JP2019041203A - Imaging apparatus, control method, and program - Google Patents

Abstract

To confirm the activation state of an imaging apparatus even when first and second electronic viewfinders are not used.SOLUTION: An imaging apparatus includes a first display unit having a first electronic viewfinder and first detection means for detecting an object approaching the first electronic viewfinder, a second display unit having a second electronic viewfinder and second detection means for detecting an object approaching the second electronic viewfinder, and control means for operating the second electronic viewfinder in a display state until a predetermined time has elapsed when the first electronic viewfinder is in the non-displayed state, the second electronic viewfinder is in the display state, and a distance between the first detection means and the object is equal to or greater than a first threshold value, in a case in which a distance between the second detection means and the object becomes equal to or more than a second threshold value.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an imaging apparatus, a control method thereof, and a program related thereto.

  Patent Document 1 describes an imaging apparatus having an electronic viewfinder for a user to check an image, a large image display monitor for improving the visibility of the image, and an eyepiece detection unit of the electronic viewfinder. Yes. When the eyepiece detection unit detects the eyepiece of the user, the imaging apparatus drives the electronic viewfinder and stops driving the large image display monitor. When the eyepiece detection unit does not detect the user's eyepiece, the imaging apparatus stops driving the electronic viewfinder and drives the large image display monitor.

  In Patent Document 2, an electronic viewfinder, a movable liquid crystal monitor, an eyepiece detecting unit, and an image displayed on the electronic viewfinder even when the eyepiece detecting unit detects an eyepiece when the movable liquid crystal monitor is in a non-storage state. An image pickup apparatus having control means for preventing it from being described is described.

Japanese Patent Laid-Open No. 10-4509 JP 2011-71971 A

  However, when the driving of the electronic viewfinder is stopped, it is difficult for the user to misunderstand that the connection state of the electronic viewfinder is bad or to confirm the activation state of the imaging apparatus from a remote position. Furthermore, Patent Documents 1 and 2 do not describe a method for controlling an imaging apparatus having two electronic viewfinders.

  Accordingly, an object of the present invention is to make it possible to confirm the activation state of an imaging apparatus even when the first and second electronic viewfinders are not used.

  An imaging apparatus according to the present invention includes a first display unit having a first electronic viewfinder and first detection means for detecting an object approaching the first electronic viewfinder, and a second electronic view. A second display unit having a finder and a second detection means for detecting an object approaching the second electronic viewfinder, and the first electronic viewfinder is in a non-display state, When the electronic viewfinder is in the display state and the distance between the first detection means and the object is equal to or greater than a first threshold, the distance between the second detection means and the object is a second value. A control unit configured to operate the second electronic viewfinder in a display state until a predetermined time elapses when the threshold value is exceeded.

  The control method according to the present invention includes a first display unit having a first electronic viewfinder and first detection means for detecting an object approaching the first electronic viewfinder, and a second electronic view. An image pickup apparatus control method comprising: a finder; and a second display unit having a second detection unit that detects an object approaching the second electronic viewfinder, wherein the first electronic viewfinder is Bringing the second electronic viewfinder into a display state and making the second electronic viewfinder in a display state; making the first electronic viewfinder in a non-display state; and wherein the first electronic viewfinder is in a non-display state; When the second electronic viewfinder is in a display state and the distance between the first detection means and the object is equal to or greater than a first threshold, the second detection means and the object If the distance between becomes equal to or higher than the second threshold includes a step of so as to operate the second electronic viewfinder in a display state until a predetermined time elapses.

  A program according to the present invention includes a computer, a first display unit having a first electronic viewfinder, and first detection means for detecting an object approaching the first electronic viewfinder; A second display unit having an electronic viewfinder and a second detection means for detecting an object approaching the second electronic viewfinder; the first electronic viewfinder is in a non-display state; When the second electronic viewfinder is in the display state and the distance between the first detection means and the object is equal to or greater than a first threshold, the distance between the second detection means and the object is This program is for causing the second electronic viewfinder to function as a control unit that operates in a display state until a predetermined time elapses when a threshold value of 2 or more is reached.

  According to the present invention, the activation state of the imaging apparatus can be confirmed even when the first and second electronic viewfinders are not used.

FIG. 2 is a diagram for explaining components of the imaging apparatus 100 according to the first embodiment. It is a figure for demonstrating the positional relationship of an electronic viewfinder and an eyepiece sensor. 10 is a flowchart for explaining an operation example of the imaging apparatus 100. It is a figure for demonstrating the threshold value of a proximity distance.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the present invention is not limited to the following embodiments.

[Embodiment 1]
FIG. 1 is a block diagram for explaining components of the imaging apparatus 100 according to the first embodiment.

  As shown in FIG. 1, the imaging apparatus 100 includes an imaging unit 101, a digital signal processing unit 102, an operation unit 103, a timer unit 104, a power switch unit 105, an EVF control unit 106, a system control unit 107, a memory unit 108, 1 display portion 109 and second display portion 112 are provided. The imaging apparatus 100 further includes a power source (such as a battery) for operating the imaging apparatus 100. The first display unit 109 and the second display unit 112 are removable from the imaging device 100, for example. The first display unit 109 is a display device connected to the first connection unit of the imaging device 100 without a cable. The second display unit 112 is connected to the second connection unit of the imaging apparatus 100 via a cable.

  The first display unit 109 includes an EVF 110 and an eyepiece sensor unit 111, and functions as an EVF device that displays captured image data or reproduced image data from the imaging device 100. The eye sensor 111 is provided corresponding to the EVF 110. Electric power for operating the first display unit 109 is supplied from a power supply (battery or the like) of the imaging apparatus 100. The EVF 110 has an eyepiece, and displays captured image data or reproduced image data. The user can confirm an image displayed on the EVF 110 by observing the eyepiece of the EVF 110. As shown in FIG. 2A, the eyepiece sensor unit 111 is installed in the vicinity of the EVF 110, and detects the voltage according to the distance between the eyepiece sensor unit 111 and an object (including a user), thereby the EVF 110. It is possible to detect the eyepiece of the user with respect to the eyepiece.

  The EVF 110 is an electronic viewfinder having a display panel (for example, an organic EL display panel or a liquid crystal display panel) that displays captured image data or reproduced image data from the imaging apparatus 100. The eyepiece sensor unit 111 functions as a sensor that detects an object (including a user) approaching the EVF 110. The eye sensor 111 includes an infrared light emitting element and a light receiving element. The infrared light emitting element irradiates a predetermined amount of infrared light from the infrared light emitting lens window. The infrared light is reflected by objects (including the user). The light receiving element condenses the reflected and dispersed infrared light by the light receiving lens window, photoelectrically converts it, and outputs a voltage. The eye sensor 111 outputs the voltage of the light receiving element to the system controller 107. The system control unit 107 calculates an eyepiece distance of the eyepiece sensor unit 111 (corresponding to a distance between the eyepiece sensor unit 111 and an object (including a user)) based on the output voltage of the eyepiece sensor unit 111. The system control unit 107 compares the eyepiece distance of the eyepiece sensor unit 111 with the threshold Th.

  The second display unit 112 includes an EVF 113 and an eye sensor unit 114, and functions as an EVF device that displays captured image data or reproduced image data from the imaging device 100. The eye sensor unit 114 is provided corresponding to the EVF 113. Electric power for operating the second display unit 112 is supplied from a power source (battery or the like) of the imaging apparatus 100. The EVF 113 has an eyepiece, and displays captured image data or reproduced image data. The user can confirm an image displayed on the EVF 113 by observing the eyepiece of the EVF 113. As shown in FIG. 2B, the eyepiece sensor unit 114 is installed in the vicinity of the EVF 113, and detects the voltage according to the distance between the eyepiece sensor unit 114 and the object (including the user), thereby the EVF 113. It is possible to detect the eyepiece of the user with respect to the eyepiece.

  The EVF 113 is an electronic viewfinder having a display panel (for example, an organic EL display panel or a liquid crystal display panel) that displays captured image data or reproduced image data from the imaging apparatus 100. The eyepiece sensor unit 114 functions as a sensor that detects an object (including a user) approaching the EVF 113. The eyepiece sensor unit 114 includes an infrared light emitting element and a light receiving element. The infrared light emitting element irradiates a predetermined amount of infrared light from the infrared light emitting lens window. The infrared light is reflected by objects (including the user). The light receiving element condenses the reflected and dispersed infrared light by the light receiving lens window, photoelectrically converts it, and outputs a voltage. The eyepiece sensor unit 114 outputs the voltage of the light receiving element to the system control unit 107. The system control unit 107 calculates the eyepiece distance of the eyepiece sensor unit 114 (corresponding to the distance between the eyepiece sensor unit 114 and the object (including the user)) based on the output voltage of the eyepiece sensor unit 114. The system control unit 107 compares the eyepiece distance of the eyepiece sensor unit 114 with the threshold Th.

  The imaging unit 101 includes an imaging device that converts an optical image into an electrical signal, and an A / D conversion unit that converts an electrical signal generated by the imaging device into digital data, and generates digital data. The digital signal processing unit 102 generates image data by performing predetermined image processing (pixel interpolation, resizing processing, or color conversion processing) on the digital data generated by the imaging unit 101. In addition, the digital signal processing unit 102 performs predetermined calculation processing using the digital data generated by the imaging unit 101, and supplies the calculation result obtained by the predetermined calculation processing to the system control unit 107. The system control unit 107 performs exposure control and distance measurement control based on the calculation result supplied from the digital signal processing unit 102. As a result, the imaging apparatus 100 performs TTL (through the lens) AF (autofocus) processing, AE (automatic exposure) processing, and EF (flash pre-emission) processing.

  The operation unit 103 includes a plurality of buttons such as a menu button, up / down / left / right four-way buttons, and a SET button. When the menu button is pressed, various settable menu screens are displayed on the first display unit 109 and the second display unit 112. The user can select items on the menu screen displayed on the first display unit 109 and the second display unit 112 by using the four-way buttons up, down, left, and right, and can determine using the SET button. Note that the operation unit 103 may be a touch panel. The touch panel may be any one of various types of touch panels such as a resistive film method, a capacitance method, a surface acoustic wave method, an infrared method, an electromagnetic induction method, an image recognition method, and an optical sensor method.

  The system control unit 107 outputs information indicating whether or not the eyepiece distance of the eyepiece sensor unit 111 is less than the threshold value Th to the timer unit 104. The timer unit 104 determines the time when the eyepiece distance of the eyepiece sensor unit 111 is equal to or greater than the threshold value Th based on the information indicating whether or not the eyepiece distance of the eyepiece sensor unit 111 is less than the threshold value Th. Measure as detection time. Then, the timer unit 104 outputs the measured eyepiece non-detection time of the eyepiece sensor unit 111 to the system control unit 107.

  Similarly, the system control unit 107 outputs information indicating whether or not the eyepiece distance of the eyepiece sensor unit 114 is less than the threshold value Th to the timer unit 104. The timer unit 104 determines the time during which the eyepiece distance of the eyepiece sensor unit 114 is equal to or greater than the threshold value Th based on the information indicating whether or not the eyepiece distance of the eyepiece sensor unit 114 is less than the threshold value Th. Measure as detection time. Then, the timer unit 104 outputs the measured eyepiece non-detection time of the eyepiece sensor unit 114 to the system control unit 107.

  The power switch unit 105 detects whether the power switch unit 105 is turned on and outputs the detection result to the system control unit 107. The power switch unit 105 includes a mechanical switch, for example.

  The system control unit 107 outputs information for turning on / off each of the EVF 110 and the EVF 113 and the brightness setting values of the EVF 110 and the EVF 113 to the EVF control unit 106. The EVF control unit 106 controls the EVF 110 based on information for turning on or off the EVF 110 and the brightness setting value of the EVF 110. Similarly, the EVF control unit 106 controls the EVF 113 based on information for turning on or off the EVF 113 and the brightness setting value of the EVF 113.

  The system control unit 107 includes a memory and a processor. The memory stores a program for controlling each component of the imaging device 100, the first display unit 109, and the second display unit 112. The processor controls each component of the imaging device 100, the first display unit 109, and the second display unit 112 by executing a program stored in the memory.

  When the eyepiece no-detection time of the eyepiece sensor unit 111 is 30 seconds or more, the system control unit 107 reads out the low luminance setting value from the memory unit 108, and performs EVF control using the low luminance setting value as the luminance setting value of the EVF 110. To the unit 106. Further, the system control unit 107 outputs information for turning off the EVF 110 to the EVF control unit 106 when the eyepiece no-detection time of the eyepiece sensor unit 111 is 300 seconds or longer.

  In addition, when the eyepiece distance of the eyepiece sensor unit 111 is less than the threshold Th, the system control unit 107 resets the eyepiece non-detection time of the eyepiece sensor unit 111 measured by the timer unit 104 and performs normal operation from the memory unit 108. Read the brightness setting value. Then, the system control unit 107 outputs information for lighting the EVF 110 with the normal luminance setting value to the EVF control unit 106.

  Similarly, the system control unit 107 reads out the low luminance setting value from the memory unit 108 when the eyepiece non-detection time of the eyepiece sensor unit 114 is 30 seconds or more, and uses the low luminance setting value as the luminance setting value of the EVF 113. To the EVF control unit 106. Further, the system control unit 107 outputs information for turning off the EVF 113 to the EVF control unit 106 when the eyepiece non-detection time of the eyepiece sensor unit 114 is 300 seconds or longer.

  Further, when the eyepiece distance of the eyepiece sensor unit 114 is less than the threshold Th, the system control unit 107 resets the eyepiece non-detection time of the eyepiece sensor unit 114 measured by the timer unit 104, Read the brightness setting value. Then, the system control unit 107 outputs information for lighting the EVF 113 at the normal luminance setting value to the EVF control unit 106.

  The memory unit 108 is, for example, a flash memory, and stores a normal luminance setting value and a low luminance setting value. The normal brightness setting value is a brightness setting value when the EVF 110 or the EVF 113 is normally turned on. The low luminance setting value is a luminance setting value for reducing the luminance of the EVF 110 or the EVF 113 when the ocular non-detection time of the eye sensor 111 or 114 is 30 seconds or more. The low luminance setting value is a luminance setting value of the EVF 110 or the EVF 113 that allows the activation state of the imaging apparatus 100 to be recognized from a distance when the user is not using the EVF 110 and the EVF 113. For example, the low luminance setting value is about half as bright as the normal luminance setting value.

  When the user looks into the EVF 110, the EVF 110 lights up with normal luminance. When the user does not look into the EVF 110, the EVF 110 is turned on or off with low brightness according to the eyepiece non-detection time of the eyepiece sensor unit 111.

  Similarly, when the user looks into the EVF 113, the EVF 113 lights up with normal luminance. When the user does not look into the EVF 113, the EVF 113 is turned on or off with low brightness according to the eyepiece non-detection time of the eyepiece sensor unit 114.

  FIG. 3 is a flowchart for explaining an operation example of the imaging apparatus 100. Hereinafter, the luminance reduction control method and the extinction control method of the EVF 110 and the EVF 113 of the imaging apparatus 100 will be described.

  When the power switch unit 105 is turned on, the system control unit 107 activates the imaging device 100 in step S301. In step S302, the system control unit 107 reads the normal luminance setting value from the memory unit 108, and outputs the normal luminance setting value to the EVF control unit 106 as the luminance setting values of the EVF 110 and the EVF 113. The EVF control unit 106 lights up the EVF 110 and the EVF 113 with normal luminance based on the normal luminance set value. As described above, when the power switch unit 105 is turned on (power-on state), the system control unit 107 puts the EVF 110 and the EVF 113 into the display state. The EVF control unit 106 lights both the EVF 110 and the EVF 113 with normal luminance. However, both the EVF 110 and the EVF 113 may light with low luminance, or one of the EVF 110 and the EVF 113 may be turned on.

  In step S303, the system control unit 107 determines whether the eyepiece distance of the eyepiece sensor unit 111 is less than the threshold Th. FIG. 4 is a diagram for explaining an example of the threshold Th. The eyepiece distance is a distance between the eyepiece sensor unit 111 and an object (including a user), and is calculated based on the output voltage of the eyepiece sensor unit 111. The threshold value Th is, for example, 7.5 cm. The system control unit 107 proceeds to step S304 when the eyepiece distance of the eyepiece sensor unit 111 is not less than the threshold value Th, and proceeds to step S306 when the eyepiece distance of the eyepiece sensor unit 111 is less than the threshold value Th.

  In step S304, the system control unit 107 determines whether the eyepiece distance of the eyepiece sensor unit 114 is less than the threshold Th. The system control unit 107 returns to step S303 when the eyepiece distance of the eyepiece sensor unit 114 is not less than the threshold value Th, and proceeds to step S305 when the eyepiece distance of the eyepiece sensor unit 114 is less than the threshold value Th.

  In step S305, the system control unit 107 detects the eyepiece of the EVF 113 based on the determination in step S304, and does not detect the eyepiece of the EVF 110 based on the determination in step S303. Therefore, the EVF control unit 106 turns on the EVF 113 with normal luminance and turns off the EVF 110 under the control of the system control unit 107. The system control unit 107 resets the eyepiece non-detection time of the eyepiece sensor unit 114 measured by the timer unit 104, and proceeds to step S309. As described above, when the eyepiece distance of the eyepiece sensor unit 114 is less than the threshold value Th when the eyepiece distance of the eyepiece sensor unit 111 is greater than or equal to the threshold value Th, the system control unit 107 puts the EVF 110 into a non-display state. At the same time, the EVF 113 is displayed.

  In step S309, the system control unit 107 determines whether at least one of the eyepiece distance of the eyepiece sensor unit 111 and the eyepiece distance of the eyepiece sensor unit 114 is less than the threshold Th. When at least one of the eyepiece distances of the eyepiece sensor units 111 and 114 is less than the threshold Th (when the EVF 110 or the EVF 113 is in contact with the eye), the system control unit 107 returns to step S303. If both eyepiece distances of the eyepiece sensor units 111 and 114 are greater than or equal to the threshold Th (when both the EVF 110 and the EVF 113 are not in contact with the eye), the system control unit 107 proceeds to step S310.

  In step S <b> 310, the system control unit 107 inputs the non-eye detection time of the eye sensor unit 114 from the timer unit 104, and is the eye detection time of the eye sensor unit 114 equal to or longer than a first time (for example, 30 seconds)? Determine whether or not. If the eyepiece non-detection time of the eyepiece sensor unit 114 is equal to or longer than the first time (predetermined time), the system control unit 107 proceeds to step S311 and the eyepiece no detection time of the eyepiece sensor unit 114 is the first time. If not, the process returns to step S309.

  In step S <b> 311, the system control unit 107 reads the low luminance setting value from the memory unit 108 and outputs the low luminance setting value to the EVF control unit 106 as the luminance setting value of the EVF 113. The EVF control unit 106 lights the EVF 113 with low luminance based on the low luminance setting value.

  In step S <b> 312, the system control unit 107 inputs the eyepiece non-detection time of the eyepiece sensor unit 114 from the timer unit 104, and the second time (for example, the eyepiece no detection time of the eyepiece sensor unit 114 is longer than the first time) 300 seconds) or more. The system control unit 107 proceeds to step S313 when the ocular non-detection time of the eye sensor 114 is equal to or longer than the second time, and proceeds to step S313 when the ocular non-detection time of the eye sensor 114 is not equal to or longer than the second time. Returns to step S309.

  In step S 313, the EVF control unit 106 turns off the EVF 113 under the control of the system control unit 107.

  As described above, in step S309, when the eyepiece distance of the eyepiece sensor unit 111 is greater than or equal to the threshold Th and the eyepiece distance of the eyepiece sensor unit 114 is greater than or equal to the threshold Th, the system control unit 107 performs step S310. Proceed to In that case, the system control unit 107 maintains the brightness of the display panel of the EVF 113. Then, the system control unit 107 reduces the luminance of the display panel of the EVF 113 in step S311 after the first time has elapsed since the eyepiece sensor 114 has not detected the eyepiece. Then, the system control unit 107 puts the EVF 113 in a non-display state in step S313 after the second period of time elapses when the eyepiece sensor unit 114 does not detect the eyepiece.

  In step S314, the system control unit 107 determines whether at least one of the eyepiece distances of the eyepiece sensor units 111 and 114 is less than the threshold Th. If both the eyepiece distances of the eyepiece sensor units 111 and 114 are equal to or greater than the threshold Th (when both the EVF 110 and the EVF 113 are not in contact with each other), the system control unit 107 proceeds to step S328. When at least one of the eyepiece distances of the eyepiece sensor units 111 and 114 is less than the threshold Th (when the EVF 110 or the EVF 113 is in contact with the eye), the system control unit 107 returns to step S303.

  In step S306, the system control unit 107 determines whether the eyepiece distance of the eyepiece sensor unit 114 is less than the threshold value Th. The system control unit 107 proceeds to step S307 when the eyepiece distance of the eyepiece sensor unit 114 is not less than the threshold value Th, and proceeds to step S308 when the eyepiece distance of the eyepiece sensor unit 114 is less than the threshold value Th.

  In step S307, the system control unit 107 detects the eyepiece of the EVF 110 based on the determination in step S303, and does not detect the eyepiece of the EVF 113 based on the determination in step S306. Therefore, the EVF control unit 106 turns on the EVF 110 with normal luminance and turns off the EVF 113 under the control of the system control unit 107. The system control unit 107 resets the eyepiece non-detection time of the eyepiece sensor unit 111 measured by the timer unit 104, and proceeds to step S315. As described above, when the eyepiece distance of the eyepiece sensor unit 111 is less than the threshold value Th and the eyepiece distance of the eyepiece sensor unit 114 is greater than or equal to the threshold value Th, the system control unit 107 sets the EVF 110 in the display state. The EVF 113 is set in a non-display state.

  In step S315, the system control unit 107 determines whether at least one of the eyepiece distances of the eyepiece sensor units 111 and 114 is less than the threshold value Th. If both of the eyepiece distances of the eyepiece sensor units 111 and 114 are equal to or greater than the threshold Th (when both the EVF 110 and the EVF 113 are not in contact with each other), the system control unit 107 proceeds to step S316. When at least one of the eyepiece distances of the eyepiece sensor units 111 and 114 is less than the threshold Th (when the EVF 110 or the EVF 113 is in contact with the eye), the system control unit 107 returns to step S303.

  In step S316, the system control unit 107 inputs the eyeless detection time of the eyepiece sensor unit 111 from the timer unit 104, and is the eyepiece detection time of the eyepiece sensor unit 111 equal to or longer than a first time (for example, 30 seconds)? Determine whether or not. If the eyepiece no-detection time of the eyepiece sensor unit 111 is equal to or longer than the first time, the system control unit 107 proceeds to step S317, and if the eyepiece no-detection time of the eyepiece sensor unit 111 is not equal to or longer than the first time. Returns to step S315.

  In step S317, the system control unit 107 reads the low luminance setting value from the memory unit 108, and outputs the low luminance setting value to the EVF control unit 106 as the luminance setting value of the EVF 110. The EVF control unit 106 turns on the EVF 110 with low luminance based on the low luminance setting value.

  In step S318, the system control unit 107 inputs the ocular non-detection time of the eye sensor unit 111 from the timer unit 104, and a second time (for example, the eye non-detection time of the eye sensor unit 111 is longer than the first time (for example, 300 seconds) or more. If the eyepiece no-detection time of the eyepiece sensor unit 111 is equal to or longer than the second time, the system control unit 107 proceeds to step S319, and if the eyepiece no-detection time of the eyepiece sensor unit 111 is not equal to or longer than the second time. Returns to step S315.

  In step S319, the EVF control unit 106 turns off the EVF 110 under the control of the system control unit 107.

  As described above, in step S315, the system control unit 107 determines that the eyepiece distance of the eyepiece sensor unit 111 is equal to or greater than the threshold value Th and the eyepiece distance of the eyepiece sensor unit 114 is equal to or greater than the threshold value Th. Proceed to In that case, the system control unit 107 maintains the brightness of the display panel of the EVF 110. Then, the system control unit 107 reduces the brightness of the display panel of the EVF 110 in step S317 after the first period of time when the eyepiece sensor unit 111 has not detected the eyepiece. Then, the system control unit 107 puts the EVF 110 in a non-display state in step S319 after the second time has elapsed after the eyepiece no-detection time of the eyepiece sensor unit 111.

  In step S320, the system control unit 107 determines whether at least one of the eyepiece distances of the eyepiece sensor units 111 and 114 is less than the threshold value Th. If both the eyepiece distances of the eyepiece sensor units 111 and 114 are equal to or greater than the threshold Th (when both the EVF 110 and the EVF 113 are not in contact with each other), the system control unit 107 proceeds to step S328. When at least one of the eyepiece distances of the eyepiece sensor units 111 and 114 is less than the threshold Th (when the EVF 110 or the EVF 113 is in contact with the eye), the system control unit 107 returns to step S303.

  In step S308, the system control unit 107 detects the eyepieces of the EVF 110 and the EVF 113 based on the determinations in steps S303 and S306. Therefore, the EVF control unit 106 lights the EVF 110 and the EVF 113 with normal brightness under the control of the system control unit 107. The system control unit 107 resets the eyepiece non-detection time of the eyepiece sensor units 111 and 114 measured by the timer unit 104, and proceeds to step S321. As described above, when the eyepiece distance of the eyepiece sensor unit 111 is less than the threshold value Th and the eyepiece distance of the eyepiece sensor unit 114 is less than the threshold value Th, the system control unit 107 sets the EVF 110 and the EVF 113 to the display state. .

  In step S321, the system control unit 107 determines whether at least one of the eyepiece distances of the eyepiece sensor units 111 and 114 is less than the threshold value Th. If both of the eyepiece distances of the eyepiece sensor units 111 and 114 are greater than or equal to the threshold Th (when both the EVF 110 and the EVF 113 are not eyepieces), the system control unit 107 proceeds to step S322. When at least one of the eyepiece distances of the eyepiece sensor units 111 and 114 is less than the threshold Th (when the EVF 110 or the EVF 113 is in contact with the eye), the system control unit 107 returns to step S303.

  In step S322, the system control unit 107 detects that both the EVF 110 and the EVF 113 are not in contact with each other based on the determination in step S321. Therefore, under the control of the system control unit 107, the EVF control unit 106 prioritizes lighting of the second display unit 112 over lighting of the first display unit 109, and thus turns off the EVF 110 and maintains the lighting of the EVF 113. . Here, the first display unit 109 is built in the imaging device 100, and the second display unit 112 is detachable from the imaging device 100. Since the user intentionally connects the second display unit 112 to the imaging apparatus 100, the EVF control unit 106 needs to preferentially light the EVF 113 of the second display unit 112.

  In step S323, the system control unit 107 inputs the eyepiece non-detection time of the eyepiece sensor unit 114 from the timer unit 104, and is the eyepiece nondetection time of the eyepiece sensor unit 114 equal to or longer than a first time (for example, 30 seconds)? Determine whether or not. The system control unit 107 proceeds to step S324 when the ocular non-detection time of the eye sensor 114 is equal to or longer than the first time, and proceeds to step S324 when the ocular non-detection time of the eye sensor 114 is not equal to or longer than the first time. Returns to step S321.

  In step S324, the system control unit 107 reads the low luminance setting value from the memory unit 108, and outputs the low luminance setting value to the EVF control unit 106 as the luminance setting value of the EVF 113. The EVF control unit 106 lights the EVF 113 with low luminance based on the low luminance setting value.

  In step S325, the system control unit 107 inputs the eyepiece non-detection time of the eyepiece sensor unit 114 from the timer unit 104, and a second time (for example, the eyepiece nondetection time of the eyepiece sensor unit 114 is longer than the first time (for example, 300 seconds) or more. If the ocular no detection time of the eye sensor 114 is equal to or longer than the second time, the system control unit 107 proceeds to step S326, and if the ocular no detection time of the eye sensor 114 is not equal to or longer than the second time. Returns to step S321.

  In step S326, the EVF control unit 106 turns off the EVF 113 under the control of the system control unit 107.

  As described above, in step S321, the system control unit 107 determines that the eyepiece distance of the eyepiece sensor unit 111 is equal to or greater than the threshold value Th and the eyepiece distance of the eyepiece sensor unit 114 is equal to or greater than the threshold value Th. Proceed to In step S322, the system control unit 107 sets the EVF 110 in a non-display state and maintains the brightness of the display panel of the EVF 113. Then, the system control unit 107 reduces the brightness of the display panel of the EVF 113 in step S324 after the first period of time when the eyepiece sensor unit 114 has not detected the eyepiece. Then, the system control unit 107 puts the EVF 113 in a non-display state in step S326 after the second period of time elapses when the eyepiece sensor unit 114 does not detect the eyepiece.

  In step S327, the system control unit 107 determines whether at least one of the eyepiece distances of the eyepiece sensor units 111 and 114 is less than the threshold value Th. If both the eyepiece distances of the eyepiece sensor units 111 and 114 are equal to or greater than the threshold Th (when both the EVF 110 and the EVF 113 are not in contact with each other), the system control unit 107 proceeds to step S328. When at least one of the eyepiece distances of the eyepiece sensor units 111 and 114 is less than the threshold Th (when the EVF 110 or the EVF 113 is in contact with the eye), the system control unit 107 returns to step S303.

  In step S328, the system control unit 107 determines whether the power switch unit 105 has been turned off. When the power switch unit 105 is turned off, the system control unit 107 sets the imaging apparatus 100 in a power-off state (YES in step S328). If the power switch unit 105 is not turned off, the system control unit 107 returns to step S303 (NO in step S328).

  As described above, according to the first embodiment, the imaging apparatus 100 performs the luminance reduction control or the extinction control on the EVF 110 or the EVF 113 that was used last depending on the non-eyepiece detection time. Thereby, the imaging device 100 can prevent wasteful power consumption, burn-in, and life deterioration of the EVF 110 and the EVF 113. When the EVF 110 or the EVF 113 has an organic EL display panel, luminance deterioration of the EVF 110 or the EVF 113 can be suppressed. When the user does not use both EVF 110 and EVF 113, the brightness of EVF 110 or EVF 113 that was used last only decreases for a certain period of time. Thereby, the user can confirm the activation state of the imaging apparatus 100 even from a remote position.

[Embodiment 2]
The various functions, processes, or methods described in the first embodiment can also be realized by a personal computer, a microcomputer, a CPU (central processing unit), a processor, and the like using a program. Hereinafter, in the second embodiment, a personal computer, a microcomputer, a CPU (central processing unit), a processor, and the like are referred to as “computer X”. In the second embodiment, a program for controlling the computer X and realizing the various functions, processes, or methods described in the first embodiment is referred to as “program Y”.

  The various functions, processes, or methods described in the first embodiment are realized by the computer X executing the program Y. In this case, the program Y is supplied to the computer X via a computer-readable storage medium. The computer-readable storage medium according to the second embodiment includes at least one of a hard disk device, a magnetic storage device, an optical storage device, a magneto-optical storage device, a memory card, a volatile memory, and a nonvolatile memory. The computer-readable storage medium in Embodiment 2 is a non-transitory storage medium.

  The embodiment of the present invention is not limited to the above-described first or second embodiment. Embodiments 1 and 2 that are changed or modified without departing from the gist of the invention are also included in the embodiments of the present invention.

DESCRIPTION OF SYMBOLS 100 Imaging device, 101 Imaging part, 102 Digital signal processing part, 103 Operation part, 104 Timer part, 105 Power switch part, 106 EVF control part, 107 System control part, 108 Memory part, 109 1st display part, 110 EVF (Electronic viewfinder), 111 eyepiece sensor unit, 112 second display unit, 113 EVF (electronic viewfinder), 114 eyepiece sensor unit

Claims (15)

A first display unit having a first electronic viewfinder and first detection means for detecting an object approaching the first electronic viewfinder;
A second display unit comprising: a second electronic viewfinder; and second detection means for detecting an object approaching the second electronic viewfinder;
When the first electronic viewfinder is in a non-display state, the second electronic viewfinder is in a display state, and the distance between the first detection means and the object is greater than or equal to a first threshold value Control that causes the second electronic viewfinder to operate in a display state until a predetermined time elapses when the distance between the second detection means and the object exceeds a second threshold value. And an imaging device.   The control means is configured such that the first electronic viewfinder is in a non-display state, the second electronic viewfinder is in a display state, and the distance between the first detection means and the object is the first electronic viewfinder. If the distance between the second detection means and the object is equal to or greater than the second threshold when the threshold is equal to or greater than the threshold, the luminance of the display panel of the second electronic viewfinder is set to the predetermined time. The imaging apparatus according to claim 1, wherein control is performed until the time elapses.   The control means is configured such that the first electronic viewfinder is in a non-display state, the second electronic viewfinder is in a display state, and the distance between the first detection means and the object is the first electronic viewfinder. If the distance between the second detection means and the object is equal to or greater than the second threshold when the threshold is equal to or greater than the threshold, the second electronic viewfinder is used after the predetermined time has elapsed. The imaging apparatus according to claim 1, wherein control for reducing the luminance of the display panel is performed.   The control means is configured such that the first electronic viewfinder is in a non-display state, the second electronic viewfinder is in a display state, and the distance between the first detection means and the object is the first electronic viewfinder. When the distance between the second detection means and the object is equal to or greater than the second threshold when the threshold is equal to or greater than the threshold, the second time is exceeded after a time longer than the predetermined time. The imaging apparatus according to claim 1, wherein the electronic viewfinder is in a non-display state.   The control means is configured such that the first electronic viewfinder is in a display state, the second electronic viewfinder is in a non-display state, and the distance between the second detection means and the object is the second electronic viewfinder. If the distance between the first detection means and the object is equal to or greater than the first threshold when the threshold is equal to or greater than the threshold, the first electronic viewfinder is displayed until the predetermined time has elapsed. The imaging apparatus according to claim 1, wherein the imaging apparatus is operated in a state.   The control means is configured such that the first electronic viewfinder is in a display state, the second electronic viewfinder is in a non-display state, and the distance between the second detection means and the object is the second electronic viewfinder. If the distance between the first detection means and the object is equal to or greater than the first threshold when the threshold is equal to or greater than the threshold, the luminance of the display panel of the first electronic viewfinder is set to the predetermined time. 6. The imaging apparatus according to claim 5, wherein control is performed until the time elapses.   The control means is configured such that the first electronic viewfinder is in a display state, the second electronic viewfinder is in a non-display state, and the distance between the second detection means and the object is the second electronic viewfinder. If the distance between the first detection means and the object is equal to or greater than the first threshold when the threshold is equal to or greater than the threshold, the first electronic viewfinder is used after the predetermined time has elapsed. The imaging apparatus according to claim 5, wherein control for reducing the luminance of the display panel is performed.   The control means is configured such that the first electronic viewfinder is in a display state, the second electronic viewfinder is in a non-display state, and the distance between the second detection means and the object is the second electronic viewfinder. When the distance between the first detection means and the object is equal to or greater than the first threshold when the threshold is equal to or greater than the threshold, the first time is exceeded after a time longer than the predetermined time. The imaging apparatus according to claim 5, wherein the electronic viewfinder is in a non-display state.   When the first electronic viewfinder is in a display state and the second electronic viewfinder is in a display state, the control means is configured such that a distance between the first detection means and an object is the first electronic viewfinder. When the distance between the second detection means and the object is equal to or greater than the second threshold, the first electronic viewfinder is set in a non-display state and the second The imaging apparatus according to claim 1, wherein the electronic viewfinder is operated in a display state until the predetermined time elapses.   When the first electronic viewfinder is in a display state and the second electronic viewfinder is in a display state, the control means is configured such that a distance between the first detection means and an object is the first electronic viewfinder. When the distance between the second detection means and the object is equal to or greater than the second threshold, the brightness of the display panel of the second electronic viewfinder is set to the predetermined time. The imaging apparatus according to claim 9, wherein control is performed until the time elapses.   When the first electronic viewfinder is in a display state and the second electronic viewfinder is in a display state, the control means is configured such that a distance between the first detection means and an object is the first electronic viewfinder. And when the distance between the second detection means and the object is greater than or equal to the second threshold, the second electronic viewfinder is displayed after the predetermined time has elapsed. The image pickup apparatus according to claim 9, wherein control for reducing the brightness of the panel is performed.   When the first electronic viewfinder is in a display state and the second electronic viewfinder is in a display state, the control means is configured such that a distance between the first detection means and an object is the first electronic viewfinder. And when the distance between the second detection means and the object is greater than or equal to the second threshold, the second electrons are passed after a time longer than the predetermined time. The imaging apparatus according to claim 9, wherein the viewfinder is in a non-display state.   13. The control unit according to claim 1, wherein the control unit sets the first electronic viewfinder and the second electronic viewfinder to a display state when the imaging apparatus is turned on. The imaging apparatus of Claim 1. A first display unit having a first electronic viewfinder and first detection means for detecting an object approaching the first electronic viewfinder; a second electronic viewfinder; and the second electronic And a second display unit having a second detection means for detecting an object approaching the viewfinder,
Placing the first electronic viewfinder in a display state and placing the second electronic viewfinder in a display state;
Disabling the first electronic viewfinder,
When the first electronic viewfinder is in a non-display state, the second electronic viewfinder is in a display state, and the distance between the first detection means and the object is greater than or equal to a first threshold value When the distance between the second detection means and the object is equal to or greater than a second threshold, the second electronic viewfinder is operated in a display state until a predetermined time elapses. The control method characterized by having. Computer
A first display unit having a first electronic viewfinder and first detection means for detecting an object approaching the first electronic viewfinder;
A second display unit comprising: a second electronic viewfinder; and second detection means for detecting an object approaching the second electronic viewfinder;
When the first electronic viewfinder is in a non-display state, the second electronic viewfinder is in a display state, and the distance between the first detection means and the object is greater than or equal to a first threshold value Control that causes the second electronic viewfinder to operate in a display state until a predetermined time elapses when the distance between the second detection means and the object exceeds a second threshold value. Program to function as a means.

Images