JP3860045B2 - Imaging device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an imaging apparatus. In particular, the present invention relates to an imaging apparatus having imaging settings and imaging preparation settings.
[0002]
[Prior art]
Japanese Patent Laid-Open No. 9-93484 discloses an imaging apparatus that switches the response speed of exposure adjustment, white balance adjustment, or focus adjustment between still image shooting and moving image shooting.
[0003]
[Problems to be solved by the invention]
However, in the conventional imaging device, the driving sound of the imaging device may be recorded as noise when capturing a moving image.
[0004]
SUMMARY An advantage of some aspects of the invention is that it provides an imaging apparatus that can solve the above-described problems. This object is achieved by a combination of features described in the independent claims. The dependent claims define further advantageous specific examples of the present invention.
[0005]
[Means for Solving the Problems]
In other words, according to the first aspect of the present invention, an imaging apparatus that captures an image includes an imaging unit that captures a subject image, a moving unit that moves when the imaging unit captures the subject image, and a subject image that is a moving image. Alternatively, a control condition storage unit that stores a control condition for controlling the moving unit in association with an imaging setting to be captured by the imaging unit as a still image, or an imaging preparation setting that is a preparation state of the imaging setting, and an imaging setting in the imaging unit An imaging setting acquisition unit that acquires imaging instruction information for instructing imaging preparation settings, and a control unit that controls the moving unit based on a control condition associated with the imaging instruction information in the control condition storage unit.
[0006]
The control condition stored in the control condition storage unit is a correlation between the position of the moving unit and a parameter that determines the position of the moving unit, and the correlation may be a hysteresis. The moving unit may adjust the exposure amount by moving when the imaging unit captures the subject image, and may control the moving unit based on the control condition.
[0007]
The above summary of the invention does not enumerate all the necessary features of the present invention, and sub-combinations of these feature groups can also be the invention.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described through embodiments of the invention. However, the following embodiments do not limit the invention according to the claims, and all combinations of features described in the embodiments are included in the invention. It is not always essential to the solution.
[0009]
FIG. 1 shows an example of a functional configuration characteristic of the imaging apparatus 10 according to the present embodiment. The imaging device 10 captures moving images and still images. The imaging apparatus 10 includes a control unit 150, an imaging unit 20, an imaging setting acquisition unit 160, and a control condition storage unit 170.
[0010]
The imaging unit 20 acquires a subject image. The imaging unit 20 includes an optical unit 22, a diaphragm 24 as an example of a moving unit, and a CCD 30. The optical unit 22 captures a subject image. The imaging unit 20 converts the subject image captured by the optical unit 22 into an image signal. The imaging unit 20 sends the converted image signal to the control unit 150.
[0011]
The control condition storage unit 170 stores a control condition for controlling the diaphragm 24 for each setting. The settings are, for example, a moving image capturing setting for causing the image capturing unit 20 to capture a subject image as a moving image, a still image capturing setting for capturing the subject image as a still image to the image capturing unit 20, and a preparation state of the moving image capturing setting and the still image capturing setting. It is a certain imaging preparation setting.
[0012]
The imaging setting acquisition unit 160 acquires imaging instruction information indicating any of moving image imaging setting, still image imaging setting, or imaging preparation setting. The imaging setting acquisition unit 160 sends the acquired imaging instruction information to the control unit 150. Specifically, the imaging setting acquisition unit 160 acquires imaging instruction information by accepting switching of imaging settings from the user of the imaging device 10.
[0013]
The control unit 150 calculates brightness information indicating the brightness of the subject based on the image signal received from the imaging unit 20. The control unit 150 transmits movement instruction information for moving the diaphragm 24 based on the control condition and brightness information associated with the imaging instruction information. The diaphragm 24 moves based on the movement instruction information received from the control unit 150. That is, the aperture 24 changes the aperture value based on the movement instruction information received from the control unit 150. In addition, the control unit 150 controls the imaging unit 20 based on the imaging instruction information received from the imaging setting acquisition unit 160.
[0014]
According to an example of the functional configuration illustrated in FIG. 1, the imaging device 10 includes a state where the imaging unit 20 captures a subject image as a moving image or a still image, and a state where the imaging unit 20 does not capture a subject image. , The diaphragm 24 can be controlled under optimum control conditions.
[0015]
In the present embodiment, the diaphragm 24 is used as an example of the moving unit. However, as another example, the focus driving unit that drives the focus lens of the optical unit 22 and the light that has passed through the optical unit 22 are supplied to the CCD 30. There is also a shutter for controlling whether to perform exposure.
[0016]
FIG. 2 is a flowchart showing the operation of the imaging apparatus 10 according to the present embodiment. When the imaging setting acquisition unit 160 acquires imaging instruction information indicating imaging preparation settings from the user of the imaging device 10, the control unit 150 sets a third control condition corresponding to the imaging preparation settings from the control condition storage unit 170. Read (step S202). Next, the control unit 150 adjusts the focus of the optical unit 22 (step S204). Next, the control unit 150 calculates brightness information indicating the brightness of the subject image based on the image signal received from the imaging unit 20. The control unit 150 controls the diaphragm 24 based on the third control condition read from the control condition storage unit 170 and the brightness information (step S206).
[0017]
Next, the control unit 150 determines whether the imaging instruction information acquired by the imaging setting acquisition unit 160 indicates moving image imaging setting or still image imaging setting (step S208). When the imaging instruction information indicates the moving image imaging setting, the control unit 150 determines whether or not the release switch is fully pressed (step S210). When the control unit 150 determines that the release switch is not fully pressed, the process returns to step S202. When the control unit 150 determines that the release switch is fully pressed, the control unit 150 reads the first control condition, which is a control condition associated with the moving image capturing setting, from the control condition storage unit 170 ( Step S212). Next, the control unit 150 adjusts the focus of the optical unit 22 (step S214). Next, the control unit 150 controls the diaphragm 24 based on the brightness information and the first control condition read from the control condition storage unit 170 (step S216). Next, the imaging unit 20 starts capturing a moving image (step S218).
[0018]
Next, the optical unit 22 adjusts the focus (step S220). Next, the control unit 150 controls the diaphragm 24 based on the brightness information and the first control condition read from the control condition storage unit 170 (step S222). Next, the control unit 150 determines whether or not the release switch has been fully pressed (step S224). When determining that the release switch is not fully pressed, the control unit 150 returns to step S220 and continues to capture the moving image. If it is determined that the release switch has been fully pressed, the control unit 150 stops capturing the moving image (step S226).
[0019]
In step S208, when the imaging instruction information indicates the still image imaging setting, the control unit 150 determines whether or not the release switch is half-pressed (step S230). If the release switch has not been pressed halfway, the process returns to step S202. When the release switch is half-pressed, the control unit 150 reads out the second control condition corresponding to the still image capturing setting from the control condition storage unit 170 (step S232). Next, the control unit 150 adjusts the focus of the optical unit 22 (step S234). Next, the control unit 150 controls the diaphragm 24 based on the brightness information and the first control condition read from the control condition storage unit 170 (step S236).
[0020]
Next, the control unit 150 determines whether or not the half-press of the release switch has been released (step S238). When the half-press of the release switch has not been released, the control unit 150 determines whether or not the release switch has been fully pressed (step S240). If the release switch has not been fully pressed, the process returns to step S238. When the release switch is fully pressed, the imaging unit 20 captures a subject image (step S242).
[0021]
According to the operation shown in the flowchart of FIG. 2, the imaging apparatus 10 according to the present embodiment can control the diaphragm 24 under optimal control conditions in each setting of moving image imaging setting, still image imaging setting, and imaging preparation setting. it can.
[0022]
FIG. 3 shows an example of control conditions stored in the control condition storage unit 170. Here, the control condition is a diagram illustrating a relationship among the aperture value of the imaging apparatus 10, the shutter speed, the brightness of the subject image, and the EV value calculated based on the sensitivity of the CCD 30. In FIG. 3, the vertical axis of the control condition indicates the aperture value of the imaging apparatus 10, the horizontal axis of the control condition indicates the shutter speed of the imaging apparatus 10, and the oblique axis of the control condition indicates the EV value of the subject.
[0023]
The control unit 150 selects an aperture value and a shutter speed corresponding to the EV value with reference to FIG. Here, the control unit 150 selects an aperture value and a shutter speed from the bold line in FIG.
[0024]
As shown in FIG. 3, the control condition has a hysteresis in the correlation between the position of the diaphragm 24 and the EV value that is a parameter for determining the position of the diaphragm 24. The control condition storage unit 170 stores control conditions associated with imaging preparation settings, still image imaging settings, and moving image imaging settings.
[0025]
FIG. 3A is a diagram illustrating the first control condition. In the moving image capturing setting, the control unit 150 changes the aperture value of the aperture 24 for each stage according to the change in the EV value. For example, when the EV value is 10.5 or more and less than 11, the control unit 150 changes the aperture value to F4. When the aperture value is F4 and the EV value changes to less than 10, the control unit 150 changes the aperture value to F2.8. When the aperture value is F2.8 and the EV value changes to 10.5 or more, the control unit 150 changes the aperture value to F4. That is, when the EV value is within the range of 10 or more and less than 10.5, the control unit 150 changes the aperture value to either F2.8 or F4.
[0026]
3 (2) and 3 (3) are diagrams illustrating the second control condition. FIG. 3B is used when the zoom position of the optical unit 22 is on the WIDE side in the still image capturing setting shown in the second control condition. FIG. 3C is used when the zoom position of the optical unit 22 is on the TELE side in the still image capturing setting shown in the second control condition. Since the brightness of the lens is different between the zoom WIDE side and the TELE side even in the same optical unit 22, the control unit 150 uses two types of control conditions properly in the still image capturing setting. 3 (2) and 3 (3), the control unit 150 changes the aperture value of the aperture 24 for each 1/3 stage in accordance with the change in the EV value.
[0027]
FIG. 3 (4) is a diagram showing a fourth control condition. In FIG. 3 (4), the control unit 150 changes the aperture value of the aperture 24 every 1/2 steps according to the change of the EV value.
[0028]
In addition to the control conditions shown in FIG. 3, the control condition storage unit 170 may store a plurality of control conditions that can be arbitrarily selected by the user of the imaging device 10 in, for example, moving image capturing settings or still image capturing settings. The control conditions correspond to, for example, the AUTO mode, the program mode, the portrait mode, the sports mode, and the like, and are set to be suitable for each mode.
[0029]
The control unit 150 uses the control conditions shown in FIG. 3 to control the optimum diaphragm 24 in each setting of moving image shooting setting, still image shooting setting, and imaging preparation setting. Specifically, in the moving image capturing setting, the control unit 150 uses a control condition in which the diaphragm 24 is moved less frequently. Thereby, the noise generated by the diaphragm 24 can be reduced.
[0030]
Further, in the still image capturing setting, the control unit 150 controls the aperture 24 more frequently than the moving image capturing setting. Thereby, the imaging device 10 can capture a high-quality still image. In the imaging preparation setting, the control unit 150 makes the movement frequency of the aperture 24 less than the still image imaging setting. Thereby, the imaging device 10 can reduce power consumption in the imaging preparation setting.
[0031]
FIG. 4 shows a hardware configuration of a digital camera 12 that is an example of the imaging apparatus 10 according to the present embodiment. The digital camera 12 includes an imaging unit 20, an imaging control unit 40, a system control unit 60, a display unit 100, an operation unit 110, a storage unit 120, an external connection unit 130, and an image processing unit 140.
[0032]
The imaging unit 20 includes an optical unit 22, a diaphragm 24, a shutter 26, an optical LPF 28, a CCD 30, an imaging signal processing unit 32, a finder 34, and a strobe 36.
[0033]
The optical unit 22 captures a subject image and performs processing. The optical unit 22 includes a focus lens, a zoom lens, and the like, and forms a subject image on the light receiving surface of the CCD 30. The stop 24 stops light that has passed through the optical unit 22, and the optical LPF 28 passes wavelength components that are longer than a predetermined wavelength included in the light that has passed through the stop 24. Each sensor element of the CCD 30 accumulates charges according to the amount of light of the imaged subject image (hereinafter, the charges are referred to as “accumulated charges”).
[0034]
The shutter 26 is a mechanical shutter and controls whether or not the light having passed through the optical unit 22 is exposed to the CCD 30. The digital camera 12 may have an electronic shutter function instead of the shutter 26. In order to realize the electronic shutter function, the sensor element of the CCD 30 has a shutter gate and a shutter drain. By driving the shutter gate, the accumulated charge is swept out to the shutter drain. By controlling the shutter gate, the time for accumulating charges in each sensor element, that is, the shutter speed can be controlled. In the CCD 30, the accumulated charge is read to the shift register by a read gate pulse, and sequentially read as a voltage signal by a register transfer pulse.
[0035]
The imaging signal processing unit 32 color-separates a voltage signal indicating an object image output from the CCD 30, that is, an analog signal, into R, G, and B components. Then, the imaging signal processing unit 32 adjusts the white balance of the subject image by adjusting the R, G, and B components. The imaging signal processing unit 32 performs gamma correction on the subject image. The imaging signal processing unit 32 performs A / D conversion on the analog signal decomposed into R, G, and B components, and digital image data (hereinafter referred to as “digital image data”) of the subject image obtained as a result. Output to the system control unit 60.
[0036]
The finder 34 may have a display means, and may display various types of information from the main CPU 62 described later in the finder 34. The strobe 36 has a discharge tube 37 that discharges the energy stored in the capacitor, and functions when the discharge tube 37 emits light when energy is supplied to the discharge tube 37.
[0037]
The imaging control unit 40 includes a zoom driving unit 42, a focus driving unit 44, an aperture driving unit 46, a shutter driving unit 48, an imaging system CPU 50 that controls them, a distance measuring sensor 52, and a photometric sensor 54. The zoom driving unit 42, the focus driving unit 44, the aperture driving unit 46, and the shutter driving unit 48 each have a driving unit such as a stepping motor, and drive a mechanism member included in the imaging unit 20. In response to pressing of a release switch 114 described later, the distance measuring sensor 52 measures the distance to the subject, and the photometric sensor 54 measures the subject brightness. The distance measuring sensor 52 and the photometric sensor 54 respectively measure the measured distance to the subject (hereinafter simply referred to as “distance data”) and the subject luminance data (hereinafter simply referred to as “photometric data”). It supplies to CPU50. The imaging system CPU 50 executes the function of the control unit 150.
[0038]
The imaging system CPU 50 adjusts the zoom magnification and focus of the optical unit 22 by controlling the zoom drive unit 42 and the focus drive unit 44 based on the shooting information such as the zoom magnification specified by the user. Further, the imaging system CPU 50 may adjust the zoom magnification and focus by controlling the zoom drive unit 42 and the focus drive unit 44 based on the distance measurement data received from the distance measurement sensor 52.
[0039]
The imaging system CPU 50 determines the aperture value and the shutter speed based on the photometric data received from the photometric sensor 54. In accordance with the determined values, the aperture driving unit 46 and the shutter driving unit 48 respectively control the aperture amount of the aperture 24 and the opening / closing of the shutter 26.
[0040]
Further, the imaging system CPU 50 controls the light emission of the strobe 36 based on the photometric data received from the photometric sensor 54 and adjusts the aperture amount of the aperture 24 at the same time. When the user instructs to capture an image, the CCD 30 starts charge accumulation, and outputs the accumulated charge to the imaging signal processing unit 32 after a lapse of the shutter time calculated from the photometric data.
[0041]
The system control unit 60 includes a main CPU 62, a character generation unit 84, a timer 86, and a clock generator 88. The main CPU 62 controls the entire digital camera 12, particularly the system control unit 60. The main CPU 62 exchanges necessary information with the imaging CPU 50 by serial communication or the like.
[0042]
The clock generator 88 generates an operation clock for the main CPU 62 and supplies it to the main CPU 62. The clock generator 88 generates an operation clock for the imaging system CPU 50 and the display unit 100. The clock generator 88 may supply operation clocks having different frequencies to the main CPU 62, the imaging system CPU 50, and the display unit 100.
[0043]
The character generation unit 84 generates character information and graphic information to be combined with a captured image such as a shooting date and time and a title. The timer 86 is backed up by a battery or the like, for example, always counts time, and supplies time information such as information related to the shooting date and time of the shot image to the main CPU 62 based on the count value. It is desirable that the timer 86 counts the time even when the power source of the digital camera body is off by the power supplied from the storage battery. The character generation unit 84 and the timer 86 are preferably provided in the main CPU 62.
[0044]
The storage unit 120 includes a memory control unit 64, a nonvolatile memory 66, and a main memory 68. The memory control unit 64 controls the nonvolatile memory 66 and the main memory 68. The non-volatile memory 66 is composed of an EEPROM (electrically erasable and programmable ROM), a FLASH memory, or the like, and should be retained even when the power of the digital camera 12 is turned off, such as setting information and adjustment values at the time of shipment. Store the data. The nonvolatile memory 66 may store a boot program, a system program, and the like for the main CPU 62.
[0045]
The main memory 68 is preferably composed of a relatively inexpensive memory having a large capacity, such as a DRAM. The main memory 68 has a function as a frame memory for storing data output from the imaging unit 20, a function as a system memory for loading various programs, and other functions as a work area. The nonvolatile memory 66 and the main memory 68 exchange data with each unit inside and outside the system control unit 60 via the bus 82. The main memory 68 executes the function of the control condition storage unit 170. The nonvolatile memory 66 may further store digital image data.
[0046]
The image processing unit 140 includes a YC processing unit 70, an encoder 72, and a compression / decompression processing unit 78. The external connection unit 130 includes an optional device control unit 74 and a communication I / F unit 80.
[0047]
The YC processing unit 70 performs YC conversion on the digital image data, and generates a luminance signal Y and color difference (chroma) signals BY and RY. The main memory 68 stores the luminance signal and the color difference signal based on the control of the memory control unit 64.
[0048]
The compression / decompression processing unit 78 sequentially reads out the luminance signal and the color difference signal from the main memory 68 and compresses them. Then, the option device control unit 74 writes the compressed digital image data (hereinafter simply referred to as “compressed data”) to a memory card that is an example of the option device 76.
[0049]
The encoder 72 converts the luminance signal and the color difference signal into a video signal (NTSC or PAL signal) and outputs it from the terminal 90. When a video signal is generated from the compressed data recorded in the option device 76, the compressed data is first supplied to the compression / decompression processing unit 78 via the option device control unit 74. Subsequently, the data that has undergone the necessary decompression processing in the compression / decompression processing unit 78 is converted into a video signal by the encoder 72.
[0050]
The optional device control unit 74 performs necessary signal generation, logical conversion, and / or voltage conversion between the bus 82 and the optional device 76 in accordance with the signal specifications allowed by the optional device 76 and the bus specifications of the bus 82. . The digital camera 12 may support a standard I / O card conforming to PCMCIA, for example, in addition to the memory card described above as the optional device 76. In this case, the option device control unit 74 may be configured by a PCMCIA bus control LSI or the like.
[0051]
The communication I / F unit 80 performs control such as protocol conversion according to communication specifications supported by the digital camera 12, such as USB, RS-232C, Ethernet, and the like. The communication I / F unit 80 may output the compressed data or digital image data to an external device including a network via the terminal 92. The communication I / F unit 80 includes a driver IC as necessary, and communicates with an external device via a terminal 92. The communication I / F unit 80 may be configured to exchange data with an external interface such as a printer, a karaoke machine, or a game machine.
[0052]
The display unit 100 includes an LCD monitor 102, an LCD panel 104, a monitor driver 106, and a panel driver 108. The monitor driver 106 controls the LCD monitor 102. The panel driver 108 controls the LCD panel 104. The LCD monitor 102 is provided on the rear side of the camera with a size of about 2 inches, for example, and the current shooting / playback mode, zoom magnification for shooting / playback, battery level, date / time, mode setting screen, subject image, etc. Is displayed. The LCD panel 104 is a small black and white LCD, for example, provided on the upper surface of the camera, and displays information such as image quality (FINE / NORMAL / BASIC, etc.), strobe light emission / flash inhibition, standard number of shoots, number of pixels, battery capacity / remaining capacity, etc. .
[0053]
The operation unit 110 includes a power switch 112, a release switch 114, a function setting unit 116, and a zoom switch 118. The power switch 112 turns on / off the power of the digital camera 12 based on a user instruction. The release switch 114 has a two-stage pushing structure of half-pressing and full-pressing. As an example, when the release switch 114 is half-pressed, the imaging control unit 40 performs automatic focus adjustment and automatic exposure adjustment, and when fully pressed, the imaging unit 20 captures a subject image.
[0054]
The function setting unit 116 is, for example, a rotary mode dial or a cross key, and includes “file format”, “special effect”, “print”, “decision / save”, “display switching”, “still image shooting”. , “Movie shooting” and the like are accepted. The zoom switch 118 receives the setting of the zoom magnification of the subject image acquired by the imaging unit 20. The function setting unit 116 executes the function of the imaging setting acquisition unit 160.
[0055]
The main operation of the above configuration is as follows. First, the power switch 112 is pressed, and power is supplied to each part of the digital camera 12. The main CPU 62 reads the state of the function setting unit 116 to determine whether the digital camera 12 is in the shooting mode or the playback mode.
[0056]
When the digital camera 12 is in the shooting mode, the main CPU 62 monitors the half-pressed state of the release switch 114. When the half-pressed state of the release switch 114 is detected, the imaging system CPU 50 obtains photometry data and distance measurement data from the photometry sensor 54 and the distance measurement sensor 52, respectively. The imaging control unit 40 adjusts the focus, aperture, and the like of the imaging unit 20 based on the photometry data and the distance measurement data obtained by the imaging system CPU 50. When the adjustment is completed, the LCD monitor displays characters such as “standby” to inform the user accordingly.
[0057]
Subsequently, the main CPU 62 monitors the fully pressed state of the release switch 114. When the fully depressed state of the release switch 114 is detected, the shutter 26 is closed after a predetermined shutter time, and the accumulated charge of the CCD 30 is swept out to the imaging signal processing unit 32. Digital image data generated as a result of processing by the imaging signal processing unit 32 is output to the bus 82. The digital image data is temporarily stored in the main memory 68, then processed by the YC processing unit 70 and the compression / decompression processing unit 78, and recorded in the option device 76 via the option device control unit 74. The captured image based on the recorded digital image data is displayed on the LCD monitor 102 for a while in a frozen state, and the user can confirm the captured image. This completes a series of shooting operations.
[0058]
On the other hand, when the digital camera 12 is in the playback mode, the main CPU 62 reads out the photographed image taken from the main memory 68, the nonvolatile memory 66, and / or the option device 76, and displays it on the LCD monitor 102 of the display unit 100. .
[0059]
In this state, when the user instructs “forward” and “reverse” in the function setting unit 116, the main CPU 62 displays other captured images stored in the main memory 68, the nonvolatile memory 66, and / or the option device 76. This is read and displayed on the LCD monitor 102 of the display unit 100.
[0060]
As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. Various modifications or improvements can be added to the above embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.
[0061]
【The invention's effect】
As is apparent from the above description, according to the present invention, it is possible to provide an imaging apparatus with less mixing of drive sound of the imaging apparatus in the moving image imaging setting.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating an example of a functional configuration characteristic of an imaging apparatus.
FIG. 2 is a flowchart showing the operation of the imaging apparatus 10;
FIG. 3 is a diagram illustrating an example of control conditions stored in a control condition storage unit 170. FIG.
4 is a diagram illustrating a hardware configuration of a digital camera 12 that is an example of an imaging apparatus 10. FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 Imaging device 12 Digital camera 20 Imaging part 22 Optical part 24 Aperture 30 CCD
150 Control Unit 160 Imaging Setting Acquisition Unit 170 Control Condition Storage Unit

Claims (7)

An imaging device that captures an image,
An imaging unit that captures a subject image;
A moving unit that moves when the imaging unit captures the subject image;
A first control condition for controlling the moving unit is stored in association with a moving image capturing setting that causes the imaging unit to capture the subject image as a moving image, and a still image that causes the imaging unit to capture the subject image as a still image in association with the imaging setting, said second control condition for controlling the moving unit to store, furthermore, in association with the imaging preparation setting the a ready video imaging setting or the still image capturing settings, the mobile and control condition storing unit that stores a third control condition for controlling the parts,
An imaging setting acquisition unit that acquires imaging instruction information indicating one of the moving image capturing settings, before SL still image capturing configuration, and the imaging preparation setting,
Wherein said control condition storing unit in association with the imaging instruction information the imaging setting acquisition unit has acquired is storing the first control condition, before Symbol second control condition, and the third control condition An imaging apparatus comprising: a control unit that controls the moving unit based on any of the above. The control condition storage unit associates the first control condition, which is less frequently moved than the second control condition stored in association with the still image capturing setting, with the moving image capturing setting. The imaging device according to claim 1, wherein the imaging device is stored. The moving unit is an aperture that adjusts an exposure amount by moving when the imaging unit captures the subject image.
The control condition storage unit associates the first control condition, which is less frequently moved than the second control condition stored in association with the still image capturing setting, with the moving image capturing setting. The imaging device according to claim 1 for storing.   The control condition storage unit associates, with the imaging preparation setting, the third control condition that is less frequently moved than the second control condition stored in association with the still image imaging setting. Store
The imaging device according to claim 1.   The moving unit is an aperture that adjusts an exposure amount by moving when the imaging unit captures the subject image.
  The control condition storage unit associates the third control condition, which is less frequently moved than the second control condition stored in association with the still image capturing setting, with the imaging preparation setting. Store
  The imaging device according to claim 1.   The imaging setting acquisition unit acquires the imaging instruction information indicating the imaging preparation setting before the release switch is pressed,
  The control unit stores the third control stored in the control condition storage unit in association with the imaging instruction information indicating the imaging preparation setting acquired by the imaging setting acquisition unit before the release switch is pressed. Controlling the moving unit based on conditions,
  The imaging setting acquisition unit acquires the imaging instruction information indicating either the moving image imaging setting or the still image imaging setting after the release switch is pressed,
  The control unit is associated with the imaging instruction information indicating either the moving image imaging setting or the still image imaging setting acquired by the imaging setting acquisition unit after the release switch is pressed. The moving unit is controlled based on either the first control condition or the second control condition stored in the control condition storage unit.
The imaging device according to claim 1.   The moving unit is a single aperture that adjusts an exposure amount by moving when the imaging unit captures the subject image.
  The imaging unit is one CCD that accumulates electric charge according to the amount of light that has passed through the diaphragm.
The imaging device according to claim 1.

Images