JP2018060229A - Information processing device, information processing method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow a user to intuitively set plural imaging parameters when the user sets the imaging parameters by using plural setting images.SOLUTION: An information processing device comprises: a controller unit which performs control to associate a first setting image for setting a first imaging parameter relating to imaging with a second setting image for setting a second imaging parameter relating to imaging and display them; and an input operation unit which allows input operation for setting the first imaging parameter and the second imaging parameter.SELECTED DRAWING: Figure 1

Description

  The present disclosure relates to an information processing apparatus, an information processing method, and a program.

  Patent Document 1 discloses a technique for displaying a graph for setting a shutter speed and an aperture value.

JP 2006-178015 A

  However, Patent Document 1 discloses nothing about setting a plurality of imaging parameters using a plurality of setting images.

  On the other hand, when a user sets a plurality of imaging parameters using a plurality of setting images, it has been desired that the user can intuitively set these imaging parameters.

  According to the present disclosure, the control for displaying the first setting image for setting the first imaging parameter relating to imaging and the second setting image for setting the second imaging parameter relating to imaging in association with each other is displayed. An information processing apparatus is provided that includes a control unit that performs an input operation unit that can perform an input operation for setting a first imaging parameter and a second imaging parameter.

  According to the present disclosure, the control for displaying the first setting image for setting the first imaging parameter relating to imaging and the second setting image for setting the second imaging parameter relating to imaging in association with each other is displayed. There is provided an information processing method including performing and setting a first imaging parameter and a second imaging parameter according to an input operation.

  According to the present disclosure, the first setting image for setting the first imaging parameter related to imaging and the second setting image for setting the second imaging parameter related to imaging are displayed in association with each other on the computer. There is provided a program for realizing a control function for performing control and an input operation function capable of performing an input operation for setting the first imaging parameter and the second imaging parameter.

  According to the present disclosure, the first setting image for setting the first imaging parameter and the second setting image for setting the second imaging parameter are displayed in association with each other. Therefore, the user can set a plurality of imaging parameters while visually recognizing a plurality of setting images associated with each other.

As described above, according to the present disclosure, when setting a plurality of imaging parameters using a plurality of setting images, the user can intuitively grasp the relevance of these imaging parameters. These imaging parameters can be set intuitively. In addition, the effect by the technique which concerns on this indication is not limited to the effect described here. The technology according to the present disclosure may have any of the effects described in the present specification or other effects.

1 is a block diagram illustrating a configuration of an information processing device according to a first embodiment of the present disclosure. It is a hardware block diagram of the information processing apparatus which concerns on the embodiment. It is a flowchart which shows the procedure of the process by information processing apparatus. It is explanatory drawing which shows the example of a display by information processing apparatus. It is explanatory drawing which shows the example of a display by information processing apparatus. It is explanatory drawing which shows the example of a display by information processing apparatus. It is explanatory drawing which shows the example of a display by information processing apparatus. It is explanatory drawing which shows the example of a display by information processing apparatus. It is explanatory drawing which shows the example of a display by information processing apparatus. It is explanatory drawing which shows the example of a display by information processing apparatus. It is explanatory drawing which shows the example of a display by information processing apparatus. It is explanatory drawing which shows the example of a display by information processing apparatus. It is explanatory drawing which shows the example of a display by information processing apparatus. It is explanatory drawing which shows the example of a display by information processing apparatus. It is explanatory drawing which shows the example of a display by information processing apparatus. It is explanatory drawing which shows the example of a display by information processing apparatus. It is explanatory drawing which shows the example of a display by information processing apparatus. It is explanatory drawing which shows the example of a display by information processing apparatus. It is explanatory drawing which shows the example of a display by information processing apparatus. It is an appearance figure showing the composition of the information processing system concerning a 2nd embodiment of this indication. It is a block diagram which shows the structure of the imaging device which concerns on the same embodiment. It is a hardware block diagram of an imaging device.

  Hereinafter, preferred embodiments of the present disclosure will be described in detail with reference to the accompanying drawings. In addition, in this specification and drawing, about the component which has the substantially same function structure, duplication description is abbreviate | omitted by attaching | subjecting the same code | symbol.

The description will be made in the following order.
1. First embodiment (an example in which an information processing apparatus performs imaging and display)
1-1. Overview of processing by information processing apparatus 1-2. Configuration of information processing apparatus 1-3. Processing by information processing apparatus 1-4. Various display examples Second Embodiment (Example in which an information processing apparatus performs display and an imaging apparatus performs imaging)
2-1. Overall configuration of information processing system 2-2. Configuration of imaging apparatus 2-3. Procedure of information processing system

<1. First Embodiment>
(1-1. Overview of processing by information processing apparatus)
The information processing apparatus 10 according to the first embodiment schematically includes a first setting image for setting a first imaging parameter for imaging and a second imaging parameter for setting a second imaging parameter for imaging. 2 setting images are displayed in association with each other.

  The first imaging parameter includes, for example, a shutter speed (Tv) and an aperture value (Av). The first setting image is, for example, an xy plane image (Tv / Av plane image) for collectively setting the shutter speed (Tv) and the aperture value (Av). The x axis (horizontal axis) indicates, for example, Tv, and the y axis (vertical axis) indicates, for example, Av. The user can set a combination of Tv value and Av value (Tv / Av value) by designating one point in the Tv / Av plane image.

  The second imaging parameter includes, for example, an ISO value. The second setting image is a bar image (ISO bar image) for setting the ISO value. Each point on the ISO bar image corresponds to the ISO value, and the user can set the ISO value by aligning the point on the ISO bar image with a predetermined reference line.

  Further, the information processing apparatus 10 displays the first setting image and the second setting image in association with each other. For example, the information processing apparatus 10 extends the above-described reference line from the Tv / Av plane image. Then, the information processing apparatus 10 intersects the ISO bar image with the reference line. More specifically, the information processing apparatus 10 intersects a portion corresponding to the optimum value (or initial value) of the ISO value in the ISO bar image with the reference line.

  It should be noted that the first imaging parameter and the second imaging parameter are not limited to the above example, and it is a matter of course that any parameter may be used as long as it is a parameter relating to imaging. That is, the present embodiment may be anything as long as a plurality of imaging parameters are set using a plurality of setting images. Examples of imaging parameters other than those described above include combinations of RGB (red, green, blue), combinations of saturation, brightness, and contrast (or sharpness, brightness, etc.).

  In the former case, for example, the first imaging parameter is RG, and the first setting image is an RG plane image (that is, a color space) for setting RG collectively. The second imaging parameter is B, and the second setting image is a B bar image for setting B. The contents of the RG plane image and the B bar image may be the same as those of the Tv / Av plane image and the ISO bar image.

  In the latter case, for example, the first imaging parameter is saturation and lightness, and the first setting image is an xy plane image (saturation / lightness plane image) for collectively setting the saturation and lightness. The second imaging parameter is contrast, and the second setting image is a contrast bar image for setting contrast. The contents of the saturation / brightness plane image and the contrast bar image may be the same as those of the Tv / Av plane image and the ISO bar image.

  In the combination of RGB and the combination of brightness, brightness, and contrast, the master-slave relationship of each parameter is not particularly limited. For example, RB may be set as the first imaging parameter. In the above example, there are a plurality of first imaging parameters, but there may be one. In this case, the first setting image may be the same as each bar image. In the following description, the first imaging parameter is Tv and Av, and the second imaging parameter is the ISO value.

(1-2. Configuration of information processing apparatus)
Next, the configuration of the information processing apparatus 10 according to the present embodiment will be described with reference to FIGS. 1 and 2.

  As illustrated in FIG. 1, the information processing apparatus 10 includes a storage unit 11, a communication unit 12, an imaging unit 13, a display unit 14, an operation unit (input operation unit) 15, and a control unit 16. The storage unit 11 is a program for causing the information processing apparatus 10 to realize the storage unit 11, the communication unit 12, the imaging unit 13, the display unit 14, the operation unit 15, and the control unit 16, and various image information (for example, Tv / Av). Planar images and ISO bar images) are stored.

  The communication unit 12 communicates with other information processing apparatuses. The imaging unit 13 performs imaging. Specifically, the imaging unit 13 outputs an image captured by the imaging device to the control unit 16 as a through image until the user performs an imaging operation (for example, pressing a shutter button (not shown)). When the user performs an imaging operation, the imaging unit 13 performs imaging according to the set values of the Tv / Av value and the ISO value (specifically, performs an operation such as releasing a shutter). Then, the imaging unit 13 outputs an image captured by the imaging element to the control unit 16 as a captured image.

  The display unit 14 displays various images such as the above-described Tv / Av plane image, ISO bar image, and captured image. The operation unit 15 is a touch panel, for example, and is disposed on the surface of the display unit 14. The operation unit 15 can perform various input operations by the user, for example, input operations for setting Tv, Av, and ISO values. The operation unit 15 outputs operation information related to the input operation performed by the user to the control unit 16. In addition to controlling the information processing apparatus 10 as a whole, the control unit 16 performs control to display a Tv / Av plane image and an ISO bar image in association with each other, and sets a Tv / Av value and an ISO value.

  The information processing apparatus 10 has the hardware configuration shown in FIG. 2, and the storage unit 11, the communication unit 12, the imaging unit 13, the display unit 14, the operation unit 15, and the control unit 16 are configured by these hardware configurations. Realized.

  That is, the information processing apparatus 10 includes a nonvolatile memory 101, a RAM 102, a communication device 103, an imaging device 104, a display 105, a touch panel 106, and a CPU 107 as hardware configurations.

  The nonvolatile memory 101 stores various programs and image information. Here, the program includes a program for causing the information processing apparatus 10 to realize the storage unit 11, the communication unit 12, the imaging unit 13, the display unit 14, the operation unit 15, and the control unit 16.

  The RAM 102 serves as a work area for the CPU 107. The communication device 103 communicates with other information processing devices. The imaging device 104 generates a captured image by performing imaging. The display 105 displays various image information. The display 105 may output audio information. The touch panel 106 accepts various input operations by the user.

  The CPU 107 reads and executes a program stored in the nonvolatile memory 101. Therefore, the CPU 107 reads out and executes the program stored in the nonvolatile memory 101, whereby the storage unit 11, the communication unit 12, the imaging unit 13, the display unit 14, the operation unit 15, and the control unit are added to the information processing apparatus 10. 16 is realized. That is, the CPU 107 can be a substantial operating subject of the information processing apparatus 10.

  Specifically, the information processing apparatus 10 is, for example, a smartphone, a smart tablet, or the like, but is not particularly limited as long as it satisfies the above requirements. For example, the information processing apparatus 10 may be an imaging apparatus having the above configuration. However, smartphones and smart tablets are preferable because the display screen is often wider than the imaging device. A specific example of the operation unit 15 is a touch panel, but may be another operation device. That is, there is no particular limitation as long as the Tv / Av plane image and the ISO bar image can be operated, and for example, a hard key such as a cross key or a dial may be used. However, a touch panel is preferable as a specific example of the operation unit 15. Further, in the operation using the hard key together, the user needs to perform image capturing while confirming the hard key, and thus the image capturing operation may be divided. For example, the user may need to confirm the confirmation of the hard key and the display on the display unit 14 separately.

(1-3. Processing procedure by information processing apparatus)
Next, a processing procedure by the information processing apparatus 10 will be described with reference to a flowchart shown in FIG.

  In step S <b> 10, the imaging unit 13 performs imaging and outputs a captured image obtained thereby to the control unit 16. The control unit 16 displays the captured image on the display unit 14 as a through image.

  In step S20, the control unit 16 displays the Tv / Av plane image and the ISO image superimposed on the through image. The control unit 16 may display another image superimposed on the through image. The control unit 16 may transparently display an image superimposed on the through image.

  In step S30, the control unit 16 performs display control of the Tv / Av image and the ISO image according to the input operation, and sets the Tv / Av value and the ISO value. Thereafter, the information processing apparatus 10 ends this process.

(1-4. Display example)
(1-4-1. First display example)
Next, a first display example by the information processing apparatus 10 will be described based on FIG. In the display example of FIG. 4, the imaging mode is set to the manual mode (M). The manual mode is a mode in which the user can arbitrarily select a Tv / Av value.

  As shown in FIG. 4, the control unit 16 captures the through image 1000, the display layer indicator 210, the Tv / Av plane image 300, the ISO bar image 400, the dial image 500, the focus mode selection image 600, and the imaging. A parameter display image 700 is displayed. Of these images, the display layer indicator 210, the dial image 500, the focus mode selection image 600, and the imaging parameter display image 700 can be omitted. Further, when the user is operating the Tv / Av plane image 300 or the ISO bar image 400, the control unit 16 deletes the display layer indicator 210, the dial image 500, the focus mode selection image 600, and the imaging parameter display image 700. May be. The imaging parameter display image 700 may be displayed when the user is operating the Tv / Av plane image 300 or the ISO bar image 400.

  The control unit 16 includes images to be superimposed on the through image 1000 (in the example of FIG. 4, the Tv / Av plane image 300, the ISO bar image 400, the dial image 500, the focus mode selection image 600, and the imaging parameter display image 700). A plurality of display layers may be produced. And the control part 16 displays the display layer indicator 210 which shows the display layer being displayed now, when a some display layer is produced. When the user performs a display layer switching operation (for example, an operation of flicking a finger in the left-right direction in FIG. 4), the control unit 16 switches the display layer to be displayed.

  In the dial image 500, a plurality of imaging mode symbols 510 indicating imaging modes are drawn along the circumferential direction, and among these imaging mode symbols 510, the leftmost imaging mode symbol 520 is highlighted. The imaging mode symbol 520 indicates the imaging mode currently set. That is, the control unit 16 rotates the dial image 500 according to the input operation by the user, and highlights the imaging mode symbol 520 displayed at the left end of the dial image 500. Then, the control unit 16 sets the current imaging mode to the imaging mode indicated by the imaging mode symbol 520. Examples of the input operation for rotating the dial image 500 include tapping a finger on the dial image 500 and moving the finger in the circumferential direction in that state. In the example of FIG. 4, the manual mode (M) is selected.

  In the focus mode selection image 600, a plurality of focus mode symbols 610 are drawn, and one of the focus mode symbols 620 is highlighted. A focus mode symbol 620 indicates the currently selected focus mode. For example, when the user taps one of the focus mode symbols 610, the control unit 16 highlights the tapped focus mode symbol 610 and shifts to the focus mode corresponding to the focus mode symbol 610. . The imaging parameter display image 700 displays imaging parameters (Tv / Av, ISO value, etc.) currently set.

  The Tv / Av plane image 300 is a plane image in which the horizontal axis 310 indicates Tv and the vertical axis 320 indicates Av. When the user taps any point on the Tv / Av plane image 300, the control unit 16 displays the point P1 at that point. Further, the control unit 16 sets the Tv / Av value to the Tv / Av value indicated by the point P1, and highlights the Tv / Av value indicated by the point P1 on the horizontal axis 310 and the vertical axis 320. In the example of FIG. 4, the Tv value is set to 1/250 and the Av value is set to 2.8. Here, since the current imaging mode is the manual mode, the control unit 16 does not limit the Tv / Av value. Therefore, the user can select (set) the Tv / Av value by tapping an arbitrary point on the Tv / Av plane image 300.

  Further, the control unit 16 displays a reference line 330 passing through the point P1 on the Tv / Av plane image 300. The Tv / Av value indicated by each point on the reference line 330 indicates the same exposure amount as that of the point P1. The reference line 330 is extended from the upper right end of the Tv / Av plane image 300 to the outside.

  When the user taps a point other than the point P1 while the point P1 is being displayed, the control unit 16 moves the point P1 to that point. Then, the control unit 16 sets the Tv / Av value to the Tv / Av value indicated by the point P1 after the movement. Further, the control unit 16 causes the reference line 330 to follow the new point P1.

  Note that the method of selecting (setting) the Tv / Av value by the user is not limited to the method of tapping a point on the Tv / Av plane image, and any method that can select a point on the Tv / Av plane image 300 can be used. Not limited. For example, the user may select a point on the Tv / Av plane image 300 by a drag and drop operation. For example, when the user drags the point P1, the control unit 16 causes the point P1 to follow the user's finger, and when the user drops the point P1, the control unit 16 displays the point P1 at that position. The control unit 16 may accept an operation using both tap and drag and drop. Then, the control unit 16 sets the Tv / Av value to the Tv / Av value indicated by the point P1 after the movement.

  The ISO bar image 400 is an image for selecting an ISO value. Each point on the length direction of the ISO bar image 400 indicates the ISO value, the upper end point 410 indicates the maximum ISO value, and the lower end point 420 indicates the minimum ISO value. In the example of FIG. 4, the maximum value is 16000 and the minimum value is 100, but the maximum value and the minimum value are not limited to these examples. The control unit 16 displays the maximum value display image 410 a near the upper end point 410 of the ISO bar image 400 and displays the minimum value display image 420 a near the lower end point 420.

  The control unit 16 displays the ISO bar image 400 in association with the Tv / Av plane image 300. Specifically, the control unit 16 displays the ISO bar image 400 at a position that intersects the reference line 330. More specifically, the control unit 16 sets the ISO value indicated by the point P2 where the ISO bar image 400 and the reference line 330 intersect as the set value of the ISO value. In other words, the control unit 16 intersects the point P2 corresponding to the set value of the ISO value and the reference line 330 in the ISO bar image 400. Further, the control unit 16 displays a set value display image 430 indicating the set value of the ISO value in the vicinity of the point P2.

  Furthermore, the control unit 16 moves the ISO bar image 400 in the direction of the arrow 400a or the arrow 400b in accordance with an input operation by the user. Examples of the input operation include a method of tapping the ISO bar image 400 with a finger and dragging the finger in the direction of the arrow 400a or the arrow 400b. As a result, the set value indicated by the point P2 also fluctuates, so the control unit 16 sets (changes) the ISO value to the set value indicated by the point P2.

  Further, when the reference line 330 moves, the control unit 16 causes the ISO bar image 400 to follow the reference line 330. Here, the control unit 16 may maintain the ISO value at the current value, or may change it to an optimum value (or a preset initial value) according to the changed Tv / Av value. The “optimum value” in the present embodiment means a value that the control unit 16 determines to be optimal. In the former case, the control unit 16 adjusts the position of the ISO bar image 400 so that the ISO value is maintained. That is, the position of the point P2 in the ISO bar image 400 is unchanged before and after the reference line 330 is moved. In the latter case, the control unit 16 calculates an optimum value of the ISO value according to the Tv / Av value, and sets the ISO value to the optimum value (or sets the preset initial value). Further, the control unit 16 adjusts the position of the ISO bar image 400 so that the point P2 indicates the optimum value (or initial value).

  In the initial state, that is, in the state where the image display shown in FIG. 4 is started, the control unit 16 calculates the optimum values of the Tv / Av value and the ISO value, and based on the optimum values, the position of the point P1, the reference line The position of 330 and the position of the ISO bar image 400 are adjusted.

  Note that the setting image (second setting image) for setting the ISO value is not limited to the bar image. For example, the second setting image may be a dial-shaped image. In this dial image, for example, the ISO value is drawn in the circumferential direction like the dial image 500. Then, the control unit 16 intersects any ISO value on the dial image with the reference line 330. The control unit 16 sets the ISO value intersecting with the reference line 330 as a set value.

  Further, the control unit 16 may change the through image 1000 according to the current Tv / Av value and ISO value. For example, the control unit 16 may perform processing such as blurring or flowing the through image 1000 according to the current Tv / Av value and ISO value. In this case, the user can easily grasp how the through image 1000 varies according to the current Tv / Av value and ISO value.

  Note that the control unit 16 may reset or maintain the set values of the Tv / Av value and the ISO value for each imaging operation.

  Further, the control unit 16 may perform the following processing when the imaging mode is set to the auto mode (a mode in which the Tv / Av value and the ISO value are automatically set). That is, the control unit 16 calculates the optimum value of the Tv / Av value and the ISO value every time the user performs a preliminary operation of the imaging operation (for example, an operation of pressing the imaging button halfway), and the point P1, The positions of the reference line 330 and the ISO bar image 400 may be dynamically changed. Thereby, the user can easily grasp how the Tv / Av value and the ISO value fluctuate for each imaging scene, for example. Thereby, for example, a beginner user and a high amateur user can understand the mechanism of the imaging device graphically. As a result, it is expected that beginner users and high-age amateur users are interested in the Tv / Av value and the ISO value, and as a result, are willing to change these imaging parameters themselves.

  According to the first display example, since the Tv / Av plane image 300 and the ISO bar image 400 are displayed in association with each other on the display unit 14, the user intuitively grasps the relevance of these imaging parameters. be able to. Therefore, the user can intuitively set these imaging parameters. Note that the user may set the Tv / Av value first or the ISO value first.

  Further, the user sets the Tv / Av value and the ISO value in only two steps: a step of tapping (or dragging and dropping) on the Tv / Av plane image 300 and a step of moving the ISO bar image 400. Can do. Therefore, the user can easily set these imaging parameters. Further, the control unit 16 varies the Tv / Av plane image 300 and the ISO bar image 400 according to a user operation (for example, the point P1 and the reference line 330 are moved, the ISO bar image 400 is moved, etc.). Therefore, the user can set these imaging parameters graphically and dynamically (flexibly).

  Moreover, the veteran user can understand each imaging parameter visually and can shift to imaging. A novice user can easily grasp how each imaging parameter varies depending on an input operation. As a result, the novice user is expected to be interested in setting each imaging parameter.

  Furthermore, the information processing apparatus 10 can provide an interface that allows a more efficient input operation to a user of an existing imaging apparatus. On the other hand, the information processing apparatus 10 can reduce a threshold for a user who has felt difficulty with the imaging apparatus, such as a user such as a smartphone or a smart tablet. Further, by applying the display form by the information processing apparatus 10 to the image pickup apparatus, the product form of the image pickup apparatus can be diversified to meet the needs of more users.

  The inventor has also studied a technique for setting each imaging parameter using only hard keys (for example, any combination of a dial, a button, a cross key, and the like). However, this technique often requires a plurality of steps of processing to set one imaging parameter. In addition, it is difficult for the user to understand the relationship between the imaging parameters. Usability depends on the number of hard keys and the installation position. When the number of hard keys is small, the number of cases in which these hard keys are operated in combination increases, and the operation can be more complicated.

(1-4-2. Second display example)
Next, a second display example will be described based on FIG. In the second display example, a light / dark gradation is added to the Tv / Av plane image 300 and the ISO bar image 400 of the first display example. In FIG. 5, the light and dark gradation is shown by shades of hatching. The lighter the hatch, the brighter it is.

  The light / dark gradation of the Tv / Av plane image 300 indicates the exposure amount determined by the Tv / Av value. The brighter the point on the Tv / Av plane image 300, the larger the exposure amount indicated by that point. The light / dark gradation of the ISO bar image 400 indicates the ISO value. The brighter the point on the ISO bar image 400, the larger the ISO value indicated by that point. Note that the light / dark gradation may be applied to only one of the Tv / Av plane image 300 and the ISO bar image 400. Further, the light / dark gradation of the Tv / Av plane image 300 may be displayed only when the user has set the Tv / Av value. Similarly, the light / dark gradation of the ISO bar image 400 may be displayed only when the user has set the ISO value. Thereby, the user can concentrate the consciousness on the subject when the Tv / Av value and the ISO value are not set.

  In the second display example, the control unit 16 displays the imaging button 800 in addition to the Tv / Av plane image 300 and the ISO bar image 400. The imaging unit 13 performs imaging when the imaging button 800 is tapped. Note that the imaging button 800 may be omitted.

  According to the second display example, the user can more intuitively grasp the exposure amount and the ISO value by referring to the gradient direction of the light / dark gradation. Furthermore, the user can easily grasp the operation direction for increasing or decreasing the exposure amount and the ISO value by referring to the gradient direction of the light / dark gradation.

(1-4-3. Third display example)
Next, a third display example will be described based on FIG. The third display example is displayed when the user selects the A mode (aperture priority mode) as the imaging mode. Also in the third display example, the control unit 16 displays the Tv / Av plane image 300 and the ISO bar image 400, but the following points are different from the first display example.

  In this mode, the control unit 16 displays the slider bar image 340 in the vicinity of the Tv / Av plane image 300, more specifically, in the vicinity of the vertical axis 320. In this mode, the control unit 16 does not accept a tap (or drag and drop) operation in the Tv / Av plane image 300 by the user, but accepts an operation of the slider bar image 340 instead.

  That is, the control unit 16 moves the slider bar image 340 in the direction of the arrow 340a or the arrow 340b in accordance with an input operation by the user. Examples of the input operation include a method of tapping the slider bar image 340 with a finger and dragging the finger in the direction of the arrow 340a or the arrow 340b. The control unit 16 sets Av to a value corresponding to the position of the slider bar image 340, and further calculates an optimum Tv value according to the set value of Av. And the control part 16 sets Tv to the said optimal value, and moves the point P1 to the position corresponding to the setting value of Tv / Av. Further, the control unit 16 displays the reference line 330. Here, the Tv / Av value indicated by each point on the reference line 330 indicates the same exposure amount as that of the point P1.

  Therefore, the reference line 330 is fixed as a graph indicating the optimum value of the exposure amount, and the point P1 moves on the reference line 330 in the directions of arrows 340a and 340b and in the directions of arrows 310a and 310b. Note that the control unit 16 controls the ISO bar image 400 in the same manner as in the first display example. Therefore, the user can set the Av and ISO values dynamically and graphically. Further, the user can dynamically and graphically understand how Tv varies depending on Av variation.

(1-4-4. Fourth display example)
Next, a fourth display example will be described with reference to FIG. The fourth display example is displayed when the user selects the S mode (shutter speed priority mode) as the imaging mode. Also in the fourth display example, the control unit 16 displays the Tv / Av plane image 300 and the ISO bar image 400, but the following points are different from the first display example.

  In this mode, the control unit 16 displays the slider bar image 350 in the vicinity of the Tv / Av plane image 300, more specifically, in the vicinity of the horizontal axis 310. In this mode, the control unit 16 does not accept a tap (or drag and drop) operation in the Tv / Av plane image 300 by the user, but instead accepts an operation of the slider bar image 350.

  That is, the control unit 16 moves the slider bar image 350 in the direction of the arrow 350a or the arrow 350b in accordance with an input operation by the user. Examples of the input operation include a method of tapping the slider bar image 350 with a finger and dragging the finger in the direction of the arrow 350a or the arrow 350b. The control unit 16 sets Tv to a value corresponding to the position of the slider bar image 350, and further calculates an optimal Av value according to the set value of Tv. And the control part 16 sets Av to the said optimal value, and moves the point P1 to the position corresponding to the setting value of Tv / Av. Further, the control unit 16 displays the reference line 330. Here, the Tv / Av value indicated by each point on the reference line 330 indicates the same exposure amount as that of the point P1.

  Accordingly, the reference line 330 is fixed as a graph indicating the optimum value of the exposure amount, and the point P1 moves on the reference line 330 in the directions of the arrows 350a and 350b and the arrows 320a and 320b. Note that the control unit 16 controls the ISO bar image 400 in the same manner as in the first display example. Therefore, the user can set the Tv and ISO values dynamically and graphically. Further, the user can dynamically and graphically understand how Av varies according to variation in Tv.

(1-4-5. Fifth display example)
Next, a fifth display example will be described with reference to FIG. The fifth display example is displayed when the user selects the P mode (program mode) as the imaging mode. Also in the fifth display example, the control unit 16 displays the Tv / Av plane image 300 and the ISO bar image 400, but the following points are different from the first display example.

  In this mode, the control unit 16 calculates the optimum value of the Tv / Av value and sets the Tv / Av value to the optimum value. Then, the control unit 16 moves the point P1 to a position corresponding to the set value of Tv / Av. Further, the control unit 16 displays the reference line 330. Here, the Tv / Av value indicated by each point on the reference line 330 indicates the same exposure amount as that of the point P1. The control unit 16 fixes the reference line 330. Then, the control unit 16 receives an input operation of tapping (or dragging and dropping) on the reference line 330, and moves the point P1 on the reference line 330 according to the input operation. That is, the control unit 16 moves the point P1 in the directions of the arrows 330a and 330b. Then, the control unit 16 changes the set value of the Tv / Av value to the Tv / Av value indicated by the point P1 after the movement.

  Note that, when a tap (or drag and drop) operation is performed in an area other than the reference line 330 in the Tv / Av plane image 300, the control unit 16 sets the point P1 on the reference line 330 according to the input operation. You may move it with. For example, when the user drags a finger in a direction parallel to the reference line 330 in a region outside the reference line 330, the control unit 16 may move the point P1 in the finger moving direction.

  Note that the control unit 16 controls the ISO bar image 400 in the same manner as in the first display example. Therefore, the user can set the Tv / Av value and the ISO value dynamically and graphically. Furthermore, the user can grasp the Tv / Av value at which the exposure amount is optimum dynamically and graphically.

(1-4-6. Sixth display example)
Next, a sixth display example will be described with reference to FIG. Also in the sixth display example, the control unit 16 displays the Tv / Av plane image 300 and the ISO bar image 400, but the following points are different from the first display example.

  The control unit 16 makes the length of the ISO bar image 400 longer than that in the first display example. Then, the control unit 16 displays a maximum value designation indicator 410b and a maximum value display image 410a in the vicinity of the upper end portion of the ISO bar image 400. The maximum value designation indicator 410b has an arrow shape and indicates a point corresponding to the maximum value of the ISO value in the ISO bar image 400. The control unit 16 displays a minimum value designation indicator 420 b and a minimum value display image 420 a in the vicinity of the lower end portion of the ISO bar image 400. The maximum value designation indicator 410b has an arrow shape and indicates a point corresponding to the maximum value of the ISO value in the ISO bar image 400.

  Further, the control unit 16 calculates the optimum value of the ISO value corresponding to the Tv / Av value, and displays the ISO bar image 400 so that the intersection P2 between the reference line 330 and the ISO bar image 400 indicates the optimum value. To do. Note that the control unit 16 may display the ISO bar image 400 so that the intersection P2 between the reference line 330 and the ISO bar image 400 indicates a preset initial value.

  Further, the control unit 16 displays an ISO value adjusting arrow image 440 at the point P2. The ISO value adjusting arrow image 440 has an arrow shape and indicates any point on the ISO bar image 400, that is, the ISO value. The control unit 16 moves the ISO value adjusting arrow image 440 in the direction of the arrow 400a or the arrow 400b in accordance with a user input operation. Here, examples of the input operation include an operation of dragging and dropping the ISO value adjusting arrow image 440, an operation of tapping a desired point on the ISO bar image 400, and the like. Then, the control unit 16 changes the set value of the ISO value to the ISO value indicated by the ISO value adjusting arrow image 440. The movable range of the ISO value adjusting arrow image 440 is between the maximum value designation indicator 410b and the minimum value designation indicator 420b.

  Further, when the reference line 330 moves, the control unit 16 causes the ISO bar image 400 to follow the reference line 330. Specifically, the control unit 16 calculates an optimum value of the ISO value according to the changed Tv / Av value, and the intersection P2 between the reference line 330 and the ISO bar image 400 indicates the optimum value. The ISO bar image 400 is moved. The control unit 16 may move the ISO bar image 400 so that the point P2 indicates a preset initial value.

  Furthermore, the control unit 16 sets the ISO value setting value to an optimum value, and returns the ISO value adjusting arrow image 440 to the point P2. The control unit 16 may maintain the ISO value at the current value (ISO value before changing the Tv / Av value). In this case, the position of the ISO value adjusting arrow image 440 in the ISO bar image 400 is maintained at the position before the change of the Tv / Av value.

  Further, the control unit 16 gives a light / dark gradation to the Tv / Av plane image 300 and the ISO bar image 400. This gradation may be omitted, and may be given only to one of the Tv / Av plane image 300 and the ISO bar image 400.

  Also according to the sixth display example, the user can set the Tv / Av value and the ISO value graphically and dynamically (flexibly). In addition, when adjusting the ISO value, the control unit 16 fixes the ISO bar image 400 and moves the ISO value adjusting arrow image 440, so that the space efficiency of the display unit 14 can be improved. Specifically, since the control unit 16 fixes the ISO bar image 400 at the time of adjusting the ISO value, the area of the through image 1000 hidden by the ISO bar image 400 can be reduced. Further, for example, when the ISO bar image 400 moves upward during the adjustment of the ISO value, the upper end portion of the ISO bar image 400 may protrude outside the display area of the display unit 14. However, in this display example, the control unit 16 fixes the ISO bar image 400 when adjusting the ISO value, so that the possibility that the upper end portion of the ISO bar image 400 protrudes outside the display area of the display unit 14 may be reduced. it can.

Note that the control unit 16 may move only the gradation while fixing the ISO bar image 400, or may move only the numerical value in the set value display image 430.
(1-4-7. Seventh display example)
Next, a seventh display example will be described with reference to FIG. Also in the seventh display example, the control unit 16 displays the Tv / Av plane image 300 and the ISO bar image 400, but the following points are different from the first display example.

  That is, the control unit 16 displays the display window image 401 and displays the ISO bar image 400 in the display window image 401. The control unit 16 fixes the position of the display window image 401. In addition, when the ISO bar image 400 protrudes from the display window image 401, the control unit 16 does not display the protruding portion (the display may be transparent).

  Also according to the seventh display example, the user can set the Tv / Av value and the ISO value graphically and dynamically (flexibly). Moreover, since the control part 16 displays the ISO bar image 400 in the display window image 401 and fixes the display window image 401, the space efficiency of the display part 14 can be improved. Specifically, since the control unit 16 displays the ISO bar image 400 in the display window image 401, the area of the through image 1000 hidden by the ISO bar image 400 can be reduced. For example, when the ISO bar image 400 is moved without displaying the display window image 401, the end of the ISO bar image 400 protrudes outside the display window image 401 depending on the movement state of the ISO bar image 400. there is a possibility. However, in the present display example, the control unit 16 does not display the portion that protrudes from the display window image 401, thereby reducing the possibility that the end of the ISO bar image 400 protrudes outside the display area of the display unit 14. Can do.

(1-4-8. Eighth display example)
Next, an eighth display example will be described with reference to FIGS. Also in the eighth display example, the control unit 16 displays the Tv / Av plane image 300 and the ISO bar image 400, but the following points are different from the first display example.

  The controller 16 displays a Tv / Av plane image 300 as shown in FIG. The control unit 16 performs the same processing as the first display example for the Tv / Av plane image 300. The control unit 16 sets the Tv / Av value and moves the point P1 using the Tv / Av plane image 300 until the ISO value setting request is received from the user. The control unit 16 may or may not display the reference line 330. The ISO value setting request includes, for example, touching the point P1 with a finger for a predetermined time or more.

  When there is an ISO value setting request from the user, the control unit 16 rotates the Tv / Av plane image 300 to the back side of the display unit 14 as shown in FIG. Further, the control unit 16 displays an ISO bar image 400 passing through the point P1. The ISO bar image 400 extends in a direction perpendicular to the Tv / Av plane image 300. Further, the control unit 16 displays the set value display image 430, the maximum value display image 410a, and the minimum value display image 420a in the same manner as in the first display example. Further, the control unit 16 sets the ISO value indicated by the intersection P1 between the ISO bar image 400 and the Tv / Av plane image 300 as a set value of the ISO value. Further, the control unit 16 moves the ISO bar image 400 in the direction of the arrow 400c or the arrow 400d in accordance with an input operation by the user. Here, examples of the input operation include a method of tapping the ISO bar image 400 with a finger and dragging the finger in the direction of the arrow 400c or the arrow 400d. As a result, the ISO value indicated by the point P1 also varies, so that the set value of the ISO value also varies.

  When there is a Tv / Av value setting request from the user, the control unit 16 rotates the Tv / Av plane image 300 toward the front side of the display unit 14 to thereby display the Tv / Av plane image 300 shown in FIG. Is displayed. Here, the setting request for the Tv / Av value includes, for example, touching the point P1 with a finger for a predetermined time or more.

  Also according to the eighth display example, the user can set the Tv / Av value and the ISO value graphically and dynamically (flexibly). Further, since the Tv / Av plane image 300 and the ISO bar image 400 are three-dimensionally displayed, the user can more intuitively understand the Tv / Av value and the ISO value.

  The control unit 16 displays the Tv / Av plane image 300 shown in FIG. 12 instead of the Tv / Av plane image 300 shown in FIG. 11, and sets the Tv / Av value using the Tv / Av plane image 300. May be performed.

(1-4-9. Ninth display example)
Next, a ninth display example will be described with reference to FIG. In this example, the control unit 16 displays an image similar to that in the sixth display example. However, it differs from the sixth display example in that the ISO bar image 400 extends in the horizontal direction. The control unit 16 moves the ISO bar image 400 in the horizontal direction in response to an input operation by the user. Other processes relating to the ISO bar image 400 may be the same as those in the first display example. Also according to this display example, the user can set the Tv / Av value and the ISO value graphically and dynamically (flexibly).

  In addition, since the control unit 16 extends the ISO bar image 400 in the horizontal direction, the space efficiency of the display unit 14 can be improved. That is, since the ISO bar image 400 extends in the horizontal direction, the control unit 16 can display the ISO bar image 400 along the edge of the display unit 14. Therefore, the ISO bar image 400 is unlikely to interfere with other images. It should be noted that the ninth display example can be applied to other display examples other than the sixth display example, for example, the first display example.

(1-4-10. Tenth display example)
Next, a tenth display example will be described with reference to FIG. In each display example described above, the reference line 330 is connected to Tv / Av values having a constant exposure amount. However, the reference line 330 is not limited to this form. The tenth display example shows another example of the reference line 330.

  The control unit 16 displays the Tv / Av plane image 300 as in the first display example, but extends the reference line 330 vertically downward from the point P1. Then, the control unit 16 displays the ISO bar image 400 below the Tv / Av plane image 300 and extends it in the horizontal direction. Then, the control unit 16 sets the ISO value indicated by the intersection P2 between the reference line 330 and the ISO bar image 400 as a set value of the ISO value. The control unit 16 moves the ISO bar image 400 in the horizontal direction in response to an input operation by the user. Other processes relating to the ISO bar image 400 may be the same as those in the first display example.

  Also according to this display example, the user can set the Tv / Av value and the ISO value graphically and dynamically (flexibly).

  Note that the control unit 16 may omit the reference line 330. Further, when the reference line 330 is omitted, the control unit 16 does not necessarily need to place the point P2 vertically below the point P1. That is, the control unit 16 may calculate the optimum value of the ISO value according to the Tv / Av value and display the point P2 corresponding to the optimum value on the ISO bar image 400. Further, the control unit 16 displays a reference line that passes through the point P2 and is orthogonal to the ISO bar image 400, and moves the ISO bar image 400 in the horizontal direction in accordance with an input operation by the user. And the control part 16 should just use the ISO value which the intersection of a reference line and the ISO bar image 400 shows as a setting value of an ISO value.

(1-4-11. Eleventh display example)
Next, an eleventh display example will be described with reference to FIGS. 15 and 16. In each display example described above, the ISO bar image 400 is displayed as an image different from the Tv / Av plane image 300. However, the ISO bar image 400 may be incorporated in the Tv / Av plane image 300. The eleventh display example and the twelfth display example show an example in which the ISO bar image 400 is incorporated into the Tv / Av plane image 300.

  The control unit 16 displays the Tv / Av plane image 300 and the reference line 330 as in the first display example. Further, the control unit 16 displays other images, that is, a dial image 500, a focus mode selection image 600, and an imaging parameter display image 700.

  Further, the control unit 16 extends the ISO adjustment linear image 450 in a direction orthogonal to the reference line 330 from the point P1 in order to clearly indicate that the ISO bar image 400 is incorporated in the Tv / Av plane image 300. Further, the control unit 16 displays an ISO decrease indicator 450b at the upper end of the ISO adjustment linear image 450, and displays an ISO increase indicator 450a at the lower end of the ISO adjustment linear image 450. The ISO adjustment linear image 450, the ISO increase indicator 450a, and the ISO decrease indicator 450b indicate operation directions for adjusting the ISO value.

  The control unit 16 sets the Tv / Av value and moves the point P1 using the Tv / Av plane image 300 until the ISO value setting request is received from the user. Further, the control unit 16 causes the reference line 330 and the ISO adjustment linear image 450 to follow the point P1. The control unit 16 may or may not display the reference line 330. The ISO value setting request includes, for example, touching the point P1 with a finger for a predetermined time or more.

  When there is an ISO value setting request from the user, the control unit 16 deletes the dial image 500 and the focus mode selection image 600 as shown in FIG. 16 and applies a light / dark gradation to the Tv / Av plane image 300. Give. This light / dark gradation shows the ISO value as in the second display example.

  And the control part 16 moves the whole gradation according to input operation by a user. For example, when the user drags a finger in the lower right direction, the control unit 16 moves the entire gradation in the lower right direction. In this case, the brightness of the point P1 increases. On the other hand, when the user drags the finger in the upper left direction, the control unit 16 moves the entire gradation in the upper left direction. In this case, the brightness of the point P1 decreases. And the control part 16 makes the ISO value corresponding to the brightness of the point P1 the setting value of an ISO value.

  Note that the control unit 16 displays a Tv / Av plane image 300 shown in FIG. 15 or the like when there is a Tv / Av value setting request from the user.

  According to the eleventh display example, the user can set the Tv / Av value and the ISO value graphically and dynamically (flexibly). Furthermore, since the ISO value is displayed by light and dark gradation, the user can more intuitively grasp the Tv / Av value and the ISO value. Further, the user can easily grasp the operation direction for increasing or decreasing the ISO value by referring to the gradient direction of the light / dark gradation, the ISO adjustment linear image 450, the ISO increase indicator 450a, and the ISO decrease indicator 450b. In addition, since the light / dark gradation is displayed during the setting of the ISO value, the user can concentrate the consciousness on the subject when the ISO value is not set.

(1-4-12. Twelfth display example)
Next, a twelfth display example will be described with reference to FIGS. 17 and 18. The control unit 16 displays the Tv / Av plane image 300 and the reference line 330 as in the first display example. Further, the control unit 16 displays other images, that is, a dial image 500, a focus mode selection image 600, and an imaging parameter display image 700.

  Further, the control unit 16 displays the ISO set value display image 430 in the vicinity of the point P1 in order to clearly indicate that the ISO bar image 400 is incorporated in the Tv / Av plane image 300. Note that the ISO value indicated by the ISO set value display image 430 may be, for example, an optimum value according to the Tv / Av value or a preset initial value. The optimum value is calculated by the control unit 16.

  When there is an ISO value setting request from the user, the control unit 16 erases the dial image 500 and the focus mode selection image 600 as shown in FIG. Examples of the ISO value setting request include touching the point P1 with a finger for a predetermined time or more. Furthermore, the control unit 16 displays the background image 470 behind the Tv / Av plane image 300 and gives a light / dark gradation to the background image 470. This light / dark gradation shows the ISO value as in the second display example.

  Further, the control unit 16 displays an ISO increasing arrow image 460a extending from the point P1 in the lower right direction and an ISO decreasing arrow image 460b extending from the point P1 in the upper left direction. Further, the control unit 16 displays the ISO increase indicator 460a-1 at the tip of the ISO increase arrow image 460a, and displays the ISO decrease indicator 460b-1 at the tip of the ISO decrease arrow image 460b. The ISO increase arrow image 460a, the ISO increase indicator 460a-1, the ISO decrease arrow image 460b, and the ISO decrease indicator 460b-1 indicate operation directions for adjusting the ISO value.

  And the control part 16 moves the background image 470, ie, the whole gradation, according to the input operation by a user. For example, when the user drags the finger in the lower right direction, the control unit 16 moves the background image 470 in the lower right direction. In this case, the brightness of the point P1 increases. On the other hand, when the user drags a finger in the upper left direction, the control unit 16 moves the background image 470 in the upper left direction. In this case, the brightness of the point P1 decreases. And the control part 16 makes the ISO value corresponding to the brightness of the point P1 the setting value of an ISO value.

  Note that the control unit 16 displays a Tv / Av plane image 300 shown in FIG. 17 or the like when a Tv / Av value setting request is received from the user.

  According to the twelfth display example, the user can set the Tv / Av value and the ISO value graphically and dynamically (flexibly). Furthermore, since the ISO value is displayed by light and dark gradation, the user can more intuitively grasp the Tv / Av value and the ISO value. Further, the user can easily grasp the operation direction for increasing or decreasing the ISO value by referring to the gradient direction of the light / dark gradation, the ISO increasing arrow image 460a, the ISO increasing indicator 460a-1, and the like.

(1-4-13. Thirteenth display example)
Next, a thirteenth display example will be described with reference to FIG. In the thirteenth display example, the control unit 16 displays an undo button 810, a reset button 820, and a lock button 830 in addition to the same image as in the first display example. When the user taps the undo button 810, the control unit 16 returns the state of each image to the state in which the previous operation by the user has been performed. When the reset button 820 is tapped, the control unit 16 returns the display state to the initial state. That is, the control unit 16 calculates the optimum value of the Tv / Av value and the ISO value, and adjusts the position of the point P1, the position of the reference line 330, and the position of the ISO bar image 400 based on the optimum values. . When the lock button 830 is tapped, the control unit 16 excludes the input operation by the user (not accepted). When the lock button 830 is tapped again, the control unit 16 accepts the input operation by the user.

  Also according to this display example, the user can set the Tv / Av value and the ISO value graphically and dynamically (flexibly). Furthermore, the usability of the Tv / Av plane image 300 and the ISO bar image 400 is improved for the user.

  Note that the display examples described above may be combined as appropriate. For example, the light / dark gradation may be applied to display examples other than the second display example. Further, the undo button 810, the reset button 820, and the lock button 830 displayed in the thirteenth display example may be displayed in other display examples. In addition, any display of the undo button 810, the reset button 820, and the lock button 830 may be omitted. Some of these buttons may be hard keys.

  As described above, according to the first embodiment, the information processing apparatus 10 sets the first setting image for setting the first imaging parameter and the second setting image for setting the second imaging parameter. Are displayed in association with each other. Therefore, the user can set a plurality of imaging parameters while visually recognizing a plurality of setting images associated with each other. Thereby, when setting a plurality of imaging parameters using a plurality of setting images, the user can intuitively grasp the relevance of these imaging parameters, and by extension, these imaging parameters can be intuitively understood. Can be set.

  In addition, the information processing apparatus 10 displays the second setting image at a position according to the setting value of the first imaging parameter. Therefore, the user can intuitively grasp a plurality of imaging parameters.

  More specifically, the information processing apparatus 10 performs control to display a reference line corresponding to the setting value of the first imaging parameter, and displays the second setting image at a position that intersects the reference line. Therefore, the user can intuitively grasp a plurality of imaging parameters.

  More specifically, each point on the second setting image indicates the value of the second imaging parameter, and the information processing apparatus 10 determines the point at which the second setting image and the reference line intersect with the second The setting value of the imaging parameter is used. Therefore, the user can intuitively grasp a plurality of imaging parameters.

  More specifically, the information processing apparatus 10 displays a spatial image (for example, a planar image) for setting a plurality of first imaging parameters as a first setting image. Therefore, the user can intuitively grasp the plurality of first imaging parameters.

  More specifically, the information processing apparatus 10 displays the Tv / Av plane image 300 for setting the shutter speed (Tv) and the aperture value (Av) as the first setting image and sets the ISO value. The ISO bar image 400 is displayed as the second setting image. Therefore, the user can intuitively grasp the Tv / Av value and the ISO value.

  In addition, since the information processing apparatus 10 incorporates the second setting image into the first setting image, the user can intuitively grasp a plurality of imaging parameters.

  Moreover, since the information processing apparatus 10 includes the second setting image in the background image of the first setting image, the user can intuitively grasp a plurality of imaging parameters.

<2.2. Second Embodiment>
Next, a second embodiment will be described. In the second embodiment, the information processing apparatus and the imaging apparatus are divided.

(2-1. Overall configuration of information processing system)
First, the configuration of an information processing system according to the second embodiment will be described with reference to FIG. The information processing system includes an information processing device 10 and an imaging device 20. The information processing apparatus 10 and the imaging apparatus 20 can communicate with each other. The information processing apparatus 10 performs the same process as in the first embodiment described above. However, the information processing apparatus 10 acquires a through image and a captured image through communication with the imaging apparatus 20. Further, the information processing apparatus 10 outputs setting value information regarding the setting values of the Tv / Av value and the ISO value to the imaging apparatus 20.

(2-2. Configuration of Imaging Device)
The configuration of the information processing apparatus 10 is as shown in the first embodiment. In the second embodiment, the information processing apparatus 10 does not have to include the imaging unit 13. Therefore, here, the configuration of the imaging device 20 will be described.

  As illustrated in FIG. 21, the imaging device 20 includes a storage unit 21, a communication unit 22, an imaging unit 23, a display unit 24, an operation unit 25, and a control unit 26. The storage unit 21 stores a program for realizing the storage unit 21, the communication unit 22, the imaging unit 23, the display unit 24, the operation unit 25, and the control unit 26 and various image information in the imaging device 20.

  The communication unit 22 communicates with the information processing apparatus 10. For example, the communication unit 22 transmits the through image given from the control unit 26 to the information processing apparatus 10. Further, the communication unit 22 outputs the set value information given from the information processing apparatus 10 to the control unit 26. The imaging unit 23 performs imaging. Specifically, the imaging unit 23 outputs an image captured by the imaging device to the control unit 26 as a through image until the user performs an imaging operation (for example, pressing a shutter button (not shown)). When the user performs an imaging operation, the imaging unit 23 performs imaging according to the set values of the Tv / Av value and the ISO value (specifically, performs an operation such as releasing a shutter). Then, the imaging unit 23 outputs the image captured by the imaging element to the control unit 26 as a captured image.

  The display unit 24 displays various images, for example, a through image and a captured image. The display unit 24 may display set values for the Tv / Av value and the ISO value. The operation unit 25 includes so-called hard keys and is arranged at each part of the imaging device 20. The operation unit 25 outputs operation information related to the input operation performed by the user to the control unit 26. The control unit 26 controls the entire imaging apparatus 20 and outputs a through image to the communication unit 22. In addition, the control unit 26 sets the imaging unit 23 based on the setting value information.

  The imaging device 20 has the hardware configuration shown in FIG. 22, and the storage unit 21, the communication unit 22, the imaging unit 23, the display unit 24, the operation unit 25, and the control unit 26 are realized by these hardware configurations. Is done.

  That is, the imaging device 20 includes a nonvolatile memory 201, a RAM 202, a communication device 203, imaging hardware 204, a display 205, an operation device (hard key or the like) 206, and a CPU 207 as hardware configurations. Prepare.

  The nonvolatile memory 201 stores various programs and image information. Here, the program includes a program for causing the imaging device 20 to realize the storage unit 21, the communication unit 22, the imaging unit 23, the display unit 24, the operation unit 25, and the control unit 26.

  The RAM 202 serves as a work area for the CPU 207. The communication device 203 communicates with the information processing device 10. The imaging hardware has a configuration similar to that of the imaging device 104 described above. That is, the imaging hardware generates a captured image by performing imaging. The display 205 displays various image information. The display 205 may output audio information. The operation device 206 accepts various input operations by the user.

  The CPU 207 reads and executes the program stored in the nonvolatile memory 201. Accordingly, the CPU 207 reads out and executes the program stored in the nonvolatile memory 201, whereby the storage unit 21, the communication unit 22, the imaging unit 23, the display unit 24, the operation unit 25, and the control unit 26 are added to the imaging device 20. Is realized. That is, the CPU 207 can be a substantial operation subject of the imaging apparatus 20.

(2-3. Processing procedure by information processing system)
The processing by the information processing system is the same as the processing by the information processing apparatus 10 described above. However, it differs from the first embodiment in that the imaging device 20 creates a through image and transmits it to the information processing device 10, and transmits setting value information from the information processing device 10 to the imaging device 20. Note that the first to thirteenth display examples are naturally applicable to the second embodiment.

  Also according to the second embodiment, the user can set the Tv / Av value and the ISO value graphically and dynamically (flexibly). In addition, since the user can remotely control the imaging parameters of the imaging apparatus 20 using the information processing apparatus 10, the usability of the Tv / Av plane image 300 and the ISO bar image 400 is further improved.

  The first and second embodiments may have any of the effects described in the present specification or other effects.

  The preferred embodiments of the present disclosure have been described in detail above with reference to the accompanying drawings, but the technical scope of the present disclosure is not limited to such examples. It is obvious that a person having ordinary knowledge in the technical field of the present disclosure can come up with various changes or modifications within the scope of the technical idea described in the claims. Of course, it is understood that it belongs to the technical scope of the present disclosure.

The following configurations also belong to the technical scope of the present disclosure.
(1)
A control unit that performs control to associate and display a first setting image for setting the first imaging parameter related to imaging and a second setting image for setting the second imaging parameter related to imaging;
An information processing apparatus comprising: an input operation unit capable of performing an input operation for setting the first imaging parameter and the second imaging parameter.
(2)
The information processing apparatus according to (1), wherein the control unit performs control to display the second setting image at a position corresponding to a setting value of the first imaging parameter.
(3)
The control unit according to (2), wherein the control unit performs control to display a reference line according to a setting value of the first imaging parameter, and displays the second setting image at a position intersecting the reference line. Information processing device.
(4)
Each point on the second setting image indicates the value of the second imaging parameter,
The information processing apparatus according to (3), wherein the control unit sets a point where the second setting image and the reference line intersect as a setting value of the second imaging parameter.
(5)
The control unit according to any one of (1) to (4), wherein the control unit performs control to display a spatial image for setting a plurality of first imaging parameters as the first setting image. Information processing device.
(6)
The first imaging parameter includes a shutter speed and an aperture value,
The information processing apparatus according to (5), wherein the second imaging parameter includes an ISO value.
(7)
The control unit performs control to display a planar image for setting a shutter speed and an aperture value as the first setting image and to display a bar image for setting an ISO value as the second setting image. The information processing apparatus according to (6).
(8)
The information processing apparatus according to (1) or (2), wherein the control unit incorporates the second setting image into the first setting image.
(9)
The information processing apparatus according to (8), wherein the control unit includes the second setting image in a background image of the first setting image.
(10)
Performing control to associate and display a first setting image for setting a first imaging parameter relating to imaging and a second setting image for setting a second imaging parameter relating to imaging;
An information processing method including: setting the first imaging parameter and the second imaging parameter in response to an input operation.
(11)
On the computer,
A control function for performing control to associate and display a first setting image for setting a first imaging parameter relating to imaging and a second setting image for setting a second imaging parameter relating to imaging;
A program for realizing an input operation function capable of an input operation for setting the first imaging parameter and the second imaging parameter.

DESCRIPTION OF SYMBOLS 10 Information processing apparatus 11, 21 Storage part 12, 22 Communication part 13, 23 Imaging part 14, 24 Display part 15, 25 Operation part 16, 26 Control part 20 Imaging device 101, 201 Non-volatile memory 102, 202 RAM
103, 203 Communication device 104 Imaging device 105, 205 Display 106 Touch panel 204 Imaging hardware 206 Operating device (hard key, etc.)
210 Display layer indicator 300 Tv / Av plane image 330 Reference line 340, 350 Slider bar image 400 ISO bar image 401 Display window image 470 Background image 500 Dial image 600 Focus mode selection image 700 Imaging parameter display image 800 Imaging button 810 Undo button 820 Reset button 830 Lock button 1000 Through image (captured image)

Claims (8)

A control unit that performs control to associate and display a first setting image for setting the first imaging parameter related to imaging and a second setting image for setting the second imaging parameter related to imaging;
An input operation unit capable of performing an input operation for setting the first imaging parameter and the second imaging parameter;
The control unit displays a reference line according to a setting value of the first imaging parameter, performs control to display the reference line and the second setting image in association with each other;
Each point on the second setting image indicates the value of the second imaging parameter,
The control unit performs control to display the second setting image at a position corresponding to a setting value of the first imaging parameter,
The control unit displays the second setting image at a position intersecting the reference line,
The information processing apparatus, wherein the control unit uses a point where the second setting image and the reference line intersect as a setting value of the second imaging parameter.   The information processing apparatus according to claim 1, wherein the control unit performs control to display a spatial image for setting a plurality of the first imaging parameters as the first setting image. The first imaging parameter includes a shutter speed and an aperture value,
The information processing apparatus according to claim 2, wherein the second imaging parameter includes an ISO value.   The control unit performs control to display a planar image for setting a shutter speed and an aperture value as the first setting image and to display a bar image for setting an ISO value as the second setting image. The information processing apparatus according to claim 3.   The information processing apparatus according to claim 1, wherein the control unit incorporates the second setting image into the first setting image.   The information processing apparatus according to claim 5, wherein the control unit includes the second setting image in a background image of the first setting image. The control unit performs control to display the first setting image for setting the first imaging parameter relating to imaging and the second setting image for setting the second imaging parameter relating to imaging in association with each other. When,
The control unit includes setting the first imaging parameter and the second imaging parameter according to an input operation,
The control unit displays a reference line according to a setting value of the first imaging parameter, performs control to display the reference line and the second setting image in association with each other;
Each point on the second setting image indicates the value of the second imaging parameter,
The control unit performs control to display the second setting image at a position corresponding to a setting value of the first imaging parameter,
The control unit displays the second setting image at a position intersecting the reference line,
The information processing method, wherein the control unit sets a point where the second setting image and the reference line intersect as a setting value of the second imaging parameter. On the computer,
A control function for performing control to associate and display a first setting image for setting a first imaging parameter relating to imaging and a second setting image for setting a second imaging parameter relating to imaging;
An input operation function capable of performing an input operation for setting the first imaging parameter and the second imaging parameter;
The control function displays a reference line according to a setting value of the first imaging parameter, performs control to display the reference line and the second setting image in association with each other,
Each point on the second setting image indicates the value of the second imaging parameter,
The control function performs control to display the second setting image at a position according to a setting value of the first imaging parameter,
The control function displays the second setting image at a position intersecting the reference line,
The control function is a program in which a point where the second setting image and the reference line intersect is set as a setting value of the second imaging parameter.

Images