the processing from step S201 to S203 in FIG.
(Step S404) Next, the software extracting unit 103d has the highest priority among the plurality of software identification information corresponding to the combination of the imaging module identification information and the optical module identification information received by the communication unit 101. Extract information.
The processing from step S405 to S406 is the same as the processing from step S205 to S206 in FIG. Above, the process of this flowchart is complete | finished.

  As described above, in the imaging operation terminal 14 according to the fourth modification of the first embodiment, the software extraction unit 103d includes a plurality of pieces of software identification information corresponding to combinations of the imaging module identification information and the optical module identification information received by the communication unit 101. Among them, the software identification information having the highest priority is extracted. The software activation unit 104 activates the software. As a result, even when there are a plurality of software candidates to be activated, the imaging editing software with higher priority is activated without being selected by the user, thereby shortening the time until the imaging editing software can be used. be able to. In addition, since the user does not have to select one imaging editing software from a plurality of imaging editing software, it is possible to eliminate the user's trouble of selecting the imaging editing software.

  When the imaging editing software with a certain priority (for example, the highest priority) is deleted, the software extraction unit 103d sequentially increments the imaging editing software with a lower priority than the deleted imaging editing software. Also good. Thereby, for example, even if the imaging editing software with the highest priority is deleted, the imaging editing software with the second highest priority is moved up to the first, so that the software extraction unit 103d has a plurality of imaging editing software at that time. The imaging editing software with the highest priority can be always extracted from the candidates.

<Modification 5>
Then, the modification 5 of 1st Embodiment is demonstrated. Compared to the imaging operation terminal 14 of the modification 4, the imaging operation terminal 15 of the modification 5 gives priority to each of the plurality of imaging editing software corresponding to the combination of the imaging module and the optical module based on a predetermined element. The processing given by is further added. FIG. 15 is a schematic block diagram illustrating a configuration of the imaging operation terminal 15 according to Modification 5 of the first embodiment. In addition, the same code | symbol is attached | subjected to the element which is common in FIG. 12 of the modification 4, and the specific description is abbreviate | omitted. The configuration of the imaging operation terminal 15 in the modification 5 is such that an operation unit 106e and a priority assigning unit 107 are added to the configuration of the imaging operation terminal 14 in the modification 4.

  For example, the user performs an operation of setting the ranking among the plurality of imaging editing software for each of the plurality of imaging editing software corresponding to the set of the imaging module and the optical module. For example, the operation unit 106 e receives an operation for specifying the order, and outputs the received operation to the priority order assignment unit 107. As a result, the priority level assigning unit 107 can determine the weight of each of the imaging editing software in accordance with the order specified by the user.

  The priority assigning unit 107 includes a plurality of imaging editing software indicated by the plurality of software identification information for a plurality of software identification information associated with each combination of the imaging module identification information and the optical module identification information in the storage unit 102d. Is determined based on a predetermined factor. Then, the priority level assigning unit 107 adds the determined priority level to the storage unit 102d in association with the software identification information that gives the priority level. Specifically, for example, the priority order assigning unit 107 additionally adds the determined priority order to the software identification information to which the priority order included in the software specifying information stored in the storage unit 102d is assigned. . Here, the predetermined element is at least one of the number of times the imaging editing software is activated, the designation of the ranking of the imaging editing software by the user, the usage history of the imaging editing software, and the installation time of the imaging editing software. In the present embodiment, as an example, the priority order assigning unit 107 includes the number of times of activation in the past or a certain period (here, as an example, the number of times the user has selected and activated the imaging editing software), the designation of the ranking by the user, The priority order is determined based on all of the history, installation time, and other factors. Details of the processing will be described later. Here, the other element is, for example, the usage time of the imaging / editing software, for example, the accumulated time of the usage time of the imaging / editing software for a certain period.

  The priority level assigning unit 107 determines the priority level before the software extraction unit 103d reads the software specifying information, and stores the determined priority level in association with the software identification information that gives the priority level. Stored in the unit 102d. The priority level assigning unit 107 may store the priority level determined and determined in the storage unit 102d at least before the time when the software extraction unit 103d extracts the software identification information. Further, for example, the priority assigning unit 107 determines the priority again at the same time as or after the update of the software specifying information stored in the storage unit 102d, and identifies the software included in the software specifying information stored in the storage unit 102d. The information may be additionally recorded in association with the determined priority order.

Details of the priority order determination process of the priority level assigning unit 107 will be described with reference to FIGS. 16 and 17.
FIG. 16 is a diagram showing an example of an element value and score conversion table for each element. In the table T6 in the figure, the number of activations and points within a certain period are associated with each other. For example, when the number of activations within a certain period is 30 or more, 20 points are associated. In this example, when the number of activations of “software 2” within a certain period is 30 or more, the priority level assigning unit 107 has a score of 20 for the number of activations for “software 2”. The adding unit 107 adds 20 to the “start count” column of the software identification information “software 2” in the table T11 of FIG.

  Note that the priority level assigning unit 107 may determine a score related to the number of activations for each imaging editing software with reference to the table T7 in FIG. In the table T7 in FIG. 16, the ranking and the score having the highest number of activations within a certain period are associated with each other. For example, a score of 20 is associated when the ranking of the number of activations within a certain period is first. In the case of this example, when the ranking of the number of activations within a certain period of “software 2” is first, the priority level assigning unit 107 has 20 points for the number of activations for “software 2”. The priority level assigning unit 107 adds 20 to the “start count” column of the software identification information “software 2” in the table T11 of FIG.

  In the table T8 of FIG. 16, the user designation order and the score are associated with each other. Here, the user designation order is a rank among a plurality of imaging editing software associated with each combination of imaging module identification information and optical module identification information, and is designated by the user for each of the plurality of imaging editing software. Shows the ranking. For example, when the user designation rank is 3rd, 10 points are associated. In this example, when the user designation rank of “software 2” is third, the priority level assigning section 107 has 10 points for the user designation rank for “software 2”. In the table T11 of FIG. 17, “10” is added to the column of “user designation order” whose software identification information is “software 2”.

  In the table T9 of FIG. 16, the installation time and the score are associated with each other. For example, when the imaging editing software is installed within the last 6 to 15 days, a score of 10 points is associated. In the case of this example, when the installation timing of “Software 2” is within the latest 6 to 15 days, the priority level assigning unit 107 has a score of 10 for the installation timing of “Software 2”. The granting unit 107 adds 10 to the “installation time” column of the software identification information “software 2” in the table T11 of FIG.

  In the table T10 of FIG. 16, the usage history and the score are associated with each other. For example, a score of 10 points is associated when the imaging editing software was used last time. In this example, when “software 2” was used last time, the priority level assigning unit 107 has a score of 10 for the usage history of the “software 2”. At T11, 10 is added to the “usage history” column of the software identification information “software 2”.

  FIG. 17 is an example of a table T11 generated by the priority level assigning unit 107 to determine the priority level of the imaging editing software. This table T11 is a table generated by the priority order assigning unit 107 for each set of imaging module identification information and optical module identification information. In the table T11, a set of software identification information, the number of times of activation, a user designation order, an installation time, a usage history, others, a total, and a priority order are shown. Here, the software identification information in the table T11 is software identification information stored in the storage unit 102d corresponding to a set of certain imaging module identification information and certain optical module identification information. The number of activations is a score determined by the priority order assigning unit 107 according to the number of activations. The user designation order is a score determined by the priority order assigning unit 107 according to the user designation order. The installation time is a score determined by the priority level assigning unit 107 according to the installation time. The usage history is a score determined by the priority order assigning unit 107 according to the usage history. Others are points determined by the priority level assigning unit 107 according to other items. The total is a score obtained by adding the points assigned according to the number of activations, the user designation order, the installation time, the usage history, and other items for each piece of software identification information by the priority order assigning unit 107. The priority order is the order assigned by the priority order assigning unit 107 in descending order of the total score.

  Next, an example of processing performed by the priority order assigning unit 107 will be described with reference to FIGS. 16 and 17. The priority level assigning unit 107 reads out a plurality of pieces of software identification information stored in the storage unit 102d corresponding to a set of certain imaging module identification information and certain optical module identification information. The priority level assigning unit 107 stores the read software identification information in the table T11 of FIG.

  The priority level assigning unit 107 counts the number of activations in a certain period in advance and holds the counted number of activations. For example, the priority level assigning unit 107 refers to the table T6 in FIG. 16 for each read software identification information, determines a score according to the number of activations for a certain period, and adds the determined score to the table T11 in FIG. .

  The priority level assigning unit 107 holds the user designation order received by the operation unit 106e. Here, the user designation order is the order designated by the user for each imaging editing software. For example, the priority level assigning unit 107 determines a score corresponding to the user-specified order with reference to the table T8 in FIG. 16 for each read software identification information, and adds the determined score to the table T11 in FIG.

  For example, the priority order assigning unit 107 holds an installation date and time for each imaging editing software in advance. Then, for example, the priority order assigning unit 107 determines an installation time indicating how many days ago the installation was performed from the installation date and time and the current date and time for each imaging editing software. For example, the priority level assigning unit 107 determines a score according to the installation time with reference to the table T9 in FIG. 16 for each read software identification information, and adds the determined score to the table T11 in FIG.

  For example, the priority assigning unit 107 previously stores a usage history indicating whether the imaging / editing software was activated last time, activated two times before, or before the last time for each imaging / editing software. For example, the priority assigning unit 107 determines the score according to the use history with reference to the table T10 in FIG. 16 for each read software identification information, and additionally writes the determined score in the table T11 in FIG. For example, the priority level assigning unit 107 determines a score according to other items for each read software identification information, and adds the determined score to the table T11 of FIG.

  The priority level assigning unit 107 refers to the table T11 in FIG. 17 to determine the number of activations, the user designation order, the installation time, the usage history, and the points assigned to each of the other items as the software identification in the table T11 in FIG. Sum up for each piece of information. Then, the total score obtained by the addition is added to the table T11 in FIG. The priority level assigning unit 107 assigns higher priority levels in descending order of the total score, and adds the assigned priority levels to the table T11 in FIG. Thereby, the table T11 for a set of certain imaging module identification information and certain optical module identification information is completed. The priority level assigning unit 107 generates this table T11 for each set of imaging module identification information and optical module identification information.

  Note that the priority level assigning unit 107 does not overlap the priority levels in a plurality of imaging editing software corresponding to a set of certain imaging module identification information and certain optical module identification information. For example, when the scores overlap, the priority order assigning unit 107 assigns priorities using the order of installation of the imaging editing software, the order of 50 sounds, and the like. As a result, there is always one imaging editing software with the highest priority, so the software extraction unit 103d can always extract one imaging editing software.

  The priority level assigning unit 107 refers to a table generated for each set of imaging module identification information and optical module identification information, and sets the imaging module identification information and the optical module identification information stored in the storage unit 102d. Each of a plurality of corresponding software identification information is associated with a priority and added to the storage unit 102d.

FIG. 18 is a flowchart illustrating an example of a process flow of the imaging operation terminal according to Modification 5 of the first embodiment. The processing in steps S501 to S502 is the same as the processing in steps S201 to S202 in FIG.
(Step S503) Next, the priority level assigning unit 107 further assigns priorities to each of the plurality of software identification information corresponding to the set of the imaging module identification information and the optical module identification information stored in the storage unit 102d. Associating and adding to the storage unit 102d.
The processing in steps S504 to S507 is the same as the processing in steps S403 to S406 in FIG. Above, the process of this flowchart is complete | finished.

  As described above, in the modified example 5, the priority order assigning unit 107 determines the priority order of the imaging editing software to be activated in consideration of the number of times of activation, the designation order of the user, the installation time of the imaging editing software, the usage history of the imaging editing software, Since the imaging editing software with the highest priority is activated, it is possible to activate imaging editing software that the user prefers. As a result, it is possible to reduce the number of times that the user reselects the imaging / editing software, so that it is possible to reduce the user's trouble in selecting the imaging / editing software.

  The user may specify the size of the points stored in the tables T6 to T10 for each element. For example, in the table T6, the user operates the operation unit 106e and designates the score when the number of activations is 30 or more as 15 points, and the priority level assigning unit 107 of the imaging operation terminal 13 uses the designated number of points as the table. May be updated. Thereby, it is possible to make the priority order closer to the user's preference.

  Further, it may be specified which element is important or unnecessary by the user. In that case, the operation unit 106 e receives the designation of the user and outputs the accepted designation to the priority order assigning unit 107. The priority level assigning unit 107 may calculate the total score by multiplying the score assigned to each element by the weight according to the received designation and adding the weighted value. At that time, for example, when a certain element is designated as unnecessary, the weight may be set to 0, and when a certain element is determined to be important, the weight may be set to 2. As a result, the user's preference is more strongly reflected in the activated imaging editing software.

  In addition, although the priority provision part 107 determined the score with reference to the tables T6-T10, it is not restricted to this. For example, the priority level assigning unit 107 may tend to increase the score as the number of activations in the past or a certain period increases. Thereby, the imaging operation terminal 13 can improve the probability that the imaging editing software preferred by the user is activated by preferentially starting the imaging editing software that is activated more frequently by the user.

For example, the priority assigning unit 107 may tend to increase the score as the imaging editing software is used more recently. As a result, the imaging operation terminal 13 can be preferentially activated as the imaging editing software is used more recently, thereby improving the probability that the imaging editing software preferred by the user is activated.
Further, for example, the priority level assigning unit 107 may tend to increase the score as the installation time is closest. Thereby, the imaging operation terminal 13 can improve the probability that the imaging editing software preferred by the user is activated by preferentially starting the imaging editing software with the latest installation time.

Further, for example, the priority level assigning unit 107 may tend to increase the score as the accumulated time of the use time of the imaging editing software within a predetermined period is longer. Thereby, the imaging operation terminal 13 can improve the probability of starting the imaging editing software preferred by the user by starting the imaging editing software with a longer usage time preferentially.
Further, for example, the priority order assigning unit 107 may hold the usage time when the latest activation is performed for each imaging editing software, and may increase the score as the usage time when the latest activation is started is longer. Thereby, the imaging operation terminal 13 can improve the probability that the imaging editing software preferred by the user is activated by preferentially starting the imaging editing software that has been used for the longer time.

When the activation time is shorter than a predetermined time, the priority level assigning unit 107 may not count the activation as the number of activations.
In addition, when the software activation unit 104 activates the imaging editing software extracted by the software extraction unit 103d, but the user brings down the imaging editing software within a predetermined time from the activation, the priority giving unit In 107, the count value of the number of activations may be decreased by one.

<Modification 6>
Then, the modification 6 of 1st Embodiment is demonstrated. For example, the imaging operation terminal 16 of Modification 6 displays a list of names of a plurality of imaging editing software corresponding to imaging module identification information and optical module information according to the priority order associated with each software identification information. Then, the imaging operation terminal 16 of Modification 6 activates the imaging editing software selected by the user from the name of the imaging editing software displayed in the list.

  FIG. 19 is a schematic block diagram illustrating a configuration of the imaging operation terminal 16 according to Modification 6 of the first embodiment. In addition, the same code | symbol is attached | subjected to the element which is common in FIG. 15, and the specific description is abbreviate | omitted. In the configuration of the imaging operation terminal 16 in the modification 6, the software extraction unit 103d is changed to the software extraction unit 103f and the operation unit 106e is changed to the operation unit 106f with respect to the configuration of the imaging operation terminal 15 in the modification 5 of FIG. It has been changed.

  The software extraction unit 103f has the same function as that of the software extraction unit 103d of the fifth modification, but differs in the following points. The software extraction unit 103f reads a plurality of pieces of software identification information corresponding to the imaging module identification information and the optical module identification information received by the communication unit 101, and the priorities associated with the software identification information. For example, the software extraction unit 103f displays a list of imaging editing software names identified by the read software identification information according to the priority order. Specifically, for example, the software extraction unit 103f arranges the name of the imaging editing software identified by the read software identification information above the pull-down menu as the priority is higher, and pulls down the imaging editing software on the display unit 105 by pull-down. Display a list of names. The user can select the name of one imaging editing software from the names of the imaging editing software displayed in a list.

The operation unit 106f has the same function as the operation unit 106e, but further has the following functions. When the user performs an operation of selecting the name of one imaging / editing software from the names of the imaging / editing software displayed as a list, the operation unit 106f accepts the operation of the user, and the received operation information is the software extraction unit 103f. Output to.
The software extraction unit 103f selects the imaging editing software selected by the user based on the operation information input from the operation unit 106f, and outputs software identification information for identifying the selected imaging editing software to the software activation unit 104. Thereby, the software activation unit 104 can activate the imaging editing software selected by the user.

  For example, the software extraction unit 103f may display a list of the names of the imaging editing software on the display unit 105 so that the names of the imaging editing software identified by the read software identification information are arranged higher as the priority is higher. Good.

FIG. 20 is a flowchart illustrating an example of a process flow of the imaging operation terminal according to Modification 6 of the first embodiment. The processing in steps S601 to S604 is the same as the processing in steps S501 to S504 in FIG.
(Step S605) Next, the software extraction unit 103f reads a plurality of pieces of software identification information corresponding to the imaging module identification information and the optical module identification information received by the communication unit 101, and the priorities associated with the software identification information. .
(Step S606) Next, the software extraction unit 103f arranges the name of the imaging editing software identified by the read software identification information above the pull-down menu as the priority is higher, and the imaging editing software is pulled down on the display unit 105. Display a list of names.
(Step S607) Next, the operation unit 106f receives selection of imaging editing software by the user.
(Step S608) Next, the software extraction unit 103f selects the imaging editing software selected by the user, and the software activation unit 104 activates the imaging editing software selected by the user.
(Step S609) Next, the software activation unit 104 displays a screen of the activated imaging editing software. Above, the process of this flowchart is complete | finished.

  As described above, in Modification 6, the software extraction unit 103f arranges the name of the imaging editing software identified by the read software identification information above the pull-down menu as the priority is higher, and pulls down the imaging editing software on the display unit 105. Display a list of names. As a result, the software extraction unit 103f arranges and displays the name of the imaging editing software with higher priority in the upper part of the list display screen, thereby displaying the imaging editing software that the user is most likely to start. The user can easily select the imaging editing software, and the burden on the user can be reduced. Furthermore, the software extraction unit 103f displays the name of the imaging / editing software in a pull-down manner, thereby reducing the burden on the user interface operation when selecting the imaging / editing software. In addition, when the user selects imaging editing software to be activated from the imaging editing software displayed as a list on the display unit 105, it is possible to prevent the imaging editing software that is not intended by the user from being activated. As described above, in addition to the effect of the modification example 5, the imaging operation terminal 16 according to the modification example 6 can reduce the user's burden and suppress the activation of the imaging editing software unintended by the user.

<Modification 7>
Subsequently, Modification 7 of the first embodiment will be described. When the imaging operation terminal 17 according to the modified example 7 receives the imaging module identification information and the optical module identification information, the imaging operation terminal 17 updates the software specifying information held in advance.
FIG. 21 is a schematic block diagram illustrating a configuration of the imaging operation terminal 17 according to Modification 7 of the first embodiment. In addition, the same code | symbol is attached | subjected to the element which is common in FIG. 4, and the specific description is abbreviate | omitted. The configuration of the imaging operation terminal 17 in Modification 7 is such that an information update unit 108 is added to the configuration of the imaging operation terminal 11 in Modification 1 of FIG.

  The information update unit 108 acquires the imaging module identification information and the optical module identification information received by the communication unit 101. Then, the information update unit 108 updates the software specifying information stored in the storage unit 102. Here, the software identification information is information in which software identification information is associated with a set of imaging module identification information and optical module identification information. Specifically, the information update unit 108 updates at least one of the software identification information, the imaging module identification information, and the optical module identification information among the software identification information stored in the storage unit 102. For example, when the combination of the imaging module identification information and the optical module identification information received by the communication unit 101 is not stored in the software identification information in the storage unit 102, the combination of the imaging module identification information and the optical module identification information is specified by the software. Add to the information. As a result, the information update unit 108 can update the software specifying information stored in the storage unit 102 to the latest state. For example, the information update unit 108 performs this update from when the communication unit 101 acquires the imaging module identification information and the optical module identification information to when the software extraction unit 103 reads the software identification information.

  Note that the software extraction unit 103 may directly read the software identification information corresponding to the set of the imaging module identification information and the optical module identification information received by the communication unit 101b from the storage unit 102. In this case, for example, the information update unit 108 performs the update from when the communication unit 101 acquires the imaging module identification information and the optical module identification information to when the software extraction unit 103 reads the software identification information from the storage unit 102. You may go in between.

FIG. 22 is a flowchart illustrating an example of a processing flow of the imaging operation terminal 17 according to Modification 7 of the first embodiment. Since the processing of steps S701 to S702 is the same as the processing of steps S201 to S202, the description thereof is omitted.
(Step S703) Next, the information update unit 108 updates the software specifying information stored in the storage unit 102.
The processing in steps S704 to S707 is the same as the processing in steps S203 to S206 in FIG. Above, the process of this flowchart is complete | finished.

  As described above, in Modification Example 7, in addition to the effect of Modification Example 1, since the software identification information is updated before reading the software identification information, the latest software identification information is always used when using the imaging editing software. be able to.

<Modification 8>
Subsequently, Modification 8 of the first embodiment will be described. When the imaging operation terminal 18 of the modification 8 receives the imaging module identification information and the optical module identification information, the imaging operation terminal 18 detects whether the imaging editing software is added or deleted, and when the imaging editing software is added or deleted, Update the software identification information to be retained.

  FIG. 23 is a schematic block diagram illustrating a configuration of the imaging operation terminal 18 according to Modification 8 of the first embodiment. In addition, the same code | symbol is attached | subjected to the element which is common in FIG. 21, and the specific description is abbreviate | omitted. In the configuration of the imaging operation terminal 18 in the modification 8, the information update unit 108 is changed to the information update unit 108h, the operation unit 106h is added, and the configuration of the imaging operation terminal 17 in the modification 7 in FIG. A portion 109 is added.

  The detection unit 109 detects that imaging editing software has been newly installed in the own device, or that imaging editing software installed in the own device has been deleted. Specifically, for example, the detection unit 109 holds a list of imaging editing software that is installed in the apparatus in advance. For example, the detection unit 109 searches for imaging editing software installed in the own apparatus. For example, the detection unit 109 compares the list of imaging editing software obtained as a result of the search with the list of imaging editing software held in advance, and adds software to the list of imaging editing software held in advance. If there is a deletion, the user is inquired whether the added or deleted software is really imaging / editing software. Specifically, for example, the detection unit 109 causes the display unit 105 to display a screen for asking the user whether the added or deleted imaging editing software is imaging editing software. Accordingly, the user can answer whether or not the added or deleted software is imaging editing software.

The operation unit 106h accepts an operation indicating a user's answer to the question, and outputs operation information indicating the operation to the detection unit 109.
The detection unit 109 acquires a user's answer based on the operation information, and when the answer that the user's answer has been added or deleted is an imaging editing software, the item changed by the addition or deletion ( The information update unit 108h is notified of the change item). On the other hand, in a case where the software to which the user's answer has been added or deleted is not the imaging editing software, the detection unit 109 does not notify the information update unit 108h.
Then, the detection unit 109 updates the imaging editing software list in advance with the imaging editing software list obtained as a result of the search. By updating, the detection unit 109 can compare the imaging editing software list obtained at the previous search with the imaging editing software list obtained at the current search.

  The information update unit 108h has a function similar to that of the information update unit 108 of the modification example 7, but is different in the following points. When the detection unit 109 detects the addition of the imaging editing software, the information update unit 108h uses, for example, the change item input from the detection unit 109, and the communication unit in the software identification information stored in the storage unit 102 The update of associating software identification information for identifying the added imaging editing software with the set of imaging module identification information and optical module identification information received in 101 is performed. Here, the software identification information is information in which software identification information is associated with a set of imaging module identification information and optical module identification information. Thereby, when imaging editing software is added, the information updating unit 108h is added to the set of the imaging module 302 that is currently connected wirelessly and the optical module 301 that is mounted on the imaging module 302. Imaging editing software can be associated.

On the other hand, when the detection unit 109 detects the deletion of the imaging editing software, the information update unit 108h uses, for example, the change item input from the detection unit 109, in the software identification information stored in the storage unit 102. Software identification information for identifying imaging editing software deleted from its own device is deleted from all sets of imaging module identification information and optical module identification information. As a result, when the imaging editing software is deleted, the information updating unit 108h identifies the software of the imaging editing software deleted from the own apparatus for all the combinations of the imaging module and the optical module 301 in the software specifying information. Information can be deleted.
Note that when the detection unit 109 does not detect the addition or deletion of the imaging editing software, the information update unit 108h does not update the software specifying information.

  FIG. 24 is an example before and after the software identification information is changed. This is an example in the case where imaging editing software has been added on the left side as viewed in the drawing, and the imaging editing software has been deleted on the right side as viewed in the drawing. When the software identification information has the configuration of the table T12, the software identification information has the configuration of the table T13 when the addition of the constellation search software is detected during wireless connection with the high-sensitivity imaging module equipped with the wide-angle lens. . In the table T13, the added constellation search software is newly associated with the set of the high-sensitivity imaging module and the wide-angle lens.

  If the software specific information has the configuration of the table T14, and software deletion information is detected during wireless connection with the high-sensitivity imaging module with the wide-angle lens attached, the software specific information has the configuration of the table T15. In the table T15, the night view software deleted from the own apparatus is deleted from all sets of the imaging module identification information and the optical module identification information.

FIG. 25 is a flowchart illustrating an example of a process flow of the imaging operation terminal 18 according to Modification 8 of the first embodiment. The processing in steps S801 to S802 is the same as the processing in steps S201 to S202 in FIG.
(Step S803) Next, the detection unit 109 searches for imaging editing software in the own device, and acquires a list of software in the own device.
(Step S804) Next, the detection unit 109 determines whether there is software added or deleted from the list of imaging editing software held by the detection unit 109 in the list of imaging editing software in the own device obtained by the search. To determine. When the detection unit 109 determines that there is imaging editing software that has been added or deleted (YES), the detection unit 109 proceeds to the process of step S805. On the other hand, if the detection unit 109 determines that there is no added or deleted imaging editing software (NO), the process proceeds to step S808.

(Step S805) Next, the detection unit 109 inquires of the user whether the software added to or deleted from the current module set in the software specifying information is imaging editing software.
(Step S806) Next, the detection unit 109 determines whether or not the user has answered that the software added or deleted is imaging editing software. When the user replies that the added or deleted software is the imaging editing software (YES), the detection unit 109 proceeds to the process of step S807. When the user replies that the added or deleted software is not the imaging editing software (NO), the detection unit 109 proceeds to the process of step S808.

(Step S807) Next, the information update unit 108h updates the software specifying information. For example, when the detection unit 109 detects the addition of the imaging editing software, the information update unit 108 h uses, for example, the change item input from the detection unit 109, the communication in the software identification information stored in the storage unit 102. Update is performed for associating software identification information for identifying the added imaging editing software with the set of imaging module identification information and optical module identification information received by the unit 101. On the other hand, for example, when the detection unit 109 detects the deletion of the imaging editing software, the information update unit 108h uses, for example, the change item input from the detection unit 109, in the software identification information stored in the storage unit 102. The software identification information for identifying the imaging editing software deleted from the own apparatus is deleted from all sets of the imaging module identification information and the optical module identification information.
The processing in steps S808 to S811 is the same as the processing in steps S203 to S206 in FIG. Above, the process of this flowchart is complete | finished.

  As described above, in the imaging operation terminal 18 according to the modified example 8, when the detection unit 109 detects the addition or deletion of the imaging editing software, and the addition or deletion is detected, the software added or deleted to the user is the imaging editing software. Inquire whether or not. Then, when the user replies that it is imaging editing software, the information update unit 108h updates the software specifying information. Thus, even when imaging editing software is added or deleted, the information updating unit 108h can update the software specifying information only by answering whether or not the imaging editing software is imaging editing software. . Therefore, in addition to the effects of the first modification, the imaging operation terminal 18 according to the eighth modification can reduce the user's effort for changing the software specifying information.

  The information update unit 108h may update the software specifying information at an arbitrary timing designated by the user. The information updating unit 108h may update the software specifying information when the imaging editing software is added or deleted. In that case, the detection unit 109 and the information update unit 108h may perform the following processing. When the imaging editing software is added or deleted, the detection unit 109 may inquire of the user whether the added or deleted imaging editing software is imaging editing software. When the operation unit 106h receives a user operation indicating that the added or deleted imaging editing software is image-related imaging editing software, the detection unit 109 notifies the information update unit 108h of the change item. Good. Then, the information update unit 108h may update the update of the software identification information using the change item notified from the detection unit 109.

<Modification 9>
Subsequently, Modification 9 of the first embodiment will be described. When the imaging operation terminal 19 of the modification 9 receives the imaging module identification information and the optical module identification information, the imaging operation terminal 19 of the modification 9 includes the imaging module identification information or the optical module identification information in the held list. If there is not, software specifying information that holds the set of the imaging module identification information and the optical module identification information is added.

  FIG. 26 is a schematic block diagram illustrating a configuration of the imaging operation terminal 19 according to Modification 9 of the first embodiment. In addition, the same code | symbol is attached | subjected to the element which is common in FIG. 21, and the specific description is abbreviate | omitted. The configuration of the imaging operation terminal 19 in the modification 9 is different from the configuration of the imaging operation terminal 17 in the modification 7 of FIG. 21 in that the information update unit 108 is changed to the information update unit 108i, and the operation unit 106i and the detection unit 109i are changed. It has been added.

  The detection unit 109i acquires the imaging module identification information and the optical module identification information received by the communication unit 101. The detection unit 109i detects that at least one of the imaging module identification information and the optical module identification information received by the communication unit 101 is not present in the imaging module identification information and the optical module identification information stored in the storage unit 102. .

  Next, a specific example of the detection process of the detection unit 109i will be described. For example, the detection unit 109i holds an imaging module registration list that is a list of imaging modules identified by imaging module identification information stored in the storage unit 102 in advance. For example, the detection unit 109i holds an optical module registration list that is a list of optical modules identified by the optical module identification information stored in the storage unit 102 in advance. For example, the detection unit 109i identifies the imaging module identification information received by the communication unit 101b, determines whether or not the imaging module specified by the identification is in the imaging module registration list, and if not, the imaging module identification information is included in the change item. Add For example, the detection unit 109i identifies the optical module identification information received by the communication unit 101b, determines whether or not the optical module specified by the identification is in the optical module registration list, and if not, the optical module identification information is included in the change item. Add Then, the detection unit 109i notifies the information update unit 108i of the change item.

When the detection unit 109i detects imaging module identification information or optical module identification information that is not stored in the storage unit 102, the information update unit 108i detects the imaging module identification information included in the software specifying information stored in the storage unit 102. In addition, the set of the imaging module identification information and the optical module identification information received by the communication unit 101 is added to the set of the optical module identification information. Specifically, for example, the information update unit 108 i appends the set of the imaging module identification information and the optical module identification information received by the communication unit 101 to the software specifying information stored in the storage unit 102. In this case, for example, the information update unit 108i sets the software identification information corresponding to the set of the imaging module identification information and the optical module identification information to be blank.
On the other hand, the information updating unit 108 i does not update the software specifying information when the detection unit 109 i detects neither the imaging module identification information nor the optical module identification information that is not stored in the storage unit 102.

FIG. 27 is a flowchart illustrating an example of a process flow of the imaging operation terminal 19 according to Modification 9 of the first embodiment. The processing in steps S901 to S902 is the same as the processing in steps S201 to S202 in FIG.
(Step S903) Next, the detection unit 109i determines whether any of the connected imaging module and the optical module attached to the imaging module is registered in the imaging module registration list or the optical module registration list, respectively. To determine. If not registered (YES), the detection unit 109i proceeds to step S904 if not registered in the imaging module registration list, and proceeds to step S905 if not registered in the optical module registration list. On the other hand, if registered (NO), the detection unit 109i proceeds to step S906.

  (Step S904) The information updating unit 108i adds a set of the imaging module identification information and the optical module identification information received by the communication unit 101 to the software specifying information. As a result, a set of imaging module identification information for identifying the imaging module to which the communication unit 101b is currently connected and optical module identification information for identifying the optical module to which the imaging module is mounted is added to the storage unit 102. In addition, the detection unit 109i adds the currently connected imaging module to the imaging module registration list.

  (Step S905) The information update unit 108i adds a set of the imaging module identification information and the optical module identification information received by the communication unit 101 to the software specifying information. As a result, a set of imaging module identification information for identifying the imaging module to which the communication unit 101 is currently connected and optical module identification information for identifying the optical module to which the imaging module is mounted is added to the storage unit 102. In addition, the detection unit 109i adds the optical module to which the currently connected imaging module is attached to the optical module registration list.

(Step S906) Next, the software extraction unit 103 reads the software specifying information stored in the storage unit 102.
(Step S907) Next, since there is no software identification information corresponding to the combination of the imaging module identification information and the optical module identification information received by the communication unit 101, the software extraction unit 103 selects default software.
(Step S908) Next, the software activation unit 104 activates default software.
(Step S909) Next, the display unit 105 displays a screen of default software activated by the software activation unit 104. Above, the process of this flowchart is complete | finished.

  As described above, in the imaging operation terminal 19 in Modification 9, the detection unit 109i has the imaging module identification information in which at least one of the imaging module identification information and the optical module identification information received by the communication unit 101 is stored in the storage unit 102. And the absence of the optical module identification information. Then, when the information update unit 108 i detects that the detection unit 109 i does not exist, the information update unit 108 i adds a set of imaging module identification information and optical module identification information received by the communication unit 101 to the storage unit 102. Thereby, even when at least one of the imaging module and the optical module is changed, the information update unit 108i additionally writes the imaging module identification information and the optical module identification information stored in the storage unit 102, and the user himself / herself module information. There is no need to add. Therefore, in addition to the effect of the first modification, the imaging operation terminal 19 according to the ninth modification can reduce the user's effort for changing the module information. Furthermore, since the imaging operation terminal 19 changes the module information and does not involve human intervention, an artificial change mistake can be prevented.

  Note that the detection unit 109i may cause the display unit 105 to display that the default software is activated when the imaging module identification information or the optical module identification information is not included in each registration list. Thereby, it is possible to notify the user that the default software is activated. Upon receiving this notification, the user may approve activation of default software or may instruct activation of arbitrary imaging editing software. In this case, the operation unit 106i accepts an operation related to the user's approval or an operation of a software start instruction, and outputs operation information indicating the accepted operation to the detection unit 109i. The detection unit 109i may cause the software activation unit 104 to activate default software when the operation information input from the operation unit 106i is an operation related to approval. On the other hand, the detection unit 109i may cause the software activation unit 104 to activate the specific imaging editing software when the operation information input from the operation unit 106i is an operation for instructing activation of the specific imaging editing software.

<Modification 10>
Then, the modification 10 of 1st Embodiment is demonstrated. The imaging operation terminal 19j of Modification 10 is a further modification of the imaging operation terminal 19 of Modification 9. When the imaging operation terminal 19j of Modification 10 receives the imaging module identification information and the optical module identification information, if the imaging module identification information or the optical module identification information is not in the held list, the imaging module identification information The imaging editing software suitable for the optical module identification information is retrieved from the external database and acquired.

FIG. 28 is a schematic block diagram illustrating a configuration of the imaging operation terminal 19 j according to Modification 10 of the first embodiment. In addition, the same code | symbol is attached | subjected to the element which is common in FIG. 26, and the specific description is abbreviate | omitted. The configuration of the imaging operation terminal 19 j in the modified example 10 is changed from the configuration of the imaging operation terminal 19 in the modified example 9 of FIG. The detection unit 109i is changed to the detection unit 109j.

  At least one of the imaging module identified by the imaging module identification information received by the communication unit 101 and the optical module identified by the optical module identification information is not registered in the imaging module registration list or the optical module registration list. If so, do the following: The detection unit 109j searches for imaging editing software corresponding to an imaging module or an optical module that is not registered from an external database (hereinafter referred to as an external database). When the corresponding imaging editing software is not found by the search, the detection unit 109j notifies the information updating unit 108j of the imaging module identification information and the optical module identification information received by the communication unit 101 as change items.

On the other hand, when the corresponding imaging editing software is found by the search, the detection unit 109j causes the display unit 105 to display a question as to whether the user can install the corresponding software. As a result, the user can be inquired whether to install the corresponding software.
The operation unit 106i accepts an operation related to an answer to the question, and outputs operation information indicating the accepted operation to the detection unit 109j. When the operation information input from the operation unit 106j is accepted, the detection unit 109j downloads and installs the imaging editing software. Then, the detection unit 109j notifies the information update unit 108j of the software identification information for identifying the software found by the search and the imaging module identification information and the optical module identification information received by the communication unit 101b as change items.
On the other hand, in the case of an operation indicating that the operation information input from the operation unit 106j is not accepted, the detection unit 109j, for example, the imaging module received by the communication unit 101 without downloading or installing the imaging editing software found by searching. The identification information and the optical module identification information are notified to the information updating unit 108j as change items.

  The information update unit 108j updates the software specifying information so as to correspond to the change item notified from the detection unit 109j. Specifically, for example, when the imaging editing software found by the detection unit 109j is installed, the information update unit 108j includes the imaging module identification information and the optical module identification information included in the change item input from the detection unit 109j. Is added to the software specifying information in the storage unit 102 in association with the software identification information included in the change item input from the detection unit 109j.

  When the detection unit 109j cannot find the imaging editing software by the search, or when the operation unit 106j receives an operation not accepting the installation of the imaging editing software found by the search, the information update unit 108j A set of imaging module identification information and optical module identification information included in the change item input from is added to the software identification information, but the software identification information is associated with the set of imaging module identification information and optical module identification information. The software identification information is left blank.

FIG. 29 is a flowchart illustrating an example of a process flow of the imaging operation terminal 19j according to Modification 10 of the first embodiment. The processing in steps S1001 to S1002 is the same as the processing in steps S201 to S202 in FIG.
(Step S1003) Next, the detection unit 109j determines whether any of the connected imaging module and the optical module attached to the imaging module is registered in the imaging module registration list or the optical module registration list, respectively. To determine. If not registered (YES), the detection unit 109j proceeds to step S1004 if not registered in the imaging module registration list, and proceeds to step S1005 if not registered in the optical module registration list. On the other hand, if registered (NO), the detection unit 109j proceeds to step S1011.

  (Step S1004) The information update unit 108j appends the set of the imaging module identification information and the optical module identification information received by the communication unit 101b to the software specifying information. As a result, a set of imaging module identification information for identifying the imaging module to which the communication unit 101 is currently connected and optical module identification information for identifying the optical module to which the imaging module is mounted is added to the storage unit 102. The detection unit 109j adds the currently connected imaging module to the imaging module registration list.

  (Step S1005) The information update unit 108j appends the set of the imaging module identification information and the optical module identification information received by the communication unit 101 to the software specifying information. As a result, a set of imaging module identification information for identifying the imaging module to which the communication unit 101 is currently connected and optical module identification information for identifying the optical module to which the imaging module is mounted is added to the storage unit 102. In addition, the detection unit 109j adds the optical module to which the currently connected imaging module is attached to the optical module registration list.

  (Step S1006) Next, the detection unit 109j searches whether there is imaging editing software corresponding to the imaging module and optical module currently connected to the external database. When the corresponding imaging editing software exists (YES), the detection unit 109j proceeds to step S1007. If there is no corresponding imaging editing software (NO), the detection unit 109j proceeds to step S1011.

(Step S1007) The detection unit 109j inquires of the user whether or not the corresponding imaging editing software can be installed.
(Step S1008) Next, the detection unit 109j determines whether the user has approved the installation of the imaging editing software. When consenting (YES), the detection unit 109j proceeds to step S1009. If not approved (NO), the detection unit 109j proceeds to step S1011.
(Step S1009) Next, the detection unit 109j downloads and installs the corresponding imaging editing software.
(Step S1010) Next, the detection unit 109j identifies the imaging module identification information for identifying the currently connected imaging module and the optical module attached to the imaging module in the software specifying information stored in the storage unit 102. The software identification information for identifying the corresponding imaging editing software is additionally recorded in association with the pair of the optical module identification information.

(Step S1011) Next, the software extraction unit 103 reads the software specifying information stored in the storage unit 102.
(Step S1012) Next, the software extraction unit 103 stores the software identification information corresponding to the combination of the imaging module identification information and the optical module identification information received by the communication unit 101 in the storage unit 102. Extract from information.

(Step S1013) Next, the software activation unit 104 activates the imaging editing software identified by the software identification information extracted by the software extraction unit 103. At that time, if the software identification information corresponding to the combination of the imaging module identification information and the optical module identification information is not stored in the storage unit 102 and the software extraction unit 103 cannot extract the software identification information, The activation unit 104 activates default software.
(Step S1014) Next, the display unit 105 displays a screen of software activated by the software activation unit 104. Above, the process of this flowchart is complete | finished.

As described above, in the imaging operation terminal 19j according to Modification 10, the detection unit 109j has the imaging module identification information in which at least one of the imaging module identification information and the optical module identification information received by the communication unit 101b is stored in the storage unit 102. In addition, when it is detected that the optical module identification information is not present, the imaging module identification information that is not stored in the storage unit 102 or imaging editing software corresponding to the optical module identification information is extracted from the external database, and the extracted imaging Download and install editing software.
Accordingly, in the imaging operation terminal 19j in the modification 10, in addition to the effect of the modification 9, the detection unit 109j searches for and finds the corresponding imaging editing software, thereby reducing the user's trouble of searching for the imaging editing software. be able to.

<Second Embodiment>
Next, the second embodiment will be described. FIG. 30 is a schematic block diagram illustrating a configuration of the imaging operation terminal 20 according to the second embodiment. The imaging operation terminal 20 includes a communication unit 201, a storage unit 202, and a software extraction unit 203. The imaging editing software according to the second embodiment includes at least one of an imaging operation of an imaging module equipped with an optical module, an operation of an accessory used together with the imaging module, and an editing of an image obtained by the imaging module. It is software that does this.
When the communication unit 201 wirelessly receives imaging module identification information for identifying the imaging module and optical module identification information for identifying the optical module mounted on the imaging module, together with the imaging module. Receive accessory identification information identifying the accessory used. Here, the accessory is a module used together with the imaging module, and is, for example, a strobe (hereinafter also referred to as a flash), a pan head, a tripod, a finder, or a GPS (Global Positioning System) receiver. The communication unit 101 outputs the received imaging module identification information, optical module identification information, and accessory identification information to the software extraction unit 103.

  In the storage unit 202, for each combination of imaging module identification information for identifying an imaging module in which an optical module is mounted, the optical module identification information, and accessory identification information for identifying an accessory used with the imaging module, Software identification information associated with software identification information for identifying the imaging editing software is stored.

  The software extraction unit 203 extracts software identification information corresponding to the combination of the imaging module identification information, the optical module identification information, and the accessory identification information received by the communication unit 201 from the storage unit 202.

  FIG. 31 is a table T <b> 16 showing an example of software specifying information stored in the storage unit 202. Table T16 shows a set of imaging module identification information, optical module identification information, accessory identification information, and software identification information. For example, in the first row of the table T16, when the imaging module identification information is a high-sensitivity imaging module, the optical module identification information is a lens, and the accessory identification information is flash, image synthesis software and ISO management software correspond as software identification information. It is attached. The image composition software is composition software that synthesizes a night scene and a person, for example. The ISO management software is software for managing the ISO sensitivity of the imaging module or the F value of the optical module. In this example, when a combination of a high-sensitivity imaging module and a flash is used, since imaging is often performed in a dark place, image composition software and ISO management software that are likely to be used in imaging in a dark place are associated with each other. Yes. In the case of this example, when a flash and a lens are attached to the high-sensitivity imaging module, the software extraction unit 203 extracts image synthesis software and ISO management software. As a result, when the user uses a combination of a high-sensitivity imaging module and a flash, the software extraction unit 203 can extract image synthesis software and ISO management software suitable for shooting the combination. The effort of selecting software can be reduced.

  In the second row of the table T16, tracking software for tracking wild birds and animals is associated with the combination of the imaging module, the telephoto lens, and the electric camera platform. This is because there are many cases of observing wild birds and animals when the imaging module is panned or tilted using an electric camera platform while observing the distance with a telephoto lens. In the case of this example, when the telephoto lens and the electric camera platform are attached to the imaging module, the software extraction unit 203 extracts the tracking software. As a result, when the user uses a combination of a telephoto lens and an electric camera platform, the software extraction unit 203 can extract tracking software suitable for shooting the combination. Can be reduced.

  In the third row of the table T16, camera shake correction switching software for switching on / off of camera shake correction is associated with the imaging module, the lens, and the tripod. This is because when the tripod is connected to the imaging module, since the imaging module is fixed, an operation for turning off the camera shake correction process is often performed. Thereby, when a lens and a tripod are attached to the imaging module, the software extraction unit 203 extracts camera shake correction switching software. As a result, when the user uses a combination of the telephoto lens and the electric camera platform, the software extraction unit 203 can extract the camera shake correction switching software suitable for shooting the combination. Time and effort can be reduced.

FIG. 32 is a flowchart illustrating an example of a processing flow of the imaging operation terminal according to the second embodiment.
(Step S1101) First, the communication unit 201 establishes a wireless connection with an imaging module that is mounted with an optical module and can communicate with an accessory.
(Step S1102) First, the communication unit 201 selects imaging module identification information for identifying an imaging module, optical module identification information for identifying an optical module mounted on the imaging module, and accessories used together with the imaging module. Acquire accessory identification information from the imaging module.
(Step S1103) Next, the software extraction unit 203 reads the software specifying information stored in the storage unit 202.
(Step S1104) Next, the software extraction unit 203 extracts software identification information corresponding to the combination of the imaging module identification information, the optical module identification information, and the accessory identification information received by the communication unit 201 from the software identification information. Above, the process of this flowchart is complete | finished.

  As described above, in the imaging operation terminal 20 in the second embodiment, the software extraction unit 203 extracts the software identification information corresponding to the combination of the imaging module identification information, the optical module identification information, and the accessory identification information received by the communication unit 201. be able to. Thereby, since the imaging operation terminal 20 selects imaging editing software according to the combination of a module, an optical module, and an accessory, it can reduce a user's effort concerning selection of imaging editing software.

<Modification 1>
Subsequently, Modification 1 of the second embodiment will be described. FIG. 33 is a schematic block diagram illustrating the configuration of the imaging operation terminal 21 according to Modification 1 of the second embodiment. In addition, the same code | symbol is attached | subjected to the element which is common in FIG.4 and FIG.30, and the specific description is abbreviate | omitted. In the configuration of the imaging operation terminal 21 in Modification 1, the communication unit 201 is changed to the communication unit 201 with respect to the configuration of the imaging operation terminal 20 in the second embodiment in FIG. 30, and the software activation unit 104 and the display unit 105 are changed. And are added. The software activation unit 104 and the display unit 105 are the same as the software activation unit 104 and the display unit 105 in FIG.

  As an example, the imaging module 302 is mounted with an optical module 301. The optical module 301 includes, for example, an electrically rewritable nonvolatile memory (not shown), and optical module identification information for identifying the optical module 301 is stored in advance. The imaging module 302 is provided with an attachment / detachment detection switch (not shown) near the mount opening in the imaging module 302, for example, and detects the mounting state of the optical module 301 and the imaging module 302. When the mounting of the optical module 301 is detected, the imaging module 302 supplies power to the optical module 301 via a contact (not shown) of the imaging module 302 and a contact (not shown) of the optical module 301. When the optical module 301 is supplied with power, the optical module identification information stored in the non-volatile memory is transmitted to the imaging module 302 via a contact (not shown) included in the optical module 301. Thereby, the imaging module 302 acquires the optical module identification information for identifying the optical module 301, and holds the acquired optical module identification information.

As an example, the accessory 303 holds accessory identification information for identifying itself. For example, the accessory 303 includes a communication unit (not shown), and the communication unit wirelessly transmits accessory identification information held by the accessory 303 to the imaging module 302. Thereby, the imaging module 302 acquires accessory identification information for identifying the accessory 303 and holds the acquired accessory identification information.
When the accessory 303 is electrically connected to the imaging module 302 via a communication contact, accessory identification information for identifying itself may be transmitted to the imaging module 302 by wire.
The imaging module 302 includes a communication unit (not shown), and the communication unit can wirelessly communicate with the communication unit 201 of the imaging operation terminal 22. For this reason, the imaging operation terminal 21 controls the accessory 303 via the imaging module 302.

  The communication unit 201 has the same function as the communication unit 101 in the second embodiment, but differs in the following points. The communication unit 201 establishes a wireless connection with the imaging module 302. When the wireless connection with the imaging module 302 is established, the communication unit 201 identifies imaging module identification information for identifying the imaging module 302 from the imaging module 302, and optical module identification information for identifying the optical module 301 mounted on the imaging module 302. Accessory identification information for identifying the accessory 303 is received wirelessly.

FIG. 34 is a flowchart illustrating an example of a process flow of the imaging operation terminal 21 according to the first modification of the second embodiment.
(Step S1201) First, the communication unit 201 establishes a wireless connection with the imaging module 302 to which the optical module 301 is attached and which can communicate with the accessory 303.
(Step S1202) First, the communication unit 201 identifies imaging module identification information for identifying the imaging module 302, optical module identification information for identifying an optical module mounted on the imaging module 302, and accessory identification for identifying the accessory 303. Information is acquired from the imaging module 302 wirelessly.
(Step S1203) Next, the software extraction unit 203 reads the software specifying information stored in the storage unit 202.

(Step S1204) Next, the software extraction unit 203 obtains software identification information corresponding to the combination of the imaging module identification information, the optical module identification information, and the accessory identification information received by the communication unit 201b from the software identification information. Extract.
(Step S1205) Next, the software activation unit 104 activates the imaging editing software identified by the software identification information extracted by the software extraction unit 203.
(Step S1206) Next, the display unit 105 displays the screen of the imaging editing software activated by the software activation unit 104. Above, the process of this flowchart is complete | finished.

  As described above, in the first modification, when wireless connection with the imaging module is established, accessory identification information is wirelessly received from the imaging module 302. Thereby, in addition to the effects of the second embodiment, an accessory (for example, a flash connected to a hot shoe) 303 that can be controlled from the imaging module 302 can be controlled. In addition, since the software activation unit 104 activates the imaging editing software extracted by the software extraction unit 203, when the imaging editing software is imaging operation software, the time required for imaging preparation can be reduced. Further, when the imaging editing software is editing software, the time required for image editing preparation can be shortened.

<Modification 2>
Then, the modification 2 of 2nd Embodiment is demonstrated. The imaging operation terminal 22 in Modification 2 of the second embodiment is different from Modification 1 in that it directly receives accessory identification information directly from the accessory 303b. FIG. 35 is a schematic block diagram illustrating a configuration of the imaging operation terminal 22 in Modification 2 of the second embodiment. Elements common to those in FIG. 33 are denoted by the same reference numerals, and a specific description thereof is omitted. The configuration of the imaging operation terminal 22 in Modification 2 is the same as that of the imaging operation terminal 21 in Modification 1 of the second embodiment in FIG. 33 except that the communication unit 201 is changed to the communication unit 201b. Yes.

  As an example, the imaging module 302 is mounted with an optical module 301. The accessory 303b is connected to the imaging module 302 in a wired or wireless manner, and is configured to communicate with the imaging module 302. The accessory 303b holds accessory identification information (for example, a MAC address) for identifying itself. The accessory 303b includes a communication unit (not shown), and the communication unit wirelessly transmits accessory identification information for identifying the accessory 303b to the communication unit 201b of the imaging operation terminal 22.

The communication unit 201b has the same function as the communication unit 201 in the first modification of the second embodiment, but differs in the following points. The communication unit 201b establishes a wireless connection with the accessory 303b in addition to the imaging module 302.
When the wireless connection with the imaging module 302 is established, the communication unit 201b receives imaging module identification information for identifying the imaging module 302 from the imaging module 302 and optical module identification information for identifying the optical module 301 mounted on the imaging module 302. Receive wirelessly. Further, when the wireless connection is established with the accessory 303b, the communication unit 201b wirelessly receives accessory identification information for identifying the accessory 303b.

As described above, in Modification 2, when the wireless connection with the accessory 303b is established, the communication unit 201b wirelessly receives accessory identification information for identifying the accessory 303b from the accessory 303b. Thereby, in addition to the effect of 2nd Embodiment, the imaging operation terminal 22 can control the accessory 303b which cannot be controlled from the imaging module 302 by radio | wireless.
In the present modification, the imaging module 302 acquires accessory identification information for identifying the accessory 303b from the accessory 303b, but the present invention is not limited to this. The imaging operation terminal 22 may display a screen for inputting accessory identification information of the accessory 303b connected to the imaging module 302 on the display unit 105 to inquire the user. In this case, the imaging operation terminal 22 may further include an operation unit, and the operation unit may acquire the accessory identification information by receiving an operation for inputting the accessory identification information by the user.

<Modification 3>
Subsequently, Modification 3 of the second embodiment will be described. The imaging operation terminal 23 in Modification 3 of the second embodiment is different from the imaging operation terminal 20 of the second embodiment in that the software specifying information to be held is updated. FIG. 36 is a schematic block diagram illustrating the configuration of the imaging operation terminal 23 according to Modification 3 of the second embodiment. Elements common to those in FIG. 33 are denoted by the same reference numerals, and a specific description thereof is omitted. The configuration of the imaging operation terminal 23 in Modification 3 is changed from the configuration of the imaging operation terminal 21 in Modification 1 of the second embodiment of FIG. 33 in that the communication unit 201 is changed to the communication unit 201c, and the user's operation is changed. A receiving operation unit 206, an information update unit 208, and a detection unit 209 are added.

The communication unit 201c has the same function as the communication unit 201, but differs in the following points. The communication unit 201c further outputs the received imaging module identification information, optical module identification information, and accessory identification information to the detection unit 209.
The detection unit 209 detects that accessory identification information that is not stored in the storage unit 202 is wirelessly received by the communication unit 201c. For example, the detection unit 209 holds an accessory registration list that is a list of accessories in advance. Based on the accessory identification information output from the communication unit 201c, the connected accessory is identified and compared with the stored accessory registration list. When the connected accessory is not registered in the accessory registration list, accessory identification information for identifying the accessory is output to the information updating unit 208 as a change item.

  The information update unit 208 adds the accessory identification information indicated by the change item input from the detection unit 209 to the software specification information while leaving the information in the software specification information stored in the storage unit 202 in advance. Hereinafter, an example of detailed processing of the information update unit 208 will be described with reference to FIG.

  FIG. 37 is a diagram for explaining a process in which software specifying information is updated by the information updating unit 208. In the figure, a table T17 indicating software specifying information before the information update unit 208 changes is shown. In addition, a table T18 indicating the software specifying information after the information update unit 208 has changed is shown. Here, the information in the third row is added to the table 18 after the change compared to the table T17 before the change. In the third line, for the high-sensitivity imaging module and wide-angle lens, a pan head is added as accessory identification information in addition to the flash, and the software identification information is not a night view software but a constellation search software and a pan head control software. Yes.

As described above, when the imaging module 302 is a high-sensitivity imaging module, the optical module 301 is a wide-angle lens, the accessory 303 is a flash, and when a pan head is added as another accessory, the information update unit 208 displays the table. A new row is added to T17, and a set in which the imaging module identification information is a high-sensitivity imaging module, the optical module identification information is a wide-angle lens, and the accessory identification information is a flash and a camera platform is generated. Further, the information updating unit 208 sets software identification information in the constellation search software and the pan head control software for the combination of these modules and accessories. Default software may be set. In addition, the operation unit 206 may accept and set an arbitrary imaging editing software selection operation from the user.
In this way, the additional accessory is added to the current module combination, and the software specifying information (for example, information on the second line of the table T18) before the accessory addition is also left.

  As described above, in Modification 3, the detection unit 209 detects that accessory identification information that is not stored in the storage unit 202 has been received by the communication unit 201b. The information update unit 208 updates the accessory identification information stored in the storage unit 202 when the detection unit 209 detects it. Thereby, in addition to the effect of the second embodiment, even when a new accessory is used, the accessory identification information in the software identification information is updated by the information updating unit 208, and the user himself identifies the accessory identification in the software identification information. Since it is not necessary to update information, it is possible to reduce the time and effort of the user for adding accessories.

  When the software extraction unit 203 extracts two pieces of software identification information, the software activation unit 104 may activate imaging editing software identified by the two software identification information. For example, the software activation unit 104 may activate imaging operation software and accessory operation software at the same time. Accordingly, the user can operate the imaging module 302 and the accessory 303 separately or operate in cooperation with each other.

  By recording a program for executing each process of the imaging operation terminal of each embodiment on a computer-readable recording medium, causing the computer system to read and execute the program recorded on the recording medium, You may perform the various process mentioned above which concerns on an imaging operation terminal.

  Here, the “computer system” may include an OS and hardware such as peripheral devices. Further, the “computer system” includes a homepage providing environment (or display environment) if a WWW system is used. The “computer-readable recording medium” means a flexible disk, a magneto-optical disk, a ROM, a writable nonvolatile memory such as a flash memory, a portable medium such as a CD-ROM, a hard disk built in a computer system, etc. This is a storage device.

  Further, the “computer-readable recording medium” means a volatile memory (for example, DRAM (Dynamic) in a computer system which becomes a server or a client when a program is transmitted through a network such as the Internet or a communication line such as a telephone line. Random Access Memory)) that holds a program for a certain period of time is also included. The program may be transmitted from a computer system storing the program in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. Here, the “transmission medium” for transmitting the program refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line. The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, and what is called a difference file (difference program) may be sufficient.

  As mentioned above, although embodiment of this invention was explained in full detail with reference to drawings, a specific structure is not restricted to this embodiment. Each configuration in each embodiment, a combination thereof, and the like are examples, and the addition, omission, replacement, and other changes of the configuration can be made without departing from the spirit of the present invention. Further, the present invention is not limited by the embodiments, and is limited only by the scope of the claims.

10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 19j, 20, 21, 22, 23 Imaging operation terminal 101, 101c, 201, 201b, 201c Communication unit 102, 102b, 102c, 102d , 202 Storage unit 103, 103b, 103c, 103d, 103f, 203 Software extraction unit 104 Software activation unit 105 Display unit 106, 106e, 106f, 106h, 106i, 106j, 206 Operation unit 107 Priority assignment unit 108, 108h, 108i , 108j, 208 Information update unit 109, 109i, 109j, 209 Detection unit 301, 311 Optical module 302, 312 Imaging module 303, 303b Accessories

Claims (10)

Used for photographing by a combination of the imaging module and the optical module, performing at least one of an operation related to imaging of the imaging module equipped with the optical module and editing of an image obtained by the imaging module. A storage unit in which software identification information for identifying imaging imaging software with high possibility is stored for each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module;
Communication that wirelessly receives imaging module identification information for identifying the imaging module from the imaging module and optical module identification information for identifying the optical module mounted on the imaging module when wireless connection is established with the imaging module And
A software extraction unit that extracts software identification information corresponding to a combination of the imaging module identification information and the optical module identification information received by the communication unit from the storage unit;
Equipped with a,
The storage unit is an imaging operation terminal that stores the software identification information that identifies the imaging editing software that is highly likely to be used when capturing an imaging target estimated by a combination of the imaging module and the optical module . Used for photographing by a combination of the imaging module and the optical module, performing at least one of an operation related to imaging of the imaging module equipped with the optical module and editing of an image obtained by the imaging module. A storage unit in which software identification information for identifying imaging imaging software with high possibility is stored for each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module;
Communication that wirelessly receives imaging module identification information for identifying the imaging module from the imaging module and optical module identification information for identifying the optical module mounted on the imaging module when wireless connection is established with the imaging module And
A software extraction unit that extracts software identification information corresponding to a combination of the imaging module identification information and the optical module identification information received by the communication unit from the storage unit;
With
The storage unit stores the software identification information for identifying the imaging editing software that is likely to be used when shooting in a surrounding state at the time of shooting estimated by a combination of the imaging module and the optical module. that an imaging operation terminal. In the storage unit, accessory identification information for identifying an accessory used together with the imaging module is stored in association with the set of the imaging module identification information, the optical module identification information, and the software identification information. ,
The communication unit further receives accessory identification information for identifying an accessory used together with the imaging module when receiving the imaging module identification information and the optical module identification information wirelessly,
Wherein the software extraction unit, according to claim 1 or claim extracts the software identification information corresponding to the combination of said imaging module identification information received by the communication unit and said optical module identification information the accessory identification information from the storage unit imaging operation terminal according to 2. In the storage unit, the accessory identification information for identifying at least one of a camera platform and a tripod is stored in association with the set of the imaging module identification information, the optical module identification information, and the software identification information. The imaging operation terminal according to claim 3 . An imaging system comprising an imaging module on which an optical module is mounted, and an imaging operation terminal for operating the imaging module,
The imaging operation terminal is
Used for photographing by a combination of the imaging module and the optical module, performing at least one of an operation related to imaging of the imaging module equipped with the optical module and editing of an image obtained by the imaging module. A storage unit in which software identification information for identifying imaging imaging software with high possibility is stored for each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module;
Communication that wirelessly receives imaging module identification information for identifying the imaging module from the imaging module and optical module identification information for identifying the optical module mounted on the imaging module when wireless connection is established with the imaging module And
A software extraction unit that extracts software identification information corresponding to a combination of the imaging module identification information and the optical module identification information received by the communication unit from the storage unit;
Equipped with a,
The storage system stores the software identification information for identifying the imaging editing software that is likely to be used when shooting a shooting target estimated by a combination of the imaging module and the optical module . An imaging system comprising an imaging module on which an optical module is mounted, and an imaging operation terminal for operating the imaging module,
The imaging operation terminal is
Used for photographing by a combination of the imaging module and the optical module, performing at least one of an operation related to imaging of the imaging module equipped with the optical module and editing of an image obtained by the imaging module. A storage unit in which software identification information for identifying imaging imaging software with high possibility is stored for each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module;
Communication that wirelessly receives imaging module identification information for identifying the imaging module from the imaging module and optical module identification information for identifying the optical module mounted on the imaging module when wireless connection is established with the imaging module And
A software extraction unit that extracts software identification information corresponding to a combination of the imaging module identification information and the optical module identification information received by the communication unit from the storage unit;
With
The storage unit stores the software identification information for identifying the imaging editing software that is likely to be used when shooting in a surrounding state at the time of shooting estimated by a combination of the imaging module and the optical module. Imaging system. Used for photographing by a combination of the imaging module and the optical module, performing at least one of an operation related to imaging of the imaging module equipped with the optical module and editing of an image obtained by the imaging module. An imaging operation terminal including a storage unit in which software identification information for identifying imaging imaging software having a high possibility is stored for each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module Is an imaging operation method executed by
When the communication unit establishes a wireless connection with the imaging module, imaging module identification information for identifying the imaging module from the imaging module and optical module identification information for identifying the optical module mounted on the imaging module are wirelessly transmitted. The procedure to receive at
A procedure in which a software extraction unit extracts software identification information corresponding to a combination of the imaging module identification information and the optical module identification information received by the communication unit from the storage unit;
I have a,
A software extraction method for storing the software identification information for identifying the imaging editing software that is likely to be used when the imaging unit estimated by the combination of the imaging module and the optical module is captured by the storage unit . Used for photographing by a combination of the imaging module and the optical module, performing at least one of an operation related to imaging of the imaging module equipped with the optical module and editing of an image obtained by the imaging module. An imaging operation terminal including a storage unit in which software identification information for identifying imaging imaging software having a high possibility is stored for each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module Is an imaging operation method executed by
When the communication unit establishes a wireless connection with the imaging module, imaging module identification information for identifying the imaging module from the imaging module and optical module identification information for identifying the optical module mounted on the imaging module are wirelessly transmitted. The procedure to receive at
A procedure in which a software extraction unit extracts software identification information corresponding to a combination of the imaging module identification information and the optical module identification information received by the communication unit from the storage unit;
Have
The storage unit stores the software identification information for identifying the imaging editing software that is likely to be used when shooting in a surrounding state at the time of shooting estimated by a combination of the imaging module and the optical module. Software extraction method. Used for photographing by a combination of the imaging module and the optical module, performing at least one of an operation related to imaging of the imaging module equipped with the optical module and editing of an image obtained by the imaging module. An imaging operation terminal including a storage unit in which software identification information for identifying imaging imaging software having a high possibility is stored for each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module In addition,
Communication that wirelessly receives imaging module identification information for identifying the imaging module from the imaging module and optical module identification information for identifying the optical module mounted on the imaging module when wireless connection is established with the imaging module Steps,
The storage unit stores software identification information for identifying the imaging editing software that is highly likely to be used when imaging an imaging target estimated by a combination of the imaging module and the optical module, and in the communication step and software extracting the software identification information corresponding to the combination of the received the imaging module identification information and said optical module identification information from the storage unit,
A program for running Used for photographing by a combination of the imaging module and the optical module, performing at least one of an operation related to imaging of the imaging module equipped with the optical module and editing of an image obtained by the imaging module. An imaging operation terminal including a storage unit in which software identification information for identifying imaging imaging software having a high possibility is stored for each combination of imaging module identification information for identifying an imaging module and optical module identification information for identifying an optical module In addition,
Communication that wirelessly receives imaging module identification information for identifying the imaging module from the imaging module and optical module identification information for identifying the optical module mounted on the imaging module when wireless connection is established with the imaging module Steps,
The storage unit stores software identification information that identifies the imaging editing software that is likely to be used when shooting in a surrounding state at the time of shooting estimated by a combination of the imaging module and the optical module; A software extraction step for extracting the software identification information corresponding to the combination of the imaging module identification information and the optical module identification information received in the communication step from the storage unit;
A program for running

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